//#include "stdfx.h"
#include "tfxparam.h"
//#include "tpixelutils.h"
#include "trop.h"
#include "particles.h"
#include "particlesengine.h"
#include "hsvutil.h"
#include "timage_io.h"
#include "tofflinegl.h"

/*-----------------------------------------------------------------*/
void Particle::create_Animation(const particles_values &values,
								int first, int last)
{
	switch (values.animation_val) {
	case ParticlesFx::ANIM_CYCLE:
	case ParticlesFx::ANIM_S_CYCLE:
		frame = first;
		animswing = 0; /*frame <0 perche' c'e' il preroll dialmeno un frame*/
		break;

	case ParticlesFx::ANIM_SR_CYCLE:
		frame = (int)(first + (random.getFloat()) * (last - first));
		animswing = random.getFloat() > 0.5 ? 1 : 0;
		break;

	default:
		frame = (int)(first + (random.getFloat()) * (last - first));
		break;
	}
}

//------------------------------------------------------------------
Particle::Particle(int g_lifetime, int seed, std::map<int, TTile *> porttiles, const particles_values &values,
				   const particles_ranges &ranges, std::vector<std::vector<TPointD>> &myregions,
				   int howmany, int first, int level, int last,
					 std::vector<std::vector<int>> &myHistogram,
					 std::vector<float> &myWeight)
{
	double random_s_a_range, random_speed;
	std::map<int, double> imagereferences;
	random = TRandom(seed);
	double randomxreference = 0.0;
	double randomyreference = 0.0;
	create_Animation(values, 0, last);
	//lifetime=values.lifetime_val.first+ranges.lifetime_range*random->getFloat();

	this->level = level;

	/*- 初期座標値をつくる -*/
	/*-- Perspective DistributionがONかつ、SizeのControlImageが刺さっている場合	--*/
	if (myregions.size() &&
		values.scale_ctrl_val != ParticlesFx::CTRL_NONE &&
		values.perspective_distribution_val) {
		float size = myWeight[255];
		/*- 候補の中のIndex -*/
		float partindex = size * random.getFloat();
		for (int i = 0; i < 256; i++) {
			if (myWeight[i] > partindex) {
				int m = 255 - i;
				/*- 明度からサイズ サイズから重みを計算 -*/
				float scale = values.scale_val.first + ranges.scale_range * (float)m / 255.0f;
				float weight = 1.0f / (scale * scale);
				if (i > 0)
					partindex -= myWeight[i - 1];
				int index = myHistogram[m][(int)(partindex / weight)];
				x = myregions[0][index].x + (double)random.getFloat() - 0.5;
				y = myregions[0][index].y + (double)random.getFloat() - 0.5;
				break;
			}
		}
	}
	/*- 領域がある かつ 発生領域のControlImageが刺さっている場合 -*/
	else if (myregions.size() && values.source_ctrl_val != ParticlesFx::CTRL_NONE) {
		/*- howmany：発生Particlesのうち、何番目に発生させたものか。
			myregionが複数有る場合は、均等に割り振ることになる。 -*/
		int regionindex = howmany % myregions.size();
		/*- ウェイトを足しこむ -*/
		float size;
		if (values.source_gradation_val && !values.multi_source_val && myregions.size() == 1)
			size = myWeight[254];
		else /*- ウェイトがすべて１の場合 -*/
			size = (float)myregions[regionindex].size();
		/*- 候補の中のIndex -*/
		int partindex = (int)(size * random.getFloat());

