/*
FLAM3 - cosmic recursive fractal flames
Copyright (C) 1992-2009 Spotworks LLC
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see .
*/
#include "variations.h"
#include "interpolation.h"
#define badvalue(x) (((x)!=(x))||((x)>1e10)||((x)<-1e10))
/* Wrap the sincos function for Macs */
#if defined(__APPLE__) || defined(_MSC_VER)
#define sincos(x,s,c) *(s)=sin(x); *(c)=cos(x);
#else
extern void sincos(double x, double *s, double *c);
#endif
#ifdef _MSC_VER
#define trunc (int)
#endif
char *flam3_variation_names[1+flam3_nvariations] = {
"linear",
"sinusoidal",
"spherical",
"swirl",
"horseshoe",
"polar",
"handkerchief",
"heart",
"disc",
"spiral",
"hyperbolic",
"diamond",
"ex",
"julia",
"bent",
"waves",
"fisheye",
"popcorn",
"exponential",
"power",
"cosine",
"rings",
"fan",
"blob",
"pdj",
"fan2",
"rings2",
"eyefish",
"bubble",
"cylinder",
"perspective",
"noise",
"julian",
"juliascope",
"blur",
"gaussian_blur",
"radial_blur",
"pie",
"ngon",
"curl",
"rectangles",
"arch",
"tangent",
"square",
"rays",
"blade",
"secant2",
"twintrian",
"cross",
"disc2",
"super_shape",
"flower",
"conic",
"parabola",
"bent2",
"bipolar",
"boarders",
"butterfly",
"cell",
"cpow",
"curve",
"edisc",
"elliptic",
"escher",
"foci",
"lazysusan",
"loonie",
"pre_blur",
"modulus",
"oscilloscope",
"polar2",
"popcorn2",
"scry",
"separation",
"split",
"splits",
"stripes",
"wedge",
"wedge_julia",
"wedge_sph",
"whorl",
"waves2",
"exp",
"log",
"sin",
"cos",
"tan",
"sec",
"csc",
"cot",
"sinh",
"cosh",
"tanh",
"sech",
"csch",
"coth",
"auger",
"flux",
0
};
/*
* VARIATION FUNCTIONS
* must be of the form void (void *, double)
*/
void var0_linear (flam3_iter_helper *f, double weight) {
/* linear */
/* nx = tx;
ny = ty;
p[0] += v * nx;
p[1] += v * ny; */
f->p0 += weight * f->tx;
f->p1 += weight * f->ty;
}
void var1_sinusoidal (flam3_iter_helper *f, double weight) {
/* sinusoidal */
/* nx = sin(tx);
ny = sin(ty);
p[0] += v * nx;
p[1] += v * ny; */
f->p0 += weight * sin(f->tx);
f->p1 += weight * sin(f->ty);
}
void var2_spherical (flam3_iter_helper *f, double weight) {
/* spherical */
/* double r2 = tx * tx + ty * ty + 1e-6;
nx = tx / r2;
ny = ty / r2;
p[0] += v * nx;
p[1] += v * ny; */
double r2 = weight / ( f->precalc_sumsq + EPS);
f->p0 += r2 * f->tx;
f->p1 += r2 * f->ty;
}
void var3_swirl (flam3_iter_helper *f, double weight) {
/* swirl */
/* double r2 = tx * tx + ty * ty; /k here is fun
double c1 = sin(r2);
double c2 = cos(r2);
nx = c1 * tx - c2 * ty;
ny = c2 * tx + c1 * ty;
p[0] += v * nx;
p[1] += v * ny; */
double r2 = f->precalc_sumsq;
double c1,c2;
double nx,ny;
sincos(r2,&c1,&c2);
// double c1 = sin(r2);
// double c2 = cos(r2);
nx = c1 * f->tx - c2 * f->ty;
ny = c2 * f->tx + c1 * f->ty;
f->p0 += weight * nx;
f->p1 += weight * ny;
}
void var4_horseshoe (flam3_iter_helper *f, double weight) {
/* horseshoe */
/* a = atan2(tx, ty);
c1 = sin(a);
c2 = cos(a);
nx = c1 * tx - c2 * ty;
ny = c2 * tx + c1 * ty;
p[0] += v * nx;
p[1] += v * ny; */
double r = weight / (f->precalc_sqrt + EPS);
f->p0 += (f->tx - f->ty) * (f->tx + f->ty) * r;
f->p1 += 2.0 * f->tx * f->ty * r;
}
void var5_polar (flam3_iter_helper *f, double weight) {
/* polar */
/* nx = atan2(tx, ty) / M_PI;
ny = sqrt(tx * tx + ty * ty) - 1.0;
p[0] += v * nx;
p[1] += v * ny; */
double nx = f->precalc_atan * M_1_PI;
double ny = f->precalc_sqrt - 1.0;
f->p0 += weight * nx;
f->p1 += weight * ny;
}
void var6_handkerchief (flam3_iter_helper *f, double weight) {
/* folded handkerchief */
/* a = atan2(tx, ty);
r = sqrt(tx*tx + ty*ty);
p[0] += v * sin(a+r) * r;
p[1] += v * cos(a-r) * r; */
double a = f->precalc_atan;
double r = f->precalc_sqrt;
f->p0 += weight * r * sin(a+r);
f->p1 += weight * r * cos(a-r);
}
void var7_heart (flam3_iter_helper *f, double weight) {
/* heart */
/* a = atan2(tx, ty);
r = sqrt(tx*tx + ty*ty);
a *= r;
p[0] += v * sin(a) * r;
p[1] += v * cos(a) * -r; */
double a = f->precalc_sqrt * f->precalc_atan;
double ca,sa;
double r = weight * f->precalc_sqrt;
sincos(a,&sa,&ca);
f->p0 += r * sa;
f->p1 += (-r) * ca;
}
void var8_disc (flam3_iter_helper *f, double weight) {
/* disc */
/* nx = tx * M_PI;
ny = ty * M_PI;
a = atan2(nx, ny);
r = sqrt(nx*nx + ny*ny);
p[0] += v * sin(r) * a / M_PI;
p[1] += v * cos(r) * a / M_PI; */
double a = f->precalc_atan * M_1_PI;
double r = M_PI * f->precalc_sqrt;
double sr,cr;
sincos(r,&sr,&cr);
f->p0 += weight * sr * a;
f->p1 += weight * cr * a;
}
void var9_spiral (flam3_iter_helper *f, double weight) {
/* spiral */
/* a = atan2(tx, ty);
r = sqrt(tx*tx + ty*ty) + 1e-6;
p[0] += v * (cos(a) + sin(r)) / r;
p[1] += v * (sin(a) - cos(r)) / r; */
double r = f->precalc_sqrt + EPS;
double r1 = weight/r;
double sr,cr;
sincos(r,&sr,&cr);
f->p0 += r1 * (f->precalc_cosa + sr);
f->p1 += r1 * (f->precalc_sina - cr);
}
void var10_hyperbolic (flam3_iter_helper *f, double weight) {
/* hyperbolic */
/* a = atan2(tx, ty);
r = sqrt(tx*tx + ty*ty) + 1e-6;
p[0] += v * sin(a) / r;
p[1] += v * cos(a) * r; */
double r = f->precalc_sqrt + EPS;
f->p0 += weight * f->precalc_sina / r;
f->p1 += weight * f->precalc_cosa * r;
}
void var11_diamond (flam3_iter_helper *f, double weight) {
/* diamond */
/* a = atan2(tx, ty);
r = sqrt(tx*tx + ty*ty);
p[0] += v * sin(a) * cos(r);
p[1] += v * cos(a) * sin(r); */
double r = f->precalc_sqrt;
double sr,cr;
sincos(r,&sr,&cr);
f->p0 += weight * f->precalc_sina * cr;
f->p1 += weight * f->precalc_cosa * sr;
}
void var12_ex (flam3_iter_helper *f, double weight) {
/* ex */
/* a = atan2(tx, ty);
r = sqrt(tx*tx + ty*ty);
n0 = sin(a+r);
n1 = cos(a-r);
m0 = n0 * n0 * n0 * r;
m1 = n1 * n1 * n1 * r;
p[0] += v * (m0 + m1);
p[1] += v * (m0 - m1); */
double a = f->precalc_atan;
double r = f->precalc_sqrt;
double n0 = sin(a+r);
double n1 = cos(a-r);
double m0 = n0 * n0 * n0 * r;
double m1 = n1 * n1 * n1 * r;
f->p0 += weight * (m0 + m1);
f->p1 += weight * (m0 - m1);
}
void var13_julia (flam3_iter_helper *f, double weight) {
/* julia */
/* a = atan2(tx, ty)/2.0;
if (flam3_random_bit()) a += M_PI;
r = pow(tx*tx + ty*ty, 0.25);
nx = r * cos(a);
ny = r * sin(a);
p[0] += v * nx;
p[1] += v * ny; */
double r;
double a = 0.5 * f->precalc_atan;
double sa,ca;
if (flam3_random_isaac_bit(f->rc)) //(flam3_random_bit())
a += M_PI;
r = weight * sqrt(f->precalc_sqrt);
sincos(a,&sa,&ca);
f->p0 += r * ca;
f->p1 += r * sa;
}
void var14_bent (flam3_iter_helper *f, double weight) {
/* bent */
/* nx = tx;
ny = ty;
if (nx < 0.0) nx = nx * 2.0;
if (ny < 0.0) ny = ny / 2.0;
p[0] += v * nx;
p[1] += v * ny; */
double nx = f->tx;
double ny = f->ty;
if (nx < 0.0)
nx = nx * 2.0;
if (ny < 0.0)
ny = ny / 2.0;
f->p0 += weight * nx;
f->p1 += weight * ny;
}
void var15_waves (flam3_iter_helper *f, double weight) {
/* waves */
/* dx = coef[2][0];
dy = coef[2][1];
nx = tx + coef[1][0]*sin(ty/((dx*dx)+EPS));
