axmol/cocos2dx/particle_nodes/CCParticleSystem.cpp

/****************************************************************************
Copyright (c) 2010-2011 cocos2d-x.org
Copyright (c) 2008-2010 Ricardo Quesada

http://www.cocos2d-x.org

Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
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all copies or substantial portions of the Software.

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IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
****************************************************************************/

// ideas taken from:
//	 . The ocean spray in your face [Jeff Lander]
//		http://www.double.co.nz/dust/col0798.pdf
//	 . Building an Advanced Particle System [John van der Burg]
//		http://www.gamasutra.com/features/20000623/vanderburg_01.htm
//   . LOVE game engine
//		http://love2d.org/
//
//
// Radius mode support, from 71 squared
//		http://particledesigner.71squared.com/
//
// IMPORTANT: Particle Designer is supported by cocos2d, but
// 'Radius Mode' in Particle Designer uses a fixed emit rate of 30 hz. Since that can't be guarateed in cocos2d,
//  cocos2d uses a another approach, but the results are almost identical. 
//

#include "CCParticleSystem.h"
#include "ccTypes.h"
#include "CCTextureCache.h"
#include "support/base64.h"
#include "CCPointExtension.h"
#include "CCFileUtils.h"
#include "CCImage.h"
#include "platform/platform.h"
#include "support/zip_support/ZipUtils.h"

// opengl
#include "platform/CCGL.h"

#if CC_ENABLE_PROFILERS
#include "Support/CCProfiling.h"
#endif

namespace cocos2d {

// ideas taken from:
//	 . The ocean spray in your face [Jeff Lander]
//		http://www.double.co.nz/dust/col0798.pdf
//	 . Building an Advanced Particle System [John van der Burg]
//		http://www.gamasutra.com/features/20000623/vanderburg_01.htm
//   . LOVE game engine
//		http://love2d.org/
//
//
// Radius mode support, from 71 squared
//		http://particledesigner.71squared.com/
//
// IMPORTANT: Particle Designer is supported by cocos2d, but
// 'Radius Mode' in Particle Designer uses a fixed emit rate of 30 hz. Since that can't be guarateed in cocos2d,
//  cocos2d uses a another approach, but the results are almost identical. 
//

CCParticleSystem::CCParticleSystem()
	:m_sPlistFile("")
	,m_fElapsed(0)
	,m_pParticles(NULL)
	,m_fEmitCounter(0)
	,m_nParticleIdx(0)
#if CC_ENABLE_PROFILERS
	,m_pProfilingTimer(NULL)
#endif
	,m_bIsActive(true)
	,m_nParticleCount(0)
	,m_fDuration(0)
	,m_tSourcePosition(CCPointZero)
	,m_tPosVar(CCPointZero)
	,m_fLife(0)
	,m_fLifeVar(0)
	,m_fAngle(0)
	,m_fAngleVar(0)
	,m_fStartSize(0)
	,m_fStartSizeVar(0)
	,m_fEndSize(0)
	,m_fEndSizeVar(0)
	,m_fStartSpin(0)
	,m_fStartSpinVar(0)
	,m_fEndSpin(0)
	,m_fEndSpinVar(0)
	,m_fEmissionRate(0)
	,m_nTotalParticles(0)
	,m_pTexture(NULL)
	,m_bIsBlendAdditive(false)
	,m_ePositionType(kCCPositionTypeFree)
	,m_bIsAutoRemoveOnFinish(false)
	,m_nEmitterMode(kCCParticleModeGravity)
{
	modeA.gravity = CCPointZero;
	modeA.speed = 0;
	modeA.speedVar = 0;
	modeA.tangentialAccel = 0;
	modeA.tangentialAccelVar = 0;
	modeA.radialAccel = 0;
	modeA.radialAccelVar = 0;
	modeB.startRadius = 0;
	modeB.startRadiusVar = 0;
	modeB.endRadius = 0;
	modeB.endRadiusVar = 0;			
	modeB.rotatePerSecond = 0;
	modeB.rotatePerSecondVar = 0;
	m_tBlendFunc.src = CC_BLEND_SRC;
	m_tBlendFunc.dst = CC_BLEND_DST;
}
// implementation CCParticleSystem
CCParticleSystem * CCParticleSystem::particleWithFile(const char *plistFile)
{
	CCParticleSystem *pRet = new CCParticleSystem();
	if (pRet && pRet->initWithFile(plistFile))
	{
		pRet->autorelease();
		return pRet;
	}
	CC_SAFE_DELETE(pRet)
	return pRet;
}
bool CCParticleSystem::initWithFile(const char *plistFile)
{
	m_sPlistFile = CCFileUtils::fullPathFromRelativePath(plistFile);
	CCDictionary<std::string, CCObject*> *dict = CCFileUtils::dictionaryWithContentsOfFile(m_sPlistFile.c_str());

