PrusaSlicer-NonPlainar/xs/src/libslic3r/EdgeGrid.cpp

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#include <algorithm>
#include <vector>
2016-09-13 13:59:23 +00:00
#include <float.h>
#include <unordered_map>
#ifdef SLIC3R_GUI
#include <wx/image.h>
#endif /* SLIC3R_GUI */
#include "libslic3r.h"
#include "EdgeGrid.hpp"
#if 0
// Enable debugging and assert in this file.
#define DEBUG
#define _DEBUG
#undef NDEBUG
#endif
#include <assert.h>
namespace Slic3r {
EdgeGrid::Grid::Grid() :
m_rows(0), m_cols(0)
{
}
EdgeGrid::Grid::~Grid()
{
m_contours.clear();
m_cell_data.clear();
m_cells.clear();
}
void EdgeGrid::Grid::create(const Polygons &polygons, coord_t resolution)
{
// Count the contours.
size_t ncontours = 0;
for (size_t j = 0; j < polygons.size(); ++ j)
if (! polygons[j].points.empty())
++ ncontours;
// Collect the contours.
m_contours.assign(ncontours, NULL);
ncontours = 0;
for (size_t j = 0; j < polygons.size(); ++ j)
if (! polygons[j].points.empty())
m_contours[ncontours++] = &polygons[j].points;
create_from_m_contours(resolution);
}
void EdgeGrid::Grid::create(const ExPolygon &expoly, coord_t resolution)
{
// Count the contours.
size_t ncontours = 0;
if (! expoly.contour.points.empty())
++ ncontours;
for (size_t j = 0; j < expoly.holes.size(); ++ j)
if (! expoly.holes[j].points.empty())
++ ncontours;
// Collect the contours.
m_contours.assign(ncontours, NULL);
ncontours = 0;
if (! expoly.contour.points.empty())
m_contours[ncontours++] = &expoly.contour.points;
for (size_t j = 0; j < expoly.holes.size(); ++ j)
if (! expoly.holes[j].points.empty())
m_contours[ncontours++] = &expoly.holes[j].points;
create_from_m_contours(resolution);
}
void EdgeGrid::Grid::create(const ExPolygons &expolygons, coord_t resolution)
{
// Count the contours.
size_t ncontours = 0;
for (size_t i = 0; i < expolygons.size(); ++ i) {
const ExPolygon &expoly = expolygons[i];
if (! expoly.contour.points.empty())
++ ncontours;
for (size_t j = 0; j < expoly.holes.size(); ++ j)
if (! expoly.holes[j].points.empty())
++ ncontours;
}
// Collect the contours.
m_contours.assign(ncontours, NULL);
ncontours = 0;
for (size_t i = 0; i < expolygons.size(); ++ i) {
const ExPolygon &expoly = expolygons[i];
if (! expoly.contour.points.empty())
m_contours[ncontours++] = &expoly.contour.points;
for (size_t j = 0; j < expoly.holes.size(); ++ j)
if (! expoly.holes[j].points.empty())
m_contours[ncontours++] = &expoly.holes[j].points;
}
create_from_m_contours(resolution);
}
void EdgeGrid::Grid::create(const ExPolygonCollection &expolygons, coord_t resolution)
{
create(expolygons.expolygons, resolution);
}
// m_contours has been initialized. Now fill in the edge grid.
void EdgeGrid::Grid::create_from_m_contours(coord_t resolution)
{
// 1) Measure the bounding box.
for (size_t i = 0; i < m_contours.size(); ++ i) {
const Slic3r::Points &pts = *m_contours[i];
for (size_t j = 0; j < pts.size(); ++ j)
m_bbox.merge(pts[j]);
}
coord_t eps = 16;
m_bbox.min.x -= eps;
m_bbox.min.y -= eps;
m_bbox.max.x += eps;
m_bbox.max.y += eps;
// 2) Initialize the edge grid.
m_resolution = resolution;
m_cols = (m_bbox.max.x - m_bbox.min.x + m_resolution - 1) / m_resolution;
m_rows = (m_bbox.max.y - m_bbox.min.y + m_resolution - 1) / m_resolution;
m_cells.assign(m_rows * m_cols, Cell());
// 3) First round of contour rasterization, count the edges per grid cell.
for (size_t i = 0; i < m_contours.size(); ++ i) {
const Slic3r::Points &pts = *m_contours[i];
for (size_t j = 0; j < pts.size(); ++ j) {
// End points of the line segment.
Slic3r::Point p1(pts[j]);
Slic3r::Point p2 = pts[(j + 1 == pts.size()) ? 0 : j + 1];
p1.x -= m_bbox.min.x;
p1.y -= m_bbox.min.y;
p2.x -= m_bbox.min.x;
p2.y -= m_bbox.min.y;
// Get the cells of the end points.
coord_t ix = p1.x / m_resolution;
coord_t iy = p1.y / m_resolution;
coord_t ixb = p2.x / m_resolution;
coord_t iyb = p2.y / m_resolution;
assert(ix >= 0 && ix < m_cols);
assert(iy >= 0 && iy < m_rows);
assert(ixb >= 0 && ixb < m_cols);
assert(iyb >= 0 && iyb < m_rows);
// Account for the end points.
++ m_cells[iy*m_cols+ix].end;
if (ix == ixb && iy == iyb)
// Both ends fall into the same cell.
continue;
// Raster the centeral part of the line.
coord_t dx = std::abs(p2.x - p1.x);
coord_t dy = std::abs(p2.y - p1.y);
if (p1.x < p2.x) {
int64_t ex = int64_t((ix + 1)*m_resolution - p1.x) * int64_t(dy);
if (p1.y < p2.y) {
// x positive, y positive
int64_t ey = int64_t((iy + 1)*m_resolution - p1.y) * int64_t(dx);
do {
assert(ix <= ixb && iy <= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix += 1;
}
else if (ex == ey) {
ex = int64_t(dy) * m_resolution;
ey = int64_t(dx) * m_resolution;
ix += 1;
iy += 1;
}
else {
assert(ex > ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy += 1;
}
++m_cells[iy*m_cols + ix].end;
} while (ix != ixb || iy != iyb);
}
else {
// x positive, y non positive
int64_t ey = int64_t(p1.y - iy*m_resolution) * int64_t(dx);
do {
assert(ix <= ixb && iy >= iyb);
if (ex <= ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix += 1;
}
else {
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
++m_cells[iy*m_cols + ix].end;
} while (ix != ixb || iy != iyb);
}
}
else {
int64_t ex = int64_t(p1.x - ix*m_resolution) * int64_t(dy);
if (p1.y < p2.y) {
// x non positive, y positive
int64_t ey = int64_t((iy + 1)*m_resolution - p1.y) * int64_t(dx);
do {
assert(ix >= ixb && iy <= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
else {
assert(ex >= ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy += 1;
}
++m_cells[iy*m_cols + ix].end;
} while (ix != ixb || iy != iyb);
}
else {
// x non positive, y non positive
int64_t ey = int64_t(p1.y - iy*m_resolution) * int64_t(dx);
do {
assert(ix >= ixb && iy >= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
else if (ex == ey) {
// The lower edge of a grid cell belongs to the cell.