ny = ty + coef[1][1]*sin(tx/((dy*dy)+EPS));
p[0] += v * nx;
p[1] += v * ny; */
double c10 = f->xform->c[1][0];
double c11 = f->xform->c[1][1];
double nx = f->tx + c10 * sin( f->ty * f->xform->waves_dx2 );
double ny = f->ty + c11 * sin( f->tx * f->xform->waves_dy2 );
f->p0 += weight * nx;
f->p1 += weight * ny;
}
void var16_fisheye (flam3_iter_helper *f, double weight) {
/* fisheye */
/* a = atan2(tx, ty);
r = sqrt(tx*tx + ty*ty);
r = 2 * r / (r + 1);
nx = r * cos(a);
ny = r * sin(a);
p[0] += v * nx;
p[1] += v * ny; */
double r = f->precalc_sqrt;
r = 2 * weight / (r+1);
f->p0 += r * f->ty;
f->p1 += r * f->tx;
}
void var17_popcorn (flam3_iter_helper *f, double weight) {
/* popcorn */
/* dx = tan(3*ty);
dy = tan(3*tx);
nx = tx + coef[2][0] * sin(dx);
ny = ty + coef[2][1] * sin(dy);
p[0] += v * nx;
p[1] += v * ny; */
double dx = tan(3*f->ty);
double dy = tan(3*f->tx);
double nx = f->tx + f->xform->c[2][0] * sin(dx);
double ny = f->ty + f->xform->c[2][1] * sin(dy);
f->p0 += weight * nx;
f->p1 += weight * ny;
}
void var18_exponential (flam3_iter_helper *f, double weight) {
/* exponential */
/* dx = exp(tx-1.0);
dy = M_PI * ty;
nx = cos(dy) * dx;
ny = sin(dy) * dx;
p[0] += v * nx;
p[1] += v * ny; */
double dx = weight * exp(f->tx - 1.0);
double dy = M_PI * f->ty;
double sdy,cdy;
sincos(dy,&sdy,&cdy);
f->p0 += dx * cdy;
f->p1 += dx * sdy;
}
void var19_power (flam3_iter_helper *f, double weight) {
/* power */
/* a = atan2(tx, ty);
sa = sin(a);
r = sqrt(tx*tx + ty*ty);
r = pow(r, sa);
nx = r * precalc_cosa;
ny = r * sa;
p[0] += v * nx;
p[1] += v * ny; */
double r = weight * pow(f->precalc_sqrt, f->precalc_sina);
f->p0 += r * f->precalc_cosa;
f->p1 += r * f->precalc_sina;
}
void var20_cosine (flam3_iter_helper *f, double weight) {
/* cosine */
/* nx = cos(tx * M_PI) * cosh(ty);
ny = -sin(tx * M_PI) * sinh(ty);
p[0] += v * nx;
p[1] += v * ny; */
double a = f->tx * M_PI;
double sa,ca;
double nx,ny;
sincos(a,&sa,&ca);
nx = ca * cosh(f->ty);
ny = -sa * sinh(f->ty);
f->p0 += weight * nx;
f->p1 += weight * ny;
}
void var21_rings (flam3_iter_helper *f, double weight) {
/* rings */
/* dx = coef[2][0];
dx = dx * dx + EPS;
r = sqrt(tx*tx + ty*ty);
r = fmod(r + dx, 2*dx) - dx + r*(1-dx);
a = atan2(tx, ty);
nx = cos(a) * r;
ny = sin(a) * r;
p[0] += v * nx;
p[1] += v * ny; */
double dx = f->xform->c[2][0] * f->xform->c[2][0] + EPS;
double r = f->precalc_sqrt;
r = weight * (fmod(r+dx, 2*dx) - dx + r * (1 - dx));
f->p0 += r * f->precalc_cosa;
f->p1 += r * f->precalc_sina;
}
void var22_fan (flam3_iter_helper *f, double weight) {
/* fan */
/* dx = coef[2][0];
dy = coef[2][1];
dx = M_PI * (dx * dx + EPS);
dx2 = dx/2;
a = atan(tx,ty);
r = sqrt(tx*tx + ty*ty);
a += (fmod(a+dy, dx) > dx2) ? -dx2 : dx2;
nx = cos(a) * r;
ny = sin(a) * r;
p[0] += v * nx;
p[1] += v * ny; */
double dx = M_PI * (f->xform->c[2][0] * f->xform->c[2][0] + EPS);
double dy = f->xform->c[2][1];
double dx2 = 0.5 * dx;
double a = f->precalc_atan;
double r = weight * f->precalc_sqrt;
double sa,ca;
a += (fmod(a+dy,dx) > dx2) ? -dx2 : dx2;
sincos(a,&sa,&ca);
f->p0 += r * ca;
f->p1 += r * sa;
}
void var23_blob (flam3_iter_helper *f, double weight) {
/* blob */
/* a = atan2(tx, ty);
r = sqrt(tx*tx + ty*ty);
r = r * (bloblow + (blobhigh-bloblow) * (0.5 + 0.5 * sin(blobwaves * a)));
nx = sin(a) * r;
ny = cos(a) * r;
p[0] += v * nx;
p[1] += v * ny; */
double r = f->precalc_sqrt;
double a = f->precalc_atan;
double bdiff = f->xform->blob_high - f->xform->blob_low;
r = r * (f->xform->blob_low +
bdiff * (0.5 + 0.5 * sin(f->xform->blob_waves * a)));
f->p0 += weight * f->precalc_sina * r;
f->p1 += weight * f->precalc_cosa * r;
}
void var24_pdj (flam3_iter_helper *f, double weight) {
/* pdj */
/* nx1 = cos(pdjb * tx);
nx2 = sin(pdjc * tx);
ny1 = sin(pdja * ty);
ny2 = cos(pdjd * ty);
p[0] += v * (ny1 - nx1);
p[1] += v * (nx2 - ny2); */
double nx1 = cos(f->xform->pdj_b * f->tx);
double nx2 = sin(f->xform->pdj_c * f->tx);
double ny1 = sin(f->xform->pdj_a * f->ty);
double ny2 = cos(f->xform->pdj_d * f->ty);
f->p0 += weight * (ny1 - nx1);
f->p1 += weight * (nx2 - ny2);
}
void var25_fan2 (flam3_iter_helper *f, double weight) {
/* fan2 */
/* a = precalc_atan;
r = precalc_sqrt;
dy = fan2y;
dx = M_PI * (fan2x * fan2x + EPS);
dx2 = dx / 2.0;
t = a + dy - dx * (int)((a + dy)/dx);
if (t > dx2)
a = a - dx2;
else
a = a + dx2;
nx = sin(a) * r;
ny = cos(a) * r;
p[0] += v * nx;
p[1] += v * ny; */
double dy = f->xform->fan2_y;
double dx = M_PI * (f->xform->fan2_x * f->xform->fan2_x + EPS);
double dx2 = 0.5 * dx;
double a = f->precalc_atan;
double sa,ca;
double r = weight * f->precalc_sqrt;
double t = a + dy - dx * (int)((a + dy)/dx);
if (t>dx2)
a = a-dx2;
else
a = a+dx2;
sincos(a,&sa,&ca);
f->p0 += r * sa;
f->p1 += r * ca;
}
void var26_rings2 (flam3_iter_helper *f, double weight) {
/* rings2 */
/* r = precalc_sqrt;
dx = rings2val * rings2val + EPS;
r += dx - 2.0*dx*(int)((r + dx)/(2.0 * dx)) - dx + r * (1.0-dx);
nx = precalc_sina * r;
ny = precalc_cosa * r;
p[0] += v * nx;
p[1] += v * ny; */
double r = f->precalc_sqrt;
double dx = f->xform->rings2_val * f->xform->rings2_val + EPS;
r += -2.0*dx*(int)((r+dx)/(2.0*dx)) + r * (1.0-dx);
f->p0 += weight * f->precalc_sina * r;
f->p1 += weight * f->precalc_cosa * r;
}
void var27_eyefish (flam3_iter_helper *f, double weight) {
/* eyefish */
/* r = 2.0 * v / (precalc_sqrt + 1.0);
p[0] += r*tx;
p[1] += r*ty; */
double r = (weight * 2.0) / (f->precalc_sqrt + 1.0);
f->p0 += r * f->tx;
f->p1 += r * f->ty;
}
void var28_bubble (flam3_iter_helper *f, double weight) {
/* bubble */
double r = weight / (0.25 * (f->precalc_sumsq) + 1);
f->p0 += r * f->tx;
f->p1 += r * f->ty;
}
void var29_cylinder (flam3_iter_helper *f, double weight) {
/* cylinder (01/06) */
f->p0 += weight * sin(f->tx);
f->p1 += weight * f->ty;
}
void var30_perspective (flam3_iter_helper *f, double weight) {
/* perspective (01/06) */
double t = 1.0 / (f->xform->perspective_dist - f->ty * f->xform->persp_vsin);
f->p0 += weight * f->xform->perspective_dist * f->tx * t;
f->p1 += weight * f->xform->persp_vfcos * f->ty * t;
}
void var31_noise (flam3_iter_helper *f, double weight) {
/* noise (03/06) */
double tmpr, sinr, cosr, r;
tmpr = flam3_random_isaac_01(f->rc) * 2 * M_PI;
sincos(tmpr,&sinr,&cosr);
r = weight * flam3_random_isaac_01(f->rc);
f->p0 += f->tx * r * cosr;
f->p1 += f->ty * r * sinr;
}
void var32_juliaN_generic (flam3_iter_helper *f, double weight) {
/* juliaN (03/06) */
int t_rnd = trunc((f->xform->julian_rN)*flam3_random_isaac_01(f->rc));
double tmpr = (f->precalc_atanyx + 2 * M_PI * t_rnd) / f->xform->julian_power;
double r = weight * pow(f->precalc_sumsq, f->xform->julian_cn);
double sina, cosa;
sincos(tmpr,&sina,&cosa);
f->p0 += r * cosa;
f->p1 += r * sina;
}
void var33_juliaScope_generic (flam3_iter_helper *f, double weight) {
