PrusaSlicer-NonPlainar/src/admesh/stlinit.cpp

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/* ADMesh -- process triangulated solid meshes
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* Copyright (C) 1995, 1996 Anthony D. Martin <amartin@engr.csulb.edu>
* Copyright (C) 2013, 2014 several contributors, see AUTHORS
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*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
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* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
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* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
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*
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* Questions, comments, suggestions, etc to
* https://github.com/admesh/admesh/issues
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*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
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#include <assert.h>
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#include <boost/nowide/cstdio.hpp>
#include <boost/detail/endian.hpp>
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#include "stl.h"
#ifndef SEEK_SET
#error "SEEK_SET not defined"
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#endif
void stl_open(stl_file *stl, const char *file)
{
stl_initialize(stl);
stl_count_facets(stl, file);
stl_allocate(stl);
stl_read(stl, 0, true);
if (stl->fp != nullptr) {
fclose(stl->fp);
stl->fp = nullptr;
}
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}
void stl_initialize(stl_file *stl)
{
stl->fp = nullptr;
stl->error = 0;
stl->facet_start.clear();
stl->neighbors_start.clear();
stl->v_indices.clear();
stl->v_shared.clear();
memset(&stl->stats, 0, sizeof(stl_stats));
stl->stats.volume = -1.0;
}
void stl_close(stl_file *stl)
{
assert(stl->fp == nullptr);
stl_initialize(stl);
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}
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#ifndef BOOST_LITTLE_ENDIAN
extern void stl_internal_reverse_quads(char *buf, size_t cnt);
#endif /* BOOST_LITTLE_ENDIAN */
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void
stl_count_facets(stl_file *stl, const char *file) {
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long file_size;
uint32_t header_num_facets;
uint32_t num_facets;
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int i;
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size_t s;
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unsigned char chtest[128];
int num_lines = 1;
char *error_msg;
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if (stl->error) return;
/* Open the file in binary mode first */
stl->fp = boost::nowide::fopen(file, "rb");
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if(stl->fp == NULL) {
error_msg = (char*)
malloc(81 + strlen(file)); /* Allow 80 chars+file size for message */
sprintf(error_msg, "stl_initialize: Couldn't open %s for reading",
file);
perror(error_msg);
free(error_msg);
stl->error = 1;
return;
}
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/* Find size of file */
fseek(stl->fp, 0, SEEK_END);
file_size = ftell(stl->fp);
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/* Check for binary or ASCII file */
fseek(stl->fp, HEADER_SIZE, SEEK_SET);
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if (!fread(chtest, sizeof(chtest), 1, stl->fp)) {
perror("The input is an empty file");
stl->error = 1;
return;
}
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stl->stats.type = ascii;
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for(s = 0; s < sizeof(chtest); s++) {
if(chtest[s] > 127) {
stl->stats.type = binary;
break;
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}
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}
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rewind(stl->fp);
/* Get the header and the number of facets in the .STL file */
/* If the .STL file is binary, then do the following */
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if(stl->stats.type == binary) {
/* Test if the STL file has the right size */
if(((file_size - HEADER_SIZE) % SIZEOF_STL_FACET != 0)
|| (file_size < STL_MIN_FILE_SIZE)) {
fprintf(stderr, "The file %s has the wrong size.\n", file);
stl->error = 1;
return;
}
num_facets = (file_size - HEADER_SIZE) / SIZEOF_STL_FACET;
/* Read the header */
if (fread(stl->stats.header, LABEL_SIZE, 1, stl->fp) > 79) {
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stl->stats.header[80] = '\0';
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}
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/* Read the int following the header. This should contain # of facets */
bool header_num_faces_read = fread(&header_num_facets, sizeof(uint32_t), 1, stl->fp) != 0;
#ifndef BOOST_LITTLE_ENDIAN
// Convert from little endian to big endian.
stl_internal_reverse_quads((char*)&header_num_facets, 4);
#endif /* BOOST_LITTLE_ENDIAN */
if (! header_num_faces_read || num_facets != header_num_facets) {
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fprintf(stderr,
"Warning: File size doesn't match number of facets in the header\n");
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}
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}
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/* Otherwise, if the .STL file is ASCII, then do the following */
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else {
/* Reopen the file in text mode (for getting correct newlines on Windows) */
// fix to silence a warning about unused return value.
