2015-02-14 23:32:58 +01:00
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#include "stl_3d.h"
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#include <stdio.h>
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#include <stdlib.h>
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#include <stdint.h>
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#include <unistd.h>
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static const int debug = 0;
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typedef struct
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{
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char header[80];
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uint32_t num_triangles;
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} __attribute__((__packed__))
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stl_3d_file_header_t;
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typedef struct
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{
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v3_t normal;
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v3_t p[3];
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uint16_t attr;
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} __attribute__((__packed__))
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stl_3d_file_triangle_t;
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/** Find or create a vertex */
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static stl_vertex_t *
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stl_vertex_find(
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stl_vertex_t * const vertices,
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int * num_vertex_ptr,
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const v3_t * const p
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)
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{
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const int num_vertex = *num_vertex_ptr;
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for (int x = 0 ; x < num_vertex ; x++)
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{
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stl_vertex_t * const v = &vertices[x];
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if (v3_eq(&v->p, p))
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return v;
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}
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if (debug)
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fprintf(stderr, "%d: %f,%f,%f\n",
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num_vertex,
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p->p[0],
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p->p[1],
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p->p[2]
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);
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stl_vertex_t * const v = &vertices[(*num_vertex_ptr)++];
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v->p = *p;
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return v;
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}
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2015-02-15 01:11:52 +01:00
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/** Check to see if the two faces share an edge.
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* \return 0 if no common edge, 1 if there is a shared link
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*/
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2015-02-15 01:01:12 +01:00
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static int
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stl_has_edge(
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const stl_face_t * const f,
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const stl_vertex_t * const v1,
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const stl_vertex_t * const v2
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)
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{
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if (f->vertex[0] != v1 && f->vertex[1] != v1 && f->vertex[2] != v1)
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return 0;
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if (f->vertex[0] != v2 && f->vertex[1] != v2 && f->vertex[2] != v2)
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return 0;
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return 1;
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}
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2015-02-15 01:11:52 +01:00
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/** Compute the angle between the two planes.
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* This is an approximation:
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* \return 0 == coplanar, negative == valley, positive == mountain.
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*/
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2015-02-15 01:01:12 +01:00
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static double
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stl_angle(
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const stl_face_t * const f1,
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const stl_face_t * const f2
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)
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{
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2015-02-15 01:11:52 +01:00
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// find the four distinct points
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v3_t x1 = f1->vertex[0]->p;
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v3_t x2 = f1->vertex[1]->p;
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v3_t x3 = f1->vertex[2]->p;
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v3_t x4;
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for (int i = 0 ; i < 3 ; i++)
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{
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x4 = f2->vertex[i]->p;
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if (v3_eq(&x1, &x4))
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continue;
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if (v3_eq(&x2, &x4))
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continue;
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if (v3_eq(&x3, &x4))
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continue;
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break;
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}
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// (x3-x1) . ((x2-x1) X (x4-x3)) == 0
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v3_t dx31 = v3_sub(x3, x1);
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v3_t dx21 = v3_sub(x2, x1);
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v3_t dx43 = v3_sub(x4, x3);
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v3_t cross = v3_cross(dx21, dx43);
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float dot = v3_dot(dx31, cross);
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2015-02-15 18:54:10 +01:00
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//if (debug)
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2015-02-15 01:11:52 +01:00
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fprintf(stderr, "dot %f:\n %f,%f,%f\n %f,%f,%f\n %f,%f,%f\n %f,%f,%f\n",
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dot,
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x1.p[0], x1.p[1], x1.p[2],
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x2.p[0], x2.p[1], x2.p[2],
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x3.p[0], x3.p[1], x3.p[2],
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x4.p[0], x4.p[1], x4.p[2]
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);
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2015-02-15 18:54:10 +01:00
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//int check = -EPS < dot && dot < +EPS;
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2015-02-16 21:00:26 +01:00
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int check = -10 < dot && dot < +10;
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2015-02-15 01:11:52 +01:00
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// if the dot product is not close enough to zero, they
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// are not coplanar.
