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geometry.cpp
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geometry.cpp
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#include <iostream>
#include <fstream>
#include <string>
#include <stack>
#include <vector>
#include <map>
#include <algorithm>
#include <cstdio>
#include <unistd.h>
#include <cmath>
#include <limits.h>
#include <sqlite3.h>
#include <mapbox/geometry/point.hpp>
#include <mapbox/geometry/multi_polygon.hpp>
#include <mapbox/geometry/snap_rounding.hpp>
#include "geometry.hpp"
#include "projection.hpp"
#include "serial.hpp"
#include "main.hpp"
#include "options.hpp"
#include "errors.hpp"
#include "projection.hpp"
drawvec decode_geometry(char **meta, int z, unsigned tx, unsigned ty, long long *bbox, unsigned initial_x, unsigned initial_y) {
drawvec out;
bbox[0] = LLONG_MAX;
bbox[1] = LLONG_MAX;
bbox[2] = LLONG_MIN;
bbox[3] = LLONG_MIN;
long long wx = initial_x, wy = initial_y;
while (1) {
draw d;
deserialize_byte(meta, &d.op);
if (d.op == VT_END) {
break;
}
if (d.op == VT_MOVETO || d.op == VT_LINETO) {
long long dx, dy;
deserialize_long_long(meta, &dx);
deserialize_long_long(meta, &dy);
wx += dx * (1 << geometry_scale);
wy += dy * (1 << geometry_scale);
long long wwx = wx;
long long wwy = wy;
if (z != 0) {
wwx -= tx << (32 - z);
wwy -= ty << (32 - z);
}
if (wwx < bbox[0]) {
bbox[0] = wwx;
}
if (wwy < bbox[1]) {
bbox[1] = wwy;
}
if (wwx > bbox[2]) {
bbox[2] = wwx;
}
if (wwy > bbox[3]) {
bbox[3] = wwy;
}
d.x = wwx;
d.y = wwy;
}
out.push_back(d);
}
return out;
}
/* pnpoly:
Copyright (c) 1970-2003, Wm. Randolph Franklin
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimers.
Redistributions in binary form must reproduce the above copyright notice in the documentation and/or other materials provided with the distribution.
The name of W. Randolph Franklin may not be used to endorse or promote products derived from this Software without specific prior written permission.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
int pnpoly(const drawvec &vert, size_t start, size_t nvert, long long testx, long long testy) {
size_t i, j;
bool c = false;
for (i = 0, j = nvert - 1; i < nvert; j = i++) {
if (((vert[i + start].y > testy) != (vert[j + start].y > testy)) &&
(testx < (vert[j + start].x - vert[i + start].x) * (testy - vert[i + start].y) / (double) (vert[j + start].y - vert[i + start].y) + vert[i + start].x))
c = !c;
}
return c;
}
void check_polygon(drawvec &geom) {
geom = remove_noop(geom, VT_POLYGON, 0);
mapbox::geometry::multi_polygon<long long> mp;
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_MOVETO) {
size_t j;
for (j = i + 1; j < geom.size(); j++) {
if (geom[j].op != VT_LINETO) {
break;
}
}
if (j >= i + 4) {
mapbox::geometry::linear_ring<long long> lr;
for (size_t k = i; k < j; k++) {
lr.push_back(mapbox::geometry::point<long long>(geom[k].x, geom[k].y));
}
if (lr.size() >= 3) {
mapbox::geometry::polygon<long long> p;
p.push_back(lr);
mp.push_back(p);
}
}
i = j - 1;
}
}
mapbox::geometry::multi_polygon<long long> mp2 = mapbox::geometry::snap_round(mp, true, true);
if (mp != mp2) {
fprintf(stderr, "Internal error: self-intersecting polygon\n");
}
size_t outer_start = -1;
size_t outer_len = 0;
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_MOVETO) {
size_t j;
for (j = i + 1; j < geom.size(); j++) {
if (geom[j].op != VT_LINETO) {
break;
}
}
double area = get_area(geom, i, j);
if (area > 0) {
outer_start = i;
outer_len = j - i;
} else {
for (size_t k = i; k < j; k++) {