		/*- ウェイトを引いていき、負になったインデックスを選択 -*/
		if (values.source_gradation_val && !values.multi_source_val && myregions.size() == 1) {
			for (int i = 0; i < 255; i++) {
				if (myWeight[i] > partindex) {
					int m = 255 - i;
					if (i > 0)
						partindex -= myWeight[i - 1];
					int index = myHistogram[m][(int)(partindex / m)];
					x = myregions[regionindex][index].x + (double)random.getFloat() - 0.5;
					y = myregions[regionindex][index].y + (double)random.getFloat() - 0.5;
					break;
				}
			}
		} else /*- ウェイトがすべて１の場合 -*/
		{
			x = myregions[regionindex][(int)partindex].x + (double)random.getFloat() - 0.5;
			y = myregions[regionindex][(int)partindex].y + (double)random.getFloat() - 0.5;
		}
	} else {
		x = values.x_pos_val + values.length_val * (random.getFloat() - 0.5);
		y = values.y_pos_val + values.height_val * (random.getFloat() - 0.5);
	}

	for (std::map<int, TTile *>::iterator it = porttiles.begin(); it != porttiles.end(); ++it) {
		if (
			(values.lifetime_ctrl_val == it->first ||
			 values.speed_ctrl_val == it->first ||
			 values.scale_ctrl_val == it->first ||
			 values.rot_ctrl_val == it->first
			 /*-  Speed Angleを明るさでコントロールする場合 -*/
			 || (values.speeda_ctrl_val == it->first && !values.speeda_use_gradient_val)) &&
			it->second->getRaster()) {
			double tmpvalue;
			get_image_reference(it->second, values, tmpvalue, ParticlesFx::GRAY_REF);
			imagereferences[it->first] = tmpvalue;
		}
	}
	if (values.lifetime_ctrl_val) {
		double lifetimereference = 0.0;
		lifetimereference = imagereferences[values.lifetime_ctrl_val];
		lifetime = g_lifetime * lifetimereference;
	} else
		lifetime = g_lifetime;

	//lifetime=g_lifetime;
	genlifetime = lifetime;
	if (values.speed_ctrl_val && (porttiles.find(values.speed_ctrl_val) != porttiles.end())) {
		double speedreference = 0.0;
		speedreference = imagereferences[values.speed_ctrl_val];
		random_speed = values.speed_val.first + (ranges.speed_range) * speedreference;
	} else
		random_speed = values.speed_val.first + (ranges.speed_range) * random.getFloat();

	/*- Speed Angleの制御。RangeモードとGradientモードがある -*/
	if (values.speeda_ctrl_val && (porttiles.find(values.speeda_ctrl_val) != porttiles.end())) {
		if (values.speeda_use_gradient_val) {
			/*- 参照画像のGradientを得る関数を利用して角度を得る -*/
			float dir_x, dir_y;
			get_image_gravity(porttiles[values.speeda_ctrl_val], values, dir_x, dir_y);
			if (dir_x == 0.0f && dir_y == 0.0f)
				random_s_a_range = values.speed_val.first;
			else
				random_s_a_range = atan2f(dir_x, -dir_y);
		} else {
			double speedareference = 0.0;
			speedareference = imagereferences[values.speeda_ctrl_val];
			random_s_a_range = values.speeda_val.first + (ranges.speeda_range) * speedareference;
		}
	} else /*- Control Imageが無ければランダム -*/
		random_s_a_range = values.speeda_val.first + (ranges.speeda_range) * random.getFloat();

	trail = (int)(values.trail_val.first + (ranges.trail_range) * random.getFloat());
	vx = random_speed * sin(random_s_a_range);
	vy = -random_speed * cos(random_s_a_range);
	oldx = 0;
	oldy = 0;
	mass = values.mass_val.first + (ranges.mass_range) * random.getFloat();
	if (values.scale_ctrl_val && (porttiles.find(values.scale_ctrl_val) != porttiles.end())) {
		double scalereference = 0.0;
		scalereference = imagereferences[values.scale_ctrl_val];
		scale = values.scale_val.first + (ranges.scale_range) * scalereference;
	} else {
		/*- ONのとき、かつ、ScaleにControlが無い場合、粒子サイズが小さいほど(遠くにあるので)多く分布するようになる。-*/
		if (values.perspective_distribution_val) {
			scale = (values.scale_val.first * values.scale_val.second) /
					(values.scale_val.second - (ranges.scale_range) * random.getFloat());
		} else
			scale = values.scale_val.first + (ranges.scale_range) * random.getFloat();
	}
	if (values.rot_ctrl_val && (porttiles.find(values.rot_ctrl_val) != porttiles.end())) {
		double anglereference = 0.0;
		anglereference = imagereferences[values.rot_ctrl_val];
		angle = -(values.rot_val.first) - (ranges.rot_range) * anglereference;
	} else
		angle = -(values.rot_val.first) - (ranges.rot_range) * random.getFloat();