// obviously if it fails we have problems....
stl->fp = boost::nowide::freopen(file, "r", stl->fp);
// do another null check to be safe
if(stl->fp == NULL) {
error_msg = (char*)
malloc(81 + strlen(file)); /* Allow 80 chars+file size for message */
sprintf(error_msg, "stl_initialize: Couldn't open %s for reading",
file);
perror(error_msg);
free(error_msg);
stl->error = 1;
return;
}
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/* Find the number of facets */
char linebuf[100];
while (fgets(linebuf, 100, stl->fp) != NULL) {
/* don't count short lines */
if (strlen(linebuf) <= 4) continue;
/* skip solid/endsolid lines as broken STL file generators may put several of them */
if (strncmp(linebuf, "solid", 5) == 0 || strncmp(linebuf, "endsolid", 8) == 0) continue;
++num_lines;
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}
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rewind(stl->fp);
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/* Get the header */
for(i = 0;
(i < 80) && (stl->stats.header[i] = getc(stl->fp)) != '\n'; i++);
stl->stats.header[i] = '\0'; /* Lose the '\n' */
stl->stats.header[80] = '\0';
num_facets = num_lines / ASCII_LINES_PER_FACET;
}
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stl->stats.number_of_facets += num_facets;
stl->stats.original_num_facets = stl->stats.number_of_facets;
}
void stl_allocate(stl_file *stl)
{
if (stl->error)
return;
// Allocate memory for the entire .STL file.
stl->facet_start.assign(stl->stats.number_of_facets, stl_facet());
// Allocate memory for the neighbors list.
stl->neighbors_start.assign(stl->stats.number_of_facets, stl_neighbors());
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}
void
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stl_open_merge(stl_file *stl, char *file_to_merge) {
int num_facets_so_far;
stl_type origStlType;
FILE *origFp;
stl_file stl_to_merge;
if (stl->error) return;
/* Record how many facets we have so far from the first file. We will start putting
facets in the next position. Since we're 0-indexed, it'l be the same position. */
num_facets_so_far = stl->stats.number_of_facets;
/* Record the file type we started with: */
origStlType=stl->stats.type;
/* Record the file pointer too: */
origFp=stl->fp;
/* Initialize the sturucture with zero stats, header info and sizes: */
stl_initialize(&stl_to_merge);
stl_count_facets(&stl_to_merge, file_to_merge);
/* Copy what we need to into stl so that we can read the file_to_merge directly into it
using stl_read: Save the rest of the valuable info: */
stl->stats.type=stl_to_merge.stats.type;
stl->fp=stl_to_merge.fp;
/* Add the number of facets we already have in stl with what we we found in stl_to_merge but
haven't read yet. */
stl->stats.number_of_facets=num_facets_so_far+stl_to_merge.stats.number_of_facets;
/* Allocate enough room for stl->stats.number_of_facets facets and neighbors: */
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stl_reallocate(stl);
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/* Read the file to merge directly into stl, adding it to what we have already.
Start at num_facets_so_far, the index to the first unused facet. Also say
that this isn't our first time so we should augment stats like min and max
instead of erasing them. */
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stl_read(stl, num_facets_so_far, false);
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/* Restore the stl information we overwrote (for stl_read) so that it still accurately
reflects the subject part: */
stl->stats.type=origStlType;
stl->fp=origFp;
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}
void stl_reallocate(stl_file *stl)
{
if (stl->error)
return;
stl->facet_start.resize(stl->stats.number_of_facets);
stl->neighbors_start.resize(stl->stats.number_of_facets);
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}
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/* Reads the contents of the file pointed to by stl->fp into the stl structure,
starting at facet first_facet. The second argument says if it's our first
time running this for the stl and therefore we should reset our max and min stats. */
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void stl_read(stl_file *stl, int first_facet, bool first) {
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stl_facet facet;
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if (stl->error) return;
if(stl->stats.type == binary) {
fseek(stl->fp, HEADER_SIZE, SEEK_SET);
} else {
rewind(stl->fp);
}
char normal_buf[3][32];
for(uint32_t i = first_facet; i < stl->stats.number_of_facets; i++) {
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if(stl->stats.type == binary)
/* Read a single facet from a binary .STL file */
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{
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/* we assume little-endian architecture! */
if (fread(&facet, 1, SIZEOF_STL_FACET, stl->fp) != SIZEOF_STL_FACET) {
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stl->error = 1;
return;
}
#ifndef BOOST_LITTLE_ENDIAN
// Convert the loaded little endian data to big endian.
