mirror of
https://github.com/DrBeef/JKXR.git
synced 2024-11-29 23:42:38 +00:00
4597b03873
Opens in Android Studio but haven't even tried to build it yet (it won't.. I know that much!)
548 lines
14 KiB
C++
548 lines
14 KiB
C++
/*
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===========================================================================
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Copyright (C) 2000 - 2013, Raven Software, Inc.
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Copyright (C) 2001 - 2013, Activision, Inc.
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Copyright (C) 2013 - 2015, OpenJK contributors
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This file is part of the OpenJK source code.
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OpenJK is free software; you can redistribute it and/or modify it
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under the terms of the GNU General Public License version 2 as
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published by the Free Software Foundation.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, see <http://www.gnu.org/licenses/>.
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===========================================================================
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*/
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////////////////////////////////////////////////////////////////////////////////////////
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// RAVEN STANDARD TEMPLATE LIBRARY
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// (c) 2002 Activision
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//
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//
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// Grid
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// ----
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// There are two versions of the Grid class. Simply, they apply a discreet function
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// mapping from a n dimensional space to a linear aray.
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//
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//
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//
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//
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//
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//
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// NOTES:
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//
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//
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//
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////////////////////////////////////////////////////////////////////////////////////////
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#if !defined(RATL_GRID_VS_INC)
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#define RATL_GRID_VS_INC
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////////////////////////////////////////////////////////////////////////////////////////
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// Includes
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////////////////////////////////////////////////////////////////////////////////////////
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#if !defined(RATL_COMMON_INC)
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#include "ratl_common.h"
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#endif
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#if !defined(RATL_ARRAY_VS)
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#include "array_vs.h"
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#endif
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namespace ratl
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{
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////////////////////////////////////////////////////////////////////////////////////////
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// The 2D Grid Class
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////////////////////////////////////////////////////////////////////////////////////////
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template <class T, int XSIZE_MAX, int YSIZE_MAX>
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class grid2_vs : public ratl_base
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{
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public:
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////////////////////////////////////////////////////////////////////////////////////
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// Constructor
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////////////////////////////////////////////////////////////////////////////////////
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grid2_vs()
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{
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clear();
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}
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enum
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{
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RANGE_NULL = 12345,
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};
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////////////////////////////////////////////////////////////////////////////////////
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// Assignment Operator
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////////////////////////////////////////////////////////////////////////////////////
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grid2_vs& operator=(const grid2_vs& other)
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{
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mData = other.mData;
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for (int i=0; i<2; i++)
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{
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mSize[i] = other.mSize[i];
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mMins[i] = other.mMins[i];
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mMaxs[i] = other.mMaxs[i];
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mScale[i] = other.mScale[i];
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}
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return (*this);
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}
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void set_size(int xSize, int ySize)
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{
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if (xSize<XSIZE_MAX)
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{
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mSize[0] = xSize;
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}
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if (ySize<YSIZE_MAX)
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{
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mSize[1] = ySize;
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}
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}
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void snap_scale()
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{
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mScale[0] = (float)((int)(mScale[0]));
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mScale[1] = (float)((int)(mScale[1]));
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}
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void get_size(int& xSize, int& ySize)
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{
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xSize = mSize[0];
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ySize = mSize[1];
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Clear
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////////////////////////////////////////////////////////////////////////////////////
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void clear()
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{
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mSize[0] = XSIZE_MAX;
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mSize[1] = YSIZE_MAX;
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mData.clear();
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for (int i=0; i<2; i++)
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{
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mMins[i] = RANGE_NULL;
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mMaxs[i] = RANGE_NULL;
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mScale[i] = 0.0f;
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}
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Initialize The Entire Grid To A Value
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////////////////////////////////////////////////////////////////////////////////////
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void init(const T& val)
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{
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for (int i=0; i<(XSIZE_MAX*YSIZE_MAX); i++)
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{
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mData[i] = val;
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}
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Copy The Bounds Of Another Grid
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////////////////////////////////////////////////////////////////////////////////////
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void copy_bounds(const grid2_vs& other)
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{
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for (int i=0; i<2; i++)
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{
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mSize[i] = other.mSize[i];
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mMins[i] = other.mMins[i];
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mMaxs[i] = other.mMaxs[i];
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mScale[i] = other.mScale[i];
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}
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Accessor
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////////////////////////////////////////////////////////////////////////////////////
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T& get(const int x, const int y)
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{
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assert(x>=0 && y>=0 && x<mSize[0] && y<mSize[1]);
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return mData[(x + y*XSIZE_MAX)];
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Accessor
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////////////////////////////////////////////////////////////////////////////////////
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T& get(float x, float y)
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{
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assert(mScale[0]!=0.0f && mScale[1]!=0.0f);
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truncate_position_to_bounds(x, y);