	CCAssert( dict != NULL, "Particles: file not found");
	return this->initWithDictionary(dict);
}

bool CCParticleSystem::initWithDictionary(CCDictionary<std::string, CCObject*> *dictionary)
{
	bool bRet = false;
	unsigned char *buffer = NULL;
	unsigned char *deflated = NULL;
	CCImage *image = NULL;
	do 
	{
		int maxParticles = atoi(valueForKey("maxParticles", dictionary));
		// self, not super
		if(this->initWithTotalParticles(maxParticles))
		{
			// angle
			m_fAngle = (float)atof(valueForKey("angle", dictionary));
			m_fAngleVar = (float)atof(valueForKey("angleVariance", dictionary));

			// duration
			m_fDuration = (float)atof(valueForKey("duration", dictionary));

			// blend function 
			m_tBlendFunc.src = atoi(valueForKey("blendFuncSource", dictionary));
			m_tBlendFunc.dst = atoi(valueForKey("blendFuncDestination", dictionary));

			// color
			m_tStartColor.r = (float)atof(valueForKey("startColorRed", dictionary));
			m_tStartColor.g = (float)atof(valueForKey("startColorGreen", dictionary));
			m_tStartColor.b = (float)atof(valueForKey("startColorBlue", dictionary));
			m_tStartColor.a = (float)atof(valueForKey("startColorAlpha", dictionary));

			m_tStartColorVar.r = (float)atof(valueForKey("startColorVarianceRed", dictionary));
			m_tStartColorVar.g = (float)atof(valueForKey("startColorVarianceGreen", dictionary));
			m_tStartColorVar.b = (float)atof(valueForKey("startColorVarianceBlue", dictionary));
			m_tStartColorVar.a = (float)atof(valueForKey("startColorVarianceAlpha", dictionary));

			m_tEndColor.r = (float)atof(valueForKey("finishColorRed", dictionary));
			m_tEndColor.g = (float)atof(valueForKey("finishColorGreen", dictionary));
			m_tEndColor.b = (float)atof(valueForKey("finishColorBlue", dictionary));
			m_tEndColor.a = (float)atof(valueForKey("finishColorAlpha", dictionary));

			m_tEndColorVar.r = (float)atof(valueForKey("finishColorVarianceRed", dictionary));
			m_tEndColorVar.g = (float)atof(valueForKey("finishColorVarianceGreen", dictionary));
			m_tEndColorVar.b = (float)atof(valueForKey("finishColorVarianceBlue", dictionary));
			m_tEndColorVar.a = (float)atof(valueForKey("finishColorVarianceAlpha", dictionary));

			// particle size
			m_fStartSize = (float)atof(valueForKey("startParticleSize", dictionary));
			m_fStartSizeVar = (float)atof(valueForKey("startParticleSizeVariance", dictionary));
			m_fEndSize = (float)atof(valueForKey("finishParticleSize", dictionary));
			m_fEndSizeVar = (float)atof(valueForKey("finishParticleSizeVariance", dictionary));

			// position
			m_tPosition.x = (float)atof(valueForKey("sourcePositionx", dictionary));
			m_tPosition.y = (float)atof(valueForKey("sourcePositiony", dictionary));
			m_tPosVar.x = (float)atof(valueForKey("sourcePositionVariancex", dictionary));
			m_tPosVar.y = (float)atof(valueForKey("sourcePositionVariancey", dictionary));

			m_nEmitterMode = atoi(valueForKey("emitterType", dictionary));

			// Mode A: Gravity + tangential accel + radial accel
			if( m_nEmitterMode == kCCParticleModeGravity ) 
			{
				// gravity
				modeA.gravity.x = (float)atof(valueForKey("gravityx", dictionary));
				modeA.gravity.y = (float)atof(valueForKey("gravityy", dictionary));

				// speed
				modeA.speed = (float)atof(valueForKey("speed", dictionary));
				modeA.speedVar = (float)atof(valueForKey("speedVariance", dictionary));

                const char * pszTmp = NULL;
				// radial acceleration
                pszTmp = valueForKey("radialAcceleration", dictionary);
                modeA.radialAccel = (pszTmp) ? (float)atof(pszTmp) : 0;

                pszTmp = valueForKey("radialAccelVariance", dictionary);
				modeA.radialAccelVar = (pszTmp) ? (float)atof(pszTmp) : 0;