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if (check)
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return 0;
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if (dot < 0)
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return -1;
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else
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return +1;
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2015-02-15 01:01:12 +01:00
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}
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static void
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stl_find_neighbors(
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stl_3d_t * const stl,
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stl_face_t * const f1
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)
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{
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for(int i = 0 ; i < 3 ; i++)
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{
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const stl_vertex_t * const v1 = f1->vertex[(i+0) % 3];
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const stl_vertex_t * const v2 = f1->vertex[(i+1) % 3];
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for(int j = 0 ; j < stl->num_face ; j++)
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{
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stl_face_t * const f2 = &stl->face[j];
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// skip this triangle against itself
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if (f1 == f2)
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continue;
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// find if these two triangles share an edge
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if (!stl_has_edge(f2, v1, v2))
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continue;
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f1->face[i] = f2;
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f1->angle[i] = stl_angle(f1, f2);
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}
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}
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}
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2015-02-14 23:32:58 +01:00
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stl_3d_t *
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stl_3d_parse(
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int fd
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)
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{
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ssize_t rc;
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stl_3d_file_header_t hdr;
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rc = read(fd, &hdr, sizeof(hdr));
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if (rc != sizeof(hdr))
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return NULL;
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const int num_triangles = hdr.num_triangles;
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fprintf(stderr, "%d triangles\n", num_triangles);
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stl_3d_file_triangle_t * fts;
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const size_t file_len = num_triangles * sizeof(*fts);
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fts = calloc(1, file_len);
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2015-02-14 23:42:20 +01:00
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rc = read(fd, fts, file_len);
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2015-02-14 23:32:58 +01:00
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if (rc < 0 || (size_t) rc != file_len)
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return NULL;
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stl_3d_t * const stl = calloc(1, sizeof(*stl));
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*stl = (stl_3d_t) {
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.num_vertex = 0,
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.num_face = num_triangles,
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.vertex = calloc(num_triangles, sizeof(*stl->vertex)),
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.face = calloc(num_triangles, sizeof(*stl->face)),
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};
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2015-02-14 23:59:08 +01:00
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// build the unique set of vertices and their connection
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// to each face.
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2015-02-14 23:32:58 +01:00
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for(int i = 0 ; i < num_triangles ; i++)
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{
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const stl_3d_file_triangle_t * const ft = &fts[i];
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stl_face_t * const f = &stl->face[i];
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for (int j = 0 ; j < 3 ; j++)
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{
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const v3_t * const p = &ft->p[j];
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2015-02-15 01:01:12 +01:00
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stl_vertex_t * const v = stl_vertex_find(
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stl->vertex,
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&stl->num_vertex,
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p
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);
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2015-02-14 23:32:58 +01:00
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// add this vertex to this face
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f->vertex[j] = v;
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// and add this face to the vertex
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2015-02-14 23:59:08 +01:00
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v->face[v->num_face] = f;
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v->face_num[v->num_face] = j;
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v->num_face++;
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2015-02-14 23:32:58 +01:00
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}
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}
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2015-02-14 23:59:08 +01:00
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// build the connections between each face
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for(int i = 0 ; i < num_triangles ; i++)
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{
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2015-02-15 01:01:12 +01:00
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stl_face_t * const f = &stl->face[i];
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stl_find_neighbors(stl, f);
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2015-02-14 23:59:08 +01:00
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}
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2015-02-14 23:32:58 +01:00
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return stl;
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}
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2015-02-15 20:35:42 +01:00
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/** Starting at a point, trace the coplanar polygon and return a
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* list of vertices.
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*/
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int
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stl_trace_face(
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const stl_3d_t * const stl,
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const stl_face_t * const f_start,
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const stl_vertex_t ** vertex_list,
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2015-02-15 22:03:41 +01:00
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int * const face_used,
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const int start_vertex
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2015-02-15 20:35:42 +01:00
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)
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{
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const stl_face_t * f = f_start;
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2015-02-15 22:03:41 +01:00
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int i = start_vertex;
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2015-02-15 20:35:42 +01:00
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int vertex_count = 0;
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do {
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const stl_vertex_t * const v1 = f->vertex[(i+0) % 3];
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const stl_vertex_t * const v2 = f->vertex[(i+1) % 3];
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const stl_face_t * const f_next = f->face[i];
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fprintf(stderr, "%p %d: %f,%f,%f\n", f, i, v1->p.p[0], v1->p.p[1], v1->p.p[2]);
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if (face_used)
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face_used[f - stl->face] = 1;
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if (!f_next || f->angle[i] != 0)
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{
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// not coplanar or no connection.
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// add the NEXT vertex on this face and continue
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vertex_list[vertex_count++] = v2;
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i = (i+1) % 3;
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continue;
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}
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// coplanar; figure out which vertex on the next
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// face we start at
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int i_next = -1;
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for (int j = 0 ; j < 3 ; j++)
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{
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if (f_next->vertex[j] != v1)
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continue;
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i_next = j;
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break;
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}
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if (i_next == -1)
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abort();
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// move to the new face
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f = f_next;
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i = i_next;
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// keep going until we reach our starting face
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// at vertex 0.
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2015-02-15 22:03:41 +01:00
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} while (f != f_start || i != start_vertex);
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2015-02-15 20:35:42 +01:00
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return vertex_count;
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}
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2015-02-15 20:55:43 +01:00
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void
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refframe_init(
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refframe_t * ref,
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const v3_t p0,
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const v3_t p1,
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const v3_t p2
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)
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{
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ref->origin = p0;
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const v3_t dx = v3_norm(v3_sub(p1, ref->origin));
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const v3_t dy = v3_norm(v3_sub(p2, ref->origin));
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ref->x = dx;
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ref->z = v3_norm(v3_cross(dx, dy));
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ref->y = v3_norm(v3_cross(ref->x, ref->z));
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}
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void
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v3_project(
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const refframe_t * const ref,
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const v3_t p_in,
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double * const x_out,
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double * const y_out
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)
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{
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v3_t p = v3_sub(p_in, ref->origin);
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double x = ref->x.p[0]*p.p[0] + ref->x.p[1]*p.p[1] + ref->x.p[2]*p.p[2];
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double y = ref->y.p[0]*p.p[0] + ref->y.p[1]*p.p[1] + ref->y.p[2]*p.p[2];
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double z = ref->z.p[0]*p.p[0] + ref->z.p[1]*p.p[1] + ref->z.p[2]*p.p[2];
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fprintf(stderr, "%f,%f,%f\n", x, y, z);
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*x_out = x;
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*y_out = y;
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}
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2015-02-15 22:13:32 +01:00
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// Determines the intersection point of the line defined by points A and B with the
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// line defined by points C and D.