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int xint = (int)( (x-mMins[0]) / mScale[0] );
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int yint = (int)( (y-mMins[1]) / mScale[1] );
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assert(xint>=0 && yint>=0 && xint<mSize[0] && yint<mSize[1]);
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return mData[(xint + yint*XSIZE_MAX)];
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Convert The Scaled Coordinates To A Grid Coordinate
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////////////////////////////////////////////////////////////////////////////////////
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void get_cell_coords(float x, float y, int& xint, int& yint)
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{
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assert(mScale[0]!=0.0f && mScale[1]!=0.0f);
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truncate_position_to_bounds(x, y);
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xint = (int)( (x-mMins[0]) / mScale[0] );
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yint = (int)( (y-mMins[1]) / mScale[1] );
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assert(xint>=0 && yint>=0 && xint<mSize[0] && yint<mSize[1]);
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Expand
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//
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// NOTE: This MUST be at least a 2 dimensional point
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////////////////////////////////////////////////////////////////////////////////////
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void expand_bounds(float xReal, float yReal)
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{
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float point[2] = {xReal, yReal};
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for (int i=0; i<2; i++)
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{
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if (point[i]<mMins[i] || mMins[i]==RANGE_NULL)
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{
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mMins[i] = point[i];
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}
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if (point[i]>mMaxs[i] || mMaxs[i]==RANGE_NULL)
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{
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mMaxs[i] = point[i];
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}
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}
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assert(mSize[0]>0 && mSize[1]>0);
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mScale[0] = ((mMaxs[0] - mMins[0])/mSize[0]);
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mScale[1] = ((mMaxs[1] - mMins[1])/mSize[1]);
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}
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////////////////////////////////////////////////////////////////////////////////////
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//
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////////////////////////////////////////////////////////////////////////////////////
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void truncate_position_to_bounds(float& xReal, float& yReal)
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{
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if (xReal<mMins[0])
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{
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xReal = mMins[0];
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}
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if (xReal>(mMaxs[0]-1.0f))
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{
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xReal = mMaxs[0]-1.0f;
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}
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if (yReal<mMins[1])
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{
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yReal = mMins[1];
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}
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if (yReal>(mMaxs[1]-1.0f))
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{
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yReal = mMaxs[1]-1.0f;
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}
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}
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////////////////////////////////////////////////////////////////////////////////////
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//
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////////////////////////////////////////////////////////////////////////////////////
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void get_cell_position(int x, int y, float& xReal, float& yReal)
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{
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// assert(mScale[0]!=0.0f && mScale[1]!=0.0f);
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xReal = (x * mScale[0]) + mMins[0] + (mScale[0] * 0.5f);
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yReal = (y * mScale[1]) + mMins[1] + (mScale[1] * 0.5f);
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}
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void get_cell_upperleft(int x, int y, float& xReal, float& yReal)
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{
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// assert(mScale[0]!=0.0f && mScale[1]!=0.0f);
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xReal = (x * mScale[0]) + mMins[0];
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yReal = (y * mScale[1]) + mMins[1];
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}
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void get_cell_lowerright(int x, int y, float& xReal, float& yReal)
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{
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// assert(mScale[0]!=0.0f && mScale[1]!=0.0f);
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xReal = (x * mScale[0]) + mMins[0] + (mScale[0]);
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yReal = (y * mScale[1]) + mMins[1] + (mScale[1]);
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}
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void scale_by_largest_axis(float& dist)
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{
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assert(mScale[0]!=0.0f && mScale[1]!=0.0f);
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if (mScale[0]>mScale[1])
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{
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dist /= mScale[0];
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}
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else
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{
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dist /= mScale[1];
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}
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Data
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////////////////////////////////////////////////////////////////////////////////////
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private:
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array_vs<T, XSIZE_MAX*YSIZE_MAX> mData;
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int mSize[2];
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float mMins[2];
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float mMaxs[2];
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float mScale[2];
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public:
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////////////////////////////////////////////////////////////////////////////////////
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// Raw Get - For The Iterator Dereference Function
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////////////////////////////////////////////////////////////////////////////////////
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T& rawGet(int Loc)
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{
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assert(Loc>=0 && Loc<XSIZE_MAX*YSIZE_MAX);
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return mData[Loc];
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Iterator
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////////////////////////////////////////////////////////////////////////////////////
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class iterator
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{
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public:
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// Constructors
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//--------------
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iterator() {}
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iterator(grid2_vs* p, int t) : mOwner(p), mLoc(t) {}
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// Assignment Operator
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//---------------------
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void operator= (const iterator &t) {mOwner=t.mOwner; mLoc=t.mLoc;}
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// Equality & Inequality Operators
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//---------------------------------
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bool operator!=(const iterator &t) {return (mLoc!=t.mLoc);}
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bool operator==(const iterator &t) {return (mLoc==t.mLoc);}
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// Dereference Operator
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//----------------------
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T& operator* () {return (mOwner->rawGet(mLoc));}
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// Inc Operator
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//--------------
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void operator++(int) {mLoc++;}
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// Row & Col Offsets
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//-------------------
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void offsetRows(int num) {mLoc += (YSIZE_MAX*num);}
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void offsetCols(int num) {mLoc += (num);}
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// Return True If On Frist Column Of A Row
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//-----------------------------------------
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bool onColZero()
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{
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return (mLoc%XSIZE_MAX)==0;
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}
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// Evaluate The XY Position Of This Iterator
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//-------------------------------------------
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void position(int& X, int& Y)