	if (values.randomx_ctrl_val)
		randomxreference = imagereferences[values.randomx_ctrl_val];
	if (values.randomy_ctrl_val)
		randomyreference = imagereferences[values.randomy_ctrl_val];
	//if(check_Swing(values))
	create_Swing(values, ranges, randomxreference, randomyreference);

	create_Colors(values, ranges, porttiles);

	if (scale < 0.001)
		scale = 0;
}

//------------------------------------------------------------------
int Particle::check_Swing(const particles_values &values)
{
	return (values.randomx_val.first || values.randomx_val.second ||
			values.randomy_val.first || values.randomy_val.second ||
			values.rotsca_val.first || values.rotsca_val.second);
}

/*-----------------------------------------------------------------*/

void Particle::create_Swing(const particles_values &values,
							const particles_ranges &ranges,
							double randomxreference, double randomyreference)
{
	changesignx = (int)(values.swing_val.first + random.getFloat() * (ranges.swing_range));
	changesigny = (int)(values.swing_val.first + random.getFloat() * (ranges.swing_range));
	changesigna = (int)(values.rotswing_val.first + random.getFloat() * (ranges.rotswing_range));
	if (values.swingmode_val == ParticlesFx::SWING_SMOOTH) {
		if (values.randomx_ctrl_val)
			smswingx = abs((int)values.randomx_val.first) + randomxreference * (ranges.randomx_range);
		else
			smswingx = abs((int)values.randomx_val.first) + random.getFloat() * (ranges.randomx_range);
		if (values.randomy_ctrl_val)
			smswingy = abs((int)values.randomy_val.first) + randomyreference * (ranges.randomy_range);
		else
			smswingy = abs((int)values.randomy_val.first) + random.getFloat() * (ranges.randomy_range);
		smperiodx = changesignx;
		smperiody = changesigny;
	}
	if (values.rotswingmode_val == ParticlesFx::SWING_SMOOTH) {
		smswinga = abs((int)(values.rotsca_val.first + random.getFloat() * (ranges.rotsca_range)));
		smperioda = changesigna;
	}
	signx = random.getInt(0, 1) > 0 ? 1 : -1;
	signy = random.getInt(0, 1) > 0 ? 1 : -1;
	signa = random.getInt(0, 1) > 0 ? 1 : -1;
}

/*-----------------------------------------------------------------*/

void Particle::create_Colors(const particles_values &values,
							 const particles_ranges &ranges,
							 std::map<int, TTile *> porttiles)
{
	//TPixel32 color;

	if (values.genfadecol_val) {
		TPixel32 color;
		if (values.gencol_ctrl_val && (porttiles.find(values.gencol_ctrl_val) != porttiles.end()))
			get_image_reference(porttiles[values.gencol_ctrl_val], values, color);
		else
			color = values.gencol_val.getPremultipliedValue(random.getFloat());
		gencol.fadecol = values.genfadecol_val;
		if (values.gencol_spread_val)
			spread_color(color, values.gencol_spread_val);
		gencol.col = color;
	} else {
		gencol.col = TPixel32::Transparent;
		gencol.fadecol = 0;
	}
	if (values.finfadecol_val) {
		TPixel32 color;
		if (values.fincol_ctrl_val && (porttiles.find(values.fincol_ctrl_val) != porttiles.end()))
			get_image_reference(porttiles[values.fincol_ctrl_val], values, color);
		else
			color = values.fincol_val.getPremultipliedValue(random.getFloat());
		fincol.rangecol = (int)values.finrangecol_val;
		fincol.fadecol = values.finfadecol_val;
		if (values.fincol_spread_val)
			spread_color(color, values.fincol_spread_val);
		fincol.col = color;
	} else {
		fincol.col = TPixel32::Transparent;
		fincol.rangecol = 0;
		fincol.fadecol = 0;
	}
	if (values.foutfadecol_val) {
		TPixel32 color;
		if (values.foutcol_ctrl_val && (porttiles.find(values.foutcol_ctrl_val) != porttiles.end()))
			get_image_reference(porttiles[values.foutcol_ctrl_val], values, color);
		else
			color = values.foutcol_val.getPremultipliedValue(random.getFloat());
		;
		foutcol.rangecol = (int)values.foutrangecol_val;
		foutcol.fadecol = values.foutfadecol_val;
		if (values.foutcol_spread_val)
			spread_color(color, values.foutcol_spread_val);
		foutcol.col = color;
	} else {
		foutcol.col = TPixel32::Transparent;
		foutcol.rangecol = 0;
		foutcol.fadecol = 0;
	}
}