if (!pnpoly(geom, outer_start, outer_len, geom[k].x, geom[k].y)) {
bool on_edge = false;
for (size_t l = outer_start; l < outer_start + outer_len; l++) {
if (geom[k].x == geom[l].x || geom[k].y == geom[l].y) {
on_edge = true;
break;
}
}
if (!on_edge) {
fprintf(stderr, "%lld,%lld at %lld not in outer ring (%lld to %lld)\n", geom[k].x, geom[k].y, (long long) k, (long long) outer_start, (long long) (outer_start + outer_len));
}
}
}
}
}
}
}
drawvec reduce_tiny_poly(drawvec &geom, int z, int detail, bool *still_needs_simplification, bool *reduced_away, double *accum_area, serial_feature *this_feature, serial_feature *tiny_feature) {
drawvec out;
const double pixel = (1LL << (32 - detail - z)) * (double) tiny_polygon_size;
bool includes_real = false;
bool includes_dust = false;
bool included_last_outer = false;
*still_needs_simplification = false;
*reduced_away = false;
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_MOVETO) {
size_t j;
for (j = i + 1; j < geom.size(); j++) {
if (geom[j].op != VT_LINETO) {
break;
}
}
double area = get_area(geom, i, j);
// XXX There is an ambiguity here: If the area of a ring is 0 and it is followed by holes,
// we don't know whether the area-0 ring was a hole too or whether it was the outer ring
// that these subsequent holes are somehow being subtracted from. I hope that if a polygon
// was simplified down to nothing, its holes also became nothing.
if (area != 0) {
// These are pixel coordinates, so area > 0 for the outer ring.
// If the outer ring of a polygon was reduced to a pixel, its
// inner rings must just have their area de-accumulated rather
// than being drawn since we don't really know where they are.
// i.e., this outer ring is small enough that we are including it
// in a tiny polygon rather than letting it represent itself,
// OR it is an inner ring and we haven't output an outer ring for it to be
// cut out of, so we are just subtracting its area from the tiny polygon
// rather than trying to deal with it geometrically
if ((area > 0 && area <= pixel * pixel) || (area < 0 && !included_last_outer)) {
*accum_area += area;
*reduced_away = true;
if (area > 0 && *accum_area > pixel * pixel) {
// XXX use centroid;
out.push_back(draw(VT_MOVETO, geom[i].x - pixel / 2, geom[i].y - pixel / 2));
out.push_back(draw(VT_LINETO, geom[i].x - pixel / 2 + pixel, geom[i].y - pixel / 2));
out.push_back(draw(VT_LINETO, geom[i].x - pixel / 2 + pixel, geom[i].y - pixel / 2 + pixel));
out.push_back(draw(VT_LINETO, geom[i].x - pixel / 2, geom[i].y - pixel / 2 + pixel));
out.push_back(draw(VT_LINETO, geom[i].x - pixel / 2, geom[i].y - pixel / 2));
includes_dust = true;
*accum_area -= pixel * pixel;
}
if (area > 0) {
included_last_outer = false;
}
}
// i.e., this ring is large enough that it gets to represent itself
// or it is a tiny hole out of a real polygon, which we are still treating
// as a real geometry because otherwise we can accumulate enough tiny holes
// that we will drop the next several outer rings getting back up to 0.
else {
for (size_t k = i; k < j && k < geom.size(); k++) {
out.push_back(geom[k]);
}
// which means that the overall polygon has a real geometry,
// which means that it gets to be simplified.
*still_needs_simplification = true;
includes_real = true;
if (area > 0) {
included_last_outer = true;
}
}
} else {
// area is 0: doesn't count as either having been reduced away,
// since it was probably just degenerate from having been clipped,
// or as needing simplification, since it produces no output.