				// tangential acceleration
                pszTmp = valueForKey("tangentialAcceleration", dictionary);
				modeA.tangentialAccel = (pszTmp) ? (float)atof(pszTmp) : 0;

                pszTmp = valueForKey("tangentialAccelVariance", dictionary);
				modeA.tangentialAccelVar = (pszTmp) ? (float)atof(pszTmp) : 0;
			}

			// or Mode B: radius movement
			else if( m_nEmitterMode == kCCParticleModeRadius ) 
			{
				modeB.startRadius = (float)atof(valueForKey("maxRadius", dictionary));
				modeB.startRadiusVar = (float)atof(valueForKey("maxRadiusVariance", dictionary));
				modeB.endRadius = (float)atof(valueForKey("minRadius", dictionary));
				modeB.endRadiusVar = 0;
				modeB.rotatePerSecond = (float)atof(valueForKey("rotatePerSecond", dictionary));
				modeB.rotatePerSecondVar = (float)atof(valueForKey("rotatePerSecondVariance", dictionary));

			} else {
				CCAssert( false, "Invalid emitterType in config file");
				CC_BREAK_IF(true);
			}

			// life span
			m_fLife = (float)atof(valueForKey("particleLifespan", dictionary));
			m_fLifeVar = (float)atof(valueForKey("particleLifespanVariance", dictionary));

			// emission Rate
			m_fEmissionRate = m_nTotalParticles / m_fLife;

			// texture		
			// Try to get the texture from the cache
			char *textureName = (char *)valueForKey("textureFileName", dictionary);
            std::string fullpath = CCFileUtils::fullPathFromRelativeFile(textureName, m_sPlistFile.c_str());

            if (strlen(textureName) > 0)
            {
                // set not pop-up message box when load image failed
                bool bNotify = CCFileUtils::getIsPopupNotify();
                CCFileUtils::setIsPopupNotify(false);
                this->m_pTexture = CCTextureCache::sharedTextureCache()->addImage(fullpath.c_str());

                // reset the value of UIImage notify
                CCFileUtils::setIsPopupNotify(bNotify);
            }

			// if it fails, try to get it from the base64-gzipped data			
            char *textureData = NULL;
			if ( ! m_pTexture && 
                (textureData = (char *)valueForKey("textureImageData", dictionary)))
			{
				int dataLen = strlen(textureData);
				if(dataLen != 0)
				{
					int decodeLen = base64Decode((unsigned char*)textureData, dataLen, &buffer);
					CCAssert( buffer != NULL, "CCParticleSystem: error decoding textureImageData");
					CC_BREAK_IF(!buffer);

						int deflatedLen = ZipUtils::ccInflateMemory(buffer, decodeLen, &deflated);
						CCAssert( deflated != NULL, "CCParticleSystem: error ungzipping textureImageData");
						CC_BREAK_IF(!deflated);
						
						image = new CCImage();
						bool isOK = image->initWithImageData(deflated, deflatedLen);
						CCAssert(isOK, "CCParticleSystem: error init image with Data");
						CC_BREAK_IF(!isOK);
						
						m_pTexture = CCTextureCache::sharedTextureCache()->addUIImage(image, fullpath.c_str());
				}
			}
			CCAssert( this->m_pTexture != NULL, "CCParticleSystem: error loading the texture");
			
			CC_BREAK_IF(!m_pTexture);
			this->m_pTexture->retain();
			bRet = true;
		}
	} while (0);
	CC_SAFE_DELETE_ARRAY(buffer);
    CC_SAFE_DELETE_ARRAY(deflated);
	CC_SAFE_DELETE(image);
	return bRet;
}
bool CCParticleSystem::initWithTotalParticles(int numberOfParticles)
{
	m_nTotalParticles = numberOfParticles;

    CC_SAFE_DELETE_ARRAY(m_pParticles);
	
	m_pParticles = new tCCParticle[m_nTotalParticles];

	if( ! m_pParticles )
	{
		CCLOG("Particle system: not enough memory");
		this->release();
		return false;
	}

	// default, active
	m_bIsActive = true;

	// default blend function
	m_tBlendFunc.src = CC_BLEND_SRC;
	m_tBlendFunc.dst = CC_BLEND_DST;