/*-----------------------------------------------------------------*/
/*-- modify_colors_and_opacityから呼ばれる。
	lifetime: 粒子の現在の年齢
	gencol/fincol/foutcolから色を決める --*/
void Particle::modify_colors(TPixel32 &color, double &intensity)
{
	float percent = 0;
	if ((gencol.fadecol || fincol.fadecol) &&
		(genlifetime - lifetime) <= fincol.rangecol) {
		if (fincol.rangecol)
			percent = (genlifetime - lifetime) / (float)(fincol.rangecol);
		//color=gencol.col+percent*(fincol.col-gencol.col);
		color = blend(gencol.col, fincol.col, percent);
		intensity = gencol.fadecol + percent * (fincol.fadecol - gencol.fadecol);
	} else if (foutcol.fadecol && lifetime <= foutcol.rangecol) {
		if (foutcol.rangecol)
			percent = 1 - (lifetime - 1) / (float)(foutcol.rangecol);
		if (fincol.rangecol && fincol.fadecol) {
			color = blend(fincol.col, foutcol.col, percent);
			intensity = fincol.fadecol + percent * (foutcol.fadecol - fincol.fadecol);
		} else {
			color = blend(gencol.col, foutcol.col, percent);
			intensity = gencol.fadecol + percent * (foutcol.fadecol - gencol.fadecol);
		}
	} else {
		if (fincol.fadecol && fincol.rangecol) {
			color = fincol.col;
			intensity = fincol.fadecol;
		} else {
			color = gencol.col;
			intensity = gencol.fadecol;
		}
	}
}

/*-----------------------------------------------------------------*/
/*- do_render から呼ばれる。各粒子の描画の直前に色を決める -*/
void Particle::modify_colors_and_opacity(const particles_values &values,
										 float curr_opacity, int dist_frame, TRaster32P raster32)
{

	double intensity = 0;
	TPixel32 col;
	if (gencol.fadecol || fincol.fadecol || foutcol.fadecol) {
		modify_colors(col, intensity);
		int j;
		raster32->lock();
		for (j = 0; j < raster32->getLy(); j++) {
			TPixel32 *pix = raster32->pixels(j);
			TPixel32 *endPix = pix + raster32->getLx();
			while (pix < endPix) {
				double factor = pix->m / 255.0;
				pix->r = (UCHAR)(pix->r + intensity * (factor * col.r - pix->r));
				pix->g = (UCHAR)(pix->g + intensity * (factor * col.g - pix->g));
				pix->b = (UCHAR)(pix->b + intensity * (factor * col.b - pix->b));
				pix->m = (UCHAR)(pix->m + intensity * (factor * col.m - pix->m));
				++pix;
			}
		}
		raster32->unlock();
		//pop_rgbfade(pars, 0, 0, raster, raster, 1);
	}

	if (curr_opacity != 1.0)
		TRop::rgbmScale(raster32, raster32, 1, 1, 1, curr_opacity);
}

