// Optimize the extrusion simulator to the bones. //#pragma GCC optimize ("O3") //#undef SLIC3R_DEBUG //#define NDEBUG #include #include #include #include #include #include #include #include "libslic3r.h" #include "ExtrusionSimulator.hpp" #ifndef M_PI #define M_PI 3.1415926535897932384626433832795 #endif namespace Slic3r { // Replacement for a template alias. // Shorthand for the point_xy. template struct V2 { typedef boost::geometry::model::d2::point_xy Type; }; // Replacement for a template alias. // Shorthand for the point with a cartesian coordinate system. template struct V3 { typedef boost::geometry::model::point Type; }; // Replacement for a template alias. // Shorthand for the point with a cartesian coordinate system. template struct V4 { typedef boost::geometry::model::point Type; }; typedef V2::Type V2i; typedef V2::Type V2f; typedef V2::Type V2d; // Used for an RGB color. typedef V3::Type V3uc; // Used for an RGBA color. typedef V4::Type V4uc; typedef boost::geometry::model::box B2i; typedef boost::geometry::model::box B2f; typedef boost::geometry::model::box B2d; typedef boost::multi_array A2uc; typedef boost::multi_array A2i; typedef boost::multi_array A2f; typedef boost::multi_array A2d; template inline void operator+=( boost::geometry::model::d2::point_xy &v1, const boost::geometry::model::d2::point_xy &v2) { boost::geometry::add_point(v1, v2); } template inline void operator-=( boost::geometry::model::d2::point_xy &v1, const boost::geometry::model::d2::point_xy &v2) { boost::geometry::subtract_point(v1, v2); } template inline void operator*=(boost::geometry::model::d2::point_xy &v, const T c) { boost::geometry::multiply_value(v, c); } template inline void operator/=(boost::geometry::model::d2::point_xy &v, const T c) { boost::geometry::divide_value(v, c); } template inline typename boost::geometry::model::d2::point_xy operator+( const boost::geometry::model::d2::point_xy &v1, const boost::geometry::model::d2::point_xy &v2) { boost::geometry::model::d2::point_xy out(v1); out += v2; return out; } template inline boost::geometry::model::d2::point_xy operator-( const boost::geometry::model::d2::point_xy &v1, const boost::geometry::model::d2::point_xy &v2) { boost::geometry::model::d2::point_xy out(v1); out -= v2; return out; } template inline boost::geometry::model::d2::point_xy operator*( const boost::geometry::model::d2::point_xy &v, const T c) { boost::geometry::model::d2::point_xy out(v); out *= c; return out; } template inline typename boost::geometry::model::d2::point_xy operator*( const T c, const boost::geometry::model::d2::point_xy &v) { boost::geometry::model::d2::point_xy out(v); out *= c; return out; } template inline typename boost::geometry::model::d2::point_xy operator/( const boost::geometry::model::d2::point_xy &v, const T c) { boost::geometry::model::d2::point_xy out(v); out /= c; return out; } template inline T dot( const boost::geometry::model::d2::point_xy &v1, const boost::geometry::model::d2::point_xy &v2) { return boost::geometry::dot_product(v1, v2); } template inline T dot(const boost::geometry::model::d2::point_xy &v) { return boost::geometry::dot_product(v, v); } template inline T cross( const boost::geometry::model::d2::point_xy &v1, const boost::geometry::model::d2::point_xy &v2) { return v1.x() * v2.y() - v2.x() * v1.y(); } // Euclidian measure template inline T l2(const boost::geometry::model::d2::point_xy &v) { return std::sqrt(dot(v)); } // Euclidian measure template inline T mag(const boost::geometry::model::d2::point_xy &v) { return l2(v); } template inline T dist2_to_line( const boost::geometry::model::d2::point_xy &p0, const boost::geometry::model::d2::point_xy &p1, const boost::geometry::model::d2::point_xy &px) { boost::geometry::model::d2::point_xy v = p1 - p0; boost::geometry::model::d2::point_xy vx = px - p0; T l = dot(v); T t = dot(v, vx); if (l != T(0) && t > T(0.)) { t /= l; vx = px - ((t > T(1.)) ? p1 : (p0 + t * v)); } return dot(vx); } // Intersect a circle with a line segment. // Returns number of intersection points. template int line_circle_intersection( const boost::geometry::model::d2::point_xy &p0, const boost::geometry::model::d2::point_xy &p1, const boost::geometry::model::d2::point_xy ¢er, const T radius, boost::geometry::model::d2::point_xy intersection[2]) { typedef typename V2::Type V2T; V2T v = p1 - p0; V2T vc = p0 - center; T a = dot(v); T b = T(2.) * dot(vc, v); T c = dot(vc) - radius * radius; T d = b * b - T(4.) * a * c; if (d < T(0)) // The circle misses the ray. return 0; int n = 0; if (d == T(0)) { // The circle touches the ray at a single tangent point. T t = - b / (T(2.) * a); if (t >= T(0.) && t <= T(1.)) intersection[n ++] = p0 + t * v; } else { // The circle intersects the ray in two points. d = sqrt(d); T t = (- b - d) / (T(2.) * a); if (t >= T(0.) && t <= T(1.)) intersection[n ++] = p0 + t * v; t = (- b + d) / (T(2.) * a); if (t >= T(0.) && t <= T(1.)) intersection[n ++] = p0 + t * v; } return n; } // Sutherland–Hodgman clipping of a rectangle against an AABB. // Expects the first 4 points of rect to be filled at the beginning. // The clipping may produce up to 8 points. // Returns the number of resulting points. template int clip_rect_by_AABB( boost::geometry::model::d2::point_xy rect[8], const boost::geometry::model::box > &aabb) { typedef typename V2::Type V2T; V2T result[8]; int nin = 4; int nout = 0; V2T *in = rect; V2T *out = result; // Clip left { const V2T *S = in + nin - 1; T left = aabb.min_corner().x(); for (int i = 0; i < nin; ++i) { const V2T &E = in[i]; if (E.x() == left) { out[nout++] = E; } else if (E.x() > left) { // E is inside the AABB. if (S->x() < left) { // S is outside the AABB. Calculate an intersection point. T t = (left - S->x()) / (E.x() - S->x()); out[nout++] = V2T(left, S->y() + t * (E.y() - S->y())); } out[nout++] = E; } else if (S->x() > left) { // S is inside the AABB, E is outside the AABB. T t = (left - S->x()) / (E.x() - S->x()); out[nout++] = V2T(left, S->y() + t * (E.y() - S->y())); } S = &E; } assert(nout <= 8); } // Clip bottom { std::swap(in, out); nin = nout; nout = 0; const V2T *S = in + nin - 1; T bottom = aabb.min_corner().y(); for (int i = 0; i < nin; ++i) { const V2T &E = in[i]; if (E.y() == bottom) { out[nout++] = E; } else if (E.y() > bottom) { // E is inside the AABB. if (S->y() < bottom) { // S is outside the AABB. Calculate an intersection point. T t = (bottom - S->y()) / (E.y() - S->y()); out[nout++] = V2T(S->x() + t * (E.x() - S->x()), bottom); } out[nout++] = E; } else if (S->y() > bottom) { // S is inside the AABB, E is outside the AABB. T t = (bottom - S->y()) / (E.y() - S->y()); out[nout++] = V2T(S->x() + t * (E.x() - S->x()), bottom); } S = &E; } assert(nout <= 8); } // Clip right { std::swap(in, out); nin = nout; nout = 0; const V2T *S = in + nin - 1; T right = aabb.max_corner().x(); for (int i = 0; i < nin; ++i) { const V2T &E = in[i]; if (E.x() == right) { out[nout++] = E; } else if (E.x() < right) { // E is inside the AABB. if (S->x() > right) { // S is outside the AABB. Calculate an intersection point. T t = (right - S->x()) / (E.x() - S->x()); out[nout++] = V2T(right, S->y() + t * (E.y() - S->y())); } out[nout++] = E; } else if (S->x() < right) { // S is inside the AABB, E is outside the AABB. T t = (right - S->x()) / (E.x() - S->x()); out[nout++] = V2T(right, S->y() + t * (E.y() - S->y())); } S = &E; } assert(nout <= 8); } // Clip top { std::swap(in, out); nin = nout; nout = 0; const V2T *S = in + nin - 1; T top = aabb.max_corner().y(); for (int i = 0; i < nin; ++i) { const V2T &E = in[i]; if (E.y() == top) { out[nout++] = E; } else if (E.y() < top) { // E is inside the AABB. if (S->y() > top) { // S is outside the AABB. Calculate an intersection point. T t = (top - S->y()) / (E.y() - S->y()); out[nout++] = V2T(S->x() + t * (E.x() - S->x()), top); } out[nout++] = E; } else if (S->y() < top) { // S is inside the AABB, E is outside the AABB. T t = (top - S->y()) / (E.y() - S->y()); out[nout++] = V2T(S->x() + t * (E.x() - S->x()), top); } S = &E; } assert(nout <= 8); } assert(nout <= 8); return nout; } // Calculate area of the circle x AABB intersection. // The calculation is approximate in a way, that the circular segment // intersecting the cell is approximated by its chord (a linear segment). template int clip_circle_by_AABB( const boost::geometry::model::d2::point_xy ¢er, const T radius, const boost::geometry::model::box > &aabb, boost::geometry::model::d2::point_xy result[8], bool result_arc[8]) { typedef typename V2::Type V2T; V2T rect[4] = { aabb.min_corner(), V2T(aabb.max_corner().x(), aabb.min_corner().y()), aabb.max_corner(), V2T(aabb.min_corner().x(), aabb.max_corner().y()) }; int bits_corners = 0; T r2 = sqr(radius); for (int i = 0; i < 4; ++ i, bits_corners <<= 1) bits_corners |= dot(rect[i] - center) >= r2; bits_corners >>= 1; if (bits_corners == 0) { // all inside memcpy(result, rect, sizeof(rect)); memset(result_arc, true, 4); return 4; } if (bits_corners == 0x0f) // all outside return 0; // Some corners are outside, some are inside. Trim the rectangle. int n = 0; for (int i = 0; i < 4; ++ i) { bool inside = (bits_corners & 0x08) == 0; bits_corners <<= 1; V2T chordal_points[2]; int n_chordal_points = line_circle_intersection(rect[i], rect[(i + 1)%4], center, radius, chordal_points); if (n_chordal_points == 2) { result_arc[n] = true; result[n ++] = chordal_points[0]; result_arc[n] = true; result[n ++] = chordal_points[1]; } else { if (inside) { result_arc[n] = false; result[n ++] = rect[i]; } if (n_chordal_points == 1) { result_arc[n] = false; result[n ++] = chordal_points[0]; } } } return n; } /* // Calculate area of the circle x AABB intersection. // The calculation is approximate in a way, that the circular segment // intersecting the cell is approximated by its chord (a linear segment). template T circle_AABB_intersection_area( const boost::geometry::model::d2::point_xy ¢er, const T radius, const boost::geometry::model::box > &aabb) { typedef typename V2::Type V2T; typedef typename boost::geometry::model::box B2T; T radius2 = radius * radius; bool intersectionLeft = sqr(aabb.min_corner().x() - center.x()) < radius2; bool intersectionRight = sqr(aabb.max_corner().x() - center.x()) < radius2; bool intersectionBottom = sqr(aabb.min_corner().y() - center.y()) < radius2; bool intersectionTop = sqr(aabb.max_corner().y() - center.y()) < radius2; if (! (intersectionLeft || intersectionRight || intersectionTop || intersectionBottom)) // No intersection between the aabb and the center. return boost::geometry::point_in_box()::apply(center, aabb) ? 