man/man3/arith3.3 - plan9 - Git at Google

 .TH ARITH3 3
 .SH NAME
 add3, sub3, neg3, div3, mul3, eqpt3, closept3, dot3, cross3, len3, dist3, unit3, midpt3, lerp3, reflect3, nearseg3, pldist3, vdiv3, vrem3, pn2f3, ppp2f3, fff2p3, pdiv4, add4, sub4 \- operations on 3-d points and planes
 .SH SYNOPSIS
 .PP
 .B
 #include <draw.h>
 .PP
 .B
 #include <geometry.h>
 .PP
 .B
 Point3 add3(Point3 a, Point3 b)
 .PP
 .B
 Point3 sub3(Point3 a, Point3 b)
 .PP
 .B
 Point3 neg3(Point3 a)
 .PP
 .B
 Point3 div3(Point3 a, double b)
 .PP
 .B
 Point3 mul3(Point3 a, double b)
 .PP
 .B
 int eqpt3(Point3 p, Point3 q)
 .PP
 .B
 int closept3(Point3 p, Point3 q, double eps)
 .PP
 .B
 double dot3(Point3 p, Point3 q)
 .PP
 .B
 Point3 cross3(Point3 p, Point3 q)
 .PP
 .B
 double len3(Point3 p)
 .PP
 .B
 double dist3(Point3 p, Point3 q)
 .PP
 .B
 Point3 unit3(Point3 p)
 .PP
 .B
 Point3 midpt3(Point3 p, Point3 q)
 .PP
 .B
 Point3 lerp3(Point3 p, Point3 q, double alpha)
 .PP
 .B
 Point3 reflect3(Point3 p, Point3 p0, Point3 p1)
 .PP
 .B
 Point3 nearseg3(Point3 p0, Point3 p1, Point3 testp)
 .PP
 .B
 double pldist3(Point3 p, Point3 p0, Point3 p1)
 .PP
 .B
 double vdiv3(Point3 a, Point3 b)
 .PP
 .B
 Point3 vrem3(Point3 a, Point3 b)
 .PP
 .B
 Point3 pn2f3(Point3 p, Point3 n)
 .PP
 .B
 Point3 ppp2f3(Point3 p0, Point3 p1, Point3 p2)
 .PP
 .B
 Point3 fff2p3(Point3 f0, Point3 f1, Point3 f2)
 .PP
 .B
 Point3 pdiv4(Point3 a)
 .PP
 .B
 Point3 add4(Point3 a, Point3 b)
 .PP
 .B
 Point3 sub4(Point3 a, Point3 b)
 .SH DESCRIPTION
 These routines do arithmetic on points and planes in affine or projective 3-space.
 Type
 .B Point3
 is
 .IP
 .EX
 .ta 6n
 typedef struct Point3 Point3;
 struct Point3{
 	double x, y, z, w;
 };
 .EE
 .PP
 Routines whose names end in
 .B 3
 operate on vectors or ordinary points in affine 3-space, represented by their Euclidean
 .B (x,y,z)
 coordinates.
 (They assume
 .B w=1
 in their arguments, and set
 .B w=1
 in their results.)
 .TF reflect3
 .TP
 Name
 Description
 .TP
 .B add3
 Add the coordinates of two points.
 .TP
 .B sub3
 Subtract coordinates of two points.
 .TP
 .B neg3
 Negate the coordinates of a point.
 .TP
 .B mul3
 Multiply coordinates by a scalar.
 .TP
 .B div3
 Divide coordinates by a scalar.
 .TP
 .B eqpt3
 Test two points for exact equality.
 .TP
 .B closept3
 Is the distance between two points smaller than
 .IR eps ?
 .TP
 .B dot3
 Dot product.
 .TP
 .B cross3
 Cross product.
 .TP
 .B len3
 Distance to the origin.
 .TP
 .B dist3
 Distance between two points.
 .TP
 .B unit3
 A unit vector parallel to
 .IR p .
 .TP
 .B midpt3
 The midpoint of line segment
 .IR pq .
 .TP
 .B lerp3
 Linear interpolation between
 .I p
 and
 .IR q .
 .TP
 .B reflect3
 The reflection of point
 .I p
 in the segment joining
 .I p0
 and
 .IR p1 .
 .TP
 .B nearseg3
 The closest point to
 .I testp
 on segment
 .IR "p0 p1" .