/*-----------------------------------------------------------------*/
void Particle::update_Animation(const particles_values &values,
								int first, int last, int keep)
{
	switch (values.animation_val) {
	case ParticlesFx::ANIM_RANDOM:
		frame = (int)(first + random.getFloat() * (last - first));
		break;

	case ParticlesFx::ANIM_R_CYCLE:
	case ParticlesFx::ANIM_CYCLE:
		if (!keep || frame != keep - 1)
			frame = first + (frame + 1) % (last - first);
		break;

	case ParticlesFx::ANIM_S_CYCLE:
	case ParticlesFx::ANIM_SR_CYCLE:
		if (!keep || frame != keep - 1) {
			if (!animswing && frame < last - 1) {
				frame = (frame + 1);
				if (frame == last - 1)
					animswing = 1;
			} else
				frame = (frame - 1);
			if (frame <= first) {
				animswing = 0;
				frame = first;
			}
		}
		break;
	}
}

/*-----------------------------------------------------------------*/
void Particle::update_Swing(const particles_values &values,
							const particles_ranges &ranges,
							struct pos_dummy &dummy,
							double randomxreference, double randomyreference)
{

	if (values.swingmode_val == ParticlesFx::SWING_SMOOTH) {
		if (smperiodx)
			dummy.x = smswingx * randomxreference * sin((M_PI * changesignx) / smperiodx);
		else
			dummy.x = 0;
		if (smperiody)
			dummy.y = smswingy * randomyreference * sin((M_PI * changesigny) / smperiody);
		else
			dummy.y = 0;
	} else {
		if (values.randomx_ctrl_val)
			dummy.x = (values.randomx_val.first + (ranges.randomx_range) * randomxreference);
		else
			dummy.x = (values.randomx_val.first + (ranges.randomx_range) * random.getFloat());
		if (values.randomy_ctrl_val)
			dummy.y = (values.randomy_val.first + (ranges.randomy_range) * randomyreference);
		else
			dummy.y = (values.randomy_val.first + (ranges.randomy_range) * random.getFloat());
	}

	if (values.rotswingmode_val == ParticlesFx::SWING_SMOOTH) {
		if (smperioda)
			dummy.a = smswinga * sin((M_PI * changesigna) / smperioda);
		else
			dummy.a = 0;
	} else
		dummy.a = (values.rotsca_val.first + (ranges.rotsca_range) * random.getFloat());

	if (!(genlifetime - lifetime)) {
		signx = dummy.x > 0 ? 1 : -1;
		signy = dummy.y > 0 ? 1 : -1;
		signa = dummy.a > 0 ? 1 : -1;
	} else {
		dummy.x = (fabs(dummy.x)) * signx;
		dummy.y = (fabs(dummy.y)) * signy;
		dummy.a = (fabs(dummy.a)) * signa;
	}

	changesignx--;
	changesigny--;
	changesigna--;
	if (changesignx <= 0) {
		//  if(random->getFloat()<0.5);
		signx *= -1;
		changesignx = abs((int)(values.swing_val.first) + (int)(random.getFloat() * (ranges.swing_range)));
		if (values.swingmode_val == ParticlesFx::SWING_SMOOTH) {
			smperiodx = changesignx;
			if (values.randomx_ctrl_val)
				smswingx = values.randomx_val.first + randomxreference * (ranges.randomx_range);
			else
				smswingx = values.randomx_val.first + random.getFloat() * (ranges.randomx_range);
		}
	}
	if (changesigny <= 0) {
		//  if(random->getFloat()<0.5);
		signy *= -1;
		changesigny = abs((int)(values.swing_val.first) + (int)(random.getFloat() * (ranges.swing_range)));
		if (values.swingmode_val == ParticlesFx::SWING_SMOOTH) {
			smperiody = changesigny;
			if (values.randomy_ctrl_val)
				smswingy = values.randomy_val.first + randomyreference * (ranges.randomy_range);
			else
				smswingy = values.randomy_val.first + random.getFloat() * (ranges.randomy_range);
		}
	}
	if (changesigna <= 0) {
		signa *= -1;
		changesigna = abs((int)(values.rotswing_val.first) + (int)(random.getFloat() * (ranges.rotswing_range)));
		if (values.rotswingmode_val == ParticlesFx::SWING_SMOOTH) {
			smperioda = changesigna;
			smswinga = values.rotsca_val.first + random.getFloat() * (ranges.rotsca_range);
		}
	}
}
/*-----------------------------------------------------------------*/
void Particle::update_Scale(const particles_values &values,
							const particles_ranges &ranges, double scalereference,
							double scalestepreference)
{
	double scalestep;