}
i = j - 1;
} else {
fprintf(stderr, "how did we get here with %d in %d?\n", geom[i].op, (int) geom.size());
for (size_t n = 0; n < geom.size(); n++) {
fprintf(stderr, "%d/%lld/%lld ", geom[n].op, geom[n].x, geom[n].y);
}
fprintf(stderr, "\n");
out.push_back(geom[i]);
includes_real = true;
}
}
if (!includes_real) {
if (includes_dust) {
// this geometry is just dust, so if there is another feature that
// contributed to the dust that is larger than this feature,
// keep its attributes instead of this one that just happened to be
// the one that hit the threshold of survival.
if (tiny_feature->extent > this_feature->extent) {
*this_feature = *tiny_feature;
tiny_feature->extent = 0;
}
} else {
// this is a feature that we are throwing away, so hang on to it
// attributes if it is bigger than the biggest one we threw away so far
if (this_feature->extent > tiny_feature->extent) {
*tiny_feature = *this_feature;
}
}
}
return out;
}
int quick_check(long long *bbox, int z, long long buffer) {
long long min = 0;
long long area = 1LL << (32 - z);
// bbox entirely within the tile proper
if (bbox[0] > min && bbox[1] > min && bbox[2] < area && bbox[3] < area) {
return 1;
}
min -= buffer * area / 256;
area += buffer * area / 256;
// bbox entirely within the tile, including its buffer
if (bbox[0] > min && bbox[1] > min && bbox[2] < area && bbox[3] < area) {
return 3;
}
// bbox entirely outside the tile
if (bbox[0] > area || bbox[1] > area) {
return 0;
}
if (bbox[2] < min || bbox[3] < min) {
return 0;
}
// some overlap of edge
return 2;
}
bool point_within_tile(long long x, long long y, int z) {
// No adjustment for buffer, because the point must be
// strictly within the tile to appear exactly once
long long area = 1LL << (32 - z);
return x >= 0 && y >= 0 && x < area && y < area;
}
double distance_from_line(long long point_x, long long point_y, long long segA_x, long long segA_y, long long segB_x, long long segB_y) {
long long p2x = segB_x - segA_x;
long long p2y = segB_y - segA_y;
double something = p2x * p2x + p2y * p2y;
double u = (0 == something) ? 0 : ((point_x - segA_x) * p2x + (point_y - segA_y) * p2y) / (something);
if (u >= 1) {
u = 1;
} else if (u <= 0) {
u = 0;
}
double x = segA_x + u * p2x;
double y = segA_y + u * p2y;
double dx = x - point_x;
double dy = y - point_y;
double out = std::round(sqrt(dx * dx + dy * dy) * 16.0) / 16.0;
return out;
}
// https://github.com/Project-OSRM/osrm-backend/blob/733d1384a40f/Algorithms/DouglasePeucker.cpp
static void douglas_peucker(drawvec &geom, int start, int n, double e, size_t kept, size_t retain) {
std::stack<int> recursion_stack;
if (!geom[start + 0].necessary || !geom[start + n - 1].necessary) {
fprintf(stderr, "endpoints not marked necessary\n");
exit(EXIT_IMPOSSIBLE);
}
int prev = 0;
for (int here = 1; here < n; here++) {
if (geom[start + here].necessary) {
recursion_stack.push(prev);
recursion_stack.push(here);
prev = here;
if (prevent[P_SIMPLIFY_SHARED_NODES]) {
if (retain > 0) {
retain--;
}
}
}
}
// These segments are put on the stack from start to end,
// independent of winding, so note that anything that uses
// "retain" to force it to keep at least N points will
// keep a different set of points when wound one way than
// when wound the other way.