1.f : 0.f; V2T rect[4] = { aabb.min_corner(), V2T(aabb.max_corner().x(), aabb.min_corner().y()), aabb.max_corner(), V2T(aabb.min_corner().x(), aabb.max_corner().y()) }; int bits_corners = 0; T r2 = sqr(radius); for (int i = 0; i < 4; ++ i, bits_corners <<= 1) bits_corners |= dot(rect[i] - center) >= r2; bits_corners >>= 1; if (bits_corners == 0) { // all inside memcpy(result, rect, sizeof(rect)); memset(result_arc, true, 4); return 4; } if (bits_corners == 0x0f) // all outside return 0; // Some corners are outside, some are inside. Trim the rectangle. int n = 0; for (int i = 0; i < 4; ++ i) { bool inside = (bits_corners & 0x08) == 0; bits_corners <<= 1; V2T chordal_points[2]; int n_chordal_points = line_circle_intersection(rect[i], rect[(i + 1)%4], center, radius, chordal_points); if (n_chordal_points == 2) { result_arc[n] = true; result[n ++] = chordal_points[0]; result_arc[n] = true; result[n ++] = chordal_points[1]; } else { if (inside) { result_arc[n] = false; result[n ++] = rect[i]; } if (n_chordal_points == 1) { result_arc[n] = false; result[n ++] = chordal_points[0]; } } } return n; } */ template inline T polyArea(const boost::geometry::model::d2::point_xy *poly, int n) { T area = T(0); for (int i = 1; i + 1 < n; ++i) area += cross(poly[i] - poly[0], poly[i + 1] - poly[0]); return T(0.5) * area; } template boost::geometry::model::d2::point_xy polyCentroid(const boost::geometry::model::d2::point_xy *poly, int n) { boost::geometry::model::d2::point_xy centroid(T(0), T(0)); for (int i = 0; i < n; ++i) centroid += poly[i]; return (n == 0) ? centroid : (centroid / float(n)); } void gcode_paint_layer( const std::vector &polyline, float width, float thickness, A2f &acc) { int nc = acc.shape()[1]; int nr = acc.shape()[0]; // printf("gcode_paint_layer %d,%d\n", nc, nr); for (size_t iLine = 1; iLine != polyline.size(); ++iLine) { const V2f &p1 = polyline[iLine - 1]; const V2f &p2 = polyline[iLine]; // printf("p1, p2: %f,%f %f,%f\n", p1.x(), p1.y(), p2.x(), p2.y()); const V2f dir = p2 - p1; V2f vperp(- dir.y(), dir.x()); vperp = vperp * 0.5f * width / l2(vperp); // Rectangle of the extrusion. V2f rect[4] = { p1 + vperp, p1 - vperp, p2 - vperp, p2 + vperp }; // Bounding box of the extrusion. B2f bboxLine(rect[0], rect[0]); boost::geometry::expand(bboxLine, rect[1]); boost::geometry::expand(bboxLine, rect[2]); boost::geometry::expand(bboxLine, rect[3]); B2i bboxLinei( V2i(clamp(0, nc-1, int(floor(bboxLine.min_corner().x()))), clamp(0, nr-1, int(floor(bboxLine.min_corner().y())))), V2i(clamp(0, nc-1, int(ceil (bboxLine.max_corner().x()))), clamp(0, nr-1, int(ceil (bboxLine.max_corner().y()))))); // printf("bboxLinei %d,%d %d,%d\n", bboxLinei.min_corner().x(), bboxLinei.min_corner().y(), bboxLinei.max_corner().x(), bboxLinei.max_corner().y()); #ifdef _DEBUG float area = polyArea(rect, 4); assert(area > 0.f); #endif /* _DEBUG */ for (int j = bboxLinei.min_corner().y(); j + 1 < bboxLinei.max_corner().y(); ++ j) { for (int i = bboxLinei.min_corner().x(); i + 1 < bboxLinei.max_corner().x(); ++i) { V2f rect2[8]; memcpy(rect2, rect, sizeof(rect)); int n = clip_rect_by_AABB(rect2, B2f(V2f(float(i), float(j)), V2f(float(i + 1), float(j + 1)))); float area = polyArea(rect2, n); assert(area >= 0.f && area <= 1.000001f); acc[j][i] += area * thickness; } } } } void gcode_paint_bitmap( const std::vector &polyline, float width, A2uc &bitmap, float scale) { int nc = bitmap.shape()[1]; int nr = bitmap.shape()[0]; float r2 = width * width * 0.25f; // printf("gcode_paint_layer %d,%d\n", nc, nr); for (size_t iLine = 1; iLine != polyline.size(); ++iLine) { const V2f &p1 = polyline[iLine - 1]; const V2f &p2 = polyline[iLine]; // printf("p1, p2: %f,%f %f,%f\n", p1.x(), p1.y(), p2.x(), p2.y()); V2f dir = p2 - p1; dir = dir * 0.5f * width / l2(dir); V2f vperp(- dir.y(), dir.x()); // Rectangle of the extrusion. V2f rect[4] = { (p1 + vperp - dir) * scale, (p1 - vperp - dir) * scale, (p2 - vperp + dir) * scale, (p2 + vperp + dir) * scale }; // Bounding box of the extrusion. B2f