	if (values.scale_ctrl_val && values.scale_ctrl_all_val)
		scale = values.scale_val.first + (ranges.scale_range) * scalereference;
	else {
		if (values.scalestep_ctrl_val)
			scalestep = values.scalestep_val.first + (ranges.scalestep_range) * scalestepreference;
		else
			scalestep = values.scalestep_val.first + (ranges.scalestep_range) * random.getFloat();
		if (scalestep)
			scale += scalestep;
	}
	if (scale < 0.001)
		scale = 0;
}

/*-----------------------------------------------------------------*/
void Particle::get_image_reference(TTile *ctrl, const particles_values &values,
								   double &imagereference, int type)
{
	TRaster32P raster32 = ctrl->getRaster();
	TPointD tmp(x, y);
	tmp -= ctrl->m_pos;
	imagereference = 0.0;
	raster32->lock();
	switch (type) {
	case ParticlesFx::GRAY_REF:
		if (raster32 && tmp.x >= 0 && tmp.x < raster32->getLx() && tmp.y >= 0 && troundp(tmp.y) < raster32->getLy()) {
			TPixel32 pix = raster32->pixels(troundp(tmp.y))[(int)tmp.x];
			imagereference = TPixelGR8::from(pix).value / (double)TPixelGR8::maxChannelValue;
		}
		break;

	case ParticlesFx::H_REF:
		if (raster32 && tmp.x >= 0 && tmp.x < raster32->getLx() && tmp.y >= 0 && tround(tmp.y) < raster32->getLy()) {
			double aux = (double)TPixel32::maxChannelValue;
			double h, s, v;
			TPixel32 pix = raster32->pixels(troundp(tmp.y))[(int)tmp.x];
			OLDRGB2HSV(pix.r / aux, pix.g / aux, pix.b / aux, &h, &s, &v);
			imagereference = h / 360.0;
		}
		break;
	}
	raster32->unlock();
}

/*-----------------------------------------------------------------*/
void Particle::get_image_gravity(TTile *ctrl1, const particles_values &values,
								 float &gx, float &gy)
{
	TRaster32P raster32 = ctrl1->getRaster();
	TPointD tmp(x, y);
	tmp -= ctrl1->m_pos;
	int radius = 4;
	gx = 0;
	gy = 0;
//#define OLDSTUFF
#ifdef OLDSTUFF
	int i;
#endif
	raster32->lock();
#ifdef OLDSTUFF
	if (!values.gravity_radius_val) {
		radius = 4;
		if (raster32 && tmp.x >= radius && tmp.x < raster32->getLx() - radius && tmp.y >= radius && tmp.y < raster32->getLy() - radius) {
			TPixel32 *pix = &(raster32->pixels(troundp(tmp.y))[(int)tmp.x]);
			double norm = 1 / ((double)TPixelGR8::maxChannelValue);
			for (i = 1; i < radius; i++) {
				gx += TPixelGR8::from(*(pix + i)).value;
				gx -= TPixelGR8::from(*(pix - i)).value;
				gy += TPixelGR8::from(*(pix + raster32->getWrap() * i)).value;
				gy -= TPixelGR8::from(*(pix - raster32->getWrap() * i)).value;
			}
			gx = gx * norm;
			gy = gy * norm;
		}
	} else {
#endif
		radius = 2;
		if (raster32 && tmp.x >= radius && tmp.x < raster32->getLx() - radius && tmp.y >= radius && tmp.y < raster32->getLy() - radius) {
			TPixel32 *pix = &(raster32->pixels(troundp(tmp.y))[(int)tmp.x]);

