mirror of
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173 lines
6.7 KiB
C++
173 lines
6.7 KiB
C++
//
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// vec3.h
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// CubicVR2
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//
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// Created by Charles J. Cliffe on 2013-02-21.
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// Copyright (c) 2013 Charles J. Cliffe. All rights reserved.
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//
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#ifndef __CubicVR2__vec3__
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#define __CubicVR2__vec3__
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#include <iostream>
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#include "cubic_types.h"
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#include <cmath>
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namespace CubicVR {
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#define vec3SG(c,x,y) \
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vec3 COMBINE(get,x)() { return y; } \
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c & COMBINE(set,x)(vec3 value) { y = value; return *this; }
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struct vec3 {
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__float x,y,z;
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operator __float*() const { return (__float *)this; }
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__float& r() { return x; }
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__float& g() { return y; }
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__float& b() { return z; }
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#ifndef _WIN32
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__float& operator [] (unsigned i) { return ((__float *)this)[i]; }
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#endif
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vec3 (__float xi,__float yi,__float zi) { x = xi; y = yi; z = zi; }
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vec3 () { x = y = z = 0.0f; }
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vec3 operator*(__float v) { return vec3(x*v, y*v, z*v); }
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vec3 operator*(vec3 v) { return vec3::cross(*this,v); }
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vec3 operator+(vec3 v) { return vec3::add(*this,v); }
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vec3 operator-(vec3 v) { return vec3::subtract(*this,v); }
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static __float length(vec3 pta, vec3 ptb) {
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__float a,b,c;
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a = ptb[0]-pta[0];
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b = ptb[1]-pta[1];
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c = ptb[2]-pta[2];
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return sqrtf((a*a) + (b*b) + (c*c));
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};
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static __float length(vec3 pta) {
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__float a,b,c;
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a = pta[0];
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b = pta[1];
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c = pta[2];
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return sqrtf((a*a) + (b*b) + (c*c));
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};
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static vec3 normalize(vec3 pt) {
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__float a = pt[0], b = pt[1], c = pt[2],
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d = sqrtf((a*a) + (b*b) + (c*c));
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if (d) {
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pt[0] = pt[0]/d;
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pt[1] = pt[1]/d;
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pt[2] = pt[2]/d;
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return pt;
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}
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pt = vec3(0.0f,0.0f,0.0f);
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return pt;
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};
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static __float dot(vec3 v1, vec3 v2) {
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return v1[0] * v2[0] + v1[1] * v2[1] + v1[2] * v2[2];
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};
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static __float angle(vec3 v1, vec3 v2) {
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__float a = acosf((v1[0] * v2[0] + v1[1] * v2[1] + v1[2] * v2[2]) / (sqrtf(v1[0] * v1[0] + v1[1] * v1[1] + v1[2] * v1[2]) * sqrtf(v2[0] * v2[0] + v2[1] * v2[1] + v2[2] * v2[2])));
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return a;
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};
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static vec3 cross(vec3 vectA, vec3 vectB) {
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return vec3(
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vectA[1] * vectB[2] - vectB[1] * vectA[2], vectA[2] * vectB[0] - vectB[2] * vectA[0], vectA[0] * vectB[1] - vectB[0] * vectA[1]
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);
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};
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static vec3 multiply(vec3 vectA, __float constB) {
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return vec3(vectA[0] * constB, vectA[1] * constB, vectA[2] * constB);
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};
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static vec3 add(vec3 vectA, vec3 vectB) {
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return vec3(vectA[0] + vectB[0], vectA[1] + vectB[1], vectA[2] + vectB[2]);
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};
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static vec3 subtract(vec3 vectA, vec3 vectB) {
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return vec3(vectA[0] - vectB[0], vectA[1] - vectB[1], vectA[2] - vectB[2]);
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};
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static bool equal(vec3 a, vec3 b, __float epsilon = 0.0000001f) {
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return ((fabs(a[0] - b[0]) < epsilon) && (fabs(a[1] - b[1]) < epsilon) && (fabs(a[2] - b[2]) < epsilon));
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};
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static vec3 moveViewRelative(vec3 position, vec3 target, __float xdelta, __float zdelta) {
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__float ang = atan2f(zdelta, xdelta);
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__float cam_ang = atan2f(target[2] - position[2], target[0] - position[0]);
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__float mag = sqrtf(xdelta * xdelta + zdelta * zdelta);
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__float move_ang = cam_ang + ang + (float)M_PI/2.0f;
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// if (typeof(alt_source) === 'object') {
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// return [alt_source[0] + mag * Math.cos(move_ang), alt_source[1], alt_source[2] + mag * Math.sin(move_ang)];
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// }
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return vec3(position[0] + mag * cosf(move_ang), position[1], position[2] + mag * sinf(move_ang));
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};
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static vec3 trackTarget(vec3 position, vec3 target, __float trackingSpeed, __float safeDistance) {
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vec3 camv = vec3::subtract(target, position);
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vec3 dist = camv;
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__float fdist = vec3::length(dist);
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vec3 motionv = camv;
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motionv = vec3::normalize(motionv);
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motionv = vec3::multiply(motionv, trackingSpeed * (1.0f / (1.0f / (fdist - safeDistance))));
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vec3 ret_pos;
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if (fdist > safeDistance) {
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ret_pos = vec3::add(position, motionv);
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} else if (fdist < safeDistance) {
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motionv = camv;
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motionv = vec3::normalize(motionv);
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motionv = vec3::multiply(motionv, trackingSpeed * (1.0f / (1.0f / (fabsf(fdist - safeDistance)))));
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ret_pos = vec3::subtract(position, motionv);
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} else {
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ret_pos = vec3(position[0], position[1] + motionv[2], position[2]);
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}
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return ret_pos;
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};
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static vec3 getClosestTo(vec3 ptA, vec3 ptB, vec3 ptTest) {
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vec3 S, T, U;
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S = vec3::subtract(ptB, ptA);
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T = vec3::subtract(ptTest, ptA);
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U = vec3::add(vec3::multiply(S, vec3::dot(S, T) / vec3::dot(S, S)), ptA);
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return U;
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};
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// linePlaneIntersect: function(normal, point_on_plane, segment_start, segment_end)
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// {
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// // form a plane from normal and point_on_plane and test segment start->end to find intersect point
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// var denom,mu;
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//
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// var d = - normal[0] * point_on_plane[0] - normal[1] * point_on_plane[1] - normal[2] * point_on_plane[2];
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//
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// // calculate position where the plane intersects the segment
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// denom = normal[0] * (segment_end[0] - segment_start[0]) + normal[1] * (segment_end[1] - segment_start[1]) + normal[2] * (segment_end[2] - segment_start[2]);
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// if (Math.fabs(denom) < 0.001) return false;
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//
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// mu = - (d + normal[0] * segment_start[0] + normal[1] * segment_start[1] + normal[2] * segment_start[2]) / denom;
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// return [
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// (segment_start[0] + mu * (segment_end[0] - segment_start[0])),
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// (segment_start[1] + mu * (segment_end[1] - segment_start[1])),
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// (segment_start[2] + mu * (segment_end[2] - segment_start[2]))
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// ];
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// }
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};
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}
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#endif /* defined(__CubicVR2__vec3__) */
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