bboxLine(rect[0], rect[0]); boost::geometry::expand(bboxLine, rect[1]); boost::geometry::expand(bboxLine, rect[2]); boost::geometry::expand(bboxLine, rect[3]); B2i bboxLinei( V2i(clamp(0, nc-1, int(floor(bboxLine.min_corner().x()))), clamp(0, nr-1, int(floor(bboxLine.min_corner().y())))), V2i(clamp(0, nc-1, int(ceil (bboxLine.max_corner().x()))), clamp(0, nr-1, int(ceil (bboxLine.max_corner().y()))))); // printf("bboxLinei %d,%d %d,%d\n", bboxLinei.min_corner().x(), bboxLinei.min_corner().y(), bboxLinei.max_corner().x(), bboxLinei.max_corner().y()); for (int j = bboxLinei.min_corner().y(); j + 1 < bboxLinei.max_corner().y(); ++ j) { for (int i = bboxLinei.min_corner().x(); i + 1 < bboxLinei.max_corner().x(); ++i) { float d2 = dist2_to_line(p1, p2, V2f(float(i) + 0.5f, float(j) + 0.5f) / scale); if (d2 < r2) bitmap[j][i] = 1; } } } } struct Cell { // Cell index in the grid. V2i idx; // Total volume of the material stored in this cell. float volume; // Area covered inside this cell, <0,1>. float area; // Fraction of the area covered by the print head. <0,1> float fraction_covered; // Height of the covered part in excess to the expected layer height. float excess_height; bool operator<(const Cell &c2) const { return this->excess_height < c2.excess_height; } }; struct ExtrusionPoint { V2f center; float radius; float height; }; typedef std::vector ExtrusionPoints; void gcode_spread_points( A2f &acc, const A2f &mask, const ExtrusionPoints &points, ExtrusionSimulationType simulationType) { int nc = acc.shape()[1]; int nr = acc.shape()[0]; // Maximum radius of the spreading points, to allocate a large enough cell array. float rmax = 0.f; for (ExtrusionPoints::const_iterator it = points.begin(); it != points.end(); ++ it) rmax = std::max(rmax, it->radius); size_t n_rows_max = size_t(ceil(rmax * 2.f + 2.f)); size_t n_cells_max = sqr(n_rows_max); std::vector > spans; std::vector cells(n_cells_max, Cell()); std::vector areas_sum(n_cells_max, 0.f); for (ExtrusionPoints::const_iterator it = points.begin(); it != points.end(); ++ it) { const V2f ¢er = it->center; const float radius = it->radius; const float radius2 = radius * radius; const float height_target = it->height; B2f bbox(center - V2f(radius, radius), center + V2f(radius, radius)); B2i bboxi( V2i(clamp(0, nc-1, int(floor(bbox.min_corner().x()))), clamp(0, nr-1, int(floor(bbox.min_corner().y())))), V2i(clamp(0, nc-1, int(ceil (bbox.max_corner().x()))), clamp(0, nr-1, int(ceil (bbox.max_corner().y()))))); /* // Fill in the spans, at which the circle intersects the rows. int row_first = bboxi.min_corner().y(); int row_last = bboxi.max_corner().y(); for (; row_first <= row_last; ++ row_first) { float y = float(j) - center.y(); float discr = radius2 - sqr(y); if (discr > 0) { // Circle intersects the row j at 2 points. float d = sqrt(discr); spans.push_back(std.pair(center.x() - d, center.x() + d))); break; } } for (int j = row_first + 1; j <= row_last; ++ j) { float y = float(j) - center.y(); float discr = radius2 - sqr(y); if (discr > 0) { // Circle intersects the row j at 2 points. float d = sqrt(discr); spans.push_back(std.pair(center.x() - d, center.x() + d))); } else { row_last = j - 1; break; } } */ float area_total = 0; float volume_total = 0; float volume_excess = 0; float volume_deficit = 0; size_t n_cells = 0; float area_circle_total = 0; #if 0 // The intermediate lines. for (int j = row_first; j < row_last; ++ j) { const std::pair &span1 = spans[j]; const std::pair &span2 = spans[j+1]; float l1 = span1.first; float l2 = span2.first; float r1 = span1.second; float r2 = span2.second; if (l2 < l1) std::swap(l1, l2); if (r1 > r2) std::swap(r1, r2); int il1 = int(floor(l1)); int il2 = int(ceil(l2)); int ir1 = int(floor(r1)); int ir2 = int(floor(r2)); assert(il2 <= ir1); for (int i = il1; i < il2; ++ i) { Cell &cell = cells[n_cells ++]; cell.idx.x(i); cell.idx.y(j); cell.area = area; } for (int i = il2; i < ir1; ++ i) { Cell &cell = cells[n_cells ++]; cell.idx.x(i); cell.idx.y(j); cell.area = 1.f; } for (int i = ir1; i < ir2; ++ i) { Cell &cell = cells[n_cells ++]; cell.idx.x(i); cell.idx.y(j); cell.area = area; } } #else for (int j = bboxi.min_corner().y(); j < bboxi.max_corner().y(); ++ j) { for (int i = bboxi.min_corner().x(); i < bboxi.max_corner().x(); ++i) { B2f bb(V2f(float(i), float(j)), V2f(float(i + 1), float(j + 1))); V2f poly[8]; bool poly_arc[8]; int n = clip_circle_by_AABB(center, radius, bb, poly, poly_arc); float area = polyArea(poly, n); assert(area >= 0.f && area <= 1.000001f); if (area == 0.f) continue; Cell &cell = cells[n_cells ++]; cell.idx.x(i); cell.idx.y(j); cell.volume = acc[j][i]; cell.area = mask[j][i]; assert(cell.area >= 0.f && cell.area <= 1.000001f); area_circle_total += area; if (cell.area < area) cell.area = area; cell.fraction_covered = clamp(0.f, 1.f, (cell.area > 0) ? (area / cell.area) : 0); if (cell.fraction_covered == 0) { -- n_cells; continue; } float cell_height = cell.volume / cell.area; cell.excess_height = cell_height - height_target; if (cell.excess_height > 0.f) volume_excess += cell.excess_height * cell.area * cell.fraction_covered; else volume_deficit -= cell.excess_height * cell.area * cell.fraction_covered; volume_total += cell.volume * cell.fraction_covered; area_total += cell.area * cell.fraction_covered; } } #endif float area_circle_total2 = float(M_PI) * sqr(radius); float area_err = fabs(area_circle_total2 - area_circle_total) / area_circle_total2; // printf("area_circle_total: %f, %f, %f\n", area_circle_total, area_circle_total2, area_err); float volume_full = float(M_PI) * sqr(radius) * height_target; // if (true) { // printf("volume_total: %f, volume_full: %f, fill factor: %f\n", volume_total, volume_full, 100.f - 100.f * volume_total / volume_full); // printf("volume_full: %f, volume_excess+deficit: %f, volume_excess: %f, volume_deficit: %f\n", volume_full, volume_excess+volume_deficit, volume_excess, volume_deficit); if (simulationType == ExtrusionSimulationSpreadFull || volume_total <= volume_full) { // The volume under the circle is spreaded fully. float height_avg = volume_total / area_total; for (size_t i = 0; i < n_cells; ++ i) { const Cell &cell = cells[i]; acc[cell.idx.y()][cell.idx.x()] = (1.f - cell.fraction_covered) * cell.volume + cell.fraction_covered * cell.area * height_avg; } } else if (simulationType == ExtrusionSimulationSpreadExcess) { // The volume under the circle does not fit. // 1) Fill the underfilled cells and remove them from the list. float volume_borrowed_total = 0.; for (size_t i = 0; i < n_cells;) { Cell &cell = cells[i]; if (cell.excess_height <= 0) { // Fill in the part of the cell below the circle. float volume_borrowed = - cell.excess_height * cell.area * cell.fraction_covered; assert(volume_borrowed >= 0.f); acc[cell.idx.y()][cell.idx.x()] = cell.volume + volume_borrowed; volume_borrowed_total += volume_borrowed; cell = cells[-- n_cells]; } else ++ i; } // 2) Sort the remaining cells by their excess height. std::sort(cells.begin(), cells.begin() + n_cells); // 3) Prefix sum the areas per excess height. // The excess height is discrete with the number of excess cells. areas_sum[n_cells-1] = cells[n_cells-1].area * cells[n_cells-1].fraction_covered; for (int i = n_cells - 2; i >= 0; -- i) { const Cell &cell = cells[i]; areas_sum[i] = areas_sum[i + 1] + cell.area * cell.fraction_covered; } // 