/* juliaScope (03/06) */
int t_rnd = trunc((f->xform->juliascope_rN) * flam3_random_isaac_01(f->rc));
double tmpr, r;
double sina, cosa;
if ((t_rnd & 1) == 0)
tmpr = (2 * M_PI * t_rnd + f->precalc_atanyx) / f->xform->juliascope_power;
else
tmpr = (2 * M_PI * t_rnd - f->precalc_atanyx) / f->xform->juliascope_power;
sincos(tmpr,&sina,&cosa);
r = weight * pow(f->precalc_sumsq, f->xform->juliascope_cn);
f->p0 += r * cosa;
f->p1 += r * sina;
}
void var34_blur (flam3_iter_helper *f, double weight) {
/* blur (03/06) */
double tmpr, sinr, cosr, r;
tmpr = flam3_random_isaac_01(f->rc) * 2 * M_PI;
sincos(tmpr,&sinr,&cosr);
r = weight * flam3_random_isaac_01(f->rc);
f->p0 += r * cosr;
f->p1 += r * sinr;
}
void var35_gaussian (flam3_iter_helper *f, double weight) {
/* gaussian (09/06) */
double ang, r, sina, cosa;
ang = flam3_random_isaac_01(f->rc) * 2 * M_PI;
sincos(ang,&sina,&cosa);
r = weight * ( flam3_random_isaac_01(f->rc) + flam3_random_isaac_01(f->rc)
+ flam3_random_isaac_01(f->rc) + flam3_random_isaac_01(f->rc) - 2.0 );
f->p0 += r * cosa;
f->p1 += r * sina;
}
void var36_radial_blur (flam3_iter_helper *f, double weight) {
/* radial blur (09/06) */
/* removed random storage 6/07 */
double rndG, ra, rz, tmpa, sa, ca;
/* Get pseudo-gaussian */
rndG = weight * (flam3_random_isaac_01(f->rc) + flam3_random_isaac_01(f->rc)
+ flam3_random_isaac_01(f->rc) + flam3_random_isaac_01(f->rc) - 2.0);
/* Calculate angle & zoom */
ra = f->precalc_sqrt;
tmpa = f->precalc_atanyx + f->xform->radialBlur_spinvar*rndG;
sincos(tmpa,&sa,&ca);
rz = f->xform->radialBlur_zoomvar * rndG - 1;
f->p0 += ra * ca + rz * f->tx;
f->p1 += ra * sa + rz * f->ty;
}
void var37_pie(flam3_iter_helper *f, double weight) {
/* pie by Joel Faber (June 2006) */
double a, r, sa, ca;
int sl;
sl = (int) (flam3_random_isaac_01(f->rc) * f->xform->pie_slices + 0.5);
a = f->xform->pie_rotation +
2.0 * M_PI * (sl + flam3_random_isaac_01(f->rc) * f->xform->pie_thickness) / f->xform->pie_slices;
r = weight * flam3_random_isaac_01(f->rc);
sincos(a,&sa,&ca);
f->p0 += r * ca;
f->p1 += r * sa;
}
void var38_ngon(flam3_iter_helper *f, double weight) {
/* ngon by Joel Faber (09/06) */
double r_factor,theta,phi,b, amp;
r_factor = pow(f->precalc_sumsq, f->xform->ngon_power/2.0);
theta = f->precalc_atanyx;
b = 2*M_PI/f->xform->ngon_sides;
phi = theta - (b*floor(theta/b));
if (phi > b/2)
phi -= b;
amp = f->xform->ngon_corners * (1.0 / (cos(phi) + EPS) - 1.0) + f->xform->ngon_circle;
amp /= (r_factor + EPS);
f->p0 += weight * f->tx * amp;
f->p1 += weight * f->ty * amp;
}
void var39_curl(flam3_iter_helper *f, double weight)
{
double re = 1.0 + f->xform->curl_c1 * f->tx + f->xform->curl_c2 * (f->tx * f->tx - f->ty * f->ty);
double im = f->xform->curl_c1 * f->ty + 2.0 * f->xform->curl_c2 * f->tx * f->ty;
double r = weight / (re*re + im*im);
f->p0 += (f->tx * re + f->ty * im) * r;
f->p1 += (f->ty * re - f->tx * im) * r;
}
void var40_rectangles(flam3_iter_helper *f, double weight)
{
if (f->xform->rectangles_x==0)
f->p0 += weight * f->tx;
else
f->p0 += weight * ((2 * floor(f->tx / f->xform->rectangles_x) + 1) * f->xform->rectangles_x - f->tx);
if (f->xform->rectangles_y==0)
f->p1 += weight * f->ty;
else
f->p1 += weight * ((2 * floor(f->ty / f->xform->rectangles_y) + 1) * f->xform->rectangles_y - f->ty);
}
void var41_arch(flam3_iter_helper *f, double weight)
{
/* Z+ variation Jan 07
procedure TXForm.Arch;
var
sinr, cosr: double;
begin
SinCos(random * vars[29]*pi, sinr, cosr);
FPx := FPx + sinr*vars[29];
FPy := FPy + sqr(sinr)/cosr*vars[29];
end;
*/
/*
* !!! Note !!!
* This code uses the variation weight in a non-standard fashion, and
* it may change or even be removed in future versions of flam3.
*/
double ang = flam3_random_isaac_01(f->rc) * weight * M_PI;
double sinr,cosr;
sincos(ang,&sinr,&cosr);
f->p0 += weight * sinr;
f->p1 += weight * (sinr*sinr)/cosr;
}
void var42_tangent(flam3_iter_helper *f, double weight)
{
/* Z+ variation Jan 07
procedure TXForm.Tangent;
begin
FPx := FPx + vars[30] * (sin(FTx)/cos(FTy));
FPy := FPy + vars[30] * (sin(FTy)/cos(FTy));
end;
*/
f->p0 += weight * sin(f->tx)/cos(f->ty);
f->p1 += weight * tan(f->ty);
}
void var43_square(flam3_iter_helper *f, double weight)
{
/* Z+ variation Jan 07
procedure TXForm.SquareBlur;
begin
FPx := FPx + vars[31] * (random - 0.5);
FPy := FPy + vars[31] * (random - 0.5);
end;
*/
f->p0 += weight * (flam3_random_isaac_01(f->rc) - 0.5);
f->p1 += weight * (flam3_random_isaac_01(f->rc) - 0.5);
}
void var44_rays(flam3_iter_helper *f, double weight)
{
/* Z+ variation Jan 07
procedure TXForm.Rays;
var
r, sinr, cosr, tgr: double;
begin
SinCos(random * vars[32]*pi, sinr, cosr);
r := vars[32] / (sqr(FTx) + sqr(FTy) + EPS);
tgr := sinr/cosr;
FPx := FPx + tgr * (cos(FTx)*vars[32]) * r;
FPy := FPy + tgr * (sin(FTy)*vars[32]) * r;
end;
*/
/*
* !!! Note !!!
* This code uses the variation weight in a non-standard fashion, and
* it may change or even be removed in future versions of flam3.
*/
double ang = weight * flam3_random_isaac_01(f->rc) * M_PI;
double r = weight / (f->precalc_sumsq + EPS);
double tanr = weight * tan(ang) * r;
f->p0 += tanr * cos(f->tx);
f->p1 += tanr * sin(f->ty);
}
void var45_blade(flam3_iter_helper *f, double weight)
{
/* Z+ variation Jan 07
procedure TXForm.Blade;
var
r, sinr, cosr: double;
begin
r := sqrt(sqr(FTx) + sqr(FTy))*vars[33];
SinCos(r*random, sinr, cosr);
FPx := FPx + vars[33] * FTx * (cosr + sinr);
FPy := FPy + vars[33] * FTx * (cosr - sinr);
end;
*/
/*
* !!! Note !!!
* This code uses the variation weight in a non-standard fashion, and
* it may change or even be removed in future versions of flam3.
*/
double r = flam3_random_isaac_01(f->rc) * weight * f->precalc_sqrt;
double sinr,cosr;
sincos(r,&sinr,&cosr);
f->p0 += weight * f->tx * (cosr + sinr);
f->p1 += weight * f->tx * (cosr - sinr);
}
void var46_secant2(flam3_iter_helper *f, double weight)
{
/* Intended as a 'fixed' version of secant */
/*
* !!! Note !!!
* This code uses the variation weight in a non-standard fashion, and
* it may change or even be removed in future versions of flam3.
*/
double r = weight * f->precalc_sqrt;
double cr = cos(r);
double icr = 1.0/cr;
f->p0 += weight * f->tx;
if (cr<0)
f->p1 += weight*(icr + 1);
else
f->p1 += weight*(icr - 1);
}
void var47_twintrian(flam3_iter_helper *f, double weight)
{
/* Z+ variation Jan 07
procedure TXForm.TwinTrian;
var
r, diff, sinr, cosr: double;
begin
r := sqrt(sqr(FTx) + sqr(FTy))*vars[35];
SinCos(r*random, sinr, cosr);
diff := Math.Log10(sinr*sinr)+cosr;
FPx := FPx + vars[35] * FTx * diff;
FPy := FPy + vars[35] * FTx * (diff - (sinr*pi));
end;
*/
/*
* !!! Note !!!
* This code uses the variation weight in a non-standard fashion, and
* it may change or even be removed in future versions of flam3.