 .TP
 .B pldist3
 The distance from
 .I p
 to segment
 .IR "p0 p1" .
 .TP
 .B vdiv3
 Vector divide \(em the length of the component of
 .I a
 parallel to
 .IR b ,
 in units of the length of
 .IR b .
 .TP
 .B vrem3
 Vector remainder \(em the component of
 .I a
 perpendicular to
 .IR b .
 Ignoring roundoff, we have
 .BR "eqpt3(add3(mul3(b, vdiv3(a, b)), vrem3(a, b)), a)" .
 .PD
 .PP
 The following routines convert amongst various representations of points
 and planes.  Planes are represented identically to points, by duality;
 a point
 .B p
 is on a plane
 .B q
 whenever
 .BR p.x*q.x+p.y*q.y+p.z*q.z+p.w*q.w=0 .
 Although when dealing with affine points we assume
 .BR p.w=1 ,
 we can't make the same assumption for planes.
 The names of these routines are extra-cryptic.  They contain an
 .B f
 (for `face') to indicate a plane,
 .B p
 for a point and
 .B n
 for a normal vector.
 The number
 .B 2
 abbreviates the word `to.'
 The number
 .B 3
 reminds us, as before, that we're dealing with affine points.
 Thus
 .B pn2f3
 takes a point and a normal vector and returns the corresponding plane.
 .TF reflect3
 .TP
 Name
 Description
 .TP
 .B pn2f3
 Compute the plane passing through
 .I p
 with normal
 .IR n .
 .TP
 .B ppp2f3
 Compute the plane passing through three points.
 .TP
 .B fff2p3
 Compute the intersection point of three planes.
 .PD
 .PP
 The names of the following routines end in
 .B 4
 because they operate on points in projective 4-space,
 represented by their homogeneous coordinates.
 .TP
 pdiv4
 Perspective division.  Divide
 .B p.w
 into
 .IR p 's
 coordinates, converting to affine coordinates.
 If
 .B p.w
 is zero, the result is the same as the argument.
 .TP
 add4
 Add the coordinates of two points.
 .PD
 .TP
 sub4
 Subtract the coordinates of two points.
 .SH SOURCE
 .B \*9/src/libgeometry
 .SH "SEE ALSO
 .IR matrix (3)
	.TH ARITH3 3
	.SH NAME
	add3, sub3, neg3, div3, mul3, eqpt3, closept3, dot3, cross3, len3, dist3, unit3, midpt3, lerp3, reflect3, nearseg3, pldist3, vdiv3, vrem3, pn2f3, ppp2f3, fff2p3, pdiv4, add4, sub4 \- operations on 3-d points and planes
	.SH SYNOPSIS
	.PP
	.B
	#include <draw.h>
	.PP
	.B
	#include <geometry.h>
	.PP
	.B
	Point3 add3(Point3 a, Point3 b)
	.PP
	.B
	Point3 sub3(Point3 a, Point3 b)
	.PP
	.B
	Point3 neg3(Point3 a)
	.PP
	.B
	Point3 div3(Point3 a, double b)
	.PP
	.B
	Point3 mul3(Point3 a, double b)
	.PP
	.B
	int eqpt3(Point3 p, Point3 q)
	.PP
	.B
	int closept3(Point3 p, Point3 q, double eps)
	.PP
	.B
	double dot3(Point3 p, Point3 q)
	.PP
	.B
	Point3 cross3(Point3 p, Point3 q)
	.PP
	.B
	double len3(Point3 p)
	.PP
	.B
	double dist3(Point3 p, Point3 q)
	.PP
	.B
	Point3 unit3(Point3 p)
	.PP
	.B
	Point3 midpt3(Point3 p, Point3 q)
	.PP
	.B
	Point3 lerp3(Point3 p, Point3 q, double alpha)
	.PP
	.B
	Point3 reflect3(Point3 p, Point3 p0, Point3 p1)
	.PP
	.B
	Point3 nearseg3(Point3 p0, Point3 p1, Point3 testp)
	.PP
	.B
	double pldist3(Point3 p, Point3 p0, Point3 p1)
	.PP
	.B
	double vdiv3(Point3 a, Point3 b)
	.PP
	.B
	Point3 vrem3(Point3 a, Point3 b)
	.PP
	.B
	Point3 pn2f3(Point3 p, Point3 n)
	.PP
	.B
	Point3 ppp2f3(Point3 p0, Point3 p1, Point3 p2)
	.PP
	.B
	Point3 fff2p3(Point3 f0, Point3 f1, Point3 f2)
	.PP
	.B
	Point3 pdiv4(Point3 a)
	.PP
	.B
	Point3 add4(Point3 a, Point3 b)
	.PP
	.B
	Point3 sub4(Point3 a, Point3 b)
	.SH DESCRIPTION
	These routines do arithmetic on points and planes in affine or projective 3-space.