// Handle the case where the ray may cross the lower left corner of a cell in a general case,
// or a left or lower edge in a degenerate case (horizontal or vertical line).
if (dx > 0) {
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
if (dy > 0) {
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
}
else {
assert(ex > ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
++m_cells[iy*m_cols + ix].end;
} while (ix != ixb || iy != iyb);
}
}
}
}
// 4) Prefix sum the numbers of hits per cells to get an index into m_cell_data.
size_t cnt = m_cells.front().end;
for (size_t i = 1; i < m_cells.size(); ++ i) {
m_cells[i].begin = cnt;
cnt += m_cells[i].end;
m_cells[i].end = cnt;
}
// 5) Allocate the cell data.
m_cell_data.assign(cnt, std::pair<size_t, size_t>(size_t(-1), size_t(-1)));
// 6) Finally fill in m_cell_data by rasterizing the lines once again.
for (size_t i = 0; i < m_cells.size(); ++i)
m_cells[i].end = m_cells[i].begin;
for (size_t i = 0; i < m_contours.size(); ++i) {
const Slic3r::Points &pts = *m_contours[i];
for (size_t j = 0; j < pts.size(); ++j) {
// End points of the line segment.
Slic3r::Point p1(pts[j]);
Slic3r::Point p2 = pts[(j + 1 == pts.size()) ? 0 : j + 1];
p1.x -= m_bbox.min.x;
p1.y -= m_bbox.min.y;
p2.x -= m_bbox.min.x;
p2.y -= m_bbox.min.y;
// Get the cells of the end points.
coord_t ix = p1.x / m_resolution;
coord_t iy = p1.y / m_resolution;
coord_t ixb = p2.x / m_resolution;
coord_t iyb = p2.y / m_resolution;
assert(ix >= 0 && ix < m_cols);
assert(iy >= 0 && iy < m_rows);
assert(ixb >= 0 && ixb < m_cols);
assert(iyb >= 0 && iyb < m_rows);
// Account for the end points.
m_cell_data[m_cells[iy*m_cols + ix].end++] = std::pair<size_t, size_t>(i, j);
if (ix == ixb && iy == iyb)
// Both ends fall into the same cell.
continue;
// Raster the centeral part of the line.
coord_t dx = std::abs(p2.x - p1.x);
coord_t dy = std::abs(p2.y - p1.y);
if (p1.x < p2.x) {
int64_t ex = int64_t((ix + 1)*m_resolution - p1.x) * int64_t(dy);
if (p1.y < p2.y) {
// x positive, y positive
int64_t ey = int64_t((iy + 1)*m_resolution - p1.y) * int64_t(dx);
do {
assert(ix <= ixb && iy <= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix += 1;
}
else if (ex == ey) {
ex = int64_t(dy) * m_resolution;
ey = int64_t(dx) * m_resolution;
ix += 1;
iy += 1;
}
else {
assert(ex > ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy += 1;
}
m_cell_data[m_cells[iy*m_cols + ix].end++] = std::pair<size_t, size_t>(i, j);
} while (ix != ixb || iy != iyb);
}
else {
// x positive, y non positive
int64_t ey = int64_t(p1.y - iy*m_resolution) * int64_t(dx);
do {
assert(ix <= ixb && iy >= iyb);
if (ex <= ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix += 1;
}
else {
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
m_cell_data[m_cells[iy*m_cols + ix].end++] = std::pair<size_t, size_t>(i, j);
} while (ix != ixb || iy != iyb);
}
}
else {
int64_t ex = int64_t(p1.x - ix*m_resolution) * int64_t(dy);
if (p1.y < p2.y) {
// x non positive, y positive
int64_t ey = int64_t((iy + 1)*m_resolution - p1.y) * int64_t(dx);
do {
assert(ix >= ixb && iy <= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
else {
assert(ex >= ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy += 1;
}
m_cell_data[m_cells[iy*m_cols + ix].end++] = std::pair<size_t, size_t>(i, j);
} while (ix != ixb || iy != iyb);
}
else {
// x non positive, y non positive
int64_t ey = int64_t(p1.y - iy*m_resolution) * int64_t(dx);
do {
assert(ix >= ixb && iy >= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
else if (ex == ey) {
// The lower edge of a grid cell belongs to the cell.
// Handle the case where the ray may cross the lower left corner of a cell in a general case,
// or a left or lower edge in a degenerate case (horizontal or vertical line).
if (dx > 0) {
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
if (dy > 0) {
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
}
else {
assert(ex > ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
m_cell_data[m_cells[iy*m_cols + ix].end++] = std::pair<size_t, size_t>(i, j);
} while (ix != ixb || iy != iyb);
}
}
}
}
}
#if 0
// Divide, round to a grid coordinate.
