// CCLayer
public override bool ccTouchBegan(CCTouch pTouch, CCEvent pEvent)
{
Debug.WriteLine("++++++++++++++++++++++++++++++++++++++++++++");
m_beginPos = pTouch.locationInView(pTouch.view());
m_beginPos = CCDirector.sharedDirector().convertToGL(m_beginPos);
return true;
}
public void SetTouchInfo(int id, float x, float y)
{
m_nId = id;
m_prevPoint = m_point;
m_point.X = x;
m_point.Y = y;
}
public LayerLevels()
{
//�ؿ�ѡ���
CCPoint offset = new CCPoint(170, 180);
for (int i = 0; i < 4; i++)
{
for (int j = 0; j < 3; j++)
{
//�ؿ��İ�ť
CCMenuItemSprite level = CCMenuItemSprite.itemFromNormalSprite(
CCSprite.spriteWithSpriteFrameName("btn_level1.png"),
CCSprite.spriteWithSpriteFrameName("btn_level2.png"),
this, click_level);
CCMenu menu = CCMenu.menuWithItems(level);
//λ����������ϵ�UI����
menu.position = CCDirector.sharedDirector().convertToUI(new CCPoint(offset.x + 160 * i, offset.y + 85 * j));
this.addChild(menu);
//����һ��MenuItem�������ı�����
CCMenuItem menuitem = new CCMenuItem();
//ָ��Arial��������������֤fonts����Arial.spritefont
var text = CCLabelTTF.labelWithString((j * 4 + i + 1).ToString(), "Arial", 12);
//����ɫָ��Ϊ��ɫ
text.Color = new ccColor3B();
menuitem.addChild(text);
menu.addChild(menuitem);
}
}
}
public StackObject(b2World world,
CCPoint location,
string spriteFileName,
bool breaksOnGround,
bool breaksFromNinja,
bool hasAnimatedBreakFrames,
bool damagesEnemy,
float density,
CreationMethod createHow,
int angleChange,
bool makeImmovable,
int points,
BreakEffect simpleScoreVisualFXType)
{
InitWithWorld(world,
location,
spriteFileName,
breaksOnGround,
breaksFromNinja,
hasAnimatedBreakFrames,
damagesEnemy,
density,
createHow,
angleChange,
makeImmovable,
points,
simpleScoreVisualFXType);
}
public override void ccTouchesMoved(List<CCTouch> pTouches, CCEvent pEvent)
{
foreach (var it in pTouches)
{
CCTouch touch = it;
CCPoint touchLocation = touch.locationInView(touch.view());
touchLocation = CCDirector.sharedDirector().convertToGL(touchLocation);
float nMoveY = touchLocation.y - m_tBeginPos.y;
CCPoint curPos = m_pItmeMenu.position;
CCPoint nextPos = new CCPoint(curPos.x, curPos.y + nMoveY);
CCSize winSize = CCDirector.sharedDirector().getWinSize();
if (nextPos.y < 0.0f)
{
m_pItmeMenu.position = new CCPoint(0, 0);
return;
}
if (nextPos.y > ((BugsTestScene.MAX_COUNT + 1) * BugsTestScene.LINE_SPACE - winSize.height))
{
m_pItmeMenu.position = new CCPoint(0, ((BugsTestScene.MAX_COUNT + 1) * BugsTestScene.LINE_SPACE - winSize.height));
return;
}
m_pItmeMenu.position = nextPos;
m_tBeginPos = touchLocation;
BugsTestScene.s_tCurPos = nextPos;
}
}
public void Run(CCPoint p_Point)
{
WordListLayer start = new WordListLayer();
start.position = p_Point;
addChild(start);
CCDirector.sharedDirector().replaceScene(this);
}
public void addNewSpriteWithCoords(CCPoint p)
{
CCSpriteBatchNode BatchNode = (CCSpriteBatchNode)getChildByTag((int)kTags.kTagSpriteBatchNode);
int idx = (int)(rand.NextDouble() * 1400 / 100);
int x = (idx % 5) * 85;
int y = (idx / 5) * 121;
CCSprite sprite = CCSprite.spriteWithTexture(BatchNode.Texture, new CCRect(x, y, 85, 121));
BatchNode.addChild(sprite);
sprite.position = (new CCPoint(p.x, p.y));
CCActionInterval action = null;
float random = (float)rand.NextDouble();
if (random < 0.20)
action = CCScaleBy.actionWithDuration(3, 2);
else if (random < 0.40)
action = CCRotateBy.actionWithDuration(3, 360);
else if (random < 0.60)
action = CCBlink.actionWithDuration(1, 3);
else if (random < 0.8)
action = CCTintBy.actionWithDuration(2, 0, -255, -255);
else
action = CCFadeOut.actionWithDuration(2);
CCActionInterval action_back = (CCActionInterval)action.reverse();
CCActionInterval seq = (CCActionInterval)(CCSequence.actions(action, action_back));
sprite.runAction(CCRepeatForever.actionWithAction(seq));
}
public void addNewSpriteWithCoords(CCPoint p)
{
int idx = (int)(ccMacros.CCRANDOM_0_1() * 1400.0f / 100.0f);
int x = (idx % 5) * 85;
int y = (idx / 5) * 121;
CCSprite sprite = CCSprite.spriteWithFile("Images/grossini_dance_atlas", new CCRect(x, y, 85, 121));
addChild(sprite);
sprite.position = p;
CCActionInterval action;
float random = ccMacros.CCRANDOM_0_1();
if (random < 0.20)
action = CCScaleBy.actionWithDuration(3, 2);
else if (random < 0.40)
action = CCRotateBy.actionWithDuration(3, 360);
else if (random < 0.60)
action = CCBlink.actionWithDuration(1, 3);
else if (random < 0.8)
action = CCTintBy.actionWithDuration(2, 0, -255, -255);
else
action = CCFadeOut.actionWithDuration(2);
object obj = action.reverse();
CCActionInterval action_back = (CCActionInterval)action.reverse();
CCActionInterval seq = (CCActionInterval)(CCSequence.actions(action, action_back));
sprite.runAction(CCRepeatForever.actionWithAction(seq));
}
public static CCPointObject pointWithCCPoint(CCPoint ratio, CCPoint offset)
{
CCPointObject pRet = new CCPointObject();
pRet.initWithCCPoint(ratio, offset);
//pRet->autorelease();
return pRet;
}
public static CCPoint CCPointApplyAffineTransform(CCPoint point, CCAffineTransform t)
{
CCPoint p = new CCPoint();
p.x = (float)((double)t.a * point.x + (double)t.c * point.y + t.tx);
p.y = (float)((double)t.b * point.x + (double)t.d * point.y + t.ty);
return p;
}
public bool initWithCCPoint(CCPoint ratio, CCPoint offset)
{
m_tRatio = ratio;
m_tOffset = offset;
m_pChild = null;
return true;
}
public void addNewSprite()
{
CCSize s = CCDirector.SharedDirector.WinSize;
CCPoint p = new CCPoint((float)(Random.NextDouble() * s.Width), (float)(Random.NextDouble() * s.Height));
CCSpriteBatchNode batch = (CCSpriteBatchNode)GetChildByTag((int)kTags.kTagSpriteBatchNode);
int idx = (int)(Random.NextDouble() * 1400 / 100);
int x = (idx % 5) * 85;
int y = (idx / 5) * 121;
CCSprite sprite = new CCSprite(batch.Texture, new CCRect(x, y, 85, 121));
batch.AddChild(sprite);
sprite.Position = (new CCPoint(p.X, p.Y));
CCActionInterval action;
float random = (float)Random.NextDouble();
if (random < 0.20)
action = new CCScaleBy(3, 2);
else if (random < 0.40)
action = new CCRotateBy (3, 360);
else if (random < 0.60)
action = new CCBlink (1, 3);
else if (random < 0.8)
action = new CCTintBy (2, 0, -255, -255);
else
action = new CCFadeOut (2);
CCActionInterval action_back = (CCActionInterval)action.Reverse();
CCActionInterval seq = (CCActionInterval)(CCSequence.FromActions(action, action_back));
sprite.RunAction(new CCRepeatForever (seq));
}
public Enemy(b2World world,
CCPoint location,
string spriteFileName,
bool isTheRotationFixed,
bool getsDamageFromGround,
bool doesGetDamageFromDamageEnabledStackObjects,
int breaksFromHowMuchContact,
bool hasDifferentSpritesForDamage,
int numberOfFramesToAnimateOnBreak,
float density,
CreationMethod createHow,
int points,
BreakEffect simpleScoreVisualFXType )
{
InitWithWorld( world,
location,
spriteFileName,
isTheRotationFixed,
getsDamageFromGround,
doesGetDamageFromDamageEnabledStackObjects,
breaksFromHowMuchContact,
hasDifferentSpritesForDamage,
numberOfFramesToAnimateOnBreak,
density,
createHow,
points,
simpleScoreVisualFXType );
}
public void updateSize(CCPoint touchLocation)
{