stl_internal_reverse_quads((char*)&facet, 48);
#endif /* BOOST_LITTLE_ENDIAN */
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} else
/* Read a single facet from an ASCII .STL file */
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{
// skip solid/endsolid
// (in this order, otherwise it won't work when they are paired in the middle of a file)
fscanf(stl->fp, "endsolid%*[^\n]\n");
fscanf(stl->fp, "solid%*[^\n]\n"); // name might contain spaces so %*s doesn't work and it also can be empty (just "solid")
// Leading space in the fscanf format skips all leading white spaces including numerous new lines and tabs.
int res_normal = fscanf(stl->fp, " facet normal %31s %31s %31s", normal_buf[0], normal_buf[1], normal_buf[2]);
assert(res_normal == 3);
int res_outer_loop = fscanf(stl->fp, " outer loop");
assert(res_outer_loop == 0);
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int res_vertex1 = fscanf(stl->fp, " vertex %f %f %f", &facet.vertex[0](0), &facet.vertex[0](1), &facet.vertex[0](2));
assert(res_vertex1 == 3);
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int res_vertex2 = fscanf(stl->fp, " vertex %f %f %f", &facet.vertex[1](0), &facet.vertex[1](1), &facet.vertex[1](2));
assert(res_vertex2 == 3);
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int res_vertex3 = fscanf(stl->fp, " vertex %f %f %f", &facet.vertex[2](0), &facet.vertex[2](1), &facet.vertex[2](2));
assert(res_vertex3 == 3);
int res_endloop = fscanf(stl->fp, " endloop");
assert(res_endloop == 0);
// There is a leading and trailing white space around endfacet to eat up all leading and trailing white spaces including numerous tabs and new lines.
int res_endfacet = fscanf(stl->fp, " endfacet ");
if (res_normal != 3 || res_outer_loop != 0 || res_vertex1 != 3 || res_vertex2 != 3 || res_vertex3 != 3 || res_endloop != 0 || res_endfacet != 0) {
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perror("Something is syntactically very wrong with this ASCII STL!");
stl->error = 1;
return;
}
// The facet normal has been parsed as a single string as to workaround for not a numbers in the normal definition.
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if (sscanf(normal_buf[0], "%f", &facet.normal(0)) != 1 ||
sscanf(normal_buf[1], "%f", &facet.normal(1)) != 1 ||
sscanf(normal_buf[2], "%f", &facet.normal(2)) != 1) {
// Normal was mangled. Maybe denormals or "not a number" were stored?
// Just reset the normal and silently ignore it.
memset(&facet.normal, 0, sizeof(facet.normal));
}
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}
#if 0
// Report close to zero vertex coordinates. Due to the nature of the floating point numbers,
// close to zero values may be represented with singificantly higher precision than the rest of the vertices.
// It may be worth to round these numbers to zero during loading to reduce the number of errors reported
// during the STL import.
for (size_t j = 0; j < 3; ++ j) {
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if (facet.vertex[j](0) > -1e-12f && facet.vertex[j](0) < 1e-12f)
printf("stl_read: facet %d(0) = %e\r\n", j, facet.vertex[j](0));
if (facet.vertex[j](1) > -1e-12f && facet.vertex[j](1) < 1e-12f)
printf("stl_read: facet %d(1) = %e\r\n", j, facet.vertex[j](1));
if (facet.vertex[j](2) > -1e-12f && facet.vertex[j](2) < 1e-12f)
printf("stl_read: facet %d(2) = %e\r\n", j, facet.vertex[j](2));
}
#endif
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/* Write the facet into memory. */
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stl->facet_start[i] = facet;
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stl_facet_stats(stl, facet, first);
}
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stl->stats.size = stl->stats.max - stl->stats.min;
stl->stats.bounding_diameter = stl->stats.size.norm();
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}
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void stl_facet_stats(stl_file *stl, stl_facet facet, bool &first)
{
if (stl->error)
return;
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// While we are going through all of the facets, let's find the
// maximum and minimum values for x, y, and z
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if (first) {
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// Initialize the max and min values the first time through
stl->stats.min = facet.vertex[0];
stl->stats.max = facet.vertex[0];
stl_vertex diff = (facet.vertex[1] - facet.vertex[0]).cwiseAbs();
stl->stats.shortest_edge = std::max(diff(0), std::max(diff(1), diff(2)));
first = false;
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}
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// Now find the max and min values.
for (size_t i = 0; i < 3; ++ i) {
stl->stats.min = stl->stats.min.cwiseMin(facet.vertex[i]);
stl->stats.max = stl->stats.max.cwiseMax(facet.vertex[i]);
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}
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}