while (!recursion_stack.empty()) {
// pop next element
int second = recursion_stack.top();
recursion_stack.pop();
int first = recursion_stack.top();
recursion_stack.pop();
double max_distance = -1;
int farthest_element_index;
// find index idx of element with max_distance
int i;
if (geom[start + first] < geom[start + second]) {
farthest_element_index = first;
for (i = first + 1; i < second; i++) {
double temp_dist = distance_from_line(geom[start + i].x, geom[start + i].y, geom[start + first].x, geom[start + first].y, geom[start + second].x, geom[start + second].y);
double distance = std::fabs(temp_dist);
if ((distance > e || kept < retain) && (distance > max_distance || (distance == max_distance && geom[start + i] < geom[start + farthest_element_index]))) {
farthest_element_index = i;
max_distance = distance;
}
}
} else {
farthest_element_index = second;
for (i = second - 1; i > first; i--) {
double temp_dist = distance_from_line(geom[start + i].x, geom[start + i].y, geom[start + second].x, geom[start + second].y, geom[start + first].x, geom[start + first].y);
double distance = std::fabs(temp_dist);
if ((distance > e || kept < retain) && (distance > max_distance || (distance == max_distance && geom[start + i] < geom[start + farthest_element_index]))) {
farthest_element_index = i;
max_distance = distance;
}
}
}
if (max_distance >= 0) {
// mark idx as necessary
geom[start + farthest_element_index].necessary = 1;
kept++;
if (geom[start + first] < geom[start + second]) {
if (1 < farthest_element_index - first) {
recursion_stack.push(first);
recursion_stack.push(farthest_element_index);
}
if (1 < second - farthest_element_index) {
recursion_stack.push(farthest_element_index);
recursion_stack.push(second);
}
} else {
if (1 < second - farthest_element_index) {
recursion_stack.push(farthest_element_index);
recursion_stack.push(second);
}
if (1 < farthest_element_index - first) {
recursion_stack.push(first);
recursion_stack.push(farthest_element_index);
}
}
}
}
}
// If any line segment crosses a tile boundary, add a node there
// that cannot be simplified away, to prevent the edge of any
// feature from jumping abruptly at the tile boundary.
drawvec impose_tile_boundaries(drawvec &geom, long long extent) {
drawvec out;
for (size_t i = 0; i < geom.size(); i++) {
if (i > 0 && geom[i].op == VT_LINETO && (geom[i - 1].op == VT_MOVETO || geom[i - 1].op == VT_LINETO)) {
long long x1 = geom[i - 1].x;
long long y1 = geom[i - 1].y;
long long x2 = geom[i - 0].x;
long long y2 = geom[i - 0].y;
int c = clip(&x1, &y1, &x2, &y2, 0, 0, extent, extent);
if (c > 1) { // clipped
if (x1 != geom[i - 1].x || y1 != geom[i - 1].y) {
out.push_back(draw(VT_LINETO, x1, y1));
out[out.size() - 1].necessary = 1;
}
if (x2 != geom[i - 0].x || y2 != geom[i - 0].y) {
out.push_back(draw(VT_LINETO, x2, y2));
out[out.size() - 1].necessary = 1;
}
}
}
out.push_back(geom[i]);
}
return out;
}
drawvec simplify_lines(drawvec &geom, int z, int tx, int ty, int detail, bool mark_tile_bounds, double simplification, size_t retain, drawvec const &shared_nodes, struct node *shared_nodes_map, size_t nodepos) {
int res = 1 << (32 - detail - z);
long long area = 1LL << (32 - z);
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_MOVETO) {
geom[i].necessary = 1;
} else if (geom[i].op == VT_LINETO) {
geom[i].necessary = 0;
// if this is actually the endpoint, not an intermediate point,
// it will be marked as necessary below
} else {
geom[i].necessary = 1;
}
if (prevent[P_SIMPLIFY_SHARED_NODES]) {
// This is kind of weird, because we have two lists of shared nodes to look through:
// * the drawvec, which is nodes that were introduced during clipping to the tile edge,
// and which are in local tile coordinates
// * the shared_nodes_map, which was made globally before tiling began, and which
// is in global quadkey coordinates.