CCSize s = CCDirector.SharedDirector.WinSize;
CCSize newSize = new CCSize(Math.Abs(touchLocation.X - s.Width / 2) * 2, Math.Abs(touchLocation.Y - s.Height / 2) * 2);
CCLayerColor l = (CCLayerColor)GetChildByTag(kTagLayer);
l.ContentSize = newSize;
}
public void addNewSpriteWithCoords(CCPoint p)
{
int idx = (int)(CCMacros.CCRandomBetween0And1() * 1400.0f / 100.0f);
int x = (idx % 5) * 85;
int y = (idx / 5) * 121;
CCSprite sprite = new CCSprite("Images/grossini_dance_atlas", new CCRect(x, y, 85, 121));
AddChild(sprite);
sprite.Position = p;
CCActionInterval action;
float random = CCMacros.CCRandomBetween0And1();
if (random < 0.20)
action = new CCScaleBy(3, 2);
else if (random < 0.40)
action = new CCRotateBy (3, 360);
else if (random < 0.60)
action = new CCBlink (1, 3);
else if (random < 0.8)
action = new CCTintBy (2, 0, -255, -255);
else
action = new CCFadeOut (2);
object obj = action.Reverse();
CCActionInterval action_back = (CCActionInterval)action.Reverse();
CCActionInterval seq = (CCActionInterval)(CCSequence.FromActions(action, action_back));
sprite.RunAction(new CCRepeatForever (seq));
}
private void InitWithWorld( b2World world, CCPoint location, string spriteFileName)
{
this.theWorld = world;
this.initialLocation = location;
this.spriteImageName = spriteFileName;
CreateGround();
}
public void resetAndScoreBallForPlayer(int player)
{
m_ballStartingVelocity = new CCPoint(m_ballStartingVelocity.x * -1.1f, m_ballStartingVelocity.y * -1.1f);
m_ball.Velocity = m_ballStartingVelocity;
m_ball.position = new CCPoint(160.0f, 240.0f);
// TODO -- scoring
}
/// <summary>
/// Initializes a CCMenuItem with a target/selector
/// </summary>
/// <param name="rec"></param>
/// <param name="selector"></param>
/// <returns></returns>
public bool initWithTarget(SelectorProtocol rec, SEL_MenuHandler selector)
{
anchorPoint = new CCPoint(0.5f, 0.5f);
m_pListener = rec;
m_pfnSelector = selector;
m_bIsEnabled = true;
m_bIsSelected = false;
return true;
}
public override void ccTouchesBegan(List<CCTouch> pTouches, CCEvent pEvent)
{
foreach (var it in pTouches)
{
CCTouch touch = it;
m_tBeginPos = touch.locationInView(touch.view());
m_tBeginPos = CCDirector.sharedDirector().convertToGL(m_tBeginPos);
}
}
public override float testFunc(ccGridSize pos, float time)
{
CCPoint n = new CCPoint((float)(m_sGridSize.x * time), (float)(m_sGridSize.y * time));
if (n.y == 0.0f)
{
return 1.0f;
}
return (float)Math.Pow(pos.y / n.y, 6);
}
protected bool IsTouchNode(CCNode p_Node, List<CCTouch> touches)
{
CCRect rect = p_Node.boundingBox();
CCSize size = CCDirector.sharedDirector().getWinSize();
// rect.size = p_Node.contentSize;
CCPoint touch =new CCPoint( touches[0].locationInView(touches[0].view()).x, touches[0].locationInView(touches[0].view()).y);
touch.y = size.height - touch.y;
return CCRect.CCRectContainsPoint(rect, touch);
}
public CCTMXLayerInfo()
{
m_sName = "";
m_pTiles = null;
m_bOwnTiles = true;
m_uMinGID = 100000;
m_uMaxGID = 0;
m_tOffset = new CCPoint(0, 0);
m_pProperties =new Dictionary<string,string>(); ;
}
public virtual float testFunc(ccGridSize pos, float time)
{
CCPoint n = new CCPoint((float)(m_sGridSize.x * (1.0f - time)), (float)(m_sGridSize.y * (1.0f - time)));
if (pos.y == 0)
{
return 1.0f;
}
return (float)Math.Pow(n.y / pos.y, 6);
}
public virtual float testFunc(ccGridSize pos, float time)
{
CCPoint n = new CCPoint((float)(m_sGridSize.x * time), (float)(m_sGridSize.y * time));
if ((n.x + n.y) == 0.0f)
{
return 1.0f;
}
return (float)Math.Pow((pos.x + pos.y) / (n.x + n.y), 6);
}
public override float TestFunc(CCGridSize pos, float time)
{
var n = new CCPoint((m_sGridSize.X * (1.0f - time)), (m_sGridSize.Y * (1.0f - time)));
if ((pos.X + pos.Y) == 0)
{
return 1.0f;
}
return (float) Math.Pow((n.X + n.Y) / (pos.X + pos.Y), 6);
}
/// <summary>
/// Creates a full-screen CCLayer with a gradient between start and end in the direction of v.
/// </summary>
public static CCLayerGradient layerWithColor(ccColor4B start, ccColor4B end, CCPoint v)
{
CCLayerGradient pLayer = new CCLayerGradient();
if (pLayer.initWithColor(start, end, v))
{
return pLayer;
}
return null;
}
public void setPosition(CCPoint pos)
{
if (!CCPoint.CCPointEqualToPoint(pos, m_position))
{
m_position = pos;
m_positionInPixels.x = pos.x * CCDirector.sharedDirector().ContentScaleFactor;
m_positionInPixels.y = pos.y * CCDirector.sharedDirector().ContentScaleFactor;
m_bDirty = true;
}
}
public override float testFunc(ccGridSize pos, float time)
{
CCPoint n = new CCPoint((float)(m_sGridSize.x * (1.0f - time)), (float)(m_sGridSize.y * (1.0f - time)));
if ((pos.x + pos.y) == 0)
{
return 1.0f;
}
return (float)Math.Pow((n.x + n.y) / (pos.x + pos.y), 6);
}
public static CCPlace actionWithPosition(CCPoint pos)
{
CCPlace pRet = new CCPlace();
if (pRet != null && pRet.initWithPosition(pos))
{
return pRet;
}
return null;
}
/** replaces an existing controlPoint at index */
public void replaceControlPoint(CCPoint controlPoint, int index)
{
// should create a new object of CCPoint
// because developer always use this function like this
// replaceControlPoint(ccp(x, y))
// passing controlPoint is a temple object
// and CCArray::insertObject() will retain the passing object, so it
// should be an object created in heap
CCPoint temp = new CCPoint(controlPoint);
m_pControlPoints[index] = temp;
}
public CCPoint Add(CCPoint pt)
{
CCPoint cCPoint = new CCPoint(this.x + pt.x, this.y + pt.y);
return(cCPoint);
}
public override void startWithTarget(CCNode pTarget)
{
base.startWithTarget(pTarget);
this.m_startPosition = pTarget.position;
}
public override bool initWithTotalParticles(uint numberOfParticles)
{
if (base.initWithTotalParticles(numberOfParticles))
{
// duration
Duration = (float)eParticleShowingProperty.kCCParticleDurationInfinity;
EmitterMode = (int)eParticleMode.kCCParticleModeGravity;
// Gravity Mode: gravity
modeA.gravity = new CCPoint(10, -10);
// Gravity Mode: radial
modeA.radialAccel = 0;
modeA.radialAccelVar = 1;
// Gravity Mode: tagential
modeA.tangentialAccel = 0;
modeA.tangentialAccelVar = 1;
// Gravity Mode: speed of particles
modeA.speed = 130;
modeA.speedVar = 30;
// angle
Angle = -90;
AngleVar = 5;
// emitter position
CCSize winSize = CCDirector.sharedDirector().getWinSize();
this.position = new CCPoint(winSize.width / 2, winSize.height);
PosVar = new CCPoint(winSize.width / 2, 0);
// life of particles
Life = 4.5f;
LifeVar = 0;
// size, in pixels
StartSize = 4.0f;
StartSizeVar = 2.0f;
EndSize = (float)eParticleShowingProperty.kCCParticleStartSizeEqualToEndSize;
// emits per second
EmissionRate = 20;
// color of particles
StartColor.r = 0.7f;
StartColor.g = 0.8f;
StartColor.b = 1.0f;
StartColor.a = 1.0f;
StartColorVar.r = 0.0f;
StartColorVar.g = 0.0f;
StartColorVar.b = 0.0f;
StartColorVar.a = 0.0f;
EndColor.r = 0.7f;
EndColor.g = 0.8f;
EndColor.b = 1.0f;
EndColor.a = 0.5f;
EndColorVar.r = 0.0f;
EndColorVar.g = 0.0f;
EndColorVar.b = 0.0f;
EndColorVar.a = 0.0f;
// additive
this.IsBlendAdditive = false;
return(true);
}
return(false);
}
/// <summary>
/// set center position
/// </summary>