// Divide x/y, round down. y is expected to be positive.
static inline coord_t div_floor(coord_t x, coord_t y)
{
assert(y > 0);
return ((x < 0) ? (x - y + 1) : x) / y;
}
// Walk the polyline, test whether any lines of this polyline does not intersect
// any line stored into the grid.
bool EdgeGrid::Grid::intersect(const MultiPoint &polyline, bool closed)
{
size_t n = polyline.points.size();
if (closed)
++ n;
for (size_t i = 0; i < n; ++ i) {
size_t j = i + 1;
if (j == polyline.points.size())
j = 0;
Point p1src = polyline.points[i];
Point p2src = polyline.points[j];
Point p1 = p1src;
Point p2 = p2src;
// Discretize the line segment p1, p2.
p1.x -= m_bbox.min.x;
p1.y -= m_bbox.min.y;
p2.x -= m_bbox.min.x;
p2.y -= m_bbox.min.y;
// Get the cells of the end points.
coord_t ix = div_floor(p1.x, m_resolution);
coord_t iy = div_floor(p1.y, m_resolution);
coord_t ixb = div_floor(p2.x, m_resolution);
coord_t iyb = div_floor(p2.y, m_resolution);
// assert(ix >= 0 && ix < m_cols);
// assert(iy >= 0 && iy < m_rows);
// assert(ixb >= 0 && ixb < m_cols);
// assert(iyb >= 0 && iyb < m_rows);
// Account for the end points.
if (line_cell_intersect(p1src, p2src, m_cells[iy*m_cols + ix]))
return true;
if (ix == ixb && iy == iyb)
// Both ends fall into the same cell.
continue;
// Raster the centeral part of the line.
coord_t dx = std::abs(p2.x - p1.x);
coord_t dy = std::abs(p2.y - p1.y);
if (p1.x < p2.x) {
int64_t ex = int64_t((ix + 1)*m_resolution - p1.x) * int64_t(dy);
if (p1.y < p2.y) {
int64_t ey = int64_t((iy + 1)*m_resolution - p1.y) * int64_t(dx);
do {
assert(ix <= ixb && iy <= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix += 1;
}
else if (ex == ey) {
ex = int64_t(dy) * m_resolution;
ey = int64_t(dx) * m_resolution;
ix += 1;
iy += 1;
}
else {
assert(ex > ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy += 1;
}
if (line_cell_intersect(p1src, p2src, m_cells[iy*m_cols + ix]))
return true;
} while (ix != ixb || iy != iyb);
}
else {
int64_t ey = int64_t(p1.y - iy*m_resolution) * int64_t(dx);
do {
assert(ix <= ixb && iy >= iyb);
if (ex <= ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix += 1;
}
else {
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
if (line_cell_intersect(p1src, p2src, m_cells[iy*m_cols + ix]))
return true;
} while (ix != ixb || iy != iyb);
}
}
else {
int64_t ex = int64_t(p1.x - ix*m_resolution) * int64_t(dy);
if (p1.y < p2.y) {
int64_t ey = int64_t((iy + 1)*m_resolution - p1.y) * int64_t(dx);
do {
assert(ix >= ixb && iy <= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
else {
assert(ex >= ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy += 1;
}
if (line_cell_intersect(p1src, p2src, m_cells[iy*m_cols + ix]))
return true;
} while (ix != ixb || iy != iyb);
}
else {
int64_t ey = int64_t(p1.y - iy*m_resolution) * int64_t(dx);
do {
assert(ix >= ixb && iy >= iyb);
if (ex < ey) {
ey -= ex;
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
else if (ex == ey) {
if (dx > 0) {
ex = int64_t(dy) * m_resolution;
ix -= 1;
}
if (dy > 0) {
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
}
else {
assert(ex > ey);
ex -= ey;
ey = int64_t(dx) * m_resolution;
iy -= 1;
}
if (line_cell_intersect(p1src, p2src, m_cells[iy*m_cols + ix]))
return true;
} while (ix != ixb || iy != iyb);
}
}
}
return false;
}
bool EdgeGrid::Grid::line_cell_intersect(const Point &p1a, const Point &p2a, const Cell &cell)
{
BoundingBox bbox(p1a, p1a);
bbox.merge(p2a);
int64_t va_x = p2a.x - p1a.x;
int64_t va_y = p2a.y - p1a.y;
for (size_t i = cell.begin; i != cell.end; ++ i) {
const std::pair<size_t, size_t> &cell_data = m_cell_data[i];
// Contour indexed by the ith line of this cell.
const Slic3r::Points &contour = *m_contours[cell_data.first];
// Point indices in contour indexed by the ith line of this cell.
size_t idx1 = cell_data.second;
size_t idx2 = idx1 + 1;
if (idx2 == contour.size())
idx2 = 0;
// The points of the ith line of this cell and its bounding box.
const Point &p1b = contour[idx1];
const Point &p2b = contour[idx2];
BoundingBox bbox2(p1b, p1b);
bbox2.merge(p2b);
// Do the bounding boxes intersect?
if (! bbox.overlap(bbox2))
continue;
// Now intersect the two line segments using exact arithmetics.
int64_t w1_x = p1b.x - p1a.x;
int64_t w1_y = p1b.y - p1a.y;
int64_t w2_x = p2b.x - p1a.x;
int64_t w2_y = p2b.y - p1a.y;
int64_t side1 = va_x * w1_y - va_y * w1_x;
int64_t side2 = va_x * w2_y - va_y * w2_x;
if (side1 == side2 && side1 != 0)
// The line segments don't intersect.
continue;
w1_x = p1a.x - p1b.x;
w1_y = p1a.y - p1b.y;
w2_x = p2a.x - p1b.x;
w2_y = p2a.y - p1b.y;
int64_t vb_x = p2b.x - p1b.x;
int64_t vb_y = p2b.y - p1b.y;
side1 = vb_x * w1_y - vb_y * w1_x;
side2 = vb_x * w2_y - vb_y * w2_x;
if (side1 == side2 && side1 != 0)
// The line segments don't intersect.
continue;
// The line segments intersect.
return true;
}
// The line segment (p1a, p2a) does not intersect any of the line segments inside this cell.
return false;
}
// Test, whether a point is inside a contour.
bool EdgeGrid::Grid::inside(const Point &pt_src)
{
Point p = pt_src;
p.x -= m_bbox.min.x;
p.y -= m_bbox.min.y;
// Get the cell of the point.
if (p.x < 0 || p.y < 0)
return false;
coord_t ix = p.x / m_resolution;
coord_t iy = p.y / m_resolution;
if (ix >= this->m_cols || iy >= this->m_rows)
return false;
size_t i_closest = (size_t)-1;
bool inside = false;
{
// Hit in the first cell?
const Cell &cell = m_cells[iy * m_cols + ix];
for (size_t i = cell.begin; i != cell.end; ++ i) {
const std::pair<size_t, size_t> &cell_data = m_cell_data[i];
// Contour indexed by the ith line of this cell.
const Slic3r::Points &contour = *m_contours[cell_data.first];
// Point indices in contour indexed by the ith line of this cell.
size_t idx1 = cell_data.second;
size_t idx2 = idx1 + 1;
if (idx2 == contour.size())
idx2 = 0;
const Point &p1 = contour[idx1];
const Point &p2 = contour[idx2];
if (p1.y < p2.y) {
if (p.y < p1.y || p.y > p2.y)
continue;
//FIXME finish this!
int64_t vx = 0;// pt_src
//FIXME finish this!
int64_t det = 0;
} else if (p1.y != p2.y) {
assert(p1.y > p2.y);
if (p.y < p2.y || p.y > p1.y)
continue;
} else {
assert(p1.y == p2.y);
if (p1.y == p.y) {
if (p.x >= p1.x && p.x <= p2.x)
// On the segment.
return true;
// Before or after the segment.
size_t idx0 = idx1 - 1;
size_t idx2 = idx1 + 1;
if (idx0 == (size_t)-1)
idx0 = contour.size() - 1;
if (idx2 == contour.size())
idx2 = 0;
}
}
}
}
//FIXME This code follows only a single direction. Better to follow the direction closest to the bounding box.