	// default movement type;
	m_ePositionType = kCCPositionTypeFree;

	// by default be in mode A:
	m_nEmitterMode = kCCParticleModeGravity;

	// default: modulate
	// XXX: not used
	//	colorModulate = YES;

	m_bIsAutoRemoveOnFinish = false;

	// profiling
#if CC_ENABLE_PROFILERS
	/// @todo _profilingTimer = [[CCProfiler timerWithName:@"particle system" andInstance:self] retain];
#endif

	// Optimization: compile udpateParticle method
	//updateParticleSel = @selector(updateQuadWithParticle:newPosition:);
	//updateParticleImp = (CC_UPDATE_PARTICLE_IMP) [self methodForSelector:updateParticleSel];

	// udpate after action in run!
	this->scheduleUpdateWithPriority(1);

	return true;
}

CCParticleSystem::~CCParticleSystem()
{
    CC_SAFE_DELETE_ARRAY(m_pParticles);
	CC_SAFE_RELEASE(m_pTexture)
	// profiling
#if CC_ENABLE_PROFILERS
	/// @todo [CCProfiler releaseTimer:_profilingTimer];
#endif
}
bool CCParticleSystem::addParticle()
{
	if (this->isFull())
	{
		return false;
	}

	tCCParticle * particle = &m_pParticles[ m_nParticleCount ];
	this->initParticle(particle);
	++m_nParticleCount;

	return true;
}
void CCParticleSystem::initParticle(tCCParticle* particle)
{
	// timeToLive
	// no negative life. prevent division by 0
	particle->timeToLive = MAX(0, m_fLife + m_fLifeVar * CCRANDOM_MINUS1_1() );

	// position
	particle->pos.x = m_tSourcePosition.x + m_tPosVar.x * CCRANDOM_MINUS1_1();
    particle->pos.x *= CC_CONTENT_SCALE_FACTOR();
	particle->pos.y = m_tSourcePosition.y + m_tPosVar.y * CCRANDOM_MINUS1_1();
    particle->pos.y *= CC_CONTENT_SCALE_FACTOR();

	// Color
	ccColor4F start;
	start.r = MIN(1, MAX(0, m_tStartColor.r + m_tStartColorVar.r * CCRANDOM_MINUS1_1() ) );
	start.g = MIN(1, MAX(0, m_tStartColor.g + m_tStartColorVar.g * CCRANDOM_MINUS1_1() ) );
	start.b = MIN(1, MAX(0, m_tStartColor.b + m_tStartColorVar.b * CCRANDOM_MINUS1_1() ) );
	start.a = MIN(1, MAX(0, m_tStartColor.a + m_tStartColorVar.a * CCRANDOM_MINUS1_1() ) );

	ccColor4F end;
	end.r = MIN(1, MAX(0, m_tEndColor.r + m_tEndColorVar.r * CCRANDOM_MINUS1_1() ) );
	end.g = MIN(1, MAX(0, m_tEndColor.g + m_tEndColorVar.g * CCRANDOM_MINUS1_1() ) );
	end.b = MIN(1, MAX(0, m_tEndColor.b + m_tEndColorVar.b * CCRANDOM_MINUS1_1() ) );
	end.a = MIN(1, MAX(0, m_tEndColor.a + m_tEndColorVar.a * CCRANDOM_MINUS1_1() ) );

	particle->color = start;
	particle->deltaColor.r = (end.r - start.r) / particle->timeToLive;
	particle->deltaColor.g = (end.g - start.g) / particle->timeToLive;
	particle->deltaColor.b = (end.b - start.b) / particle->timeToLive;
	particle->deltaColor.a = (end.a - start.a) / particle->timeToLive;

	// size
	float startS = MAX(0, m_fStartSize + m_fStartSizeVar * CCRANDOM_MINUS1_1() ); // no negative size
    startS *= CC_CONTENT_SCALE_FACTOR();

	particle->size = startS;

	if( m_fEndSize == kCCParticleStartSizeEqualToEndSize )
	{
		particle->deltaSize = 0;
	}
	else
	{
		float endS = m_fEndSize + m_fEndSizeVar * CCRANDOM_MINUS1_1();
		endS = MAX(0, endS);
        endS *= CC_CONTENT_SCALE_FACTOR();
		particle->deltaSize = (endS - startS) / particle->timeToLive;
	}

	// rotation
	float startA = m_fStartSpin + m_fStartSpinVar * CCRANDOM_MINUS1_1();
	float endA = m_fEndSpin + m_fEndSpinVar * CCRANDOM_MINUS1_1();
	particle->rotation = startA;
	particle->deltaRotation = (endA - startA) / particle->timeToLive;