public void setPosition(CCPoint position)
{
m_position = position;
m_positionInPixels.x = position.x * CCDirector.sharedDirector().ContentScaleFactor;
m_positionInPixels.y = position.y * CCDirector.sharedDirector().ContentScaleFactor;
}
public static void LineToPolygon(CCPoint[] points, float stroke, ccVertex2F[] vertices, int offset, int nuPoints)
{
int num;
CCPoint cCPoint;
nuPoints = nuPoints + offset;
if (nuPoints <= 1)
{
return;
}
stroke = stroke * 0.5f;
int num1 = nuPoints - 1;
for (int i = offset; i < nuPoints; i++)
{
num = i * 2;
CCPoint cCPoint1 = points[i];
if (i == 0)
{
cCPoint = CCPointExtension.ccpPerp(CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(cCPoint1, points[i + 1])));
}
else if (i != num1)
{
CCPoint cCPoint2 = points[i + 1];
CCPoint cCPoint3 = points[i - 1];
CCPoint cCPoint4 = CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(cCPoint2, cCPoint1));
CCPoint cCPoint5 = CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(cCPoint3, cCPoint1));
float single = (float)Math.Acos((double)CCPointExtension.ccpDot(cCPoint4, cCPoint5));
if (single >= ccMacros.CC_DEGREES_TO_RADIANS(70f))
{
cCPoint = (single >= ccMacros.CC_DEGREES_TO_RADIANS(170f) ? CCPointExtension.ccpPerp(CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(cCPoint2, cCPoint3))) : CCPointExtension.ccpNormalize(CCPointExtension.ccpMidpoint(cCPoint4, cCPoint5)));
}
else
{
cCPoint = CCPointExtension.ccpPerp(CCPointExtension.ccpNormalize(CCPointExtension.ccpMidpoint(cCPoint4, cCPoint5)));
}
}
else
{
cCPoint = CCPointExtension.ccpPerp(CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(points[i - 1], cCPoint1)));
}
cCPoint = CCPointExtension.ccpMult(cCPoint, stroke);
vertices[num] = new ccVertex2F(cCPoint1.x + cCPoint.x, cCPoint1.y + cCPoint.y);
vertices[num + 1] = new ccVertex2F(cCPoint1.x - cCPoint.x, cCPoint1.y - cCPoint.y);
}
offset = (offset == 0 ? 0 : offset - 1);
for (int j = offset; j < num1; j++)
{
num = j * 2;
int num2 = num + 2;
ccVertex2F _ccVertex2F = vertices[num];
ccVertex2F _ccVertex2F1 = vertices[num + 1];
ccVertex2F _ccVertex2F2 = vertices[num2];
ccVertex2F _ccVertex2F3 = vertices[num2 + 1];
float single1 = 0f;
bool flag = !CCVertex.LineIntersect(_ccVertex2F.x, _ccVertex2F.y, _ccVertex2F3.x, _ccVertex2F3.y, _ccVertex2F1.x, _ccVertex2F1.y, _ccVertex2F2.x, _ccVertex2F2.y, out single1);
if (!flag && (single1 < 0f || single1 > 1f))
{
flag = true;
}
if (flag)
{
vertices[num2] = _ccVertex2F3;
vertices[num2 + 1] = _ccVertex2F2;
}
}
}
public override void update(float delta)
{
if (!m_bStartingPositionInitialized)
{
return;
}
if (m_pVerticesPCT == null)
{
m_pVerticesPCT = new VertexPositionColorTexture[((m_uNuPoints + 1) * 2)];
}
if (m_uNuPoints * 2 > m_pVerticesPCT.Length)
{
VertexPositionColorTexture[] tmp = new VertexPositionColorTexture[((m_uNuPoints + 1) * 2)];
m_pVerticesPCT.CopyTo(tmp, 0);
m_pVerticesPCT = tmp;
}
delta *= m_fFadeDelta;
int newIdx, newIdx2, i, i2;
int mov = 0;
// Update current points
for (i = 0; i < m_uNuPoints; i++)
{
if (m_pVerticesPCT[i] == null)
{
m_pVerticesPCT[i] = new VertexPositionColorTexture(m_pVertices[i].ToVector3(), m_pColor[i].XNAColor, m_pTexCoords[i].ToVector2());
}
if (m_pVerticesPCT[i * 2] == null)
{
m_pVerticesPCT[i * 2] = new VertexPositionColorTexture(m_pVerticesPCT[i].Position, m_pVerticesPCT[i].Color, m_pVerticesPCT[i].TextureCoordinate);
}
m_pPointState[i] -= delta;
if (m_pPointState[i] <= 0)
{
mov++;
}
else
{
newIdx = i - mov;
if (mov > 0)
{
// Move data
m_pPointState[newIdx] = m_pPointState[i];
// Move point
m_pPointVertexes[newIdx] = new CCPoint(m_pPointVertexes[i]);
// Move vertices
i2 = i * 2;
newIdx2 = newIdx * 2;
m_pVertices[newIdx2] = new ccVertex2F(m_pVertices[i2]);
m_pVertices[newIdx2 + 1] = new ccVertex2F(m_pVertices[i2 + 1]);
// Move color
m_pColor[newIdx2] = new ccColor4B(m_pColor[i2]);
m_pColor[newIdx2 + 1] = new ccColor4B(m_pColor[i2 + 1]);
// Move the GL vertex data
m_pVerticesPCT[newIdx2] = m_pVerticesPCT[i2];
m_pVerticesPCT[newIdx2 + 1] = m_pVerticesPCT[i2 + 1];
}
else
{
newIdx2 = newIdx * 2;
}
byte op = (byte)(m_pPointState[newIdx] * 255.0f);
m_pColor[newIdx2].a = op;
m_pColor[newIdx2 + 1].a = op;
VertexPositionColorTexture vpc;
if (m_pVertices[newIdx2] != null)
{
vpc = new VertexPositionColorTexture(m_pVertices[newIdx2].ToVector3(), m_pColor[newIdx2].XNAColor, m_pTexCoords[newIdx2].ToVector2());
m_pVerticesPCT[newIdx2] = vpc;
}
if (m_pVertices[newIdx2 + 1] != null)
{
vpc = new VertexPositionColorTexture(m_pVertices[newIdx2 + 1].ToVector3(), m_pColor[newIdx2 + 1].XNAColor, m_pTexCoords[newIdx2 + 1].ToVector2());
m_pVerticesPCT[newIdx2 + 1] = vpc;
}
}
}
m_uNuPoints -= mov;
// Append new point
bool appendNewPoint = true;
if (m_uNuPoints >= m_uMaxPoints)
{
appendNewPoint = false;
}
else if (m_uNuPoints > 0)
{
bool a1 = (m_pPointVertexes[m_uNuPoints - 1].DistanceSQ(m_tPositionR) < m_fMinSeg);
bool a2 = (m_uNuPoints == 1) ? false : (m_pPointVertexes[m_uNuPoints - 2].DistanceSQ(m_tPositionR) < (m_fMinSeg * 2.0f));
if (a1 || a2)
{
appendNewPoint = false;
}
}
if (appendNewPoint)
{
m_pPointVertexes[m_uNuPoints] = new CCPoint(m_tPositionR);
m_pPointState[m_uNuPoints] = 1.0f;
// Color asignment
int offset = m_uNuPoints * 2;
m_pColor[offset] = new ccColor4B(m_tColor);
m_pColor[offset + 1] = new ccColor4B(m_tColor);
// Opacity
m_pColor[offset].a = 255;
m_pColor[offset + 1].a = 255;
// Generate polygon
if (m_uNuPoints > 0 && m_bFastMode)
{
if (m_uNuPoints > 1)
{
CCVertex.LineToPolygon(m_pPointVertexes, m_fStroke, m_pVertices, m_uNuPoints, 1);
}
else
{
CCVertex.LineToPolygon(m_pPointVertexes, m_fStroke, m_pVertices, 0, 2);
}
}
m_uNuPoints++;
}
if (!m_bFastMode)
{
CCVertex.LineToPolygon(m_pPointVertexes, m_fStroke, m_pVertices, 0, m_uNuPoints);
}
// Updated Tex Coords only if they are different than previous step
if (m_uPreviousNuPoints != m_uNuPoints)
{
if (m_uNuPoints > m_uPreviousNuPoints)
{
int count = (m_uNuPoints + 1) * 2;
if (count < m_pVerticesPCT.Length)
{
count = m_pVerticesPCT.Length;
}
VertexPositionColorTexture[] tmp = new VertexPositionColorTexture[count];
m_pVerticesPCT.CopyTo(tmp, 0);
m_pVerticesPCT = tmp;
}
float texDelta = 1.0f / m_uNuPoints;
for (i = 0; i < m_uNuPoints; i++)
{
m_pTexCoords[i * 2] = new ccTex2F(0, texDelta * i);
m_pTexCoords[i * 2 + 1] = new ccTex2F(1, texDelta * i);
VertexPositionColorTexture vpc;
if (m_pVertices[i * 2] != null)
{
vpc = new VertexPositionColorTexture(m_pVertices[i * 2].ToVector3(), m_pColor[i * 2].XNAColor, m_pTexCoords[i * 2].ToVector2());
m_pVerticesPCT[i * 2] = vpc;
}
if (m_pVertices[i * 2 + 1] != null)
{
vpc = new VertexPositionColorTexture(m_pVertices[i * 2 + 1].ToVector3(), m_pColor[i * 2 + 1].XNAColor, m_pTexCoords[i * 2 + 1].ToVector2());
m_pVerticesPCT[i * 2 + 1] = vpc;
}
}
m_uPreviousNuPoints = m_uNuPoints;
}
}
public bool initWithPosition(CCPoint pos)
{
m_tPosition = pos;
return(true);
}
// the XML parser calls here with all the elements
public void startElement(object ctx, string name, string[] atts)
{
CCTMXMapInfo pTMXMapInfo = this;
string elementName = name;
Dictionary <string, string> attributeDict = new Dictionary <string, string>();