}
#endif
template<const int INCX, const int INCY>
struct PropagateDanielssonSingleStep {
PropagateDanielssonSingleStep(float *aL, unsigned char *asigns, size_t astride, coord_t aresolution) :
L(aL), signs(asigns), stride(astride), resolution(aresolution) {}
inline void operator()(int r, int c, int addr_delta) {
size_t addr = r * stride + c;
if ((signs[addr] & 2) == 0) {
float *v = &L[addr << 1];
float l = v[0] * v[0] + v[1] * v[1];
float *v2s = v + (addr_delta << 1);
float v2[2] = {
v2s[0] + INCX * resolution,
v2s[1] + INCY * resolution
};
float l2 = v2[0] * v2[0] + v2[1] * v2[1];
if (l2 < l) {
v[0] = v2[0];
v[1] = v2[1];
}
}
}
float *L;
unsigned char *signs;
size_t stride;
coord_t resolution;
};
struct PropagateDanielssonSingleVStep3 {
PropagateDanielssonSingleVStep3(float *aL, unsigned char *asigns, size_t astride, coord_t aresolution) :
L(aL), signs(asigns), stride(astride), resolution(aresolution) {}
inline void operator()(int r, int c, int addr_delta, bool has_l, bool has_r) {
size_t addr = r * stride + c;
if ((signs[addr] & 2) == 0) {
float *v = &L[addr<<1];
float l = v[0]*v[0]+v[1]*v[1];
float *v2s = v+(addr_delta<<1);
float v2[2] = {
v2s[0],
v2s[1] + resolution
};
float l2 = v2[0]*v2[0]+v2[1]*v2[1];
if (l2 < l) {
v[0] = v2[0];
v[1] = v2[1];
}
if (has_l) {
float *v2sl = v2s - 1;
v2[0] = v2sl[0] + resolution;
v2[1] = v2sl[1] + resolution;
l2 = v2[0]*v2[0]+v2[1]*v2[1];
if (l2 < l) {
v[0] = v2[0];
v[1] = v2[1];
}
}
if (has_r) {
float *v2sr = v2s + 1;
v2[0] = v2sr[0] + resolution;
v2[1] = v2sr[1] + resolution;
l2 = v2[0]*v2[0]+v2[1]*v2[1];
if (l2 < l) {
v[0] = v2[0];
v[1] = v2[1];
}
}
}
}
float *L;
unsigned char *signs;
size_t stride;
coord_t resolution;
};
void EdgeGrid::Grid::calculate_sdf()
{
// 1) Initialize a signum and an unsigned vector to a zero iso surface.
size_t nrows = m_rows + 1;
size_t ncols = m_cols + 1;
// Unsigned vectors towards the closest point on the surface.
std::vector<float> L(nrows * ncols * 2, FLT_MAX);
// Bit 0 set - negative.
// Bit 1 set - original value, the distance value shall not be changed by the Danielsson propagation.
// Bit 2 set - signum not propagated yet.
std::vector<unsigned char> signs(nrows * ncols, 4);
// SDF will be initially filled with unsigned DF.
// m_signed_distance_field.assign(nrows * ncols, FLT_MAX);
float search_radius = float(m_resolution<<1);
m_signed_distance_field.assign(nrows * ncols, search_radius);
// For each cell:
for (size_t r = 0; r < m_rows; ++ r) {
for (size_t c = 0; c < m_cols; ++ c) {
const Cell &cell = m_cells[r * m_cols + c];
// For each segment in the cell:
for (size_t i = cell.begin; i != cell.end; ++ i) {
const Slic3r::Points &pts = *m_contours[m_cell_data[i].first];
size_t ipt = m_cell_data[i].second;
// End points of the line segment.
const Slic3r::Point &p1 = pts[ipt];
const Slic3r::Point &p2 = pts[(ipt + 1 == pts.size()) ? 0 : ipt + 1];
// Segment vector
const Slic3r::Point v_seg = p1.vector_to(p2);
// l2 of v_seg
const int64_t l2_seg = int64_t(v_seg.x) * int64_t(v_seg.x) + int64_t(v_seg.y) * int64_t(v_seg.y);
// For each corner of this cell and its 1 ring neighbours:
for (int corner_y = -1; corner_y < 3; ++ corner_y) {
coord_t corner_r = r + corner_y;
if (corner_r < 0 || corner_r >= nrows)
continue;
for (int corner_x = -1; corner_x < 3; ++ corner_x) {
coord_t corner_c = c + corner_x;
if (corner_c < 0 || corner_c >= ncols)
continue;
float &d_min = m_signed_distance_field[corner_r * ncols + corner_c];
Slic3r::Point pt(m_bbox.min.x + corner_c * m_resolution, m_bbox.min.y + corner_r * m_resolution);
Slic3r::Point v_pt = p1.vector_to(pt);
// dot(p2-p1, pt-p1)
int64_t t_pt = int64_t(v_seg.x) * int64_t(v_pt.x) + int64_t(v_seg.y) * int64_t(v_pt.y);
if (t_pt < 0) {
// Closest to p1.
double dabs = sqrt(int64_t(v_pt.x) * int64_t(v_pt.x) + int64_t(v_pt.y) * int64_t(v_pt.y));
if (dabs < d_min) {
// Previous point.
const Slic3r::Point &p0 = pts[(ipt == 0) ? (pts.size() - 1) : ipt - 1];
Slic3r::Point v_seg_prev = p0.vector_to(p1);
int64_t t2_pt = int64_t(v_seg_prev.x) * int64_t(v_pt.x) + int64_t(v_seg_prev.y) * int64_t(v_pt.y);
if (t2_pt > 0) {
// Inside the wedge between the previous and the next segment.
