/*==LICENSE==*
CyanWorlds.com Engine - MMOG client, server and tools
Copyright (C) 2011 Cyan Worlds, Inc.
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
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along with this program. If not, see .
Additional permissions under GNU GPL version 3 section 7
If you modify this Program, or any covered work, by linking or
combining it with any of RAD Game Tools Bink SDK, Autodesk 3ds Max SDK,
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containing parts covered by the terms of the Bink SDK EULA, 3ds Max EULA,
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*==LICENSE==*/
#ifndef hsBiExpander_inc
#define hsBiExpander_inc
#include "hsMemory.h"
#include "hsTemplates.h"
///////////////////////////////////////////////////////////////////////////////
////////////// Expander ///////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////
template class hsExpander {
private:
int32_t fNumPost;
int32_t fNumPostAlloc;
T* fArray;
int32_t fGrowBy; // default = 0, to double
int32_t fMinSize; // default = 1, min == 1
int32_t fCurrent;
hsExpander(const hsExpander& x); // make it passed as ref or pointer
void IExpand(int newSize);
public:
enum { kMissingIndex = -1 };
hsExpander(int32_t minSize = 1, int32_t growBy = 0);
virtual ~hsExpander();
hsExpander& operator=(const hsExpander&orig) { return Copy(orig); }
hsExpander& Copy(const hsExpander& orig);
void SetCount(int cnt) { if( cnt >= fNumPostAlloc )IExpand(cnt); fNumPost = cnt; }
int32_t GetCount() const { return fNumPost; }
bool Empty() const { return GetCount() == 0; }
const T& Get(int32_t index) const;
int32_t Get(int32_t index, int32_t count, T data[]) const;
int32_t Find(const T&) const; // returns kMissingIndex if not found
void SetArray(T* a, int32_t cnt);
T* GetArray() { return fArray; }
T& operator[]( int32_t index );
int32_t Append(const T&); // returns t's index
T* Append();
int32_t Push(const T& t) { return Append(t); }
T* Push() { return Append(); }
T* Top() { return fNumPost ? fArray + fNumPost-1 : nil; }
int32_t Pop(T* t); // returns count of remaining
int32_t Pop();
void Reset(); // clears out everything
T& Head() { return fArray[0]; }
T& Tail() { return fArray[fNumPost-1]; }
T& Current() { return fArray[fCurrent]; }
void First();
void Last();
void Plus() { ++fCurrent; }
bool More() { return (fCurrent < fNumPost); }
};
template
hsExpander& hsExpander::Copy(const hsExpander& orig)
{
SetCount(orig.GetCount());
int i;
for( i = 0; i < GetCount(); i++ )
fArray[i] = orig.fArray[i];
return *this;
}
template
void hsExpander::SetArray(T* a, int32_t cnt)
{
delete [] fArray;
if( a )
fArray = a;
fNumPost = fNumPostAlloc = cnt;
}
template
void hsExpander::IExpand(int newSize)
{
int32_t newPostAlloc = fNumPostAlloc;
if( !newPostAlloc )
newPostAlloc++;
while( newPostAlloc <= newSize )
newPostAlloc = fGrowBy ? newPostAlloc + fGrowBy : newPostAlloc << 1;
T* newArray = new T[newPostAlloc];
int i;
for( i = 0; i < fNumPost; i++ )
newArray[i] = fArray[i];
delete [] (fArray);
fArray = newArray;
fNumPostAlloc = newPostAlloc;
}
template
hsExpander::hsExpander(int32_t minSize, int32_t growBy)
{
hsThrowIfBadParam(minSize < 0);
hsThrowIfBadParam(growBy < 0);
fMinSize = minSize+1;
fGrowBy = growBy;
fArray = new T[fMinSize];
fNumPostAlloc = fMinSize;
fNumPost = 0;
}
template
hsExpander::~hsExpander()
{
delete [] fArray;
}
template
void hsExpander::First()