	// position
	if( m_ePositionType == kCCPositionTypeFree )
	{
        CCPoint p = this->convertToWorldSpace(CCPointZero);
		particle->startPos = ccpMult( p, CC_CONTENT_SCALE_FACTOR() );
	}
    else if ( m_ePositionType == kCCPositionTypeRelative )
    {
        particle->startPos = ccpMult( m_tPosition, CC_CONTENT_SCALE_FACTOR() );
    }

	// direction
	float a = CC_DEGREES_TO_RADIANS( m_fAngle + m_fAngleVar * CCRANDOM_MINUS1_1() );	

	// Mode Gravity: A
	if( m_nEmitterMode == kCCParticleModeGravity ) 
	{
		CCPoint v(cosf( a ), sinf( a ));
		float s = modeA.speed + modeA.speedVar * CCRANDOM_MINUS1_1();
        s *= CC_CONTENT_SCALE_FACTOR();

		// direction
		particle->modeA.dir = ccpMult( v, s );

		// radial accel
		particle->modeA.radialAccel = modeA.radialAccel + modeA.radialAccelVar * CCRANDOM_MINUS1_1();
        particle->modeA.radialAccel *= CC_CONTENT_SCALE_FACTOR();

		// tangential accel
		particle->modeA.tangentialAccel = modeA.tangentialAccel + modeA.tangentialAccelVar * CCRANDOM_MINUS1_1();
        particle->modeA.tangentialAccel *= CC_CONTENT_SCALE_FACTOR();
    }

	// Mode Radius: B
	else {
		// Set the default diameter of the particle from the source position
		float startRadius = modeB.startRadius + modeB.startRadiusVar * CCRANDOM_MINUS1_1();
		float endRadius = modeB.endRadius + modeB.endRadiusVar * CCRANDOM_MINUS1_1();
        startRadius *= CC_CONTENT_SCALE_FACTOR();
        endRadius *= CC_CONTENT_SCALE_FACTOR();

		particle->modeB.radius = startRadius;

		if( modeB.endRadius == kCCParticleStartRadiusEqualToEndRadius )
			particle->modeB.deltaRadius = 0;
		else
			particle->modeB.deltaRadius = (endRadius - startRadius) / particle->timeToLive;

		particle->modeB.angle = a;
		particle->modeB.degreesPerSecond = CC_DEGREES_TO_RADIANS(modeB.rotatePerSecond + modeB.rotatePerSecondVar * CCRANDOM_MINUS1_1());
	}	
}
void CCParticleSystem::stopSystem()
{
	m_bIsActive = false;
	m_fElapsed = m_fDuration;
	m_fEmitCounter = 0;
}
void CCParticleSystem::resetSystem()
{
	m_bIsActive = true;
	m_fElapsed = 0;
	for (m_nParticleIdx = 0; m_nParticleIdx < m_nParticleCount; ++m_nParticleIdx)
	{
		tCCParticle *p = &m_pParticles[m_nParticleIdx];
		p->timeToLive = 0;
	}
}
bool CCParticleSystem::isFull()
{
	return (m_nParticleCount == m_nTotalParticles);
}

// ParticleSystem - MainLoop
void CCParticleSystem::update(ccTime dt)
{
	if( m_bIsActive && m_fEmissionRate )
	{
		float rate = 1.0f / m_fEmissionRate;
		m_fEmitCounter += dt;
		while( m_nParticleCount < m_nTotalParticles && m_fEmitCounter > rate ) 
		{
			this->addParticle();
			m_fEmitCounter -= rate;
		}

		m_fElapsed += dt;
		if(m_fDuration != -1 && m_fDuration < m_fElapsed)
		{
			this->stopSystem();
		}
	}

	m_nParticleIdx = 0;


#if CC_ENABLE_PROFILERS
	/// @todo CCProfilingBeginTimingBlock(_profilingTimer);
#endif


	CCPoint currentPosition = CCPointZero;
	if( m_ePositionType == kCCPositionTypeFree )
	{
		currentPosition = this->convertToWorldSpace(CCPointZero);
        currentPosition.x *= CC_CONTENT_SCALE_FACTOR();
        currentPosition.y *= CC_CONTENT_SCALE_FACTOR();
	}
    else if ( m_ePositionType == kCCPositionTypeRelative )
    {
        currentPosition = m_tPosition;
        currentPosition.x *= CC_CONTENT_SCALE_FACTOR();
        currentPosition.y *= CC_CONTENT_SCALE_FACTOR();
    }

	while( m_nParticleIdx < m_nParticleCount )
	{
		tCCParticle *p = &m_pParticles[m_nParticleIdx];

