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/* Copyright (c) 1998 Silicon Graphics, Inc. */ |
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/* SCCSid "$SunId$ SGI" */ |
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/* RCSid: $Id$ */ |
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/* |
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* sm_geom.h |
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*/ |
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#include <values.h> |
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#define F_TINY 1e-5 |
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#ifdef SMLFLT |
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#define EQUALITY_EPS 1e-6 |
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#else |
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#define EQUALITY_EPS 1e-10 |
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#endif |
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#define F_TINY 1e-10 |
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#define FZERO(x) ((x) < F_TINY && (x) > -F_TINY) |
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#define FEQUAL(a,b) FZERO((a) - (b)) |
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typedef long BCOORD; |
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typedef long BDIR; |
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typedef long TINT; |
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#define BITS_BCOORD (BITS(long)-2) |
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#define SHIFT_MAXBCOORD (BITS_BCOORD-1) |
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#ifndef INVALID |
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#define INVALID -1 |
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#endif |
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#define IADDV3(v,a) ((v)[0] += (a)[0],(v)[1] += (a)[1],(v)[2] += (a)[2]) |
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#define ISUBV3(v,a) ((v)[0] -= (a)[0],(v)[1] -= (a)[1],(v)[2] -= (a)[2]) |
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#define ISCALEV3(v,a) ((v)[0] *= (a),(v)[1] *= (a),(v)[2] *= (a)) |
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#define IDIVV3(v,a) ((v)[0] /= (a),(v)[1] /= (a),(v)[2] /= (a)) |
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#define GT_INVALID 0 |
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#define GT_VERTEX 1 |
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#define GT_EDGE 2 |
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#define GT_FACE 4 |
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#define GT_INTERIOR 8 |
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#define GT_INTERSECT 16 |
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#define GT_ADJACENT 32 |
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#define GT_OUT 64 |
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#define ADDV3(v,a,b) ((v)[0] = (a)[0]+(b)[0],(v)[1] = (a)[1]+(b)[1],\ |
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(v)[2] = (a)[2]+(b)[2]) |
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#define SUBV3(v,a,b) ((v)[0] = (a)[0]-(b)[0],(v)[1] = (a)[1]-(b)[1],\ |
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(v)[2] = (a)[2]-(b)[2]) |
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#define SUMV3(v,a,b,s) ((v)[0] = (a)[0]+(s)*(b)[0],(v)[1]=(a)[1]+(s)*(b)[1],\ |
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(v)[2] = (a)[2]+(s)*(b)[2]) |
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#define SCALEV3(v,a,s) ((v)[0]=(a)[0]*(s),(v)[1]=(a)[1]*(s),(v)[2]=(a)[2]*(s)) |
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#define ZERO_VEC3(v) (ZERO(v[0]) && ZERO(v[1]) && ZERO(v[2]) ) |
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#define EQUAL_VEC3(a,b) (EQUAL(a[0],b[0])&&EQUAL(a[1],b[1])&&EQUAL(a[2],b[2])) |
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#define EQUAL_VEC3(a,b) (FEQUAL(a[0],b[0])&&FEQUAL(a[1],b[1])&&FEQUAL(a[2],b[2])) |
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#define OPP_EQUAL_VEC3(a,b) (EQUAL(a[0],-b[0])&&EQUAL(a[1],-b[1])&&EQUAL(a[2],-b[2])) |
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#define FZERO_VEC3(v) (FZERO(v[0]) && FZERO(v[1]) && FZERO(v[2]) ) |
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#define FEQUAL_VEC3(a,b) (FEQUAL(a[0],b[0])&&FEQUAL(a[1],b[1])&&FEQUAL(a[2],b[2])) |
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#define MIN_VEC3(v) ((v)[0]<(v)[1]?((v)[0]<(v)[2]?(v)[0]:v[2]): \ |
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(v)[1]<(v)[2]?(v)[1]:(v)[2]) |
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#define MAX3(a,b,c) (((b)>(a))?((b) > (c))?(b):(c):((a)>(c))?(a):(c)) |
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#define MIN3(a,b,c) (((b)<(a))?((b) < (c))?(b):(c):((a)<(c))?(a):(c)) |
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#define MIN3(a,b,c) (((b)<(a))?((b) < (c))?(b):(c):((a)<(c))?(a):(c)) |