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{
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Y = mLoc / XSIZE_MAX;
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X = mLoc - (Y*XSIZE_MAX);
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}
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private:
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int mLoc;
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grid2_vs* mOwner;
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};
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////////////////////////////////////////////////////////////////////////////////////
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// Iterator Begin
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////////////////////////////////////////////////////////////////////////////////////
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iterator begin(int x=0, int y=0)
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{
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assert(x>=0 && y>=0 && x<mSize[0] && y<mSize[1]);
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return iterator(this, (x + y*XSIZE_MAX));
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Iterator Begin (scaled position, use mins and maxs to calc real position)
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////////////////////////////////////////////////////////////////////////////////////
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iterator begin(float xReal, float yReal)
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{
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assert(mScale[0]!=0.0f && mScale[1]!=0.0f);
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truncate_position_to_bounds(xReal, yReal);
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int x = (int)( (xReal-mMins[0]) / mScale[0] );
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int y = (int)( (yReal-mMins[1]) / mScale[1] );
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return begin(x,y);
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Iterator End
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////////////////////////////////////////////////////////////////////////////////////
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iterator end()
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{
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return iterator(this, (XSIZE_MAX*YSIZE_MAX));
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}
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////////////////////////////////////////////////////////////////////////////////////
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// Ranged Iterator
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////////////////////////////////////////////////////////////////////////////////////
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class riterator
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{
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public:
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// Constructors
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//--------------
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riterator()
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{}
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riterator(grid2_vs* p, int Range, int SX, int SY) :
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mOwner(p)
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{
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int Start[2] = {SX, SY};
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int Bounds[2] = {XSIZE_MAX-1, YSIZE_MAX-1};
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for (int i=0; i<2; i++)
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{
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mMins[i] = Start[i] - Range;
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mMaxs[i] = Start[i] + Range;
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if (mMins[i]<0)
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{
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mMins[i] = 0;
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}
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if (mMaxs[i] > Bounds[i])
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{
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mMaxs[i] = Bounds[i];
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}
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mLoc[i] = mMins[i];
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}
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}
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// Assignment Operator
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//---------------------
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void operator= (const riterator &t)
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{
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mOwner = t.mOwner;
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for (int i=0; i<2; i++)
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{
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mMins[i] = t.mMins[i];
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mMaxs[i] = t.mMaxs[i];
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mLoc[i] = t.mLoc[i];
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}
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}
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// Equality & Inequality Operators
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//---------------------------------
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bool operator!=(const riterator &t)
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{
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return (mLoc[0]!=t.mLoc[0] || mLoc[1]!=t.mLoc[1]);
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}
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bool operator==(const riterator &t)
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{
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return (mLoc[0]==t.mLoc[0] && mLoc[1]==t.mLoc[1]);
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}
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// Dereference Operator
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//----------------------
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T& operator* ()
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{
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return (mOwner->get(mLoc[0], mLoc[1]));
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}
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// Inc Operator
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//--------------
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void operator++(int)
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{
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if (mLoc[1] <= mMaxs[1])
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{
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mLoc[0]++;
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if (mLoc[0]>(mMaxs[0]))
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{
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mLoc[0] = mMins[0];
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mLoc[1]++;
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}
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}
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}
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bool at_end()
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{
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return (mLoc[1]>mMaxs[1]);
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}
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// Return True If On Frist Column Of A Row
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//-----------------------------------------
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bool onColZero()
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{
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return (mLoc[0]==mMins[0]);
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}
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// Evaluate The XY Position Of This Iterator
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//-------------------------------------------
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void position(int& X, int& Y)
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{
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Y = mLoc[1];
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X = mLoc[0];
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}
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private:
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int mMins[2];
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int mMaxs[2];
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int mLoc[2];
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grid2_vs* mOwner;
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};
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////////////////////////////////////////////////////////////////////////////////////
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// Ranged Iterator Begin (x and y are the center of the range)
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////////////////////////////////////////////////////////////////////////////////////
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riterator rangeBegin(int range, int x, int y)
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{
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assert(x>=0 && y>=0 && x<XSIZE_MAX && y<YSIZE_MAX);
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return riterator(this, range, x, y);
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}
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////////////////////////////////////////////////////////////////////////////////////
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//
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////////////////////////////////////////////////////////////////////////////////////
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riterator rangeBegin(int range, float xReal, float yReal)
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{
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float position[2] = {xReal, yReal};
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assert(mScale[0]!=0.0f && mScale[1]!=0.0f);
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truncate_position_to_bounds(xReal, yReal);
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int x = ( (position[0]-mMins[0]) / mScale[0] );
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int y = ( (position[1]-mMins[1]) / mScale[1] );
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assert(x>=0 && y>=0 && x<XSIZE_MAX && y<YSIZE_MAX);
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return riterator(this, range, x, y);
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}
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};
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}
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#endif
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