		// life
		p->timeToLive -= dt;

		if( p->timeToLive > 0 ) 
		{
			// Mode A: gravity, direction, tangential accel & radial accel
			if( m_nEmitterMode == kCCParticleModeGravity ) 
			{
				CCPoint tmp, radial, tangential;

				radial = CCPointZero;
				// radial acceleration
				if(p->pos.x || p->pos.y)
					radial = ccpNormalize(p->pos);
				tangential = radial;
				radial = ccpMult(radial, p->modeA.radialAccel);

				// tangential acceleration
				float newy = tangential.x;
				tangential.x = -tangential.y;
				tangential.y = newy;
				tangential = ccpMult(tangential, p->modeA.tangentialAccel);

				// (gravity + radial + tangential) * dt
				tmp = ccpAdd( ccpAdd( radial, tangential), modeA.gravity);
				tmp = ccpMult( tmp, dt);
				p->modeA.dir = ccpAdd( p->modeA.dir, tmp);
				tmp = ccpMult(p->modeA.dir, dt);
				p->pos = ccpAdd( p->pos, tmp );
			}

			// Mode B: radius movement
			else {				
				// Update the angle and radius of the particle.
				p->modeB.angle += p->modeB.degreesPerSecond * dt;
				p->modeB.radius += p->modeB.deltaRadius * dt;

				p->pos.x = - cosf(p->modeB.angle) * p->modeB.radius;
				p->pos.y = - sinf(p->modeB.angle) * p->modeB.radius;
			}

			// color
			p->color.r += (p->deltaColor.r * dt);
			p->color.g += (p->deltaColor.g * dt);
			p->color.b += (p->deltaColor.b * dt);
			p->color.a += (p->deltaColor.a * dt);

			// size
			p->size += (p->deltaSize * dt);
			p->size = MAX( 0, p->size );

			// angle
			p->rotation += (p->deltaRotation * dt);

			//
			// update values in quad
			//

			CCPoint	newPos;

			if( m_ePositionType == kCCPositionTypeFree || m_ePositionType == kCCPositionTypeRelative ) 
			{
				CCPoint diff = ccpSub( currentPosition, p->startPos );
				newPos = ccpSub(p->pos, diff);
			} 
			else
			{
				newPos = p->pos;
			}

			updateQuadWithParticle(p, newPos);
			//updateParticleImp(self, updateParticleSel, p, newPos);

			// update particle counter
			++m_nParticleIdx;

		} 
		else 
		{
			// life < 0
			if( m_nParticleIdx != m_nParticleCount-1 )
			{
				m_pParticles[m_nParticleIdx] = m_pParticles[m_nParticleCount-1];
			}
			--m_nParticleCount;

			if( m_nParticleCount == 0 && m_bIsAutoRemoveOnFinish )
			{
				this->unscheduleUpdate();
				m_pParent->removeChild(this, true);
				return;
			}
		}
	}

#if CC_ENABLE_PROFILERS
	/// @todo CCProfilingEndTimingBlock(_profilingTimer);
#endif

//#ifdef CC_USES_VBO
	this->postStep();
//#endif
}
void CCParticleSystem::updateQuadWithParticle(tCCParticle* particle, CCPoint newPosition)
{
	// should be overriden
}
void CCParticleSystem::postStep()
{
	// should be overriden
}

// ParticleSystem - CCTexture protocol
void CCParticleSystem::setTexture(CCTexture2D* var)
{
	CC_SAFE_RETAIN(var);
	CC_SAFE_RELEASE(m_pTexture)
	m_pTexture = var;

	// If the new texture has No premultiplied alpha, AND the blendFunc hasn't been changed, then update it
	if( m_pTexture && ! m_pTexture->getHasPremultipliedAlpha() &&		
		( m_tBlendFunc.src == CC_BLEND_SRC && m_tBlendFunc.dst == CC_BLEND_DST ) ) 
	{
		m_tBlendFunc.src = GL_SRC_ALPHA;
		m_tBlendFunc.dst = GL_ONE_MINUS_SRC_ALPHA;
	}
}
CCTexture2D * CCParticleSystem::getTexture()
{
	return m_pTexture;
}