// To look through the latter, we need to offset and encode the coordinates
// of the feature we are simplifying.
auto pt = std::lower_bound(shared_nodes.begin(), shared_nodes.end(), geom[i]);
if (pt != shared_nodes.end() && *pt == geom[i]) {
geom[i].necessary = true;
}
if (nodepos > 0) {
// offset to global
draw d = geom[i];
if (z != 0) {
d.x += tx * (1LL << (32 - z));
d.y += ty * (1LL << (32 - z));
}
// to quadkey
struct node n;
n.index = encode_quadkey((unsigned) d.x, (unsigned) d.y);
if (bsearch(&n, shared_nodes_map, nodepos / sizeof(node), sizeof(node), nodecmp) != NULL) {
geom[i].necessary = true;
}
}
}
}
if (mark_tile_bounds) {
geom = impose_tile_boundaries(geom, area);
}
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_MOVETO) {
size_t j;
for (j = i + 1; j < geom.size(); j++) {
if (geom[j].op != VT_LINETO) {
break;
}
}
geom[i].necessary = 1;
geom[j - 1].necessary = 1;
// empirical mapping from douglas-peucker simplifications
// to visvalingam simplifications that yield similar
// output sizes
double sim = simplification * (0.1596 * z + 0.878);
double scale = (res * sim) * (res * sim);
scale = exp(1.002 * log(scale) + 0.3043);
if (j - i > 1) {
if (additional[A_VISVALINGAM]) {
visvalingam(geom, i, j, scale, retain);
} else {
douglas_peucker(geom, i, j - i, res * simplification, 2, retain);
}
}
i = j - 1;
}
}
drawvec out;
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].necessary) {
out.push_back(geom[i]);
}
}
return out;
}
drawvec reorder_lines(drawvec &geom) {
// Only reorder simple linestrings with a single moveto
if (geom.size() == 0) {
return geom;
}
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_MOVETO) {
if (i != 0) {
// moveto is not at the start, so it is not simple
return geom;
}
} else if (geom[i].op == VT_LINETO) {
if (i == 0) {
// lineto is at the start: can't happen
return geom;
}
} else {
// something other than moveto or lineto: can't happen
return geom;
}
}
// Reorder anything that goes up and to the left
// instead of down and to the right
// so that it will coalesce better
unsigned long long l1 = encode_index(geom[0].x, geom[0].y);
unsigned long long l2 = encode_index(geom[geom.size() - 1].x, geom[geom.size() - 1].y);
if (l1 > l2) {
drawvec out;
for (size_t i = 0; i < geom.size(); i++) {
out.push_back(geom[geom.size() - 1 - i]);
}
out[0].op = VT_MOVETO;
if (out.size() > 1) {
out[out.size() - 1].op = VT_LINETO;
}
return out;
}
return geom;
}
drawvec fix_polygon(drawvec &geom) {
int outer = 1;
drawvec out;
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_CLOSEPATH) {
outer = 1;
} else if (geom[i].op == VT_MOVETO) {
// Find the end of the ring
size_t j;
for (j = i + 1; j < geom.size(); j++) {
if (geom[j].op != VT_LINETO) {
break;
}
}
// A polygon ring must contain at least three points
// (and really should contain four). If this one does
// not have enough, avoid a division by zero trying to
// calculate the centroid below.
if (j - i < 3) {
i = j - 1;
outer = 0;
continue;
}
// Make a temporary copy of the ring.
// Close it if it isn't closed.
drawvec ring;
for (size_t a = i; a < j; a++) {
ring.push_back(geom[a]);
}
if (j - i != 0 && (ring[0].x != ring[j - i - 1].x || ring[0].y != ring[j - i - 1].y)) {
ring.push_back(ring[0]);
}
// Reverse ring if winding order doesn't match
// inner/outer expectation
bool reverse_ring = false;
if (prevent[P_USE_SOURCE_POLYGON_WINDING]) {
// GeoJSON winding is reversed from vector winding
reverse_ring = true;
} else if (prevent[P_REVERSE_SOURCE_POLYGON_WINDING]) {
// GeoJSON winding is reversed from vector winding
reverse_ring = false;
} else {
double area = get_area(ring, 0, ring.size());
if ((area > 0) != outer) {
reverse_ring = true;
}
}
if (reverse_ring) {
drawvec tmp;
for (int a = ring.size() - 1; a >= 0; a--) {
tmp.push_back(ring[a]);
}
ring = tmp;
}
// Now we are rotating the ring to make the first/last point
// one that would be unlikely to be simplified away.