// Set the signum depending on whether the vertex is convex or reflex.
int64_t det = int64_t(v_seg_prev.x) * int64_t(v_seg.y) - int64_t(v_seg_prev.y) * int64_t(v_seg.x);
assert(det != 0);
d_min = dabs;
// Fill in an unsigned vector towards the zero iso surface.
float *l = &L[(corner_r * ncols + corner_c) << 1];
l[0] = std::abs(v_pt.x);
l[1] = std::abs(v_pt.y);
#ifdef _DEBUG
double dabs2 = sqrt(l[0]*l[0]+l[1]*l[1]);
assert(std::abs(dabs-dabs2) < 1e-4 * std::max(dabs, dabs2));
#endif /* _DEBUG */
signs[corner_r * ncols + corner_c] = ((det < 0) ? 1 : 0) | 2;
}
}
}
else if (t_pt > l2_seg) {
// Closest to p2. Then p2 is the starting point of another segment, which shall be discovered in the same cell.
continue;
} else {
// Closest to the segment.
assert(t_pt >= 0 && t_pt <= l2_seg);
int64_t d_seg = int64_t(v_seg.y) * int64_t(v_pt.x) - int64_t(v_seg.x) * int64_t(v_pt.y);
double d = double(d_seg) / sqrt(double(l2_seg));
double dabs = std::abs(d);
if (dabs < d_min) {
d_min = dabs;
// Fill in an unsigned vector towards the zero iso surface.
float *l = &L[(corner_r * ncols + corner_c) << 1];
float linv = float(d_seg) / float(l2_seg);
l[0] = std::abs(float(v_seg.y) * linv);
l[1] = std::abs(float(v_seg.x) * linv);
#ifdef _DEBUG
double dabs2 = sqrt(l[0]*l[0]+l[1]*l[1]);
assert(std::abs(dabs-dabs2) <= 1e-4 * std::max(dabs, dabs2));
#endif /* _DEBUG */
signs[corner_r * ncols + corner_c] = ((d_seg < 0) ? 1 : 0) | 2;
}
}
}
}
}
}
}
#if 0
static int iRun = 0;
++ iRun;
//#ifdef SLIC3R_GUI
{
wxImage img(ncols, nrows);
unsigned char *data = img.GetData();
memset(data, 0, ncols * nrows * 3);
for (coord_t r = 0; r < nrows; ++r) {
for (coord_t c = 0; c < ncols; ++c) {
unsigned char *pxl = data + (((nrows - r - 1) * ncols) + c) * 3;
float d = m_signed_distance_field[r * ncols + c];
if (d != search_radius) {
float s = 255 * d / search_radius;
int is = std::max(0, std::min(255, int(floor(s + 0.5f))));
pxl[0] = 255;
pxl[1] = 255 - is;
pxl[2] = 255 - is;
}
else {
pxl[0] = 0;
pxl[1] = 255;
pxl[2] = 0;
}
}
}
img.SaveFile(debug_out_path("unsigned_df-%d.png", iRun), wxBITMAP_TYPE_PNG);
}
{
wxImage img(ncols, nrows);
unsigned char *data = img.GetData();
memset(data, 0, ncols * nrows * 3);
for (coord_t r = 0; r < nrows; ++r) {
for (coord_t c = 0; c < ncols; ++c) {
unsigned char *pxl = data + (((nrows - r - 1) * ncols) + c) * 3;
float d = m_signed_distance_field[r * ncols + c];
if (d != search_radius) {
float s = 255 * d / search_radius;
int is = std::max(0, std::min(255, int(floor(s + 0.5f))));
if ((signs[r * ncols + c] & 1) == 0) {
// Positive
pxl[0] = 255;
pxl[1] = 255 - is;
pxl[2] = 255 - is;
}
else {
// Negative
pxl[0] = 255 - is;
pxl[1] = 255 - is;
pxl[2] = 255;
}
}
else {
pxl[0] = 0;
pxl[1] = 255;
pxl[2] = 0;
}
}
}
img.SaveFile(debug_out_path("signed_df-%d.png", iRun), wxBITMAP_TYPE_PNG);
}
#endif /* SLIC3R_GUI */
// 2) Propagate the signum.
#define PROPAGATE_SIGNUM_SINGLE_STEP(DELTA) do { \
size_t addr = r * ncols + c; \
unsigned char &cur_val = signs[addr]; \
if (cur_val & 4) { \
unsigned char old_val = signs[addr + (DELTA)]; \
if ((old_val & 4) == 0) \
cur_val = old_val & 1; \
} \
} while (0);
// Top to bottom propagation.
for (size_t r = 0; r < nrows; ++ r) {
if (r > 0)
for (size_t c = 0; c < ncols; ++ c)
PROPAGATE_SIGNUM_SINGLE_STEP(- int(ncols));
for (size_t c = 1; c < ncols; ++ c)
PROPAGATE_SIGNUM_SINGLE_STEP(- 1);
for (int c = int(ncols) - 2; c >= 0; -- c)
PROPAGATE_SIGNUM_SINGLE_STEP(+ 1);
}
// Bottom to top propagation.
for (int r = int(nrows) - 2; r >= 0; -- r) {
for (size_t c = 0; c < ncols; ++ c)
PROPAGATE_SIGNUM_SINGLE_STEP(+ ncols);
for (size_t c = 1; c < ncols; ++ c)
PROPAGATE_SIGNUM_SINGLE_STEP(- 1);
for (int c = int(ncols) - 2; c >= 0; -- c)
PROPAGATE_SIGNUM_SINGLE_STEP(+ 1);
}
#undef PROPAGATE_SIGNUM_SINGLE_STEP
// 3) Propagate the distance by the Danielsson chamfer metric.
// Top to bottom propagation.