*/
double r = flam3_random_isaac_01(f->rc) * weight * f->precalc_sqrt;
double sinr,cosr,diff;
sincos(r,&sinr,&cosr);
diff = log10(sinr*sinr)+cosr;
if (badvalue(diff))
diff = -30.0;
f->p0 += weight * f->tx * diff;
f->p1 += weight * f->tx * (diff - sinr*M_PI);
}
void var48_cross(flam3_iter_helper *f, double weight)
{
/* Z+ variation Jan 07
procedure TXForm.Cross;
var
r: double;
begin
r := vars[36]*sqrt(1/(sqr(sqr(FTx)-sqr(FTy))+EPS));
FPx := FPx + FTx * r;
FPy := FPy + FTy * r;
end;
*/
double s = f->tx*f->tx - f->ty*f->ty;
double r = weight * sqrt(1.0 / (s*s+EPS));
f->p0 += f->tx * r;
f->p1 += f->ty * r;
}
void var49_disc2(flam3_iter_helper *f, double weight)
{
/* Z+ variation Jan 07
c := vvar/PI;
k := rot*PI;
sinadd := Sin(add);
cosadd := Cos(add);
cosadd := cosadd - 1;
if (add > 2*PI) then begin
cosadd := cosadd * (1 + add - 2*PI);
sinadd := sinadd * (1 + add - 2*PI)
end
else if (add < -2*PI) then begin
cosadd := cosadd * (1 + add + 2*PI);
sinadd := sinadd * (1 + add + 2*PI)
end
end;
procedure TVariationDisc2.CalcFunction;
var
r, sinr, cosr: extended;
begin
SinCos(k * (FTx^+FTy^), sinr, cosr); //rot*PI
r := c * arctan2(FTx^, FTy^); //vvar/PI
FPx^ := FPx^ + (sinr + cosadd) * r;
FPy^ := FPy^ + (cosr + sinadd) * r;
*/
double r,t,sinr, cosr;
t = f->xform->disc2_timespi * (f->tx + f->ty);
sincos(t,&sinr,&cosr);
r = weight * f->precalc_atan / M_PI;
f->p0 += (sinr + f->xform->disc2_cosadd) * r;
f->p1 += (cosr + f->xform->disc2_sinadd) * r;
}
void var50_supershape(flam3_iter_helper *f, double weight) {
double theta;
double t1,t2,r;
double st,ct;
double myrnd;
theta = f->xform->super_shape_pm_4 * f->precalc_atanyx + M_PI_4;
sincos(theta,&st,&ct);
t1 = fabs(ct);
t1 = pow(t1,f->xform->super_shape_n2);
t2 = fabs(st);
t2 = pow(t2,f->xform->super_shape_n3);
myrnd = f->xform->super_shape_rnd;
r = weight * ( (myrnd*flam3_random_isaac_01(f->rc) + (1.0-myrnd)*f->precalc_sqrt) - f->xform->super_shape_holes)
* pow(t1+t2,f->xform->super_shape_pneg1_n1) / f->precalc_sqrt;
f->p0 += r * f->tx;
f->p1 += r * f->ty;
}
void var51_flower(flam3_iter_helper *f, double weight) {
/* cyberxaos, 4/2007 */
/* theta := arctan2(FTy^, FTx^);
r := (random-holes)*cos(petals*theta);
FPx^ := FPx^ + vvar*r*cos(theta);
FPy^ := FPy^ + vvar*r*sin(theta);*/
double theta = f->precalc_atanyx;
double r = weight * (flam3_random_isaac_01(f->rc) - f->xform->flower_holes) *
cos(f->xform->flower_petals*theta) / f->precalc_sqrt;
f->p0 += r * f->tx;
f->p1 += r * f->ty;
}
void var52_conic(flam3_iter_helper *f, double weight) {
/* cyberxaos, 4/2007 */
/* theta := arctan2(FTy^, FTx^);
r := (random - holes)*((eccentricity)/(1+eccentricity*cos(theta)));
FPx^ := FPx^ + vvar*r*cos(theta);
FPy^ := FPy^ + vvar*r*sin(theta); */
double ct = f->tx / f->precalc_sqrt;
double r = weight * (flam3_random_isaac_01(f->rc) - f->xform->conic_holes) *
f->xform->conic_eccentricity / (1 + f->xform->conic_eccentricity*ct) / f->precalc_sqrt;
f->p0 += r * f->tx;
f->p1 += r * f->ty;
}
void var53_parabola(flam3_iter_helper *f, double weight) {
/* cyberxaos, 4/2007 */
/* r := sqrt(sqr(FTx^) + sqr(FTy^));
FPx^ := FPx^ + parabola_height*vvar*sin(r)*sin(r)*random;
FPy^ := FPy^ + parabola_width*vvar*cos(r)*random; */
double r = f->precalc_sqrt;
double sr,cr;
sincos(r,&sr,&cr);
f->p0 += f->xform->parabola_height * weight * sr*sr * flam3_random_isaac_01(f->rc);
f->p1 += f->xform->parabola_width * weight * cr * flam3_random_isaac_01(f->rc);
}
void var54_bent2 (flam3_iter_helper *f, double weight) {
/* Bent2 in the Apophysis Plugin Pack */
double nx = f->tx;
double ny = f->ty;
if (nx < 0.0)
nx = nx * f->xform->bent2_x;
if (ny < 0.0)
ny = ny * f->xform->bent2_y;
f->p0 += weight * nx;
f->p1 += weight * ny;
}
void var55_bipolar (flam3_iter_helper *f, double weight) {
/* Bipolar in the Apophysis Plugin Pack */
double x2y2 = f->precalc_sumsq;
double t = x2y2+1;
double x2 = 2*f->tx;
double ps = -M_PI_2 * f->xform->bipolar_shift;
double y = 0.5 * atan2(2.0 * f->ty, x2y2 - 1.0) + ps;
if (y > M_PI_2)
y = -M_PI_2 + fmod(y + M_PI_2, M_PI);
else if (y < -M_PI_2)
y = M_PI_2 - fmod(M_PI_2 - y, M_PI);
f->p0 += weight * 0.25 * M_2_PI * log ( (t+x2) / (t-x2) );
f->p1 += weight * M_2_PI * y;
}
void var56_boarders (flam3_iter_helper *f, double weight) {
/* Boarders in the Apophysis Plugin Pack */
double roundX, roundY, offsetX, offsetY;
roundX = rint(f->tx);
roundY = rint(f->ty);
offsetX = f->tx - roundX;
offsetY = f->ty - roundY;
if (flam3_random_isaac_01(f->rc) >= 0.75) {
f->p0 += weight*(offsetX*0.5 + roundX);
f->p1 += weight*(offsetY*0.5 + roundY);
} else {
if (fabs(offsetX) >= fabs(offsetY)) {
if (offsetX >= 0.0) {
f->p0 += weight*(offsetX*0.5 + roundX + 0.25);
f->p1 += weight*(offsetY*0.5 + roundY + 0.25 * offsetY / offsetX);
} else {
f->p0 += weight*(offsetX*0.5 + roundX - 0.25);
f->p1 += weight*(offsetY*0.5 + roundY - 0.25 * offsetY / offsetX);
}
} else {
if (offsetY >= 0.0) {
f->p1 += weight*(offsetY*0.5 + roundY + 0.25);
f->p0 += weight*(offsetX*0.5 + roundX + offsetX/offsetY*0.25);
} else {
f->p1 += weight*(offsetY*0.5 + roundY - 0.25);
f->p0 += weight*(offsetX*0.5 + roundX - offsetX/offsetY*0.25);
}
}
}
}
void var57_butterfly (flam3_iter_helper *f, double weight) {
/* Butterfly in the Apophysis Plugin Pack */
/* wx is weight*4/sqrt(3*pi) */
double wx = weight*1.3029400317411197908970256609023;
double y2 = f->ty*2.0;
double r = wx*sqrt(fabs(f->ty * f->tx)/(EPS + f->tx*f->tx + y2*y2));
f->p0 += r * f->tx;
f->p1 += r * y2;
}
void var58_cell (flam3_iter_helper *f, double weight) {
/* Cell in the Apophysis Plugin Pack */
double inv_cell_size = 1.0/f->xform->cell_size;
/* calculate input cell */
int x = floor(f->tx*inv_cell_size);
int y = floor(f->ty*inv_cell_size);
/* Offset from cell origin */
double dx = f->tx - x*f->xform->cell_size;
double dy = f->ty - y*f->xform->cell_size;
/* interleave cells */
if (y >= 0) {
if (x >= 0) {
y *= 2;
x *= 2;
} else {
y *= 2;
x = -(2*x+1);
}
} else {
if (x >= 0) {
y = -(2*y+1);
x *= 2;
} else {
y = -(2*y+1);
x = -(2*x+1);
}
}
f->p0 += weight * (dx + x*f->xform->cell_size);
f->p1 -= weight * (dy + y*f->xform->cell_size);
}
void var59_cpow (flam3_iter_helper *f, double weight) {
/* Cpow in the Apophysis Plugin Pack */
double a = f->precalc_atanyx;
double lnr = 0.5 * log(f->precalc_sumsq);
double va = 2.0 * M_PI / f->xform->cpow_power;
double vc = f->xform->cpow_r / f->xform->cpow_power;
double vd = f->xform->cpow_i / f->xform->cpow_power;
double ang = vc*a + vd*lnr + va*floor(f->xform->cpow_power*flam3_random_isaac_01(f->rc));
double sa,ca;
double m = weight * exp(vc * lnr - vd * a);
sincos(ang,&sa,&ca);
f->p0 += m * ca;
f->p1 += m * sa;
}
void var60_curve (flam3_iter_helper *f, double weight) {
/* Curve in the Apophysis Plugin Pack */
double pc_xlen = f->xform->curve_xlength*f->xform->curve_xlength;
double pc_ylen = f->xform->curve_ylength*f->xform->curve_ylength;
if (pc_xlen<1E-20) pc_xlen = 1E-20;
if (pc_ylen<1E-20) pc_ylen = 1E-20;
f->p0 += weight * (f->tx + f->xform->curve_xamp * exp(-f->ty*f->ty/pc_xlen));
f->p1 += weight * (f->ty + f->xform->curve_yamp * exp(-f->tx*f->tx/pc_ylen));
}
void var61_edisc (flam3_iter_helper *f, double weight) {
/* Edisc in the Apophysis Plugin Pack */
double tmp = f->precalc_sumsq + 1.0;
double tmp2 = 2.0 * f->tx;
double r1 = sqrt(tmp+tmp2);
double r2 = sqrt(tmp-tmp2);
double xmax = (r1+r2) * 0.5;
double a1 = log(xmax + sqrt(xmax - 1.0));
double a2 = -acos(f->tx/xmax);
double w = weight / 11.57034632;
double snv,csv,snhu,cshu;
sincos(a1,&snv,&csv);
snhu = sinh(a2);
cshu = cosh(a2);
if (f->ty > 0.0) snv = -snv;
f->p0 += w * cshu * csv;
f->p1 += w * snhu * snv;
}
void var62_elliptic (flam3_iter_helper *f, double weight) {
/* Elliptic in the Apophysis Plugin Pack */
double tmp = f->precalc_sumsq + 1.0;
double x2 = 2.0 * f->tx;
double xmax = 0.5 * (sqrt(tmp+x2) + sqrt(tmp-x2));
double a = f->tx / xmax;
double b = 1.0 - a*a;
double ssx = xmax - 1.0;
double w = weight / M_PI_2;
if (b<0)
b = 0;
else
b = sqrt(b);
if (ssx<0)
ssx = 0;
else
ssx = sqrt(ssx);
f->p0 += w * atan2(a,b);
if (f->ty > 0)
f->p1 += w * log(xmax + ssx);
else
f->p1 -= w * log(xmax + ssx);
}
void var63_escher (flam3_iter_helper *f, double weight) {
/* Escher in the Apophysis Plugin Pack */
double seb,ceb;
double vc,vd;
double m,n;
double sn,cn;
double a = f->precalc_atanyx;
double lnr = 0.5 * log(f->precalc_sumsq);
sincos(f->xform->escher_beta,&seb,&ceb);
vc = 0.5 * (1.0 + ceb);
vd = 0.5 * seb;
m = weight * exp(vc*lnr - vd*a);
n = vc*a + vd*lnr;
sincos(n,&sn,&cn);
f->p0 += m * cn;
f->p1 += m * sn;
}
void var64_foci (flam3_iter_helper *f, double weight) {
/* Foci in the Apophysis Plugin Pack */
double expx = exp(f->tx) * 0.5;
double expnx = 0.25 / expx;
double sn,cn,tmp;
sincos(f->ty,&sn,&cn);
tmp = weight/(expx + expnx - cn);
f->p0 += tmp * (expx - expnx);
f->p1 += tmp * sn;
}
void var65_lazysusan (flam3_iter_helper *f, double weight) {
/* Lazysusan in the Apophysis Plugin Pack */
double x = f->tx - f->xform->lazysusan_x;
double y = f->ty + f->xform->lazysusan_y;
double r = sqrt(x*x + y*y);
double sina, cosa;
if (rxform->lazysusan_spin +
f->xform->lazysusan_twist*(weight-r);
sincos(a,&sina,&cosa);
r = weight * r;
f->p0 += r*cosa + f->xform->lazysusan_x;
f->p1 += r*sina - f->xform->lazysusan_y;
} else {
r = weight * (1.0 + f->xform->lazysusan_space / r);
f->p0 += r*x + f->xform->lazysusan_x;
f->p1 += r*y - f->xform->lazysusan_y;
}
}
void var66_loonie (flam3_iter_helper *f, double weight) {
/* Loonie in the Apophysis Plugin Pack */
/*
* !!! Note !!!