4) Find the excess height, where the volume_excess is over the volume_borrowed_total. float volume_current = 0.f; float excess_height_prev = 0.f; size_t i_top = n_cells; for (size_t i = 0; i < n_cells; ++ i) { const Cell &cell = cells[i]; volume_current += (cell.excess_height - excess_height_prev) * areas_sum[i]; excess_height_prev = cell.excess_height; if (volume_current > volume_borrowed_total) { i_top = i; break; } } // 5) Remove material from the cells with deficit. // First remove all the excess material from the cells, where the deficit is low. for (size_t i = 0; i < i_top; ++ i) { const Cell &cell = cells[i]; float volume_removed = cell.excess_height * cell.area * cell.fraction_covered; acc[cell.idx.y()][cell.idx.x()] = cell.volume - volume_removed; volume_borrowed_total -= volume_removed; } // Second remove some excess material from the cells, where the deficit is high. if (i_top < n_cells) { float height_diff = volume_borrowed_total / areas_sum[i_top]; for (size_t i = i_top; i < n_cells; ++ i) { const Cell &cell = cells[i]; acc[cell.idx.y()][cell.idx.x()] = cell.volume - height_diff * cell.area * cell.fraction_covered; } } } } } inline std::vector CreatePowerColorGradient24bit() { int i; int iColor = 0; std::vector out(6 * 255 + 1, V3uc(0, 0, 0)); for (i = 0; i < 256; ++i) out[iColor++] = V3uc(0, 0, i); for (i = 1; i < 256; ++i) out[iColor++] = V3uc(0, i, 255); for (i = 1; i < 256; ++i) out[iColor++] = V3uc(0, 255, 256 - i); for (i = 1; i < 256; ++i) out[iColor++] = V3uc(i, 255, 0); for (i = 1; i < 256; ++i) out[iColor++] = V3uc(255, 256 - i, 0); for (i = 1; i < 256; ++i) out[iColor++] = V3uc(255, 0, i); return out; } class ExtrusionSimulatorImpl { public: std::vector image_data; A2f accumulator; A2uc bitmap; unsigned int bitmap_oversampled; ExtrusionPoints extrusion_points; // RGB gradient to color map the fullness of an accumulator bucket into the output image. std::vector > color_gradient; }; ExtrusionSimulator::ExtrusionSimulator() : pimpl(new ExtrusionSimulatorImpl) { pimpl->color_gradient = CreatePowerColorGradient24bit(); pimpl->bitmap_oversampled = 4; } ExtrusionSimulator::~ExtrusionSimulator() { delete pimpl; pimpl = NULL; } void ExtrusionSimulator::set_image_size(const Point &image_size) { // printf("ExtrusionSimulator::set_image_size()\n"); if (this->image_size.x() == image_size.x() && this->image_size.y() == image_size.y()) return; // printf("Setting image size: %d, %d\n", image_size.x, image_size.y); this->image_size = image_size; // Allocate the image data in an RGBA format. // printf("Allocating image data, size %d\n", image_size.x * image_size.y * 4); pimpl->image_data.assign(image_size.x() * image_size.y() * 4, 0); // printf("Allocating image data, allocated\n"); //FIXME fill the image with red vertical lines. for (size_t r = 0; r < image_size.y(); ++ r) { for (size_t c = 0; c < image_size.x(); c += 2) { // Color red pimpl->image_data[r * image_size.x() * 4 + c * 4] = 255; // Opacity full pimpl->image_data[r * image_size.x() * 4 + c * 4 + 3] = 255; } } // printf("Allocating image data, set\n"); } void ExtrusionSimulator::set_viewport(const BoundingBox &viewport) { // printf("ExtrusionSimulator::set_viewport(%d, %d, %d, %d)\n", viewport.min.x, viewport.min.y, viewport.max.x, viewport.max.y); if (this->viewport != viewport) { this->viewport = viewport; Point sz = viewport.size(); pimpl->accumulator.resize(boost::extents[sz.y()][sz.x()]); pimpl->bitmap.resize(boost::extents[sz.y()*pimpl->bitmap_oversampled][sz.x()*pimpl->bitmap_oversampled]); // printf("Accumulator size: %d, %d\n", sz.y, sz.x); } } void ExtrusionSimulator::set_bounding_box(const BoundingBox &bbox) { this->bbox = bbox; } const void* ExtrusionSimulator::image_ptr() const { return (pimpl->image_data.empty()) ? NULL : (void*)&pimpl->image_data.front(); } void ExtrusionSimulator::reset_accumulator() { // printf("ExtrusionSimulator::reset_accumulator()\n"); Point sz = viewport.size(); // printf("Reset accumulator, Accumulator size: %d, %d\n", sz.y, sz.x); memset(&pimpl->accumulator[0][0], 0, sizeof(float) * sz.x() * sz.y()); memset(&pimpl->bitmap[0][0], 0, sz.x() * sz.y() * pimpl->bitmap_oversampled * pimpl->bitmap_oversampled); pimpl->extrusion_points.clear(); // printf("Reset accumulator, done.\n"); } void ExtrusionSimulator::extrude_to_accumulator(const ExtrusionPath &path, const Point &shift, ExtrusionSimulationType simulationType) { // printf("Extruding a path. Nr points: %d, width: %f, height: %f\r\n", path.polyline.points.size(), path.width, path.height); // Convert the path to V2f points, shift and scale them to the viewport. std::vector polyline; polyline.reserve(path.polyline.points.size()); float scalex = float(viewport.size().x()) / float(bbox.size().x()); float scaley = float(viewport.size().y()) / float(bbox.size().y()); float w = scale_(path.width) * scalex; float h = scale_(path.height) * scalex; w = scale_(path.mm3_per_mm / path.height) * scalex; // printf("scalex: %f, scaley: %f\n", scalex, scaley); // printf("bbox: %d,%d %d,%d\n", bbox.min.x(), bbox.min.y, bbox.max.x(), bbox.max.y); for (Points::const_iterator it = path.polyline.points.begin(); it != path.polyline.points.end(); ++ it) { // printf("point %d,%d\n", it->x+shift.x(), it->y+shift.y); ExtrusionPoint ept; ept.center = V2f(float(it->x()+shift.x()-bbox.min.x()) * scalex, float(it->y()+shift.y()-bbox.min.y()) * scaley); ept.radius = w/2.f; ept.height = 0.5f; polyline.push_back(ept.center); pimpl->extrusion_points.push_back(ept); } // Extrude the polyline into an accumulator. // printf("width scaled: %f, height scaled: %f\n", w, h); gcode_paint_layer(polyline, w, 0.5f, pimpl->accumulator); if (simulationType > ExtrusionSimulationDontSpread) gcode_paint_bitmap(polyline, w, pimpl->bitmap, pimpl->bitmap_oversampled); // double path.mm3_per_mm; // mm^3 of plastic per mm of linear head motion // float path.width; // float path.height; } void ExtrusionSimulator::evaluate_accumulator(ExtrusionSimulationType simulationType) { // printf("ExtrusionSimulator::evaluate_accumulator()\n"); Point sz = viewport.size(); if (simulationType > ExtrusionSimulationDontSpread) { // Average the cells of a bitmap into a lower resolution floating point mask. A2f mask(boost::extents[sz.y()][sz.x()]); for (int r = 0; r < sz.y(); ++r) { for (int c = 0; c < sz.x(); ++c) { float p = 0; for (int j = 0; j < pimpl->bitmap_oversampled; ++ j) { for (int i = 0; i < pimpl->bitmap_oversampled; ++ i) { if (pimpl->bitmap[r * pimpl->bitmap_oversampled + j][c * pimpl->bitmap_oversampled + i]) p += 1.f; } } p /= float(pimpl->bitmap_oversampled * pimpl->bitmap_oversampled * 2); mask[r][c] = p; } } // Spread the excess of the material. gcode_spread_points(pimpl->accumulator, mask, pimpl->extrusion_points, simulationType); } // Color map the accumulator. for (int r = 0; r < sz.y(); ++r) { unsigned char *ptr = &pimpl->image_data[(image_size.x() * (viewport.min.y() + r) + viewport.min.x()) * 4]; for (int c = 0; c < sz.x(); ++c) { #if 1 float p = pimpl->accumulator[r][c]; #else float p = mask[r][c]; #endif int idx = int(floor(p * float(pimpl->color_gradient.size()) + 0.5f)); V3uc clr = pimpl->color_gradient[clamp(0, int(pimpl->color_gradient.size()-1), idx)]; *ptr ++ = clr.get<0>(); *ptr ++ = clr.get<1>(); *ptr ++ = clr.get<2>(); *ptr ++ = (idx == 0) ? 0 : 255; } } } } // namespace Slic3r