PropagateDanielssonSingleStep<1, 0> danielsson_hstep(L.data(), signs.data(), ncols, m_resolution);
PropagateDanielssonSingleStep<0, 1> danielsson_vstep(L.data(), signs.data(), ncols, m_resolution);
PropagateDanielssonSingleVStep3 danielsson_vstep3(L.data(), signs.data(), ncols, m_resolution);
// Top to bottom propagation.
for (size_t r = 0; r < nrows; ++ r) {
if (r > 0)
for (size_t c = 0; c < ncols; ++ c)
danielsson_vstep(r, c, -int(ncols));
// PROPAGATE_DANIELSSON_SINGLE_VSTEP3(-int(ncols), c != 0, c + 1 != ncols);
for (size_t c = 1; c < ncols; ++ c)
danielsson_hstep(r, c, -1);
for (int c = int(ncols) - 2; c >= 0; -- c)
danielsson_hstep(r, c, +1);
}
// Bottom to top propagation.
for (int r = int(nrows) - 2; r >= 0; -- r) {
for (size_t c = 0; c < ncols; ++ c)
danielsson_vstep(r, c, +ncols);
// PROPAGATE_DANIELSSON_SINGLE_VSTEP3(+int(ncols), c != 0, c + 1 != ncols);
for (size_t c = 1; c < ncols; ++ c)
danielsson_hstep(r, c, -1);
for (int c = int(ncols) - 2; c >= 0; -- c)
danielsson_hstep(r, c, +1);
}
// Update signed distance field from absolte vectors to the iso-surface.
for (size_t r = 0; r < nrows; ++ r) {
for (size_t c = 0; c < ncols; ++ c) {
size_t addr = r * ncols + c;
float *v = &L[addr<<1];
float d = sqrt(v[0]*v[0]+v[1]*v[1]);
if (signs[addr] & 1)
d = -d;
m_signed_distance_field[addr] = d;
}
}
#if 0
//#ifdef SLIC3R_GUI
{
wxImage img(ncols, nrows);
unsigned char *data = img.GetData();
memset(data, 0, ncols * nrows * 3);
float search_radius = float(m_resolution * 5);
for (coord_t r = 0; r < nrows; ++r) {
for (coord_t c = 0; c < ncols; ++c) {
unsigned char *pxl = data + (((nrows - r - 1) * ncols) + c) * 3;
unsigned char sign = signs[r * ncols + c];
switch (sign) {
case 0:
// Positive, outside of a narrow band.
pxl[0] = 0;
pxl[1] = 0;
pxl[2] = 255;
break;
case 1:
// Negative, outside of a narrow band.
pxl[0] = 255;
pxl[1] = 0;
pxl[2] = 0;
break;
case 2:
// Positive, outside of a narrow band.
pxl[0] = 100;
pxl[1] = 100;
pxl[2] = 255;
break;
case 3:
// Negative, outside of a narrow band.
pxl[0] = 255;
pxl[1] = 100;
pxl[2] = 100;
break;
case 4:
// This shall not happen. Undefined signum.
pxl[0] = 0;
pxl[1] = 255;
pxl[2] = 0;
break;
default:
// This shall not happen. Invalid signum value.
pxl[0] = 255;
pxl[1] = 255;
pxl[2] = 255;
break;
}
}
}
img.SaveFile(debug_out_path("signed_df-signs-%d.png", iRun), wxBITMAP_TYPE_PNG);
}
#endif /* SLIC3R_GUI */
#if 0
//#ifdef SLIC3R_GUI
{
wxImage img(ncols, nrows);
unsigned char *data = img.GetData();
memset(data, 0, ncols * nrows * 3);
float search_radius = float(m_resolution * 5);
for (coord_t r = 0; r < nrows; ++r) {
for (coord_t c = 0; c < ncols; ++c) {
unsigned char *pxl = data + (((nrows - r - 1) * ncols) + c) * 3;
float d = m_signed_distance_field[r * ncols + c];
float s = 255.f * fabs(d) / search_radius;
int is = std::max(0, std::min(255, int(floor(s + 0.5f))));
if (d < 0.f) {
pxl[0] = 255;
pxl[1] = 255 - is;
pxl[2] = 255 - is;
}
else {
pxl[0] = 255 - is;
pxl[1] = 255 - is;
pxl[2] = 255;
}
}
}
img.SaveFile(debug_out_path("signed_df2-%d.png", iRun), wxBITMAP_TYPE_PNG);
}
#endif /* SLIC3R_GUI */
}
float EdgeGrid::Grid::signed_distance_bilinear(const Point &pt) const
{
coord_t x = pt.x - m_bbox.min.x;
coord_t y = pt.y - m_bbox.min.y;
coord_t w = m_resolution * m_cols;
coord_t h = m_resolution * m_rows;
bool clamped = false;
coord_t xcl = x;
coord_t ycl = y;
if (x < 0) {
xcl = 0;
clamped = true;
} else if (x >= w) {
xcl = w - 1;
clamped = true;
}
if (y < 0) {
ycl = 0;
clamped = true;
} else if (y >= h) {
ycl = h - 1;
clamped = true;
}
coord_t cell_c = coord_t(floor(xcl / m_resolution));
coord_t cell_r = coord_t(floor(ycl / m_resolution));
float tx = float(xcl - cell_c * m_resolution) / float(m_resolution);
assert(tx >= -1e-5 && tx < 1.f + 1e-5);
float ty = float(ycl - cell_r * m_resolution) / float(m_resolution);
assert(ty >= -1e-5 && ty < 1.f + 1e-5);
size_t addr = cell_r * (m_cols + 1) + cell_c;
float f00 = m_signed_distance_field[addr];
float f01 = m_signed_distance_field[addr+1];
addr += m_cols + 1;
float f10 = m_signed_distance_field[addr];
float f11 = m_signed_distance_field[addr+1];
float f0 = (1.f - tx) * f00 + tx * f01;
float f1 = (1.f - tx) * f10 + tx * f11;
float f = (1.f - ty) * f0 + ty * f1;
if (clamped) {
if (f > 0) {
if (x < 0)
f += -x;
else if (x >= w)
f += x - w + 1;
if (y < 0)
f += -y;
else if (y >= h)
f += y - h + 1;
} else {
if (x < 0)
f -= -x;
else if (x >= w)
f -= x - w + 1;
if (y < 0)
f -= -y;
else if (y >= h)
f -= y - h + 1;
}
}
return f;
}
bool EdgeGrid::Grid::signed_distance_edges(const Point &pt, coord_t search_radius, coordf_t &result_min_dist, bool *pon_segment) const {
BoundingBox bbox;
bbox.min = bbox.max = Point(pt.x - m_bbox.min.x, pt.y - m_bbox.min.y);
bbox.defined = true;
// Upper boundary, round to grid and test validity.