* This code uses the variation weight in a non-standard fashion, and
* it may change or even be removed in future versions of flam3.
*/
double r2 = f->precalc_sumsq;
double w2 = weight*weight;
if (r2 < w2) {
double r = weight * sqrt(w2/r2 - 1.0);
f->p0 += r * f->tx;
f->p1 += r * f->ty;
} else {
f->p0 += weight * f->tx;
f->p1 += weight * f->ty;
}
}
void var67_pre_blur (flam3_iter_helper *f, double weight) {
/* pre-xform: PreBlur (Apo 2.08) */
/* Get pseudo-gaussian */
double rndG = weight * (flam3_random_isaac_01(f->rc) + flam3_random_isaac_01(f->rc)
+ flam3_random_isaac_01(f->rc) + flam3_random_isaac_01(f->rc) - 2.0);
double rndA = flam3_random_isaac_01(f->rc) * 2.0 * M_PI;
double sinA,cosA;
sincos(rndA,&sinA,&cosA);
/* Note: original coordinate changed */
f->tx += rndG * cosA;
f->ty += rndG * sinA;
}
void var68_modulus (flam3_iter_helper *f, double weight) {
/* Modulus in the Apophysis Plugin Pack */
double xr = 2*f->xform->modulus_x;
double yr = 2*f->xform->modulus_y;
if (f->tx > f->xform->modulus_x)
f->p0 += weight * (-f->xform->modulus_x + fmod(f->tx + f->xform->modulus_x, xr));
else if (f->tx < -f->xform->modulus_x)
f->p0 += weight * ( f->xform->modulus_x - fmod(f->xform->modulus_x - f->tx, xr));
else
f->p0 += weight * f->tx;
if (f->ty > f->xform->modulus_y)
f->p1 += weight * (-f->xform->modulus_y + fmod(f->ty + f->xform->modulus_y, yr));
else if (f->ty < -f->xform->modulus_y)
f->p1 += weight * ( f->xform->modulus_y - fmod(f->xform->modulus_y - f->ty, yr));
else
f->p1 += weight * f->ty;
}
void var69_oscope (flam3_iter_helper *f, double weight) {
/* oscilloscope from the apophysis plugin pack */
double tpf = 2 * M_PI * f->xform->oscope_frequency;
double t;
if (f->xform->oscope_damping == 0.0)
t = f->xform->oscope_amplitude * cos(tpf*f->tx) + f->xform->oscope_separation;
else {
t = f->xform->oscope_amplitude * exp(-fabs(f->tx)*f->xform->oscope_damping)
* cos(tpf*f->tx) + f->xform->oscope_separation;
}
if (fabs(f->ty) <= t) {
f->p0 += weight*f->tx;
f->p1 -= weight*f->ty;
} else {
f->p0 += weight*f->tx;
f->p1 += weight*f->ty;
}
}
void var70_polar2 (flam3_iter_helper *f, double weight) {
/* polar2 from the apophysis plugin pack */
double p2v = weight / M_PI;
f->p0 += p2v * f->precalc_atan;
f->p1 += p2v/2.0 * log(f->precalc_sumsq);
}
void var71_popcorn2 (flam3_iter_helper *f, double weight) {
/* popcorn2 from the apophysis plugin pack */
f->p0 += weight * ( f->tx + f->xform->popcorn2_x * sin(tan(f->ty*f->xform->popcorn2_c)));
f->p1 += weight * ( f->ty + f->xform->popcorn2_y * sin(tan(f->tx*f->xform->popcorn2_c)));
}
void var72_scry (flam3_iter_helper *f, double weight) {
/* scry from the apophysis plugin pack */
/* note that scry does not multiply by weight, but as the */
/* values still approach 0 as the weight approaches 0, it */
/* should be ok */
/*
* !!! Note !!!
* This code uses the variation weight in a non-standard fashion, and
* it may change or even be removed in future versions of flam3.
*/
double t = f->precalc_sumsq;
double r = 1.0 / (f->precalc_sqrt * (t + 1.0/(weight+EPS)));
f->p0 += f->tx * r;
f->p1 += f->ty * r;
}
void var73_separation (flam3_iter_helper *f, double weight) {
/* separation from the apophysis plugin pack */
double sx2 = f->xform->separation_x * f->xform->separation_x;
double sy2 = f->xform->separation_y * f->xform->separation_y;
if (f->tx > 0.0)
f->p0 += weight * (sqrt(f->tx*f->tx + sx2)- f->tx*f->xform->separation_xinside);
else
f->p0 -= weight * (sqrt(f->tx*f->tx + sx2)+ f->tx*f->xform->separation_xinside);
if (f->ty > 0.0)
f->p1 += weight * (sqrt(f->ty*f->ty + sy2)- f->ty*f->xform->separation_yinside);
else
f->p1 -= weight * (sqrt(f->ty*f->ty + sy2)+ f->ty*f->xform->separation_yinside);
}
void var74_split (flam3_iter_helper *f, double weight) {
/* Split from apo plugins pack */
if (cos(f->tx*f->xform->split_xsize*M_PI) >= 0)
f->p1 += weight*f->ty;
else
f->p1 -= weight*f->ty;
if (cos(f->ty*f->xform->split_ysize*M_PI) >= 0)
f->p0 += weight * f->tx;
else
f->p0 -= weight * f->tx;
}
void var75_splits (flam3_iter_helper *f, double weight) {
/* Splits from apo plugins pack */
if (f->tx >= 0)
f->p0 += weight*(f->tx+f->xform->splits_x);
else
f->p0 += weight*(f->tx-f->xform->splits_x);
if (f->ty >= 0)
f->p1 += weight*(f->ty+f->xform->splits_y);
else
f->p1 += weight*(f->ty-f->xform->splits_y);
}
void var76_stripes (flam3_iter_helper *f, double weight) {
/* Stripes from apo plugins pack */
double roundx,offsetx;
roundx = floor(f->tx + 0.5);
offsetx = f->tx - roundx;
f->p0 += weight * (offsetx*(1.0-f->xform->stripes_space)+roundx);
f->p1 += weight * (f->ty + offsetx*offsetx*f->xform->stripes_warp);
}
void var77_wedge (flam3_iter_helper *f, double weight) {
/* Wedge from apo plugins pack */
double r = f->precalc_sqrt;
double a = f->precalc_atanyx + f->xform->wedge_swirl * r;
double c = floor( (f->xform->wedge_count * a + M_PI)*M_1_PI*0.5);
double comp_fac = 1 - f->xform->wedge_angle*f->xform->wedge_count*M_1_PI*0.5;
double sa, ca;
a = a * comp_fac + c * f->xform->wedge_angle;
sincos(a,&sa,&ca);
r = weight * (r + f->xform->wedge_hole);
f->p0 += r*ca;
f->p1 += r*sa;
}
void var78_wedge_julia (flam3_iter_helper *f, double weight) {
/* wedge_julia from apo plugin pack */
double r = weight * pow(f->precalc_sumsq, f->xform->wedgeJulia_cn);
int t_rnd = (int)((f->xform->wedgeJulia_rN)*flam3_random_isaac_01(f->rc));
double a = (f->precalc_atanyx + 2 * M_PI * t_rnd) / f->xform->wedge_julia_power;
double c = floor( (f->xform->wedge_julia_count * a + M_PI)*M_1_PI*0.5 );
double sa,ca;
a = a * f->xform->wedgeJulia_cf + c * f->xform->wedge_julia_angle;
sincos(a,&sa,&ca);
f->p0 += r * ca;
f->p1 += r * sa;
}
void var79_wedge_sph (flam3_iter_helper *f, double weight) {
/* Wedge_sph from apo plugins pack */
double r = 1.0/(f->precalc_sqrt+EPS);
double a = f->precalc_atanyx + f->xform->wedge_sph_swirl * r;
double c = floor( (f->xform->wedge_sph_count * a + M_PI)*M_1_PI*0.5);
double comp_fac = 1 - f->xform->wedge_sph_angle*f->xform->wedge_sph_count*M_1_PI*0.5;
double sa, ca;
a = a * comp_fac + c * f->xform->wedge_sph_angle;
sincos(a,&sa,&ca);
r = weight * (r + f->xform->wedge_sph_hole);
f->p0 += r*ca;
f->p1 += r*sa;
}
void var80_whorl (flam3_iter_helper *f, double weight) {
/* whorl from apo plugins pack */
/*
* !!! Note !!!
* This code uses the variation weight in a non-standard fashion, and
* it may change or even be removed in future versions of flam3.