if (atts != null && atts[0] != null)
{
for (int i = 0; i + 1 < atts.Length; i += 2)
{
string key = atts[i];
string value = atts[i + 1];
attributeDict.Add(key, value);
}
}
if (elementName == "map")
{
string version = attributeDict["version"];
if (version != "1.0")
{
CCLog.Log("cocos2d: TMXFormat: Unsupported TMX version: {0}", version);
}
string orientationStr = attributeDict["orientation"];
if (orientationStr == "orthogonal")
{
pTMXMapInfo.Orientation = (int)(CCTMXOrientatio.CCTMXOrientationOrtho);
}
else if (orientationStr == "isometric")
{
pTMXMapInfo.Orientation = (int)(CCTMXOrientatio.CCTMXOrientationIso);
}
else if (orientationStr == "hexagonal")
{
pTMXMapInfo.Orientation = (int)(CCTMXOrientatio.CCTMXOrientationHex);
}
else
{
CCLog.Log("cocos2d: TMXFomat: Unsupported orientation: {0}", pTMXMapInfo.Orientation);
}
CCSize sMapSize = new CCSize();
sMapSize.width = ccUtils.ccParseFloat(attributeDict["width"]);
sMapSize.height = ccUtils.ccParseFloat(attributeDict["height"]);
pTMXMapInfo.MapSize = sMapSize;
CCSize sTileSize = new CCSize();
sTileSize.width = ccUtils.ccParseFloat(attributeDict["tilewidth"]);
sTileSize.height = ccUtils.ccParseFloat(attributeDict["tileheight"]);
pTMXMapInfo.TileSize = sTileSize;
// The parent element is now "map"
pTMXMapInfo.ParentElement = (int)TMXProperty.TMXPropertyMap;
}
else if (elementName == "tileset")
{
// If this is an external tileset then start parsing that
if (attributeDict.Keys.Contains("source"))
{
string externalTilesetFilename = attributeDict["source"];
externalTilesetFilename = CCFileUtils.fullPathFromRelativeFile(externalTilesetFilename, pTMXMapInfo.TMXFileName);
pTMXMapInfo.parseXMLFile(externalTilesetFilename);
}
else
{
CCTMXTilesetInfo tileset = new CCTMXTilesetInfo();
tileset.m_sName = attributeDict["name"];
tileset.m_uFirstGid = ccUtils.ccParseInt(attributeDict["firstgid"]);
if (attributeDict.Keys.Contains("spacing"))
{
tileset.m_uSpacing = ccUtils.ccParseInt(attributeDict["spacing"]);
}
if (attributeDict.Keys.Contains("margin"))
{
tileset.m_uMargin = ccUtils.ccParseInt(attributeDict["margin"]);
}
CCSize s = new CCSize();
s.width = ccUtils.ccParseFloat(attributeDict["tilewidth"]);
s.height = ccUtils.ccParseFloat(attributeDict["tileheight"]);
tileset.m_tTileSize = s;
pTMXMapInfo.Tilesets.Add(tileset);
}
}
else if (elementName == "tile")
{
CCTMXTilesetInfo info = pTMXMapInfo.Tilesets.LastOrDefault();
Dictionary <string, string> dict = new Dictionary <string, string>();
pTMXMapInfo.ParentGID = (info.m_uFirstGid + ccUtils.ccParseInt(attributeDict["id"]));
pTMXMapInfo.TileProperties.Add(pTMXMapInfo.ParentGID, dict);
pTMXMapInfo.ParentElement = (int)TMXProperty.TMXPropertyTile;
}
else if (elementName == "layer")
{
CCTMXLayerInfo layer = new CCTMXLayerInfo();
layer.m_sName = attributeDict["name"];
CCSize s = new CCSize();
s.width = ccUtils.ccParseFloat(attributeDict["width"]);
s.height = ccUtils.ccParseFloat(attributeDict["height"]);
layer.m_tLayerSize = s;
layer.m_pTiles = new int[(int)s.width * (int)s.height];
if (attributeDict.Keys.Contains("visible"))
{
string visible = attributeDict["visible"];
layer.m_bVisible = !(visible == "0");
}
else
{
layer.m_bVisible = true;
}
if (attributeDict.Keys.Contains("opacity"))
{
string opacity = attributeDict["opacity"];
layer.m_cOpacity = (byte)(255 * ccUtils.ccParseFloat(opacity));
}
else
{
layer.m_cOpacity = 255;
}
float x = attributeDict.Keys.Contains("x") ? ccUtils.ccParseFloat(attributeDict["x"]) : 0;
float y = attributeDict.Keys.Contains("y") ? ccUtils.ccParseFloat(attributeDict["y"]) : 0;
layer.m_tOffset = new CCPoint(x, y);
pTMXMapInfo.Layers.Add(layer);
// The parent element is now "layer"
pTMXMapInfo.ParentElement = (int)TMXProperty.TMXPropertyLayer;
}
else if (elementName == "objectgroup")
{
CCTMXObjectGroup objectGroup = new CCTMXObjectGroup();
objectGroup.GroupName = attributeDict["name"];
CCPoint positionOffset = new CCPoint();
if (attributeDict.ContainsKey("x"))
{
positionOffset.x = ccUtils.ccParseFloat(attributeDict["x"]) * pTMXMapInfo.TileSize.width;
}
if (attributeDict.ContainsKey("y"))
{
positionOffset.y = ccUtils.ccParseFloat(attributeDict["y"]) * pTMXMapInfo.TileSize.height;
}
objectGroup.PositionOffset = positionOffset;
pTMXMapInfo.ObjectGroups.Add(objectGroup);
// The parent element is now "objectgroup"
pTMXMapInfo.ParentElement = (int)TMXProperty.TMXPropertyObjectGroup;
}
else if (elementName == "image")
{
CCTMXTilesetInfo tileset = pTMXMapInfo.Tilesets.LastOrDefault();
// build full path
string imagename = attributeDict["source"];
tileset.m_sSourceImage = CCFileUtils.fullPathFromRelativeFile(imagename, pTMXMapInfo.TMXFileName);
}
else if (elementName == "data")
{
string encoding = attributeDict.ContainsKey("encoding") ? attributeDict["encoding"] : "";
string compression = attributeDict.ContainsKey("compression") ? attributeDict["compression"] : "";
if (encoding == "base64")
{
int layerAttribs = pTMXMapInfo.LayerAttribs;
pTMXMapInfo.LayerAttribs = layerAttribs | (int)TMXLayerAttrib.TMXLayerAttribBase64;
pTMXMapInfo.StoringCharacters = true;
if (compression == "gzip")
{
layerAttribs = pTMXMapInfo.LayerAttribs;
pTMXMapInfo.LayerAttribs = layerAttribs | (int)TMXLayerAttrib.TMXLayerAttribGzip;
}
else
if (compression == "zlib")
{
layerAttribs = pTMXMapInfo.LayerAttribs;
pTMXMapInfo.LayerAttribs = layerAttribs | (int)TMXLayerAttrib.TMXLayerAttribZlib;
}
Debug.Assert(compression == "" || compression == "gzip" || compression == "zlib", "TMX: unsupported compression method");
}
Debug.Assert(pTMXMapInfo.LayerAttribs != (int)TMXLayerAttrib.TMXLayerAttribNone, "TMX tile map: Only base64 and/or gzip/zlib maps are supported");
}
else if (elementName == "object")
{
char[] buffer = new char[32];
CCTMXObjectGroup objectGroup = pTMXMapInfo.ObjectGroups.LastOrDefault();
// The value for "type" was blank or not a valid class name
// Create an instance of TMXObjectInfo to store the object and its properties
Dictionary <string, string> dict = new Dictionary <string, string>();
// Set the name of the object to the value for "name"
string key = "name";
string value = attributeDict.ContainsKey("name") ? attributeDict["name"] : "";
dict.Add(key, value);
// Assign all the attributes as key/name pairs in the properties dictionary
key = "type";
value = attributeDict.ContainsKey("type") ? attributeDict["type"] : "";
dict.Add(key, value);
int x = ccUtils.ccParseInt(attributeDict["x"]) + (int)objectGroup.PositionOffset.x;
key = "x";
value = x.ToString();
dict.Add(key, value);
int y = ccUtils.ccParseInt(attributeDict["y"]) + (int)objectGroup.PositionOffset.y;
// Correct y position. (Tiled uses Flipped, cocos2d uses Standard)
y = (int)(pTMXMapInfo.MapSize.height * pTMXMapInfo.TileSize.height) - y - (attributeDict.ContainsKey("height") ? ccUtils.ccParseInt(attributeDict["height"]) : 0);
key = "y";
value = y.ToString();
dict.Add(key, value);
key = "width";
value = attributeDict.ContainsKey("width") ? attributeDict["width"] : "";
dict.Add(key, value);
key = "height";
value = attributeDict.ContainsKey("height") ? attributeDict["height"] : "";