	Type
	.B Point3
	is
	.IP
	.EX
	.ta 6n
	typedef struct Point3 Point3;
	struct Point3{
	double x, y, z, w;
	};
	.EE
	.PP
	Routines whose names end in
	.B 3
	operate on vectors or ordinary points in affine 3-space, represented by their Euclidean
	.B (x,y,z)
	coordinates.
	(They assume
	.B w=1
	in their arguments, and set
	.B w=1
	in their results.)
	.TF reflect3
	.TP
	Name
	Description
	.TP
	.B add3
	Add the coordinates of two points.
	.TP
	.B sub3
	Subtract coordinates of two points.
	.TP
	.B neg3
	Negate the coordinates of a point.
	.TP
	.B mul3
	Multiply coordinates by a scalar.
	.TP
	.B div3
	Divide coordinates by a scalar.
	.TP
	.B eqpt3
	Test two points for exact equality.
	.TP
	.B closept3
	Is the distance between two points smaller than
	.IR eps ?
	.TP
	.B dot3
	Dot product.
	.TP
	.B cross3
	Cross product.
	.TP
	.B len3
	Distance to the origin.
	.TP
	.B dist3
	Distance between two points.
	.TP
	.B unit3
	A unit vector parallel to
	.IR p .
	.TP
	.B midpt3
	The midpoint of line segment
	.IR pq .
	.TP
	.B lerp3
	Linear interpolation between
	.I p
	and
	.IR q .
	.TP
	.B reflect3
	The reflection of point
	.I p
	in the segment joining
	.I p0
	and
	.IR p1 .
	.TP
	.B nearseg3
	The closest point to
	.I testp
	on segment
	.IR "p0 p1" .
	.TP
	.B pldist3
	The distance from
	.I p
	to segment
	.IR "p0 p1" .
	.TP
	.B vdiv3
	Vector divide \(em the length of the component of
	.I a
	parallel to
	.IR b ,
	in units of the length of
	.IR b .
	.TP
	.B vrem3
	Vector remainder \(em the component of
	.I a
	perpendicular to
	.IR b .
	Ignoring roundoff, we have
	.BR "eqpt3(add3(mul3(b, vdiv3(a, b)), vrem3(a, b)), a)" .
	.PD
	.PP
	The following routines convert amongst various representations of points
	and planes. Planes are represented identically to points, by duality;
	a point
	.B p
	is on a plane
	.B q
	whenever
	.BR p.xq.x+p.yq.y+p.zq.z+p.wq.w=0 .
	Although when dealing with affine points we assume
	.BR p.w=1 ,
	we can't make the same assumption for planes.
	The names of these routines are extra-cryptic. They contain an
	.B f
	(for `face') to indicate a plane,
	.B p
	for a point and
	.B n
	for a normal vector.
	The number
	.B 2
	abbreviates the word `to.'
	The number
	.B 3
	reminds us, as before, that we're dealing with affine points.
	Thus
	.B pn2f3
	takes a point and a normal vector and returns the corresponding plane.
	.TF reflect3
	.TP
	Name
	Description
	.TP
	.B pn2f3
	Compute the plane passing through
	.I p
	with normal
	.IR n .
	.TP
	.B ppp2f3
	Compute the plane passing through three points.
	.TP
	.B fff2p3
	Compute the intersection point of three planes.
	.PD
	.PP
	The names of the following routines end in
	.B 4
	because they operate on points in projective 4-space,
	represented by their homogeneous coordinates.
	.TP
	pdiv4
	Perspective division. Divide
	.B p.w
	into
	.IR p 's
	coordinates, converting to affine coordinates.
	If
	.B p.w
	is zero, the result is the same as the argument.
	.TP
	add4
	Add the coordinates of two points.
	.PD
	.TP
	sub4
	Subtract the coordinates of two points.
	.SH SOURCE
	.B \*9/src/libgeometry
	.SH "SEE ALSO
	.IR matrix (3)