bbox.max.x += search_radius;
bbox.max.y += search_radius;
if (bbox.max.x < 0 || bbox.max.y < 0)
return false;
bbox.max.x /= m_resolution;
bbox.max.y /= m_resolution;
if (bbox.max.x >= m_cols)
bbox.max.x = m_cols - 1;
if (bbox.max.y >= m_rows)
bbox.max.y = m_rows - 1;
// Lower boundary, round to grid and test validity.
bbox.min.x -= search_radius;
bbox.min.y -= search_radius;
if (bbox.min.x < 0)
bbox.min.x = 0;
if (bbox.min.y < 0)
bbox.min.y = 0;
bbox.min.x /= m_resolution;
bbox.min.y /= m_resolution;
// Is the interval empty?
if (bbox.min.x > bbox.max.x ||
bbox.min.y > bbox.max.y)
return false;
// Traverse all cells in the bounding box.
float d_min = search_radius;
// Signum of the distance field at pt.
int sign_min = 0;
bool on_segment = false;
for (int r = bbox.min.y; r <= bbox.max.y; ++ r) {
for (int c = bbox.min.x; c <= bbox.max.x; ++ c) {
const Cell &cell = m_cells[r * m_cols + c];
for (size_t i = cell.begin; i < cell.end; ++ i) {
const Slic3r::Points &pts = *m_contours[m_cell_data[i].first];
size_t ipt = m_cell_data[i].second;
// End points of the line segment.
const Slic3r::Point &p1 = pts[ipt];
const Slic3r::Point &p2 = pts[(ipt + 1 == pts.size()) ? 0 : ipt + 1];
Slic3r::Point v_seg = p1.vector_to(p2);
Slic3r::Point v_pt = p1.vector_to(pt);
// dot(p2-p1, pt-p1)
int64_t t_pt = int64_t(v_seg.x) * int64_t(v_pt.x) + int64_t(v_seg.y) * int64_t(v_pt.y);
// l2 of seg
int64_t l2_seg = int64_t(v_seg.x) * int64_t(v_seg.x) + int64_t(v_seg.y) * int64_t(v_seg.y);
if (t_pt < 0) {
// Closest to p1.
double dabs = sqrt(int64_t(v_pt.x) * int64_t(v_pt.x) + int64_t(v_pt.y) * int64_t(v_pt.y));
if (dabs < d_min) {
// Previous point.
const Slic3r::Point &p0 = pts[(ipt == 0) ? (pts.size() - 1) : ipt - 1];
Slic3r::Point v_seg_prev = p0.vector_to(p1);
int64_t t2_pt = int64_t(v_seg_prev.x) * int64_t(v_pt.x) + int64_t(v_seg_prev.y) * int64_t(v_pt.y);
if (t2_pt > 0) {
// Inside the wedge between the previous and the next segment.
d_min = dabs;
// Set the signum depending on whether the vertex is convex or reflex.
int64_t det = int64_t(v_seg_prev.x) * int64_t(v_seg.y) - int64_t(v_seg_prev.y) * int64_t(v_seg.x);
assert(det != 0);
sign_min = (det > 0) ? 1 : -1;
on_segment = false;
}
}
}
else if (t_pt > l2_seg) {
// Closest to p2. Then p2 is the starting point of another segment, which shall be discovered in the same cell.
continue;
} else {
// Closest to the segment.
assert(t_pt >= 0 && t_pt <= l2_seg);
int64_t d_seg = int64_t(v_seg.y) * int64_t(v_pt.x) - int64_t(v_seg.x) * int64_t(v_pt.y);
double d = double(d_seg) / sqrt(double(l2_seg));
double dabs = std::abs(d);
if (dabs < d_min) {
d_min = dabs;
sign_min = (d_seg < 0) ? -1 : ((d_seg == 0) ? 0 : 1);
on_segment = true;
}
}
}
}
}
if (d_min >= search_radius)
return false;
result_min_dist = d_min * sign_min;
if (pon_segment != NULL)
*pon_segment = on_segment;
return true;
}
bool EdgeGrid::Grid::signed_distance(const Point &pt, coord_t search_radius, coordf_t &result_min_dist) const
{
if (signed_distance_edges(pt, search_radius, result_min_dist))
return true;
if (m_signed_distance_field.empty())
return false;
result_min_dist = signed_distance_bilinear(pt);
return true;
}
Polygons EdgeGrid::Grid::contours_simplified(coord_t offset) const
{
typedef std::unordered_multimap<Point, int, PointHash> EndPointMapType;
// 0) Prepare a binary grid.
size_t cell_rows = m_rows + 2;
size_t cell_cols = m_cols + 2;
std::vector<char> cell_inside(cell_rows * cell_cols, false);
for (int r = 0; r < int(cell_rows); ++ r)
for (int c = 0; c < int(cell_cols); ++ c)
cell_inside[r * cell_cols + c] = cell_inside_or_crossing(r - 1, c - 1);
// Fill in empty cells, which have a left / right neighbor filled.
// Fill in empty cells, which have the top / bottom neighbor filled.
{
std::vector<char> cell_inside2(cell_inside);
for (int r = 1; r + 1 < int(cell_rows); ++ r) {
for (int c = 1; c + 1 < int(cell_cols); ++ c) {
int addr = r * cell_cols + c;
if ((cell_inside2[addr - 1] && cell_inside2[addr + 1]) ||
(cell_inside2[addr - cell_cols] && cell_inside2[addr + cell_cols]))
cell_inside[addr] = true;
}
}
}
// 1) Collect the lines.
std::vector<Line> lines;
EndPointMapType start_point_to_line_idx;
for (int r = 0; r <= int(m_rows); ++ r) {
for (int c = 0; c <= int(m_cols); ++ c) {
int addr = (r + 1) * cell_cols + c + 1;
bool left = cell_inside[addr - 1];
bool top = cell_inside[addr - cell_cols];
bool current = cell_inside[addr];
if (left != current) {
lines.push_back(
left ?
Line(Point(c, r+1), Point(c, r )) :
Line(Point(c, r ), Point(c, r+1)));
start_point_to_line_idx.insert(std::pair<Point, int>(lines.back().a, int(lines.size()) - 1));
}
if (top != current) {
lines.push_back(
top ?