dict.Add(key, value);
// Add the object to the objectGroup
objectGroup.Objects.Add(dict);
// The parent element is now "object"
pTMXMapInfo.ParentElement = (int)TMXProperty.TMXPropertyObject;
}
else if (elementName == "property")
{
if (pTMXMapInfo.ParentElement == (int)TMXProperty.TMXPropertyNone)
{
CCLog.Log("TMX tile map: Parent element is unsupported. Cannot add property named '{0}' with value '{1}'",
attributeDict["name"], attributeDict["value"]);
}
else if (pTMXMapInfo.ParentElement == (int)TMXProperty.TMXPropertyMap)
{
// The parent element is the map
string value = attributeDict["value"];
string key = attributeDict["name"];
pTMXMapInfo.Properties.Add(key, value);
}
else if (pTMXMapInfo.ParentElement == (int)TMXProperty.TMXPropertyLayer)
{
// The parent element is the last layer
CCTMXLayerInfo layer = pTMXMapInfo.Layers.LastOrDefault();
string value = attributeDict["value"];
string key = attributeDict["name"];
// Add the property to the layer
layer.Properties.Add(key, value);
}
else if (pTMXMapInfo.ParentElement == (int)TMXProperty.TMXPropertyObjectGroup)
{
// The parent element is the last object group
CCTMXObjectGroup objectGroup = pTMXMapInfo.ObjectGroups.LastOrDefault();
string value = attributeDict["value"];
string key = attributeDict["name"];
objectGroup.Properties.Add(key, value);
}
else if (pTMXMapInfo.ParentElement == (int)TMXProperty.TMXPropertyObject)
{
// The parent element is the last object
CCTMXObjectGroup objectGroup = pTMXMapInfo.ObjectGroups.LastOrDefault();
Dictionary <string, string> dict = objectGroup.Objects.LastOrDefault();
string propertyName = attributeDict["name"];
string propertyValue = attributeDict["value"];
dict.Add(propertyName, propertyValue);
}
else if (pTMXMapInfo.ParentElement == (int)TMXProperty.TMXPropertyTile)
{
Dictionary <string, string> dict = pTMXMapInfo.TileProperties[pTMXMapInfo.ParentGID];
string propertyName = attributeDict["name"];
string propertyValue = attributeDict["value"];
dict.Add(propertyName, propertyValue);
}
}
if (attributeDict != null)
{
attributeDict = null;
}
}
/// <summary>
/// Create a CCSpriteFrame with a texture, rect, rotated, offset and originalSize in pixels.
/// The originalSize is the size in points of the frame before being trimmed.
/// </summary>
public static CCSpriteFrame frameWithTexture(CCTexture2D pobTexture, CCRect rect, bool rotated, CCPoint offset, CCSize originalSize)
{
CCSpriteFrame pSpriteFrame = new CCSpriteFrame();
pSpriteFrame.initWithTexture(pobTexture, rect, rotated, offset, originalSize);
return(pSpriteFrame);
}
public void initParticle(CCParticle particle)
{
particle.timeToLive = this.m_fLife + (this.m_fLifeVar * ccMacros.CCRANDOM_MINUS1_1());
particle.timeToLive = (0f > particle.timeToLive) ? 0f : particle.timeToLive;
particle.pos.x = this.m_tSourcePosition.x + (this.m_tPosVar.x * ccMacros.CCRANDOM_MINUS1_1());
particle.pos.x *= CCDirector.sharedDirector().ContentScaleFactor;
particle.pos.y = this.m_tSourcePosition.y + (this.m_tPosVar.y * ccMacros.CCRANDOM_MINUS1_1());
particle.pos.y *= CCDirector.sharedDirector().ContentScaleFactor;
ccColor4F colorf = new ccColor4F
{
r = CCPointExtension.clampf(this.m_tStartColor.r + (this.m_tStartColorVar.r * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
g = CCPointExtension.clampf(this.m_tStartColor.g + (this.m_tStartColorVar.g * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
b = CCPointExtension.clampf(this.m_tStartColor.b + (this.m_tStartColorVar.b * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
a = CCPointExtension.clampf(this.m_tStartColor.a + (this.m_tStartColorVar.a * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f)
};
ccColor4F colorf2 = new ccColor4F
{
r = CCPointExtension.clampf(this.m_tEndColor.r + (this.m_tEndColorVar.r * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
g = CCPointExtension.clampf(this.m_tEndColor.g + (this.m_tEndColorVar.g * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
b = CCPointExtension.clampf(this.m_tEndColor.b + (this.m_tEndColorVar.b * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
a = CCPointExtension.clampf(this.m_tEndColor.a + (this.m_tEndColorVar.a * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f)
};
particle.color = colorf;
particle.deltaColor.r = (colorf2.r - colorf.r) / particle.timeToLive;
particle.deltaColor.g = (colorf2.g - colorf.g) / particle.timeToLive;
particle.deltaColor.b = (colorf2.b - colorf.b) / particle.timeToLive;
particle.deltaColor.a = (colorf2.a - colorf.a) / particle.timeToLive;
float num = this.m_fStartSize + (this.m_fStartSizeVar * ccMacros.CCRANDOM_MINUS1_1());
num = (0f > num) ? 0f : num;
num *= CCDirector.sharedDirector().ContentScaleFactor;
particle.size = num;
if (this.m_fEndSize == -1f)
{
particle.deltaSize = 0f;
}
else
{
float num2 = this.m_fEndSize + (this.m_fEndSizeVar * ccMacros.CCRANDOM_MINUS1_1());
num2 = (0f > num2) ? 0f : num2;
num2 *= CCDirector.sharedDirector().ContentScaleFactor;
particle.deltaSize = (num2 - num) / particle.timeToLive;
}
float num3 = this.m_fStartSpin + (this.m_fStartSpinVar * ccMacros.CCRANDOM_MINUS1_1());
float num4 = this.m_fEndSpin + (this.m_fEndSpinVar * ccMacros.CCRANDOM_MINUS1_1());
particle.rotation = num3;
particle.deltaRotation = (num4 - num3) / particle.timeToLive;
if (this.m_ePositionType == eParticlePositionType.kCCPositionTypeFree)
{
CCPoint v = base.convertToWorldSpace(new CCPoint(0f, 0f));
particle.startPos = CCPointExtension.ccpMult(v, CCDirector.sharedDirector().ContentScaleFactor);
}
else if (this.m_ePositionType == eParticlePositionType.kCCPositionTypeRelative)
{
particle.startPos = CCPointExtension.ccpMult(base.m_tPosition, CCDirector.sharedDirector().ContentScaleFactor);
}
float num5 = ccMacros.CC_DEGREES_TO_RADIANS(this.m_fAngle + (this.m_fAngleVar * ccMacros.CCRANDOM_MINUS1_1()));
if (this.m_nEmitterMode == 0)
{
CCPoint point2 = new CCPoint((float)Math.Cos((double)num5), (float)Math.Sin((double)num5));
float s = this.modeA.speed + (this.modeA.speedVar * ccMacros.CCRANDOM_MINUS1_1());
s *= CCDirector.sharedDirector().ContentScaleFactor;
particle.modeA.dir = CCPointExtension.ccpMult(point2, s);
particle.modeA.radialAccel = this.modeA.radialAccel + (this.modeA.radialAccelVar * ccMacros.CCRANDOM_MINUS1_1());
particle.modeA.radialAccel *= CCDirector.sharedDirector().ContentScaleFactor;
particle.modeA.tangentialAccel = this.modeA.tangentialAccel + (this.modeA.tangentialAccelVar * ccMacros.CCRANDOM_MINUS1_1());
particle.modeA.tangentialAccel *= CCDirector.sharedDirector().ContentScaleFactor;
}
else
{
float num7 = this.modeB.startRadius + (this.modeB.startRadiusVar * ccMacros.CCRANDOM_MINUS1_1());
float num8 = this.modeB.endRadius + (this.modeB.endRadiusVar * ccMacros.CCRANDOM_MINUS1_1());
num7 *= CCDirector.sharedDirector().ContentScaleFactor;
num8 *= CCDirector.sharedDirector().ContentScaleFactor;
particle.modeB.radius = num7;
if (this.modeB.endRadius == -1f)
{
particle.modeB.deltaRadius = 0f;
}
else
{
particle.modeB.deltaRadius = (num8 - num7) / particle.timeToLive;
}
particle.modeB.angle = num5;
