Assignment for RMIT Mixed Reality in 2020
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// Amplify Shader Editor - Visual Shader Editing Tool
// Copyright (c) Amplify Creations, Lda <info@amplify.pt>
using System.Collections.Generic;
using UnityEngine;
using UnityEditor;
namespace AmplifyShaderEditor
{
public class NodeGrid
{
private bool m_debugGrid = false;
private const float GRID_SIZE_X = 100;
private const float GRID_SIZE_Y = 100;
private const float GRID_AREA_X = 1000;
private const float GRID_AREA_Y = 1000;
private Dictionary<int, Dictionary<int, List<ParentNode>>> m_grid;
private int m_xMin = int.MaxValue;
private int m_yMin = int.MaxValue;
private int m_xMax = int.MinValue;
private int m_yMax = int.MinValue;
public NodeGrid()
{
m_grid = new Dictionary<int, Dictionary<int, List<ParentNode>>>();
}
public void AddNodeToGrid( ParentNode node )
{
Rect pos = node.Position;
if ( Mathf.Abs( pos.width ) < 0.001f || Mathf.Abs( pos.height ) < 0.001f )
{
return;
}
float initialXf = pos.x / GRID_SIZE_X;
float initialYf = pos.y / GRID_SIZE_Y;
int endX = Mathf.CeilToInt( initialXf + pos.width / GRID_SIZE_X );
int endY = Mathf.CeilToInt( initialYf + pos.height / GRID_SIZE_Y );
int initialX = Mathf.FloorToInt( initialXf );
int initialY = Mathf.FloorToInt( initialYf );
if ( initialX < m_xMin )
{
m_xMin = initialX;
}
if ( initialY < m_yMin )
{
m_yMin = initialY;
}
if ( endX > m_xMax )
{
m_xMax = endX;
}
if ( endY > m_yMax )
{
m_yMax = endY;
}
for ( int x = initialX; x < endX; x += 1 )
{
for ( int y = initialY; y < endY; y += 1 )
{
if ( !m_grid.ContainsKey( x ) )
{
m_grid.Add( x, new Dictionary<int, List<ParentNode>>() );
}
if ( !m_grid[ x ].ContainsKey( y ) )
{
m_grid[ x ].Add( y, new List<ParentNode>() );
}
m_grid[ x ][ y ].Add( node );
}
}
node.IsOnGrid = true;
//DebugLimits();
}
public void RemoveNodeFromGrid( ParentNode node, bool useCachedPos )
{
Rect pos = useCachedPos ? node.CachedPos : node.Position;
if ( Mathf.Abs( pos.width ) < 0.001f || Mathf.Abs( pos.height ) < 0.001f )
{
return;
}
float initialXf = pos.x / GRID_SIZE_X;
float initialYf = pos.y / GRID_SIZE_Y;
int endX = Mathf.CeilToInt( initialXf + pos.width / GRID_SIZE_X );
int endY = Mathf.CeilToInt( initialYf + pos.height / GRID_SIZE_Y );
int initialX = Mathf.FloorToInt( initialXf );
int initialY = Mathf.FloorToInt( initialYf );
bool testLimits = false;
int xMinCount = 0;
int xMaxCount = 0;
int yMinCount = 0;
int yMaxCount = 0;
for ( int x = initialX; x < endX; x += 1 )
{
for ( int y = initialY; y < endY; y += 1 )
{
if ( m_grid.ContainsKey( x ) )
{
if ( m_grid[ x ].ContainsKey( y ) )
{
m_grid[ x ][ y ].Remove( node );
node.IsOnGrid = false;
if ( initialX == m_xMin && x == initialX )
{
testLimits = true;
if ( m_grid[ x ][ y ].Count != 0 )
{
xMinCount += 1;
}
}
if ( endX == m_xMax && x == endX )
{
testLimits = true;
if ( m_grid[ x ][ y ].Count != 0 )
{
xMaxCount += 1;
