src/cmd/map/libmap/twocirc.c - plan9 - Git at Google

 #include <u.h>
 #include <libc.h>
 #include "map.h"

 static double
 quadratic(double a, double b, double c)
 {
 	double disc = b*b - 4*a*c;
 	return disc<0? 0: (-b-sqrt(disc))/(2*a);
 }

 /* for projections with meridians being circles centered
 on the x axis and parallels being circles centered on the y
 axis.  Find the intersection of the meridian thru (m,0), (90,0),
 with the parallel thru (0,p), (p1,p2) */

 static int
 twocircles(double m, double p, double p1, double p2, double *x, double *y)
 {
 	double a;	/* center of meridian circle, a>0 */
 	double b;	/* center of parallel circle, b>0 */
 	double t,bb;
 	if(m > 0) {
 		twocircles(-m,p,p1,p2,x,y);
 		*x = -*x;
 	} else if(p < 0) {
 		twocircles(m,-p,p1,-p2,x,y);
 		*y = -*y;
 	} else if(p < .01) {
 		*x = m;
 		t = m/p1;
 		*y = p + (p2-p)*t*t;
 	} else if(m > -.01) {
 		*y = p;
 		*x = m - m*p*p;
 	} else {
 		b = p>=1? 1: p>.99? 0.5*(p+1 + p1*p1/(1-p)):
 			0.5*(p*p-p1*p1-p2*p2)/(p-p2);
 		a = .5*(m - 1/m);
 		t = m*m-p*p+2*(b*p-a*m);
 		bb = b*b;
 		*x = quadratic(1+a*a/bb, -2*a + a*t/bb,
 			t*t/(4*bb) - m*m + 2*a*m);
 		*y = (*x*a+t/2)/b;
 	}
 	return 1;
 }

 static int
 Xglobular(struct place *place, double *x, double *y)
 {
 	twocircles(-2*place->wlon.l/PI,
 		2*place->nlat.l/PI, place->nlat.c, place->nlat.s, x, y);
 	return 1;
 }

 proj
 globular(void)
 {
 	return Xglobular;
 }

 static int
 Xvandergrinten(struct place *place, double *x, double *y)
 {
 	double t = 2*place->nlat.l/PI;
 	double abst = fabs(t);
 	double pval = abst>=1? 1: abst/(1+sqrt(1-t*t));
 	double p2 = 2*pval/(1+pval);
 	twocircles(-place->wlon.l/PI, pval, sqrt(1-p2*p2), p2, x, y);
 	if(t < 0)
 		*y = -*y;
 	return 1;
 }

 proj
 vandergrinten(void)
 {
 	return Xvandergrinten;
 }
	#include <u.h>
	#include <libc.h>
	#include "map.h"

	static double
	quadratic(double a, double b, double c)
	{
	double disc = bb - 4a*c;
	return disc<0? 0: (-b-sqrt(disc))/(2*a);
	}

	/* for projections with meridians being circles centered
	on the x axis and parallels being circles centered on the y
	axis. Find the intersection of the meridian thru (m,0), (90,0),
	with the parallel thru (0,p), (p1,p2) */

	static int
	twocircles(double m, double p, double p1, double p2, double x, double y)
	{
	double a; /* center of meridian circle, a>0 */
	double b; /* center of parallel circle, b>0 */
	double t,bb;
	if(m > 0) {
	twocircles(-m,p,p1,p2,x,y);
	x = -x;
	} else if(p < 0) {
	twocircles(m,-p,p1,-p2,x,y);
	y = -y;
	} else if(p < .01) {
	*x = m;
	t = m/p1;
	y = p + (p2-p)t*t;
	} else if(m > -.01) {
	*y = p;
	x = m - mp*p;
	} else {
	b = p>=1? 1: p>.99? 0.5(p+1 + p1p1/(1-p)):
	0.5(pp-p1p1-p2p2)/(p-p2);
	a = .5*(m - 1/m);
	t = mm-pp+2(bp-a*m);
	bb = b*b;
	x = quadratic(1+aa/bb, -2a + at/bb,
	tt/(4bb) - mm + 2a*m);
	y = (x*a+t/2)/b;
	}
	return 1;
	}

	static int
	Xglobular(struct place place, double x, double *y)
	{
	twocircles(-2*place->wlon.l/PI,
	2*place->nlat.l/PI, place->nlat.c, place->nlat.s, x, y);
	return 1;
	}

	proj
	globular(void)
	{
	return Xglobular;
	}

	static int
	Xvandergrinten(struct place place, double x, double *y)
	{
	double t = 2*place->nlat.l/PI;
	double abst = fabs(t);
	double pval = abst>=1? 1: abst/(1+sqrt(1-t*t));
	double p2 = 2*pval/(1+pval);
	twocircles(-place->wlon.l/PI, pval, sqrt(1-p2*p2), p2, x, y);
	if(t < 0)
	y = -y;
	return 1;
	}

	proj
	vandergrinten(void)
	{
	return Xvandergrinten;
	}