{
fCurrent = 0;
}
template
void hsExpander::Last()
{
fCurrent = fNumPost-1;
}
template
T& hsExpander::operator[]( int32_t index )
{
hsDebugCode(hsThrowIfBadParam((index < 0)||(index >= fNumPost));)
return fArray[index];
}
template
const T& hsExpander::Get( int32_t index ) const
{
hsDebugCode(hsThrowIfBadParam((index < 0)||(index >= fNumPost));)
return fArray[index];
}
template
int32_t hsExpander::Get(int32_t index, int32_t count, T data[]) const
{
if( count > 0 )
{ hsThrowIfNilParam(data);
hsThrowIfBadParam((index < 0)||(index >= fNumPost));
if (index + count > fNumPost)
count = fNumPost - index;
for (int i = 0; i < count; i++)
data[i] = fArray[i + index];
}
return count;
}
template
int32_t hsExpander::Find(const T& obj) const
{
for (int i = 0; i < fNumPost; i++)
if (fArray[i] == obj)
return i;
return kMissingIndex;
}
template
int32_t hsExpander::Append(const T& obj)
{
hsAssert(!(fNumPost >= fNumPostAlloc), "Must be less");
if( fNumPost == fNumPostAlloc-1 )
IExpand(fNumPostAlloc);
fArray[fNumPost] = obj;
return fNumPost++;
}
template
T* hsExpander::Append()
{
hsAssert(!(fNumPost >= fNumPostAlloc), "Must be less");
if( fNumPost == fNumPostAlloc-1 )
IExpand(fNumPostAlloc);
return fArray + fNumPost++;
}
template
int32_t hsExpander::Pop(T*t)
{
hsThrowIfBadParam(Empty());
--fNumPost;
if( t )
*t = fArray[fNumPost];
return GetCount();
}
template
int32_t hsExpander::Pop()
{
hsThrowIfBadParam(Empty());
--fNumPost;
return GetCount();
}
template
void hsExpander::Reset()
{
fNumPost = 0;
}
///////////////////////////////////////////////////////////////////////////////
////////////// BiExpander /////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////
template class hsBiExpander {
private:
int32_t fNumPre;
int32_t fNumPost;
int32_t fNumPreAlloc;
int32_t fNumPostAlloc;
T* fArray;
int32_t fGrowBy; // default = 0, to double
int32_t fMinSize; // default = 1, min == 1
int32_t fCurrent;
hsBiExpander& operator=(const hsBiExpander&); // don't allow assignment
hsBiExpander(const hsBiExpander&); // make it passed as ref or pointer
void IExpand(int newSize, bool towardEnd = true);
public:
enum { kMissingIndex = -1 };
hsBiExpander(int32_t minSize = 1, int32_t growBy = 0);
virtual ~hsBiExpander();
int32_t GetFirst() const { return -fNumPre; }
int32_t GetCount() const { return fNumPre + fNumPost; }
bool Empty() const { return GetCount() == 0; }
const T& Get(int32_t index) const;
int32_t Get(int32_t index, int32_t count, T data[]) const;
int32_t Find(const T&) const; // returns kMissingIndex if not found
void SetArray(T* a, int32_t cnt, int32_t numPre=0);
T** GetArray() { return fArray - fNumPre; }
T& operator[]( int32_t index );
T* Append(); // returns t's index
T* Push(); // returns t's index
int32_t Append(const T&); // returns t's index
int32_t Push(const T&); // returns t's index
int32_t Pop(T*t = nil) { return PopHead(t); } // returns count of remaining
int32_t PopHead(T*t = nil); // returns count of remaining
int32_t PopTail(T*t = nil); // returns count of remaining
void Reset(); // clears out everything
T& Head() { return fArray[-fNumPre]; }
T& Tail() { return fArray[fNumPost-1]; }
T& Current() { return fArray[fCurrent]; }
void First();
void Last();
void Plus() { ++fCurrent; }
void Minus() { --fCurrent; }
bool More() { return (fCurrent < fNumPost)&&(fCurrent >= -fNumPre); }
};
template
void hsBiExpander::SetArray(T* a, int32_t cnt, int32_t numPre)