// ParticleSystem - Additive Blending
void CCParticleSystem::setIsBlendAdditive(bool additive)
{
	if( additive )
	{
		m_tBlendFunc.src = GL_SRC_ALPHA;
		m_tBlendFunc.dst = GL_ONE;
	}
	else
	{
		if( m_pTexture && ! m_pTexture->getHasPremultipliedAlpha() )
		{
			m_tBlendFunc.src = GL_SRC_ALPHA;
			m_tBlendFunc.dst = GL_ONE_MINUS_SRC_ALPHA;
		} 
		else 
		{
			m_tBlendFunc.src = CC_BLEND_SRC;
			m_tBlendFunc.dst = CC_BLEND_DST;
		}
	}
}
bool CCParticleSystem::getIsBlendAdditive()
{
	return( m_tBlendFunc.src == GL_SRC_ALPHA && m_tBlendFunc.dst == GL_ONE);
}

// ParticleSystem - Properties of Gravity Mode 
void CCParticleSystem::setTangentialAccel(float t)
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	modeA.tangentialAccel = t;
}
float CCParticleSystem::getTangentialAccel()
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	return modeA.tangentialAccel;
}
void CCParticleSystem::setTangentialAccelVar(float t)
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	modeA.tangentialAccelVar = t;
}
float CCParticleSystem::getTangentialAccelVar()
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	return modeA.tangentialAccelVar;
}	
void CCParticleSystem::setRadialAccel(float t)
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	modeA.radialAccel = t;
}
float CCParticleSystem::getRadialAccel()
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	return modeA.radialAccel;
}
void CCParticleSystem::setRadialAccelVar(float t)
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	modeA.radialAccelVar = t;
}
float CCParticleSystem::getRadialAccelVar()
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	return modeA.radialAccelVar;
}
void CCParticleSystem::setGravity(CCPoint g)
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	modeA.gravity = g;
}
CCPoint CCParticleSystem::getGravity()
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	return modeA.gravity;
}
void CCParticleSystem::setSpeed(float speed)
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	modeA.speed = speed;
}
float CCParticleSystem::getSpeed()
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	return modeA.speed;
}
void CCParticleSystem::setSpeedVar(float speedVar)
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	modeA.speedVar = speedVar;
}
float CCParticleSystem::getSpeedVar()
{
	CCAssert( m_nEmitterMode == kCCParticleModeGravity, "Particle Mode should be Gravity");
	return modeA.speedVar;
}