}
}
if ( initialY == m_yMin && y == initialY )
{
testLimits = true;
if ( m_grid[ x ][ y ].Count != 0 )
{
yMinCount += 1;
}
}
if ( endY == m_yMax && y == endY )
{
testLimits = true;
if ( m_grid[ x ][ y ].Count != 0 )
{
yMaxCount += 1;
}
}
}
}
}
}
if ( testLimits )
{
if ( xMinCount == 0 || xMaxCount == 0 || yMinCount == 0 || yMaxCount == 0 )
{
m_xMin = int.MaxValue;
m_yMin = int.MaxValue;
m_xMax = int.MinValue;
m_yMax = int.MinValue;
foreach ( KeyValuePair<int, Dictionary<int, List<ParentNode>>> entryX in m_grid )
{
foreach ( KeyValuePair<int, List<ParentNode>> entryY in entryX.Value )
{
if ( entryY.Value.Count > 0 )
{
if ( entryX.Key < m_xMin )
{
m_xMin = entryX.Key;
}
if ( entryY.Key < m_yMin )
{
m_yMin = entryY.Key;
}
if ( entryX.Key > m_xMax )
{
m_xMax = entryX.Key;
}
if ( entryY.Key > m_yMax )
{
m_yMax = entryY.Key;
}
}
}
}
// The += 1 is to maintain consistence with AddNodeToGrid() ceil op on max values
m_xMax += 1;
m_yMax += 1;
}
}
//DebugLimits();
}
public void DebugLimits()
{
Debug.Log( "[ " + m_xMin + " , " + m_yMin + " ] " + "[ " + m_xMax + " , " + m_yMax + " ] " );
}
//pos must be the transformed mouse position to local canvas coordinates
public List<ParentNode> GetNodesOn( Vector2 pos )
{
int x = Mathf.FloorToInt( pos.x / GRID_SIZE_X );
int y = Mathf.FloorToInt( pos.y / GRID_SIZE_Y );
if ( m_grid.ContainsKey( x ) )
{
if ( m_grid[ x ].ContainsKey( y ) )
{
return m_grid[ x ][ y ];
}
}
return null;
}
public List<ParentNode> GetNodesOn( int x, int y )
{
if ( m_grid.ContainsKey( x ) )
{
if ( m_grid[ x ].ContainsKey( y ) )
{
return m_grid[ x ][ y ];
}
}
return null;
}
public void DrawGrid( DrawInfo drawInfo )
{
if ( m_debugGrid )
{
Handles.CircleHandleCap( 0, drawInfo.InvertedZoom * ( new Vector3( drawInfo.CameraOffset.x, drawInfo.CameraOffset.y, 0f ) ), Quaternion.identity, 5,EventType.Layout );
for ( int x = -( int ) GRID_AREA_X; x < GRID_AREA_X; x += ( int ) GRID_SIZE_X )
{
Handles.DrawLine( drawInfo.InvertedZoom * ( new Vector3( x + drawInfo.CameraOffset.x, drawInfo.CameraOffset.y - GRID_AREA_Y, 0 ) ), drawInfo.InvertedZoom * ( new Vector3( drawInfo.CameraOffset.x + x, drawInfo.CameraOffset.y + GRID_AREA_Y, 0 ) ) );
}
for ( int y = -( int ) GRID_AREA_Y; y < GRID_AREA_X; y += ( int ) GRID_SIZE_Y )
{
Handles.DrawLine( drawInfo.InvertedZoom * ( new Vector3( drawInfo.CameraOffset.x - GRID_AREA_X, drawInfo.CameraOffset.y + y, 0 ) ), drawInfo.InvertedZoom * ( new Vector3( drawInfo.CameraOffset.x + GRID_AREA_X, drawInfo.CameraOffset.y + y, 0 ) ) );
}
}
}
public void Destroy()
{
foreach ( KeyValuePair<int, Dictionary<int, List<ParentNode>>> entryX in m_grid )
{
foreach ( KeyValuePair<int, List<ParentNode>> entryY in entryX.Value )
{
entryY.Value.Clear();
}
entryX.Value.Clear();
}
m_grid.Clear();
}
public float MaxNodeDist
{
get { return Mathf.Max( ( m_xMax - m_xMin )*GRID_SIZE_X, ( m_yMax - m_yMin )*GRID_SIZE_Y ); }
}
}
}