			gx += 2 * TPixelGR8::from(*(pix + 1)).value;
			gx += TPixelGR8::from(*(pix + 1 + raster32->getWrap() * 1)).value;
			gx += TPixelGR8::from(*(pix + 1 - raster32->getWrap() * 1)).value;

			gx -= 2 * TPixelGR8::from(*(pix - 1)).value;
			gx -= TPixelGR8::from(*(pix - 1 + raster32->getWrap() * 1)).value;
			gx -= TPixelGR8::from(*(pix - 1 - raster32->getWrap() * 1)).value;

			gy += 2 * TPixelGR8::from(*(pix + raster32->getWrap() * 1)).value;
			gy += TPixelGR8::from(*(pix + raster32->getWrap() * 1 + 1)).value;
			gy += TPixelGR8::from(*(pix + raster32->getWrap() * 1 - 1)).value;

			gy -= 2 * TPixelGR8::from(*(pix - raster32->getWrap() * 1)).value;
			gy -= TPixelGR8::from(*(pix - raster32->getWrap() * 1 + 1)).value;
			gy -= TPixelGR8::from(*(pix - raster32->getWrap() * 1 - 1)).value;

			double norm = sqrt(gx * gx + gy * gy);
			if (norm) {
				double inorm = 0.1 / norm;
				gx = gx * inorm;
				gy = gy * inorm;
			}
		}
#ifdef OLDSTUFF
	}
#endif
	raster32->unlock();
}

/*-----------------------------------------------------------------*/
void Particle::get_image_reference(TTile *ctrl1, const particles_values &values,
								   TPixel32 &color)
{
	TRaster32P raster32 = ctrl1->getRaster();
	TPointD tmp(x, y);
	tmp -= ctrl1->m_pos;

	if (raster32 && tmp.x >= 0 && tmp.x < raster32->getLx() && tmp.y >= 0 && troundp(tmp.y) < raster32->getLy()) {
		color = raster32->pixels(troundp(tmp.y))[(int)tmp.x];
	}
	/*-- 参照画像のBBoxの外側では、粒子を透明にする --*/
	else
		color = TPixel32::Transparent;
}
/*-----------------------------------------------------------------*/
void Particle::spread_color(TPixel32 &color, double range)
{
	int randcol = (int)((random.getFloat() - 0.5) * range);
	int r = color.r + randcol;
	int g = color.g + randcol;
	int b = color.b + randcol;
	color.r = (UCHAR)tcrop<TINT32>(r, (TINT32)0, (TINT32)255);
	color.g = (UCHAR)tcrop<TINT32>(g, (TINT32)0, (TINT32)255);
	color.b = (UCHAR)tcrop<TINT32>(b, (TINT32)0, (TINT32)255);
}
/*-----------------------------------------------------------------*/

void Particle::move(std::map<int, TTile *> porttiles, const particles_values &values, const particles_ranges &ranges,
					float windx,
					float windy, float xgravity, float ygravity,
					float dpicorr, int lastframe)
{
	struct pos_dummy dummy;
	float frictx, fricty;
	//int time;
	std::map<int, double> imagereferences;
	dummy.x = dummy.y = dummy.a = 0.0;
	frictx = fricty = 0.0;

	double frictreference = 1;
	double scalereference = 0;
	double scalestepreference = 0;
	double randomxreference = 1;
	double randomyreference = 1;

	for (std::map<int, TTile *>::iterator it = porttiles.begin(); it != porttiles.end(); ++it) {
		if (
			(values.friction_ctrl_val == it->first ||
			 values.scale_ctrl_val == it->first ||
			 values.scalestep_ctrl_val == it->first ||
			 values.randomx_ctrl_val == it->first ||
			 values.randomy_ctrl_val == it->first) &&
			it->second->getRaster()) {
			double tmpvalue;
			get_image_reference(it->second, values, tmpvalue, ParticlesFx::GRAY_REF);
			imagereferences[it->first] = tmpvalue;
		}
	}