particle.modeB.degreesPerSecond = ccMacros.CC_DEGREES_TO_RADIANS(this.modeB.rotatePerSecond + (this.modeB.rotatePerSecondVar * ccMacros.CCRANDOM_MINUS1_1()));
}
}
public void addSpriteFramesWithDictionary(Dictionary <string, object> pobDictionary, CCTexture2D pobTexture)
{
Dictionary <string, object> item = null;
if (pobDictionary.Keys.Contains <string>("metadata"))
{
item = (Dictionary <string, object>)pobDictionary["metadata"];
}
Dictionary <string, object> strs = null;
if (pobDictionary.Keys.Contains <string>("frames"))
{
strs = (Dictionary <string, object>)pobDictionary["frames"];
}
int num = 0;
if (item != null)
{
num = ccUtils.ccParseInt(item["format"].ToString());
}
foreach (string key in strs.Keys)
{
Dictionary <string, object> item1 = strs[key] as Dictionary <string, object>;
CCSpriteFrame cCSpriteFrame = new CCSpriteFrame();
if (num == 0)
{
float single = ccUtils.ccParseFloat(item1["x"].ToString());
float single1 = ccUtils.ccParseFloat(item1["y"].ToString());
float single2 = ccUtils.ccParseFloat(item1["width"].ToString());
float single3 = ccUtils.ccParseFloat(item1["height"].ToString());
float single4 = ccUtils.ccParseFloat(item1["offsetX"].ToString());
float single5 = ccUtils.ccParseFloat(item1["offsetY"].ToString());
int num1 = ccUtils.ccParseInt(item1["originalWidth"].ToString());
int num2 = ccUtils.ccParseInt(item1["originalHeight"].ToString());
if (num1 == 0 || num2 == 0)
{
CCLog.Log("cocos2d: WARNING: originalWidth/Height not found on the CCSpriteFrame. AnchorPoint won't work as expected. Regenrate the .plist");
}
num1 = Math.Abs(num1);
num2 = Math.Abs(num2);
cCSpriteFrame = new CCSpriteFrame();
cCSpriteFrame.initWithTexture(pobTexture, new CCRect(single, single1, single2, single3), false, new CCPoint(single4, single5), new CCSize((float)num1, (float)num2));
}
else if (num == 1 || num == 2)
{
CCRect cCRect = CCNS.CCRectFromString(item1["frame"].ToString());
bool flag = false;
if (num == 2 && item1.Keys.Contains <string>("rotated"))
{
flag = (ccUtils.ccParseInt(this.valueForKey("rotated", item1)) == 0 ? false : true);
}
CCPoint cCPoint = CCNS.CCPointFromString(this.valueForKey("offset", item1));
CCSize cCSize = CCNS.CCSizeFromString(this.valueForKey("sourceSize", item1));
cCSpriteFrame = new CCSpriteFrame();
cCSpriteFrame.initWithTexture(pobTexture, cCRect, flag, cCPoint, cCSize);
}
else if (num == 3)
{
CCSize cCSize1 = CCNS.CCSizeFromString(this.valueForKey("spriteSize", item1));
CCPoint cCPoint1 = CCNS.CCPointFromString(this.valueForKey("spriteOffset", item1));
CCSize cCSize2 = CCNS.CCSizeFromString(this.valueForKey("spriteSourceSize", item1));
CCRect cCRect1 = CCNS.CCRectFromString(this.valueForKey("textureRect", item1));
bool flag1 = false;
if (item1.Keys.Contains <string>("textureRotated"))
{
flag1 = (ccUtils.ccParseInt(this.valueForKey("textureRotated", item1)) == 0 ? false : true);
}
object obj = item1["aliases"];
List <object> objs = item1["aliases"] as List <object>;
string str = key;
foreach (object obj1 in objs)
{
string str1 = obj1.ToString();
if (this.m_pSpriteFramesAliases.Keys.Contains <string>(str1) && this.m_pSpriteFramesAliases[str1] != null)
{
CCLog.Log("cocos2d: WARNING: an alias with name {0} already exists", new object[] { str1 });
}
if (this.m_pSpriteFramesAliases.Keys.Contains <string>(str))
{
continue;
}
this.m_pSpriteFramesAliases.Add(str, str1);
}
cCSpriteFrame = new CCSpriteFrame();
cCSpriteFrame.initWithTexture(pobTexture, new CCRect(cCRect1.origin.x, cCRect1.origin.y, cCSize1.width, cCSize1.height), flag1, cCPoint1, cCSize2);
}
if (this.m_pSpriteFrames.Keys.Contains <string>(key))
{
continue;
}
this.m_pSpriteFrames.Add(key, cCSpriteFrame);
}
}
public void setGravity(CCPoint g)
{
this.modeA.gravity = g;
}
private CCPoint ConvertToWindowSpace(CCPoint nodePoint)
{
CCPoint worldPoint = this.ConvertToWorldSpace(nodePoint);
return(Director.SharedDirector.ConvertToUI(worldPoint));
}
public override bool initWithTotalParticles(uint numberOfParticles)
{
if (base.initWithTotalParticles(numberOfParticles))
{
// duration
Duration = (float)eParticleShowingProperty.kCCParticleDurationInfinity;
// Emitter mode: Gravity Mode
EmitterMode = (int)eParticleMode.kCCParticleModeGravity;
// Gravity Mode: gravity
modeA.gravity = new CCPoint(0, 0);
// Gravity Mode: radial acceleration
modeA.radialAccel = 0;
modeA.radialAccelVar = 0;
// Gravity Mode: speed of particles
modeA.speed = 25;
modeA.speedVar = 10;
// angle
Angle = 90;
AngleVar = 5;
// emitter position
CCSize winSize = CCDirector.sharedDirector().getWinSize();
this.position = new CCPoint(winSize.width / 2, 0);
PosVar = new CCPoint(20, 0);
// life of particles
Life = 4;
LifeVar = 1;
// size, in pixels
StartSize = 60.0f;
StartSizeVar = 10.0f;
EndSize = (float)eParticleShowingProperty.kCCParticleStartSizeEqualToEndSize;
// emits per frame
EmissionRate = TotalParticles / Life;
// color of particles
StartColor.r = 0.8f;
StartColor.g = 0.8f;
StartColor.b = 0.8f;
StartColor.a = 1.0f;
StartColorVar.r = 0.02f;
StartColorVar.g = 0.02f;
StartColorVar.b = 0.02f;
StartColorVar.a = 0.0f;
EndColor.r = 0.0f;
EndColor.g = 0.0f;
EndColor.b = 0.0f;
EndColor.a = 1.0f;
EndColorVar.r = 0.0f;
EndColorVar.g = 0.0f;
EndColorVar.b = 0.0f;
EndColorVar.a = 0.0f;
// additive
this.IsBlendAdditive = false;
return(true);
}
return(false);
}
public virtual void updatePosition(CCPoint newPos)
{
m_pTarget.position = new CCPoint(newPos);
}
public override void updateQuadWithParticle(CCParticle particle, CCPoint newPosition)
{
// colors
ccV2F_C4B_T2F_Quad quad = m_pQuads[m_uParticleIdx];
ccColor4B color = new ccColor4B((Byte)(particle.color.r * 255), (Byte)(particle.color.g * 255), (Byte)(particle.color.b * 255),
(Byte)(particle.color.a * 255));
quad.bl.colors = color;
quad.br.colors = color;
quad.tl.colors = color;
quad.tr.colors = color;
// vertices
float size_2 = particle.size / 2;
if (particle.rotation != 0)
{
float x1 = -size_2;
float y1 = -size_2;
float x2 = size_2;
float y2 = size_2;
float x = newPosition.x;
float y = newPosition.y;
float r = -ccMacros.CC_DEGREES_TO_RADIANS(particle.rotation);
float cr = (float)System.Math.Cos(r);
float sr = (float)System.Math.Sin(r);
float ax = x1 * cr - y1 * sr + x;
float ay = x1 * sr + y1 * cr + y;
float bx = x2 * cr - y1 * sr + x;
float by = x2 * sr + y1 * cr + y;
float cx = x2 * cr - y2 * sr + x;
float cy = x2 * sr + y2 * cr + y;
float dx = x1 * cr - y2 * sr + x;
float dy = x1 * sr + y2 * cr + y;
// bottom-left
quad.bl.vertices.x = ax;
quad.bl.vertices.y = ay;
// bottom-right vertex:
quad.br.vertices.x = bx;
quad.br.vertices.y = by;
// top-left vertex:
quad.tl.vertices.x = dx;
quad.tl.vertices.y = dy;
// top-right vertex:
quad.tr.vertices.x = cx;
quad.tr.vertices.y = cy;
}
else
{
// bottom-left vertex:
quad.bl.vertices.x = newPosition.x - size_2;
quad.bl.vertices.y = newPosition.y - size_2;
// bottom-right vertex:
quad.br.vertices.x = newPosition.x + size_2;
quad.br.vertices.y = newPosition.y - size_2;
// top-left vertex:
quad.tl.vertices.x = newPosition.x - size_2;
quad.tl.vertices.y = newPosition.y + size_2;
// top-right vertex:
quad.tr.vertices.x = newPosition.x + size_2;
quad.tr.vertices.y = newPosition.y + size_2;
}
}
public static void ccDrawPoints(CCPoint points, int numberOfPoints)
{
throw new NotImplementedException();
}
public override void draw()
{
base.draw();
BlendState oldBlendState = CCApplication.sharedApplication().GraphicsDevice.BlendState;
BlendState eBlendState = BlendState.AlphaBlend;
if (this.IsBlendAdditive)
{
eBlendState = BlendState.Additive;
}
CCApplication.sharedApplication().spriteBatch.Begin(SpriteSortMode.Deferred, eBlendState);
for (int i = 0; i < this.ParticleCount; i++)
{
CCParticle particle = m_pParticles[i];
CCPoint uiPoint = CCAffineTransform.CCPointApplyAffineTransform(new CCPoint(), this.nodeToWorldTransform());
uiPoint = CCPointExtension.ccpAdd(uiPoint, new CCPoint(m_pQuads[i].bl.vertices.x, m_pQuads[i].bl.vertices.y));
uiPoint = CCDirector.sharedDirector().convertToUI(uiPoint);
Vector2 vecPosition = new Vector2(uiPoint.x, uiPoint.y);
Color color = new Color(particle.color.r,
particle.color.g,
particle.color.b,
particle.color.a);
float scale = 1.0f;
if (Texture.getTexture2D().Width > Texture.getTexture2D().Height)
{
scale = particle.size / Texture.getTexture2D().Height;
}
else
{
scale = particle.size / Texture.getTexture2D().Width;
}
float rotation = particle.rotation;
Vector2 origin = new Vector2(Texture.getTexture2D().Width / 2, Texture.getTexture2D().Height / 2);
CCApplication.sharedApplication().spriteBatch.Draw(this.Texture.getTexture2D(), vecPosition, null, color, rotation, origin, scale, SpriteEffects.None, 0);
//CCPoint uiPoint = CCAffineTransform.CCPointApplyAffineTransform(new CCPoint(), this.nodeToWorldTransform());
//uiPoint.x += m_pQuads[i].bl.vertices.x;
//uiPoint.y += m_pQuads[i].bl.vertices.y;
//uiPoint = CCDirector.sharedDirector().convertToUI(uiPoint);
//Vector2 vecPosition = new Vector2(uiPoint.x, uiPoint.y);
//Color color = new Color(m_pQuads[i].bl.colors.r,
// m_pQuads[i].bl.colors.g,
// m_pQuads[i].bl.colors.b,
// m_pQuads[i].bl.colors.a);
//Vector2 origin = new Vector2(Texture.getTexture2D().Width/2, Texture.getTexture2D().Height/2);
//CCApplication.sharedApplication().spriteBatch.Draw(this.Texture.getTexture2D(), vecPosition, null, color, 0, origin, 1.0f, SpriteEffects.None, 0);
}
CCApplication.sharedApplication().spriteBatch.End();
CCApplication.sharedApplication().GraphicsDevice.BlendState = oldBlendState;
// // Default GL states: GL_TEXTURE_2D, GL_VERTEX_ARRAY, GL_COLOR_ARRAY, GL_TEXTURE_COORD_ARRAY
// // Needed states: GL_TEXTURE_2D, GL_VERTEX_ARRAY, GL_COLOR_ARRAY, GL_TEXTURE_COORD_ARRAY
// // Unneeded states: -
// glBindTexture(GL_TEXTURE_2D, m_pTexture->getName());
// #define kQuadSize sizeof(m_pQuads[0].bl)
// int offset = (int) m_pQuads;
// // vertex
// int diff = offsetof( ccV2F_C4B_T2F, vertices);
// glVertexPointer(2,GL_FLOAT, kQuadSize, (GLvoid*) (offset+diff) );
// // color
// diff = offsetof( ccV2F_C4B_T2F, colors);
// glColorPointer(4, GL_UNSIGNED_BYTE, kQuadSize, (GLvoid*)(offset + diff));
// // tex coords
// diff = offsetof( ccV2F_C4B_T2F, texCoords);
// glTexCoordPointer(2, GL_FLOAT, kQuadSize, (GLvoid*)(offset + diff));
// bool newBlend = (m_tBlendFunc.src != CC_BLEND_SRC || m_tBlendFunc.dst != CC_BLEND_DST) ? true : false;
// if( newBlend )
// {
// glBlendFunc( m_tBlendFunc.src, m_tBlendFunc.dst );
// }
// CCAssert( m_uParticleIdx == m_uParticleCount, "Abnormal error in particle quad");
// glDrawElements(GL_TRIANGLES, (GLsizei)(m_uParticleIdx*6), GL_UNSIGNED_SHORT, m_pIndices);
// // restore blend state
// if( newBlend )
// glBlendFunc( CC_BLEND_SRC, CC_BLEND_DST );
//#if CC_USES_VBO
// glBindBuffer(GL_ARRAY_BUFFER, 0);
//#endif
}
public override void update(float dt)
{
if (this.m_bIsActive && (this.m_fEmissionRate != 0f))
{
float num = 1f / this.m_fEmissionRate;
this.m_fEmitCounter += dt;
while ((this.m_uParticleCount < this.m_uTotalParticles) && (this.m_fEmitCounter > num))
{
this.addParticle();
this.m_fEmitCounter -= num;
}
this.m_fElapsed += dt;
if ((this.m_fDuration != -1f) && (this.m_fDuration < this.m_fElapsed))
{
this.stopSystem();
}
}
this.m_uParticleIdx = 0;
CCPoint tPosition = new CCPoint(0f, 0f);
if (this.m_ePositionType == eParticlePositionType.kCCPositionTypeFree)
{
tPosition = base.convertToWorldSpace(new CCPoint(0f, 0f));
tPosition.x *= CCDirector.sharedDirector().ContentScaleFactor;
tPosition.y *= CCDirector.sharedDirector().ContentScaleFactor;
}
else if (this.m_ePositionType == eParticlePositionType.kCCPositionTypeRelative)
{
tPosition = base.m_tPosition;
tPosition.x *= CCDirector.sharedDirector().ContentScaleFactor;
tPosition.y *= CCDirector.sharedDirector().ContentScaleFactor;
}
while (this.m_uParticleIdx < this.m_uParticleCount)
{
CCParticle particle = this.m_pParticles[this.m_uParticleIdx];
particle.timeToLive -= dt;
if (particle.timeToLive > 0f)
{
CCPoint pos;
if (this.m_nEmitterMode == 0)
{
CCPoint v = new CCPoint(0f, 0f);
if ((particle.pos.x != 0f) || (particle.pos.y != 0f))
{
v = CCPointExtension.ccpNormalize(particle.pos);
}
CCPoint point4 = v;
v = CCPointExtension.ccpMult(v, particle.modeA.radialAccel);
float x = point4.x;
point4.x = -point4.y;
point4.y = x;
point4 = CCPointExtension.ccpMult(point4, particle.modeA.tangentialAccel);
CCPoint point2 = CCPointExtension.ccpMult(CCPointExtension.ccpAdd(CCPointExtension.ccpAdd(v, point4), this.modeA.gravity), dt);
particle.modeA.dir = CCPointExtension.ccpAdd(particle.modeA.dir, point2);
point2 = CCPointExtension.ccpMult(particle.modeA.dir, dt);
particle.pos = CCPointExtension.ccpAdd(particle.pos, point2);
}
else
{
particle.modeB.angle += particle.modeB.degreesPerSecond * dt;
particle.modeB.radius += particle.modeB.deltaRadius * dt;
particle.pos.x = -((float)Math.Cos((double)particle.modeB.angle)) * particle.modeB.radius;
particle.pos.y = -((float)Math.Sin((double)particle.modeB.angle)) * particle.modeB.radius;
}
particle.color.r += particle.deltaColor.r * dt;
particle.color.g += particle.deltaColor.g * dt;
particle.color.b += particle.deltaColor.b * dt;
particle.color.a += particle.deltaColor.a * dt;
particle.size += particle.deltaSize * dt;
particle.size = (0f > particle.size) ? 0f : particle.size;
particle.rotation += particle.deltaRotation * dt;
if ((this.m_ePositionType == eParticlePositionType.kCCPositionTypeFree) || (this.m_ePositionType == eParticlePositionType.kCCPositionTypeRelative))
{
CCPoint point6 = CCPointExtension.ccpSub(tPosition, particle.startPos);
pos = CCPointExtension.ccpSub(particle.pos, point6);
}
else
{
pos = particle.pos;
}
this.updateQuadWithParticle(particle, pos);
this.m_uParticleIdx++;
}
else
{
if (this.m_uParticleIdx != (this.m_uParticleCount - 1))
{
this.m_pParticles[this.m_uParticleIdx].copy(this.m_pParticles[(int)((IntPtr)(this.m_uParticleCount - 1))]);
}
this.m_uParticleCount--;
if ((this.m_uParticleCount == 0) && this.m_bIsAutoRemoveOnFinish)
{
base.unscheduleUpdate();
base.m_pParent.removeChild(this, true);
return;
}
}
}
this.postStep();
}
/// <summary>
/// Initializes a CCSpriteFrame with a texture, rect, rotated, offset and originalSize in pixels.