{
if( !numPre )
Reset();
else
{
fNumPreAlloc = fNumPre = numPre;
fNumPostAlloc = fNumPost = cnt - numPre;
fArray = a + numPre;
}
}
template
void hsBiExpander::IExpand(int newSize, bool towardEnd)
{
int32_t newPreAlloc = fNumPreAlloc;
int32_t newPostAlloc = fNumPostAlloc;
if( towardEnd )
{
if( !newPostAlloc )
newPostAlloc++;
while( newPostAlloc <= newSize )
newPostAlloc = fGrowBy ? newPostAlloc + fGrowBy : newPostAlloc << 1;
}
else
{
if( !newPreAlloc )
newPreAlloc++;
while( newPreAlloc <= newSize )
newPreAlloc = fGrowBy ? newPreAlloc + fGrowBy : newPreAlloc << 1;
}
T* newArray = new T[newPreAlloc + newPostAlloc];
newArray += newPreAlloc;
int i;
for( i = -fNumPre; i < fNumPost; i++ )
newArray[i] = fArray[i];
// HSMemory::BlockMove(fArray-fNumPre, newArray-fNumPre,
// (fNumPre+fNumPost)*sizeof(*fArray));
delete [] (fArray-fNumPreAlloc);
fArray = newArray;
fNumPreAlloc = newPreAlloc;
fNumPostAlloc = newPostAlloc;
}
template
hsBiExpander::hsBiExpander(int32_t minSize, int32_t growBy)
{
hsThrowIfBadParam(minSize < 0);
hsThrowIfBadParam(growBy < 0);
fMinSize = minSize+1;
fGrowBy = growBy;
fArray = new T[fMinSize << 1];
fNumPreAlloc = fNumPostAlloc = fMinSize;
fArray += fNumPreAlloc;
fNumPre = fNumPost = 0;
}
template
hsBiExpander::~hsBiExpander()
{
delete [] (fArray - fNumPreAlloc);
}
template
void hsBiExpander::First()
{
fCurrent = -fNumPre;
}
template
void hsBiExpander::Last()
{
fCurrent = fNumPost-1;
}
template
T& hsBiExpander::operator[]( int32_t index )
{
hsDebugCode(hsThrowIfBadParam((index < -fNumPre)||(index >= fNumPost));)
return fArray[index];
}
template
const T& hsBiExpander::Get( int32_t index ) const
{
hsDebugCode(hsThrowIfBadParam((index < -fNumPre)||(index >= fNumPost));)
return fArray[index];
}
template
int32_t hsBiExpander::Get(int32_t index, int32_t count, T data[]) const
{
if( count > 0 )
{ hsThrowIfNilParam(data);
hsThrowIfBadParam((index < -fNumPre)||(index >= fNumPost));
if (index + count > fNumPost)
count = fNumPost - index;
for (int i = 0; i < count; i++)
data[i] = fArray[i + index];
}
return count;
}
template
int32_t hsBiExpander::Find(const T& obj) const
{
for (int i = -fNumPre; i < fNumPost; i++)
if (fArray[i] == obj)
return i;
return kMissingIndex;
}
template
T* hsBiExpander::Append()
{
hsAssert(!(fNumPost >= fNumPostAlloc), "Must be less");
if( fNumPost == fNumPostAlloc-1 )
IExpand(fNumPostAlloc, true);
return fArray + fNumPost++;
}
template
T* hsBiExpander::Push()
{
hsAssert(!(fNumPre >= fNumPreAlloc), "Must be less");
if( ++fNumPre == fNumPreAlloc )
IExpand(fNumPreAlloc, false);
return fArray - fNumPre;
}
template
int32_t hsBiExpander::Append(const T& obj)
{
hsAssert(!(fNumPost >= fNumPostAlloc), "Must be less");
if( fNumPost == fNumPostAlloc-1 )
IExpand(fNumPostAlloc, true);
fArray[fNumPost] = obj;
return fNumPost++;
}
template
int32_t hsBiExpander::Push(const T& obj)
{
hsAssert(!(fNumPre >= fNumPreAlloc), "Must be less");
if( ++fNumPre == fNumPreAlloc )
IExpand(fNumPreAlloc, false);
fArray[-fNumPre] = obj;
return -fNumPre;
}
template
int32_t hsBiExpander::PopHead(T*t)
{
hsThrowIfBadParam(Empty());
if( t )
*t = fArray[-fNumPre];
--fNumPre;
return GetCount();
}
template
int32_t hsBiExpander::PopTail(T*t)
{
hsThrowIfBadParam(Empty());
--fNumPost;
if( t )
*t = fArray[fNumPost];
return GetCount();
}
template
void hsBiExpander::Reset()
{
fNumPre = fNumPost = 0;
}
#endif // hsBiExpander_inc