Line(Point(c , r), Point(c+1, r)) :
Line(Point(c+1, r), Point(c , r)));
start_point_to_line_idx.insert(std::pair<Point, int>(lines.back().a, int(lines.size()) - 1));
}
}
}
// 2) Chain the lines.
std::vector<char> line_processed(lines.size(), false);
Polygons out;
for (int i_candidate = 0; i_candidate < int(lines.size()); ++ i_candidate) {
if (line_processed[i_candidate])
continue;
Polygon poly;
line_processed[i_candidate] = true;
poly.points.push_back(lines[i_candidate].b);
int i_line_current = i_candidate;
for (;;) {
std::pair<EndPointMapType::iterator,EndPointMapType::iterator> line_range =
start_point_to_line_idx.equal_range(lines[i_line_current].b);
// The interval has to be non empty, there shall be at least one line continuing the current one.
assert(line_range.first != line_range.second);
int i_next = -1;
for (EndPointMapType::iterator it = line_range.first; it != line_range.second; ++ it) {
if (it->second == i_candidate) {
// closing the loop.
goto end_of_poly;
}
if (line_processed[it->second])
continue;
if (i_next == -1) {
i_next = it->second;
} else {
// This is a corner, where two lines meet exactly. Pick the line, which encloses a smallest angle with
// the current edge.
const Line &line_current = lines[i_line_current];
const Line &line_next = lines[it->second];
const Vector v1 = line_current.vector();
const Vector v2 = line_next.vector();
int64_t cross = int64_t(v1.x) * int64_t(v2.y) - int64_t(v2.x) * int64_t(v1.y);
if (cross > 0) {
// This has to be a convex right angle. There is no better next line.
i_next = it->second;
break;
}
}
}
line_processed[i_next] = true;
i_line_current = i_next;
poly.points.push_back(lines[i_line_current].b);
}
end_of_poly:
out.push_back(std::move(poly));
}
// 3) Scale the polygons back into world, shrink slightly and remove collinear points.
for (size_t i = 0; i < out.size(); ++ i) {
Polygon &poly = out[i];
for (size_t j = 0; j < poly.points.size(); ++ j) {
Point &p = poly.points[j];
p.x *= m_resolution;
p.y *= m_resolution;
p.x += m_bbox.min.x;
p.y += m_bbox.min.y;
}
// Shrink the contour slightly, so if the same contour gets discretized and simplified again, one will get the same result.
// Remove collineaer points.
Points pts;
pts.reserve(poly.points.size());
for (size_t j = 0; j < poly.points.size(); ++ j) {
size_t j0 = (j == 0) ? poly.points.size() - 1 : j - 1;
size_t j2 = (j + 1 == poly.points.size()) ? 0 : j + 1;
Point v = poly.points[j2] - poly.points[j0];
if (v.x != 0 && v.y != 0) {
// This is a corner point. Copy it to the output contour.
Point p = poly.points[j];
p.y += (v.x < 0) ? - offset : offset;
p.x += (v.y > 0) ? - offset : offset;
pts.push_back(p);
}
}
poly.points = std::move(pts);
}
return out;
}
#if 0
void EdgeGrid::save_png(const EdgeGrid::Grid &grid, const BoundingBox &bbox, coord_t resolution, const char *path)
{
unsigned int w = (bbox.max.x - bbox.min.x + resolution - 1) / resolution;
unsigned int h = (bbox.max.y - bbox.min.y + resolution - 1) / resolution;
wxImage img(w, h);
unsigned char *data = img.GetData();
memset(data, 0, w * h * 3);
static int iRun = 0;
++iRun;
const coord_t search_radius = grid.resolution() * 2;
const coord_t display_blend_radius = grid.resolution() * 2;
for (coord_t r = 0; r < h; ++r) {
for (coord_t c = 0; c < w; ++ c) {
unsigned char *pxl = data + (((h - r - 1) * w) + c) * 3;
Point pt(c * resolution + bbox.min.x, r * resolution + bbox.min.y);
coordf_t min_dist;
bool on_segment = true;
#if 0
if (grid.signed_distance_edges(pt, search_radius, min_dist, &on_segment)) {
#else
if (grid.signed_distance(pt, search_radius, min_dist)) {
#endif
float s = 255 * std::abs(min_dist) / float(display_blend_radius);
int is = std::max(0, std::min(255, int(floor(s + 0.5f))));
if (min_dist < 0) {
if (on_segment) {
pxl[0] = 255;
pxl[1] = 255 - is;
pxl[2] = 255 - is;
} else {
pxl[0] = 255;
pxl[1] = 0;
pxl[2] = 255 - is;
}
}
else {
if (on_segment) {
pxl[0] = 255 - is;
pxl[1] = 255 - is;
pxl[2] = 255;
} else {
pxl[0] = 255 - is;
pxl[1] = 0;
pxl[2] = 255;
}
}
} else {
pxl[0] = 0;
pxl[1] = 255;
pxl[2] = 0;
}
float gridx = float(pt.x - grid.bbox().min.x) / float(grid.resolution());
float gridy = float(pt.y - grid.bbox().min.y) / float(grid.resolution());
if (gridx >= -0.4f && gridy >= -0.4f && gridx <= grid.cols() + 0.4f && gridy <= grid.rows() + 0.4f) {
int ix = int(floor(gridx + 0.5f));
int iy = int(floor(gridy + 0.5f));
float dx = gridx - float(ix);
float dy = gridy - float(iy);
float d = sqrt(dx*dx + dy*dy) * float(grid.resolution()) / float(resolution);
if (d < 1.f) {
// Less than 1 pixel from the grid point.
float t = 0.5f + 0.5f * d;
pxl[0] = (unsigned char)(t * pxl[0]);
pxl[1] = (unsigned char)(t * pxl[1]);
pxl[2] = (unsigned char)(t * pxl[2]);
}
}
float dgrid = fabs(min_dist) / float(grid.resolution());
float igrid = floor(dgrid + 0.5f);
dgrid = std::abs(dgrid - igrid) * float(grid.resolution()) / float(resolution);
if (dgrid < 1.f) {
// Less than 1 pixel from the grid point.
float t = 0.5f + 0.5f * dgrid;
pxl[0] = (unsigned char)(t * pxl[0]);
pxl[1] = (unsigned char)(t * pxl[1]);
pxl[2] = (unsigned char)(t * pxl[2]);
if (igrid > 0.f) {
// Other than zero iso contour.
int g = pxl[1] + 255.f * (1.f - t);
pxl[1] = std::min(g, 255);
}
}
}
}
img.SaveFile(path, wxBITMAP_TYPE_PNG);
}
#endif /* SLIC3R_GUI */
} // namespace Slic3r