	if (values.randomx_ctrl_val)
		randomxreference = imagereferences[values.randomx_ctrl_val];
	if (values.randomy_ctrl_val)
		randomyreference = imagereferences[values.randomy_ctrl_val];

	if (check_Swing(values))
		update_Swing(values, ranges, dummy, randomxreference, randomyreference);

	if (values.friction_ctrl_val)
		frictreference = imagereferences[values.friction_ctrl_val];

	if (values.scale_ctrl_val)
		scalereference = imagereferences[values.scale_ctrl_val];
	if (values.scalestep_ctrl_val)
		scalestepreference = imagereferences[values.scalestep_ctrl_val];
	lifetime--;
	oldx = x;
	oldy = y;
	//time=genlifetime-lifetime-1;
	//if(time<0) time=0;
	if (values.gravity_ctrl_val && (porttiles.find(values.gravity_ctrl_val) != porttiles.end())) {
		get_image_gravity(porttiles[values.gravity_ctrl_val], values, xgravity, ygravity);
		xgravity *= values.gravity_val;
		ygravity *= values.gravity_val;
	}

	if (values.friction_val * frictreference) {
		if (vx) {
			frictx = vx * (1 + values.friction_val * frictreference) + (10 / vx) * values.friction_val * frictreference;
			if ((frictx / vx) < 0)
				frictx = 0;
			vx = frictx;
		}
		if (!frictx && fabs(values.friction_val * frictreference * 10) > fabs(xgravity)) {
			xgravity = 0;
			dummy.x = 0;
			dummy.a = 0;
			windx = 0;
		}

		if (vy) {
			fricty = vy * (1 + values.friction_val * frictreference) + (10 / vy) * values.friction_val * frictreference;
			if ((fricty / vy) < 0)
				fricty = 0;
			vy = fricty;
		}
		if (!fricty && fabs(values.friction_val * frictreference * 10) > fabs(ygravity)) {
			ygravity = 0;
			dummy.y = 0;
			dummy.a = 0;
			windy = 0;
		}
	}

	vx += xgravity * mass;
	vy += ygravity * mass;
	if (values.speedscale_val) {
		float scalecorr = scale / dpicorr;
		x += (vx + windx + dummy.x) * scalecorr;
		y += (vy + windy + dummy.y) * scalecorr;
	} else {
		x += vx + windx + dummy.x;
		y += vy + windy + dummy.y;
	}
	angle -= values.rotspeed_val + dummy.a;

	if (!(lifetime % values.step_val) || (frame < 0)) {
		update_Animation(values, 0, lastframe, 0);
	}

	update_Scale(values, ranges, scalereference, scalestepreference);
}

/*-----------------------------------------------------------------*/
double Particle::set_Opacity(std::map<int, TTile *> porttiles,
							 const particles_values &values, float opacity_range, double dist_frame)
{
	double opacity = 1.0, trailcorr;

	if (values.fadein_val && (genlifetime - lifetime) < values.fadein_val)
		opacity *= (genlifetime - lifetime - 1) / (values.fadein_val);
	if (values.fadeout_val && lifetime < values.fadeout_val)
		opacity *= (lifetime) / values.fadeout_val;

	if (trail) {
		trailcorr = values.trailopacity_val.first + (values.trailopacity_val.second - values.trailopacity_val.first) * (1 - (dist_frame) / trail);
		opacity *= trailcorr;
	}
	if (values.opacity_ctrl_val && (porttiles.find(values.opacity_ctrl_val) != porttiles.end())) {
		double opacityreference = 0.0;
		get_image_reference(porttiles[values.opacity_ctrl_val], values, opacityreference, ParticlesFx::GRAY_REF);
		opacity = values.opacity_val.first + (opacity_range)*opacityreference * opacity;
	} else
		opacity = values.opacity_val.first + opacity_range * opacity;
	return opacity;
}