// ParticleSystem - Properties of Radius Mode
void CCParticleSystem::setStartRadius(float startRadius)
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	modeB.startRadius = startRadius;
}
float CCParticleSystem::getStartRadius()
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	return modeB.startRadius;
}
void CCParticleSystem::setStartRadiusVar(float startRadiusVar)
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	modeB.startRadiusVar = startRadiusVar;
}
float CCParticleSystem::getStartRadiusVar()
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	return modeB.startRadiusVar;
}
void CCParticleSystem::setEndRadius(float endRadius)
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	modeB.endRadius = endRadius;
}
float CCParticleSystem::getEndRadius()
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	return modeB.endRadius;
}
void CCParticleSystem::setEndRadiusVar(float endRadiusVar)
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	modeB.endRadiusVar = endRadiusVar;
}
float CCParticleSystem::getEndRadiusVar()
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	return modeB.endRadiusVar;
}
void CCParticleSystem::setRotatePerSecond(float degrees)
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	modeB.rotatePerSecond = degrees;
}
float CCParticleSystem::getRotatePerSecond()
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	return modeB.rotatePerSecond;
}
void CCParticleSystem::setRotatePerSecondVar(float degrees)
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	modeB.rotatePerSecondVar = degrees;
}
float CCParticleSystem::getRotatePerSecondVar()
{
	CCAssert( m_nEmitterMode == kCCParticleModeRadius, "Particle Mode should be Radius");
	return modeB.rotatePerSecondVar;
}
bool CCParticleSystem::getIsActive()
{
	return m_bIsActive;
}
int CCParticleSystem::getParticleCount()
{
	return m_nParticleCount;
}
float CCParticleSystem::getDuration()
{
	return m_fDuration;
}
void CCParticleSystem::setDuration(float var)
{
	m_fDuration = var;
}
CCPoint CCParticleSystem::getSourcePosition()
{
	return m_tSourcePosition;
}
void CCParticleSystem::setSourcePosition(CCPoint var)
{
	m_tSourcePosition = var;
}
CCPoint CCParticleSystem::getPosVar()
{
	return m_tPosVar;
}
void CCParticleSystem::setPosVar(CCPoint var)
{
	m_tPosVar = var;
}
float CCParticleSystem::getLife()
{
	return m_fLife;
}
void CCParticleSystem::setLife(float var)
{
	m_fLife = var;
}
float CCParticleSystem::getLifeVar()
{
	return m_fLifeVar;
}
void CCParticleSystem::setLifeVar(float var)
{
	m_fLifeVar = var;
}
float CCParticleSystem::getAngle()
{
	return m_fAngle;
}
void CCParticleSystem::setAngle(float var)
{
	m_fAngle = var;
}
float CCParticleSystem::getAngleVar()
{
	return m_fAngleVar;
}
void CCParticleSystem::setAngleVar(float var)
{
	m_fAngleVar = var;
}
float CCParticleSystem::getStartSize()
{
	return m_fStartSize;
}
void CCParticleSystem::setStartSize(float var)
{
	m_fStartSize = var;
}
float CCParticleSystem::getStartSizeVar()
{
	return m_fStartSizeVar;
}
void CCParticleSystem::setStartSizeVar(float var)
{
	m_fStartSizeVar = var;
}
float CCParticleSystem::getEndSize()
{
	return m_fEndSize;
}
void CCParticleSystem::setEndSize(float var)
{
	m_fEndSize = var;
}
float CCParticleSystem::getEndSizeVar()
{
	return m_fEndSizeVar;
}
void CCParticleSystem::setEndSizeVar(float var)
{
	m_fEndSizeVar = var;
}
ccColor4F CCParticleSystem::getStartColor()
{
	return m_tStartColor;
}
void CCParticleSystem::setStartColor(ccColor4F var)
{
	m_tStartColor = var;
}
ccColor4F CCParticleSystem::getStartColorVar()
{
	return m_tStartColorVar;
}
void CCParticleSystem::setStartColorVar(ccColor4F var)
{
	m_tStartColorVar = var;
}
ccColor4F CCParticleSystem::getEndColor()
{
	return m_tEndColor;
}
void CCParticleSystem::setEndColor(ccColor4F var)
{
	m_tEndColor = var;
}
ccColor4F CCParticleSystem::getEndColorVar()
{
	return m_tEndColorVar;
}
void CCParticleSystem::setEndColorVar(ccColor4F var)
{
	m_tEndColorVar = var;
}
float CCParticleSystem::getStartSpin()
{
	return m_fStartSpin;
}
void CCParticleSystem::setStartSpin(float var)
{
	m_fStartSpin = var;
}
float CCParticleSystem::getStartSpinVar()
{
	return m_fStartSpinVar;
}
void CCParticleSystem::setStartSpinVar(float var)
{
	m_fStartSpinVar = var;
}
float CCParticleSystem::getEndSpin()
{
	return m_fEndSpin;
}
void CCParticleSystem::setEndSpin(float var)
{
	m_fEndSpin = var;
}
float CCParticleSystem::getEndSpinVar()
{
	return m_fEndSpinVar;
}
void CCParticleSystem::setEndSpinVar(float var)
{
	m_fEndSpinVar = var;
}
float CCParticleSystem::getEmissionRate()
{
	return m_fEmissionRate;
}
void CCParticleSystem::setEmissionRate(float var)
{
	m_fEmissionRate = var;
}
int CCParticleSystem::getTotalParticles()
{
	return m_nTotalParticles;
}
void CCParticleSystem::setTotalParticles(int var)
{
	m_nTotalParticles = var;
}
ccBlendFunc CCParticleSystem::getBlendFunc()
{
	return m_tBlendFunc;
}
void CCParticleSystem::setBlendFunc(ccBlendFunc var)
{
	m_tBlendFunc = var;
}
tCCPositionType CCParticleSystem::getPositionType()
{
	return m_ePositionType;
}
void CCParticleSystem::setPositionType(tCCPositionType var)
{
	m_ePositionType = var;
}
bool CCParticleSystem::getIsAutoRemoveOnFinish()
{
	return m_bIsAutoRemoveOnFinish;
}
void CCParticleSystem::setIsAutoRemoveOnFinish(bool var)
{
	m_bIsAutoRemoveOnFinish = var;
}
int CCParticleSystem::getEmitterMode()
{
	return m_nEmitterMode;
}
void CCParticleSystem::setEmitterMode(int var)
{
	m_nEmitterMode = var;
}

}// namespace cocos2d