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#define MAX(a,b) (((b)>(a))?(b):(a)) |
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#define MIN(a,b) (((b)<(a))?(b):(a)) |
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#define NTH_BIT(n,i) ((n) & (1<<(i))) |
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#define SET_NTH_BIT(n,i) ((n) |= (1<<(i))) |
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#define PT_ON_PLANE(p,peq) (DOT(FP_N(peq),p)+FP_D(peq)) |
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/* int convex_angle(FVECT v0,FVECT v1,FVECT v2) */ |
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/* void triangle_centroid(FVECT v0,FVECT v1,FVECT v2,FVECT c) */ |
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/* void triangle_plane_equation(FVECT v0,FVECT v1,FVECT v2,FVECT n,double *nd, |
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char norm) */ |
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/* int vec3_equal(FVECT v1,v2) */ |
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/* int point_relative_to_plane(FVECT p,FVECT n, double nd) */ |
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/* int point_in_circle(FVECT p,FVECT p0,FVECT p1) */ |
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/* int intersect_line_plane(FVECT r,FVECT p1,FVECT p2,float *plane) */ |
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/* int point_in_cone(FVECT p,FVECT p1,FVECT p2,FVECT p3,FVECT p4) */ |
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/* void point_on_sphere(FVECT ps,FVECT p,FVECT c) */ |
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/* int test_point_against_spherical_tri(FVECT v0,FVECT v1,FVECT v2,FVECT p, |
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FVECT n,char *nset,char *which,char sides[3]) */ |
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/* int test_single_point_against_spherical_tri(FVECT v0,FVECT v1,FVECT v2, |
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FVECT p,char *which )*/ |
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/* int test_vertices_for_tri_inclusion(FVECT tri[3],FVECT pts[3],char *nset, |
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FVECT n[3],FVECT avg,char pt_sides[3][3]); */ |
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/* void set_sidedness_tests(FVECT tri[3],FVECT pts[3],char test[3], |
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char sides[3][3],char nset,FVECT n[3]) |
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/* int cs_spherical_edge_edge_test(FVECT n[2][3],int i,int j,FVECT avg[2]) */ |
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/* int spherical_tri_tri_intersect(FVECT a1,FVECT a2,FVECT a3, |
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FVECT b1,FVECT b2,FVECT b3) */ |
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/* void calculate_view_frustum(FVECT vp,hv,vv,double horiz,vert,near,far, |
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FVECT fnear[4],FVECT ffar[4]) |
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/* double triangle_normal_Newell(FVECT v0,FVECT v1,FVECT v2,FVECT n,char n)*/ |
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/* FUNCTIONS: |
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int point_in_cone(FVECT p,a,b,c) |
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void triangle_centroid(FVECT v0,v1,v2,c) |
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double tri_normal(FVECT v0,v1,v2,n,int norm) |
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void tri_plane_equation(FVECT v0,v1,v2,FPEQ *peqptr,int norm) |
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int intersect_ray_plane(FVECT orig,dir,FPEQ peq,double *pd,FVECT r) |
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double point_on_sphere(FVECT ps,p,c) |
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int point_in_stri(FVECT v0,v1,v2,p) |
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int ray_intersect_tri(FVECT orig,dir,v0,v1,v2,pt) |
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void calculate_view_frustum(FVECT vp,hv,vv,double horiz,vert,near,far, |
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FVECT fnear[4],ffar[4]) |
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void bary2d(double x1,y1,x2,y2,x3,y3,px,py,coord) |
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double tri_normal(); |
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/* double spherical_edge_normal(FVECT v0,FVECT v1,FVECT n,char norm) */ |
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double spherical_edge_normal(); |
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double point_on_sphere(); |
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#define point_in_stri_n(n0,n1,n2,p) \ |
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((DOT(n0,p)<=FTINY)&&(DOT(n1,p)<=FTINY)&&(DOT(n2,p)<=FTINY)) |
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#define PT_ON_PLANE(p,peq) (DOT(FP_N(peq),p)+FP_D(peq)) |
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