*/
double r = f->precalc_sqrt;
double a,sa,ca;
if (rprecalc_atanyx + f->xform->whorl_inside/(weight-r);
else
a = f->precalc_atanyx + f->xform->whorl_outside/(weight-r);
sincos(a,&sa,&ca);
f->p0 += weight*r*ca;
f->p1 += weight*r*sa;
}
void var81_waves2 (flam3_iter_helper *f, double weight) {
/* waves2 from Joel F */
f->p0 += weight*(f->tx + f->xform->waves2_scalex*sin(f->ty * f->xform->waves2_freqx));
f->p1 += weight*(f->ty + f->xform->waves2_scaley*sin(f->tx * f->xform->waves2_freqy));
}
/* complex vars by cothe */
/* exp log sin cos tan sec csc cot sinh cosh tanh sech csch coth */
void var82_exp (flam3_iter_helper *f, double weight) {
//Exponential EXP
double expe = exp(f->tx);
double expcos,expsin;
sincos(f->ty,&expsin,&expcos);
f->p0 += weight * expe * expcos;
f->p1 += weight * expe * expsin;
}
void var83_log (flam3_iter_helper *f, double weight) {
//Natural Logarithm LOG
// needs precalc_atanyx and precalc_sumsq
f->p0 += weight * 0.5 * log(f->precalc_sumsq);
f->p1 += weight * f->precalc_atanyx;
}
void var84_sin (flam3_iter_helper *f, double weight) {
//Sine SIN
double sinsin,sinacos,sinsinh,sincosh;
sincos(f->tx,&sinsin,&sinacos);
sinsinh = sinh(f->ty);
sincosh = cosh(f->ty);
f->p0 += weight * sinsin * sincosh;
f->p1 += weight * sinacos * sinsinh;
}
void var85_cos (flam3_iter_helper *f, double weight) {
//Cosine COS
double cossin,coscos,cossinh,coscosh;
sincos(f->tx,&cossin,&coscos);
cossinh = sinh(f->ty);
coscosh = cosh(f->ty);
f->p0 += weight * coscos * coscosh;
f->p1 -= weight * cossin * cossinh;
}
void var86_tan (flam3_iter_helper *f, double weight) {
//Tangent TAN
double tansin,tancos,tansinh,tancosh;
double tanden;
sincos(2*f->tx,&tansin,&tancos);
tansinh = sinh(2.0*f->ty);
tancosh = cosh(2.0*f->ty);
tanden = 1.0/(tancos + tancosh);
f->p0 += weight * tanden * tansin;
f->p1 += weight * tanden * tansinh;
}
void var87_sec (flam3_iter_helper *f, double weight) {
//Secant SEC
double secsin,seccos,secsinh,seccosh;
double secden;
sincos(f->tx,&secsin,&seccos);
secsinh = sinh(f->ty);
seccosh = cosh(f->ty);
secden = 2.0/(cos(2*f->tx) + cosh(2*f->ty));
f->p0 += weight * secden * seccos * seccosh;
f->p1 += weight * secden * secsin * secsinh;
}
void var88_csc (flam3_iter_helper *f, double weight) {
//Cosecant CSC
double cscsin,csccos,cscsinh,csccosh;
double cscden;
sincos(f->tx,&cscsin,&csccos);
cscsinh = sinh(f->ty);
csccosh = cosh(f->ty);
cscden = 2.0/(cosh(2.0*f->ty) - cos(2.0*f->tx));
f->p0 += weight * cscden * cscsin * csccosh;
f->p1 -= weight * cscden * csccos * cscsinh;
}
void var89_cot (flam3_iter_helper *f, double weight) {
//Cotangent COT
double cotsin,cotcos,cotsinh,cotcosh;
double cotden;
sincos(2.0*f->tx,&cotsin,&cotcos);
cotsinh = sinh(2.0*f->ty);
cotcosh = cosh(2.0*f->ty);
cotden = 1.0/(cotcosh - cotcos);
f->p0 += weight * cotden * cotsin;
f->p1 += weight * cotden * -1 * cotsinh;
}
void var90_sinh (flam3_iter_helper *f, double weight) {
//Hyperbolic Sine SINH
double sinhsin,sinhcos,sinhsinh,sinhcosh;
sincos(f->ty,&sinhsin,&sinhcos);
sinhsinh = sinh(f->tx);
sinhcosh = cosh(f->tx);
f->p0 += weight * sinhsinh * sinhcos;
f->p1 += weight * sinhcosh * sinhsin;
}
void var91_cosh (flam3_iter_helper *f, double weight) {
//Hyperbolic Cosine COSH
double coshsin,coshcos,coshsinh,coshcosh;
sincos(f->ty,&coshsin,&coshcos);
coshsinh = sinh(f->tx);
coshcosh = cosh(f->tx);
f->p0 += weight * coshcosh * coshcos;
f->p1 += weight * coshsinh * coshsin;
}
void var92_tanh (flam3_iter_helper *f, double weight) {
//Hyperbolic Tangent TANH
double tanhsin,tanhcos,tanhsinh,tanhcosh;
double tanhden;
sincos(2.0*f->ty,&tanhsin,&tanhcos);
tanhsinh = sinh(2.0*f->tx);
tanhcosh = cosh(2.0*f->tx);
tanhden = 1.0/(tanhcos + tanhcosh);
f->p0 += weight * tanhden * tanhsinh;
f->p1 += weight * tanhden * tanhsin;
}
void var93_sech (flam3_iter_helper *f, double weight) {
//Hyperbolic Secant SECH
double sechsin,sechcos,sechsinh,sechcosh;
double sechden;
sincos(f->ty,&sechsin,&sechcos);
sechsinh = sinh(f->tx);
sechcosh = cosh(f->tx);
sechden = 2.0/(cos(2.0*f->ty) + cosh(2.0*f->tx));
f->p0 += weight * sechden * sechcos * sechcosh;
f->p1 -= weight * sechden * sechsin * sechsinh;
}
void var94_csch (flam3_iter_helper *f, double weight) {
//Hyperbolic Cosecant CSCH
double cschsin,cschcos,cschsinh,cschcosh;
double cschden;
sincos(f->ty,&cschsin,&cschcos);
cschsinh = sinh(f->tx);
cschcosh = cosh(f->tx);
cschden = 2.0/(cosh(2.0*f->tx) - cos(2.0*f->ty));
f->p0 += weight * cschden * cschsinh * cschcos;
f->p1 -= weight * cschden * cschcosh * cschsin;
}
void var95_coth (flam3_iter_helper *f, double weight) {
//Hyperbolic Cotangent COTH
double cothsin,cothcos,cothsinh,cothcosh;
double cothden;
sincos(2.0*f->ty,&cothsin,&cothcos);
cothsinh = sinh(2.0*f->tx);
cothcosh = cosh(2.0*f->tx);
cothden = 1.0/(cothcosh - cothcos);
f->p0 += weight * cothden * cothsinh;
f->p1 += weight * cothden * cothsin;
}
void var96_auger (flam3_iter_helper *f, double weight) {
// Auger, by Xyrus01
double s = sin(f->xform->auger_freq * f->tx);
double t = sin(f->xform->auger_freq * f->ty);
double dy = f->ty + f->xform->auger_weight*(f->xform->auger_scale*s/2.0 + fabs(f->ty)*s);
double dx = f->tx + f->xform->auger_weight*(f->xform->auger_scale*t/2.0 + fabs(f->tx)*t);
f->p0 += weight * (f->tx + f->xform->auger_sym*(dx-f->tx));
f->p1 += weight * dy;
}
void var97_flux (flam3_iter_helper *f, double weight) {
// Flux, by meckie
double xpw = f->tx + weight;
double xmw = f->tx - weight;
double avgr = weight * (2 + f->xform->flux_spread) * sqrt( sqrt(f->ty*f->ty + xpw*xpw) / sqrt(f->ty*f->ty + xmw*xmw));
double avga = ( atan2(f->ty, xmw) - atan2(f->ty,xpw) ) * 0.5;
double s = sin(avga);
double c = cos(avga);
f->p0 += avgr * cos(avga);
f->p1 += avgr * sin(avga);
}
/* Precalc functions */
void perspective_precalc(flam3_xform *xf) {
double ang = xf->perspective_angle * M_PI / 2.0;
xf->persp_vsin = sin(ang);
xf->persp_vfcos = xf->perspective_dist * cos(ang);
}
void juliaN_precalc(flam3_xform *xf) {
xf->julian_rN = fabs(xf->julian_power);
xf->julian_cn = xf->julian_dist / (double)xf->julian_power / 2.0;
}
void wedgeJulia_precalc(flam3_xform *xf) {
xf->wedgeJulia_cf = 1.0 - xf->wedge_julia_angle * xf->wedge_julia_count * M_1_PI * 0.5;
xf->wedgeJulia_rN = fabs(xf->wedge_julia_power);
xf->wedgeJulia_cn = xf->wedge_julia_dist / xf->wedge_julia_power / 2.0;
}
void juliaScope_precalc(flam3_xform *xf) {
xf->juliascope_rN = fabs(xf->juliascope_power);
xf->juliascope_cn = xf->juliascope_dist / (double)xf->juliascope_power / 2.0;
}
void radial_blur_precalc(flam3_xform *xf) {
sincos(xf->radial_blur_angle * M_PI / 2.0,
&xf->radialBlur_spinvar, &xf->radialBlur_zoomvar);
}
void waves_precalc(flam3_xform *xf) {
double dx = xf->c[2][0];
double dy = xf->c[2][1];
xf->waves_dx2 = 1.0/(dx * dx + EPS);
xf->waves_dy2 = 1.0/(dy * dy + EPS);
}
void disc2_precalc(flam3_xform *xf) {
double add = xf->disc2_twist;
double k;
xf->disc2_timespi = xf->disc2_rot * M_PI;
sincos(add,&xf->disc2_sinadd,&xf->disc2_cosadd);
xf->disc2_cosadd -= 1;
if (add > 2 * M_PI) {
k = (1 + add - 2*M_PI);
xf->disc2_cosadd *= k;
xf->disc2_sinadd *= k;
}
if (add < -2 * M_PI) {
k = (1 + add + 2*M_PI);
xf->disc2_cosadd *= k;
xf->disc2_sinadd *= k;
}
}
void supershape_precalc(flam3_xform *xf) {
xf->super_shape_pm_4 = xf->super_shape_m / 4.0;
xf->super_shape_pneg1_n1 = -1.0 / xf->super_shape_n1;
}
void xform_precalc(flam3_genome *cp, int xi) {
perspective_precalc(&(cp->xform[xi]));
juliaN_precalc(&(cp->xform[xi]));
juliaScope_precalc(&(cp->xform[xi]));
radial_blur_precalc(&(cp->xform[xi]));
waves_precalc(&(cp->xform[xi]));
disc2_precalc(&(cp->xform[xi]));
supershape_precalc(&(cp->xform[xi]));