/// The originalSize is the size in points of the frame before being trimmed.
/// </summary>
public bool initWithTexture(CCTexture2D pobTexture, CCRect rect, bool rotated, CCPoint offset, CCSize originalSize)
{
m_pobTexture = pobTexture;
m_obRectInPixels = rect;
m_obRect = ccMacros.CC_RECT_PIXELS_TO_POINTS(rect);
m_bRotated = rotated;
m_obOffsetInPixels = offset;
m_obOriginalSizeInPixels = originalSize;
return(true);
}
public sModeA()
{
this.dir = new CCPoint();
}
public virtual void updateQuadWithParticle(CCParticle particle, CCPoint newPosition)
{
}
public static void ccDrawPoint(CCPoint point)
{
}
public static void LineToPolygon(CCPoint[] points, float stroke, ccVertex2F[] vertices, int offset, int nuPoints)
{
nuPoints += offset;
if (nuPoints <= 1)
{
return;
}
stroke *= 0.5f;
int idx;
int nuPointsMinus = nuPoints - 1;
for (int i = offset; i < nuPoints; i++)
{
idx = i * 2;
CCPoint p1 = points[i];
CCPoint perpVector;
if (i == 0)
{
perpVector = CCPointExtension.ccpPerp(CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(p1, points[i + 1])));
}
else if (i == nuPointsMinus)
{
perpVector = CCPointExtension.ccpPerp(CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(points[i - 1], p1)));
}
else
{
CCPoint p2 = points[i + 1];
CCPoint p0 = points[i - 1];
CCPoint p2p1 = CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(p2, p1));
CCPoint p0p1 = CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(p0, p1));
// Calculate angle between vectors
float angle = (float)Math.Acos(CCPointExtension.ccpDot(p2p1, p0p1));
if (angle < ccMacros.CC_DEGREES_TO_RADIANS(70))
{
perpVector = CCPointExtension.ccpPerp(CCPointExtension.ccpNormalize(CCPointExtension.ccpMidpoint(p2p1, p0p1)));
}
else if (angle < ccMacros.CC_DEGREES_TO_RADIANS(170))
{
perpVector = CCPointExtension.ccpNormalize(CCPointExtension.ccpMidpoint(p2p1, p0p1));
}
else
{
perpVector = CCPointExtension.ccpPerp(CCPointExtension.ccpNormalize(CCPointExtension.ccpSub(p2, p0)));
}
}
perpVector = CCPointExtension.ccpMult(perpVector, stroke);
vertices[idx] = new ccVertex2F(p1.x + perpVector.x, p1.y + perpVector.y);
vertices[idx + 1] = new ccVertex2F(p1.x - perpVector.x, p1.y - perpVector.y);
}
// Validate vertexes
offset = (offset == 0) ? 0 : (offset - 1);
for (int i = offset; i < nuPointsMinus; i++)
{
idx = i * 2;
int idx1 = idx + 2;
ccVertex2F p1 = vertices[idx];
ccVertex2F p2 = vertices[idx + 1];
ccVertex2F p3 = vertices[idx1];
ccVertex2F p4 = vertices[idx1 + 1];
float s = 0f;
//BOOL fixVertex = !ccpLineIntersect(ccp(p1.x, p1.y), ccp(p4.x, p4.y), ccp(p2.x, p2.y), ccp(p3.x, p3.y), &s, &t);
bool fixVertex = !LineIntersect(p1.x, p1.y, p4.x, p4.y, p2.x, p2.y, p3.x, p3.y, out s);
if (!fixVertex)
{
if (s < 0.0f || s > 1.0f)
{
fixVertex = true;
}
}
if (fixVertex)
{
vertices[idx1] = p4;
vertices[idx1 + 1] = p3;
}
}
}
public static void ccDrawCubicBezier(CCPoint origin, CCPoint control1, CCPoint control2, CCPoint destination, int segments, ccColor4F color)
{
VertexPositionColor[] vector3 = new VertexPositionColor[segments + 1];
float contentScaleFactor = CCDirector.sharedDirector().ContentScaleFactor;
CCApplication cCApplication = CCApplication.sharedApplication();
float single = 0f;
for (int i = 0; i < segments; i++)
{
float single1 = (float)Math.Pow((double)(1f - single), 3) * origin.x + 3f * (float)Math.Pow((double)(1f - single), 2) * single * control1.x + 3f * (1f - single) * single * single * control2.x + single * single * single * destination.x;
float single2 = (float)Math.Pow((double)(1f - single), 3) * origin.y + 3f * (float)Math.Pow((double)(1f - single), 2) * single * control1.y + 3f * (1f - single) * single * single * control2.y + single * single * single * destination.y;
vector3[i] = new VertexPositionColor();
vector3[i].Position = new Vector3(single1 * contentScaleFactor, single2 * contentScaleFactor, 0f);
vector3[i].Color = new Color(color.r, color.g, color.b, color.a);
single = single + 1f / (float)segments;
}
VertexPositionColor vertexPositionColor = new VertexPositionColor()
{
Color = new Color(color.r, color.g, color.b, color.a),
Position = new Vector3(destination.x * contentScaleFactor, destination.y * contentScaleFactor, 0f)
};
vector3[segments] = vertexPositionColor;
cCApplication.basicEffect.TextureEnabled = false;
cCApplication.basicEffect.VertexColorEnabled = true;
foreach (EffectPass pass in cCApplication.basicEffect.CurrentTechnique.Passes)
{
pass.Apply();
cCApplication.GraphicsDevice.DrawUserPrimitives <VertexPositionColor>(PrimitiveType.LineStrip, vector3, 0, segments);
}
}
public virtual void updatePosition(CCPoint newPos)
{
Target.Position = newPos + m_startPosition;
}
/// <summary>
/// set center position
/// </summary>
public void setPosition(CCPoint position)
{
m_position = position;
m_positionInPixels.X = position.X * Director.SharedDirector.ContentScaleFactor;
m_positionInPixels.Y = position.Y * Director.SharedDirector.ContentScaleFactor;
}
public CCTouch(int nViewId, float x, float y)
{
this.m_nViewId = nViewId;
this.m_point = new CCPoint(x, y);
this.m_prevPoint = new CCPoint(x, y);
}
public CCPlace()
{
m_tPosition = new CCPoint();
}
public virtual new void updatePosition(CCPoint newPos)
{
this.m_pTarget.position = newPos.Add(this.m_startPosition);
}