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//
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// Returns YES if the intersection point was found, and stores that point in X,Y.
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// Returns NO if there is no determinable intersection point, in which case X,Y will
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// be unmodified.
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static int
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line_intersect(
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double Ax, double Ay,
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double Bx, double By,
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double Cx, double Cy,
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double Dx, double Dy,
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double *X, double *Y
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)
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{
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// Fail if either line is undefined.
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if ((Ax==Bx && Ay==By) || (Cx==Dx && Cy==Dy))
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return 0;
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// (1) Translate the system so that point A is on the origin.
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Bx-=Ax; By-=Ay;
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Cx-=Ax; Cy-=Ay;
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Dx-=Ax; Dy-=Ay;
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// Discover the length of segment A-B.
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const double distAB=sqrt(Bx*Bx+By*By);
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// (2) Rotate the system so that point B is on the positive X axis.
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const double theCos=Bx/distAB;
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const double theSin=By/distAB;
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double newX=Cx*theCos+Cy*theSin;
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Cy =Cy*theCos-Cx*theSin; Cx=newX;
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newX=Dx*theCos+Dy*theSin;
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Dy =Dy*theCos-Dx*theSin; Dx=newX;
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// Fail if the lines are parallel.
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if (Cy==Dy) return 0;
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// (3) Discover the position of the intersection point along line A-B.
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const double ABpos=Dx+(Cx-Dx)*Dy/(Dy-Cy);
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// (4) Apply the discovered position to line A-B in the original coordinate system.
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*X=Ax+ABpos*theCos;
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*Y=Ay+ABpos*theSin;
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return 1;
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}
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/** Compute the inset coordinate.
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* http://alienryderflex.com/polygon_inset/
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// Given the sequentially connected points (a,b), (c,d), and (e,f), this
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// function returns, in (C,D), a bevel-inset replacement for point (c,d).
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//
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// Note: If vectors (a,b)->(c,d) and (c,d)->(e,f) are exactly 180° opposed,
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// or if either segment is zero-length, this function will do
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// nothing; i.e. point (C,D) will not be set.
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*/
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void
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refframe_inset(
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const refframe_t * const ref,
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const double inset_dist,
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double * const x_out,
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double * const y_out,
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const v3_t p0, // previous point
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const v3_t p1, // current point to inset
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const v3_t p2 // next point
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)
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{
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double a, b, c, d, e, f;
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v3_project(ref, p0, &a, &b);
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v3_project(ref, p1, &c, &d);
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v3_project(ref, p2, &e, &f);
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double c1 = c;
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double d1 = d;
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double c2 = c;
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double d2 = d;
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// Calculate length of line segments.
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const double dx1 = c-a;
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const double dy1 = d-b;
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const double dist1 = sqrt(dx1*dx1+dy1*dy1);
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const double dx2 = e-c;
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const double dy2 = f-d;
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const double dist2 = sqrt(dx2*dx2+dy2*dy2);
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// Exit if either segment is zero-length.
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if (dist1==0. || dist2==0.)
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{
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*x_out = *y_out = 0;
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fprintf(stderr, "inset fail\n");
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return;
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}
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// Inset each of the two line segments.
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|
|
double insetX, insetY;
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insetX = dy1/dist1 * inset_dist;
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a+=insetX;
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c1+=insetX;
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insetY = -dx1/dist1 * inset_dist;
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b+=insetY;
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d1+=insetY;
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insetX = dy2/dist2 * inset_dist;
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e+=insetX;
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c2+=insetX;
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insetY = -dx2/dist2 * inset_dist;
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|
f+=insetY;
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|
d2+=insetY;
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|
// If inset segments connect perfectly, return the connection point.
|
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|
|
if (c1==c2 && d1==d2)
|
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|
|
{
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|
*x_out = c1;
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|
|
*y_out = d1;
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|
|
return;
|
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|
|
}
|
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|
|
// Return the intersection point of the two inset segments (if any).
|
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|
|
if (line_intersect(a,b,c1,d1,c2,d2,e,f, x_out, y_out))
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|
|
return;
|
|
|
|
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|
|
|
*x_out = *y_out = 0;
|
|
|
|
fprintf(stderr, "inset failed 2\n");
|
|
|
|
}
|