wedgeJulia_precalc(&(cp->xform[xi]));
}
int prepare_precalc_flags(flam3_genome *cp) {
double d;
int i,j,totnum;
/* Loop over valid xforms */
for (i = 0; i < cp->num_xforms; i++) {
d = cp->xform[i].density;
if (d < 0.0) {
fprintf(stderr, "xform %d weight must be non-negative, not %g.\n",i,d);
return(1);
}
if (i != cp->final_xform_index && d == 0.0)
continue;
totnum = 0;
cp->xform[i].vis_adjusted = adjust_percentage(cp->xform[i].opacity);
cp->xform[i].precalc_angles_flag=0;
cp->xform[i].precalc_atan_xy_flag=0;
cp->xform[i].precalc_atan_yx_flag=0;
cp->xform[i].has_preblur=0;
cp->xform[i].has_post = !(id_matrix(cp->xform[i].post));
for (j = 0; j < flam3_nvariations; j++) {
if (cp->xform[i].var[j]!=0) {
cp->xform[i].varFunc[totnum] = j;
cp->xform[i].active_var_weights[totnum] = cp->xform[i].var[j];
if (j==VAR_POLAR) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_HANDKERCHIEF) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_HEART) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_DISC) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_SPIRAL) {
cp->xform[i].precalc_angles_flag=1;
} else if (j==VAR_HYPERBOLIC) {
cp->xform[i].precalc_angles_flag=1;
} else if (j==VAR_DIAMOND) {
cp->xform[i].precalc_angles_flag=1;
} else if (j==VAR_EX) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_JULIA) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_POWER) {
cp->xform[i].precalc_angles_flag=1;
} else if (j==VAR_RINGS) {
cp->xform[i].precalc_angles_flag=1;
} else if (j==VAR_FAN) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_BLOB) {
cp->xform[i].precalc_atan_xy_flag=1;
cp->xform[i].precalc_angles_flag=1;
} else if (j==VAR_FAN2) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_RINGS2) {
cp->xform[i].precalc_angles_flag=1;
} else if (j==VAR_JULIAN) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_JULIASCOPE) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_RADIAL_BLUR) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_NGON) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_DISC2) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_SUPER_SHAPE) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_FLOWER) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_CONIC) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_CPOW) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_ESCHER) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_PRE_BLUR) {
cp->xform[i].has_preblur=cp->xform[i].var[j];
} else if (j==VAR_POLAR2) {
cp->xform[i].precalc_atan_xy_flag=1;
} else if (j==VAR_WEDGE) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_WEDGE_JULIA) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_WEDGE_SPH) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_WHORL) {
cp->xform[i].precalc_atan_yx_flag=1;
} else if (j==VAR_LOG) {
cp->xform[i].precalc_atan_yx_flag=1;
}
totnum++;
}
}
cp->xform[i].num_active_vars = totnum;
}
return(0);
}
int apply_xform(flam3_genome *cp, int fn, double *p, double *q, randctx *rc)
{
flam3_iter_helper f;
int var_n;
double next_color,s,s1;
double weight;
f.rc = rc;
s1 = cp->xform[fn].color_speed;
q[2] = s1 * cp->xform[fn].color + (1.0-s1) * p[2];
q[3] = cp->xform[fn].vis_adjusted;
//fprintf(stderr,"%d : %f %f %f\n",fn,cp->xform[fn].c[0][0],cp->xform[fn].c[1][0],cp->xform[fn].c[2][0]);
f.tx = cp->xform[fn].c[0][0] * p[0] + cp->xform[fn].c[1][0] * p[1] + cp->xform[fn].c[2][0];
f.ty = cp->xform[fn].c[0][1] * p[0] + cp->xform[fn].c[1][1] * p[1] + cp->xform[fn].c[2][1];
/* Pre-xforms go here, and modify the f.tx and f.ty values */
if (cp->xform[fn].has_preblur!=0.0)
var67_pre_blur(&f, cp->xform[fn].has_preblur);
/* Always calculate sumsq and sqrt */
f.precalc_sumsq = f.tx*f.tx + f.ty*f.ty;
f.precalc_sqrt = sqrt(f.precalc_sumsq);
/* Check to see if we can precalculate any parts */
/* Precalculate atanxy, sin, cos */
if (cp->xform[fn].precalc_atan_xy_flag > 0) {
f.precalc_atan = atan2(f.tx,f.ty);
}
if (cp->xform[fn].precalc_angles_flag > 0) {
f.precalc_sina = f.tx / f.precalc_sqrt;
f.precalc_cosa = f.ty / f.precalc_sqrt;
}
/* Precalc atanyx */
if (cp->xform[fn].precalc_atan_yx_flag > 0) {
f.precalc_atanyx = atan2(f.ty,f.tx);
}
f.p0 = 0.0;
f.p1 = 0.0;
f.xform = &(cp->xform[fn]);
for (var_n=0; var_n < cp->xform[fn].num_active_vars; var_n++) {
weight = cp->xform[fn].active_var_weights[var_n];
switch (cp->xform[fn].varFunc[var_n]) {
case (VAR_LINEAR):
var0_linear(&f, weight); break;
case (VAR_SINUSOIDAL):
var1_sinusoidal(&f, weight); break;
case (VAR_SPHERICAL):
var2_spherical(&f, weight); break;
case (VAR_SWIRL):
var3_swirl(&f, weight); break;
case (VAR_HORSESHOE):
var4_horseshoe(&f, weight); break;
case (VAR_POLAR):
var5_polar(&f, weight); break;
case (VAR_HANDKERCHIEF):
var6_handkerchief(&f, weight); break;
case (VAR_HEART):
var7_heart(&f, weight); break;
case (VAR_DISC):
var8_disc(&f, weight); break;
case (VAR_SPIRAL):
var9_spiral(&f, weight); break;
case (VAR_HYPERBOLIC):
var10_hyperbolic(&f, weight); break;
case (VAR_DIAMOND):
var11_diamond(&f, weight); break;
case (VAR_EX):
var12_ex(&f, weight); break;
case (VAR_JULIA):
var13_julia(&f, weight); break;
case (VAR_BENT):
var14_bent(&f, weight); break;
case (VAR_WAVES):
var15_waves(&f, weight); break;
case (VAR_FISHEYE):
var16_fisheye(&f, weight); break;
case (VAR_POPCORN):
var17_popcorn(&f, weight); break;
case (VAR_EXPONENTIAL):
var18_exponential(&f, weight); break;
case (VAR_POWER):
var19_power(&f, weight); break;
case (VAR_COSINE):
var20_cosine(&f, weight); break;
case (VAR_RINGS):
var21_rings(&f, weight); break;
case (VAR_FAN):
var22_fan(&f, weight); break;
case (VAR_BLOB):
var23_blob(&f, weight); break;
case (VAR_PDJ):
var24_pdj(&f, weight); break;
case (VAR_FAN2):
var25_fan2(&f, weight); break;
case (VAR_RINGS2):
var26_rings2(&f, weight); break;
case (VAR_EYEFISH):
var27_eyefish(&f, weight); break;
case (VAR_BUBBLE):
var28_bubble(&f, weight); break;
case (VAR_CYLINDER):
var29_cylinder(&f, weight); break;
case (VAR_PERSPECTIVE):
var30_perspective(&f, weight); break;
case (VAR_NOISE):
var31_noise(&f, weight); break;
case (VAR_JULIAN):
var32_juliaN_generic(&f, weight); break;
case (VAR_JULIASCOPE):
var33_juliaScope_generic(&f, weight);break;
case (VAR_BLUR):
var34_blur(&f, weight); break;
case (VAR_GAUSSIAN_BLUR):
var35_gaussian(&f, weight); break;
case (VAR_RADIAL_BLUR):
var36_radial_blur(&f, weight); break;
case (VAR_PIE):
var37_pie(&f, weight); break;
case (VAR_NGON):
var38_ngon(&f, weight); break;
case (VAR_CURL):
var39_curl(&f, weight); break;
case (VAR_RECTANGLES):
var40_rectangles(&f, weight); break;
case (VAR_ARCH):
var41_arch(&f, weight); break;
case (VAR_TANGENT):
var42_tangent(&f, weight); break;
case (VAR_SQUARE):
var43_square(&f, weight); break;
case (VAR_RAYS):
var44_rays(&f, weight); break;
case (VAR_BLADE):
var45_blade(&f, weight); break;
case (VAR_SECANT2):
var46_secant2(&f, weight); break;
case (VAR_TWINTRIAN):
var47_twintrian(&f, weight); break;
case (VAR_CROSS):
var48_cross(&f, weight); break;
case (VAR_DISC2):
var49_disc2(&f, weight); break;
case (VAR_SUPER_SHAPE):
var50_supershape(&f, weight); break;
case (VAR_FLOWER):
var51_flower(&f, weight); break;
case (VAR_CONIC):
var52_conic(&f, weight); break;
case (VAR_PARABOLA):
var53_parabola(&f, weight); break;
case (VAR_BENT2):
var54_bent2(&f, weight); break;
case (VAR_BIPOLAR):
var55_bipolar(&f, weight); break;
case (VAR_BOARDERS):
var56_boarders(&f, weight); break;
case (VAR_BUTTERFLY):
var57_butterfly(&f, weight); break;
case (VAR_CELL):
var58_cell(&f, weight); break;
case (VAR_CPOW):
var59_cpow(&f, weight); break;
case (VAR_CURVE):
var60_curve(&f, weight); break;
case (VAR_EDISC):
var61_edisc(&f, weight); break;
case (VAR_ELLIPTIC):
var62_elliptic(&f, weight); break;
case (VAR_ESCHER):
var63_escher(&f, weight); break;
case (VAR_FOCI):
var64_foci(&f, weight); break;
case (VAR_LAZYSUSAN):
var65_lazysusan(&f, weight); break;
case (VAR_LOONIE):
var66_loonie(&f, weight); break;
case (VAR_MODULUS):
var68_modulus(&f, weight); break;
case (VAR_OSCILLOSCOPE):
var69_oscope(&f, weight); break;
case (VAR_POLAR2):
var70_polar2(&f, weight); break;
case (VAR_POPCORN2):
var71_popcorn2(&f, weight); break;
case (VAR_SCRY):
var72_scry(&f, weight); break;
case (VAR_SEPARATION):
var73_separation(&f, weight); break;
case (VAR_SPLIT):
var74_split(&f, weight); break;
case (VAR_SPLITS):
var75_splits(&f, weight); break;
case (VAR_STRIPES):
var76_stripes(&f, weight); break;
case (VAR_WEDGE):
var77_wedge(&f, weight); break;
case (VAR_WEDGE_JULIA):
var78_wedge_julia(&f, weight); break;
case (VAR_WEDGE_SPH):
var79_wedge_sph(&f, weight); break;
case (VAR_WHORL):
var80_whorl(&f, weight); break;
case (VAR_WAVES2):
var81_waves2(&f, weight); break;
case (VAR_EXP):
var82_exp(&f, weight); break;
case (VAR_LOG):
var83_log(&f, weight); break;
case (VAR_SIN):
var84_sin(&f, weight); break;
case (VAR_COS):
var85_cos(&f, weight); break;
case (VAR_TAN):
var86_tan(&f, weight); break;
case (VAR_SEC):
var87_sec(&f, weight); break;
case (VAR_CSC):
var88_csc(&f, weight); break;
case (VAR_COT):
var89_cot(&f, weight); break;
case (VAR_SINH):
var90_sinh(&f, weight); break;
case (VAR_COSH):
var91_cosh(&f, weight); break;
case (VAR_TANH):
var92_tanh(&f, weight); break;
case (VAR_SECH):
var93_sech(&f, weight); break;
case (VAR_CSCH):
var94_csch(&f, weight); break;
case (VAR_COTH):
var95_coth(&f, weight); break;
case (VAR_AUGER):
var96_auger(&f, weight); break;
case (VAR_FLUX):
var97_flux(&f, weight); break;
}
}
/* apply the post transform */
if (cp->xform[fn].has_post) {
q[0] = cp->xform[fn].post[0][0] * f.p0 + cp->xform[fn].post[1][0] * f.p1 + cp->xform[fn].post[2][0];
q[1] = cp->xform[fn].post[0][1] * f.p0 + cp->xform[fn].post[1][1] * f.p1 + cp->xform[fn].post[2][1];
} else {
q[0] = f.p0;
q[1] = f.p1;
}
/* Check for badvalues and return randoms if bad */
if (badvalue(q[0]) || badvalue(q[1])) {
q[0] = flam3_random_isaac_11(rc);
q[1] = flam3_random_isaac_11(rc);
return(1);
} else
return(0);
}
void initialize_xforms(flam3_genome *thiscp, int start_here) {
int i,j;
for (i = start_here ; i < thiscp->num_xforms ; i++) {
thiscp->xform[i].padding = 0;
thiscp->xform[i].density = 0.0;
thiscp->xform[i].color_speed = 0.5;
thiscp->xform[i].animate = 1.0;
thiscp->xform[i].color = i&1;
thiscp->xform[i].opacity = 1.0;
thiscp->xform[i].var[0] = 1.0;
thiscp->xform[i].motion_freq = 0;
thiscp->xform[i].motion_func = 0;
thiscp->xform[i].num_motion = 0;
thiscp->xform[i].motion = NULL;
for (j = 1; j < flam3_nvariations; j++)
thiscp->xform[i].var[j] = 0.0;
thiscp->xform[i].c[0][0] = 1.0;
thiscp->xform[i].c[0][1] = 0.0;
thiscp->xform[i].c[1][0] = 0.0;
thiscp->xform[i].c[1][1] = 1.0;
thiscp->xform[i].c[2][0] = 0.0;
thiscp->xform[i].c[2][1] = 0.0;
thiscp->xform[i].post[0][0] = 1.0;
thiscp->xform[i].post[0][1] = 0.0;
thiscp->xform[i].post[1][0] = 0.0;
thiscp->xform[i].post[1][1] = 1.0;
thiscp->xform[i].post[2][0] = 0.0;
thiscp->xform[i].post[2][1] = 0.0;
thiscp->xform[i].wind[0] = 0.0;
thiscp->xform[i].wind[1] = 0.0;
thiscp->xform[i].blob_low = 0.0;
thiscp->xform[i].blob_high = 1.0;
thiscp->xform[i].blob_waves = 1.0;
thiscp->xform[i].pdj_a = 0.0;
thiscp->xform[i].pdj_b = 0.0;
thiscp->xform[i].pdj_c = 0.0;
thiscp->xform[i].pdj_d = 0.0;
thiscp->xform[i].fan2_x = 0.0;
thiscp->xform[i].fan2_y = 0.0;
thiscp->xform[i].rings2_val = 0.0;
thiscp->xform[i].perspective_angle = 0.0;
thiscp->xform[i].perspective_dist = 0.0;
thiscp->xform[i].persp_vsin = 0.0;
thiscp->xform[i].persp_vfcos = 0.0;
thiscp->xform[i].radial_blur_angle = 0.0;
thiscp->xform[i].disc2_rot = 0.0;
thiscp->xform[i].disc2_twist = 0.0;
thiscp->xform[i].disc2_sinadd = 0.0;
thiscp->xform[i].disc2_cosadd = 0.0;
thiscp->xform[i].disc2_timespi = 0.0;
thiscp->xform[i].flower_petals = 0.0;
thiscp->xform[i].flower_holes = 0.0;
thiscp->xform[i].parabola_height = 0.0;
thiscp->xform[i].parabola_width = 0.0;
thiscp->xform[i].bent2_x = 1.0;
thiscp->xform[i].bent2_y = 1.0;
thiscp->xform[i].bipolar_shift = 0.0;
thiscp->xform[i].cell_size = 1.0;
thiscp->xform[i].cpow_r = 1.0;
thiscp->xform[i].cpow_i = 0.0;
thiscp->xform[i].cpow_power = 1.0;
thiscp->xform[i].curve_xamp = 0.0;
thiscp->xform[i].curve_yamp = 0.0;
thiscp->xform[i].curve_xlength = 1.0;
thiscp->xform[i].curve_ylength = 1.0;
thiscp->xform[i].escher_beta = 0.0;
thiscp->xform[i].lazysusan_space = 0.0;
thiscp->xform[i].lazysusan_twist = 0.0;
thiscp->xform[i].lazysusan_spin = 0.0;
thiscp->xform[i].lazysusan_x = 0.0;
thiscp->xform[i].lazysusan_y = 0.0;
thiscp->xform[i].modulus_x = 0.0;
thiscp->xform[i].modulus_y = 0.0;
thiscp->xform[i].oscope_separation = 1.0;
thiscp->xform[i].oscope_frequency = M_PI;
thiscp->xform[i].oscope_amplitude = 1.0;
thiscp->xform[i].oscope_damping = 0.0;
thiscp->xform[i].popcorn2_c = 0.0;
thiscp->xform[i].popcorn2_x = 0.0;
thiscp->xform[i].popcorn2_y = 0.0;
thiscp->xform[i].separation_x = 0.0;
thiscp->xform[i].separation_xinside = 0.0;
thiscp->xform[i].separation_y = 0.0;
thiscp->xform[i].separation_yinside = 0.0;
thiscp->xform[i].split_xsize = 0.0;
thiscp->xform[i].split_ysize = 0.0;
thiscp->xform[i].splits_x = 0.0;
thiscp->xform[i].splits_y = 0.0;
thiscp->xform[i].stripes_space = 0.0;
thiscp->xform[i].stripes_warp = 0.0;
thiscp->xform[i].wedge_angle = 0.0;
thiscp->xform[i].wedge_hole = 0.0;
thiscp->xform[i].wedge_count = 1.0;
thiscp->xform[i].wedge_swirl = 0.0;
thiscp->xform[i].wedge_sph_angle = 0.0;
thiscp->xform[i].wedge_sph_hole = 0.0;
thiscp->xform[i].wedge_sph_count = 1.0;
thiscp->xform[i].wedge_sph_swirl = 0.0;
thiscp->xform[i].wedge_julia_power = 1.0;
thiscp->xform[i].wedge_julia_dist = 0.0;
thiscp->xform[i].wedge_julia_count = 1.0;
thiscp->xform[i].wedge_julia_angle = 0.0;
thiscp->xform[i].wedgeJulia_cf = 0.0;
thiscp->xform[i].wedgeJulia_cn = 0.5;
thiscp->xform[i].wedgeJulia_rN = 1.0;
thiscp->xform[i].whorl_inside = 0.0;
thiscp->xform[i].whorl_outside = 0.0;
thiscp->xform[i].waves2_scalex = 0.0;
thiscp->xform[i].waves2_scaley = 0.0;
thiscp->xform[i].waves2_freqx = 0.0;
thiscp->xform[i].waves2_freqy = 0.0;
thiscp->xform[i].auger_freq = 1.0;
thiscp->xform[i].auger_weight = 0.5;
thiscp->xform[i].auger_sym = 0.0;
thiscp->xform[i].auger_scale = 1.0;
thiscp->xform[i].flux_spread = 0.0;
thiscp->xform[i].julian_power = 1.0;
thiscp->xform[i].julian_dist = 1.0;
thiscp->xform[i].julian_rN = 1.0;
thiscp->xform[i].julian_cn = 0.5;
thiscp->xform[i].juliascope_power = 1.0;
thiscp->xform[i].juliascope_dist = 1.0;
thiscp->xform[i].juliascope_rN = 1.0;
thiscp->xform[i].juliascope_cn = 0.5;
thiscp->xform[i].radialBlur_spinvar = 0.0;
thiscp->xform[i].radialBlur_zoomvar = 1.0;
thiscp->xform[i].pie_slices = 6.0;
thiscp->xform[i].pie_rotation = 0.0;
thiscp->xform[i].pie_thickness = 0.5;
thiscp->xform[i].ngon_sides = 5;
thiscp->xform[i].ngon_power = 3;
thiscp->xform[i].ngon_circle = 1;
thiscp->xform[i].ngon_corners = 2;
thiscp->xform[i].curl_c1 = 1.0;
thiscp->xform[i].curl_c2 = 0.0;
thiscp->xform[i].rectangles_x = 1.0;
thiscp->xform[i].rectangles_y = 1.0;
thiscp->xform[i].amw_amp = 1.0;
thiscp->xform[i].super_shape_rnd = 0.0;
thiscp->xform[i].super_shape_m = 0.0;
thiscp->xform[i].super_shape_n1 = 1.0;
thiscp->xform[i].super_shape_n2 = 1.0;
thiscp->xform[i].super_shape_n3 = 1.0;
thiscp->xform[i].super_shape_holes = 0.0;
thiscp->xform[i].conic_eccentricity = 1.0;
thiscp->xform[i].conic_holes = 0.0;
}
}