// calculate centroid
// a + 1 < size() because point 0 is duplicated at the end
long long xtotal = 0;
long long ytotal = 0;
long long count = 0;
for (size_t a = 0; a + 1 < ring.size(); a++) {
xtotal += ring[a].x;
ytotal += ring[a].y;
count++;
}
xtotal /= count;
ytotal /= count;
// figure out which point is furthest from the centroid
long long dist2 = 0;
long long furthest = 0;
for (size_t a = 0; a + 1 < ring.size(); a++) {
// division by 16 because these are z0 coordinates and we need to avoid overflow
long long xd = (ring[a].x - xtotal) / 16;
long long yd = (ring[a].y - ytotal) / 16;
long long d2 = xd * xd + yd * yd;
if (d2 > dist2 || (d2 == dist2 && ring[a] < ring[furthest])) {
dist2 = d2;
furthest = a;
}
}
// then figure out which point is furthest from *that*,
// which will hopefully be a good origin point since it should be
// at a far edge of the shape.
long long dist2b = 0;
long long furthestb = 0;
for (size_t a = 0; a + 1 < ring.size(); a++) {
// division by 16 because these are z0 coordinates and we need to avoid overflow
long long xd = (ring[a].x - ring[furthest].x) / 16;
long long yd = (ring[a].y - ring[furthest].y) / 16;
long long d2 = xd * xd + yd * yd;
if (d2 > dist2b || (d2 == dist2b && ring[a] < ring[furthestb])) {
dist2b = d2;
furthestb = a;
}
}
// rotate ring so the furthest point is the duplicated one.
// the idea is that simplification will then be more efficient,
// never wasting the start and end points, which are always retained,
// on a point that has little impact on the shape.
// Copy ring into output, fixing the moveto/lineto ops if necessary because of
// reversal or closing
for (size_t a = 0; a < ring.size(); a++) {
size_t a2 = (a + furthestb) % (ring.size() - 1);
if (a == 0) {
out.push_back(draw(VT_MOVETO, ring[a2].x, ring[a2].y));
} else {
out.push_back(draw(VT_LINETO, ring[a2].x, ring[a2].y));
}
}
// Next ring or polygon begins on the non-lineto that ended this one
// and is not an outer ring unless there is a terminator first
i = j - 1;
outer = 0;
} else {
fprintf(stderr, "Internal error: polygon ring begins with %d, not moveto\n", geom[i].op);
exit(EXIT_IMPOSSIBLE);
}
}
return out;
}
#if 0
std::vector<drawvec> chop_polygon(std::vector<drawvec> &geoms) {
while (1) {
bool again = false;
std::vector<drawvec> out;
for (size_t i = 0; i < geoms.size(); i++) {
if (geoms[i].size() > 700) {
static bool warned = false;
if (!warned) {
fprintf(stderr, "Warning: splitting up polygon with more than 700 sides\n");
warned = true;
}
long long midx = 0, midy = 0, count = 0;
long long maxx = LLONG_MIN, maxy = LLONG_MIN, minx = LLONG_MAX, miny = LLONG_MAX;
for (size_t j = 0; j < geoms[i].size(); j++) {
if (geoms[i][j].op == VT_MOVETO || geoms[i][j].op == VT_LINETO) {
midx += geoms[i][j].x;
midy += geoms[i][j].y;
count++;
if (geoms[i][j].x > maxx) {
maxx = geoms[i][j].x;
}
if (geoms[i][j].y > maxy) {
maxy = geoms[i][j].y;
}
if (geoms[i][j].x < minx) {
minx = geoms[i][j].x;
}
if (geoms[i][j].y < miny) {
miny = geoms[i][j].y;
}
}
}
midx /= count;
midy /= count;
drawvec c1, c2;
if (maxy - miny > maxx - minx) {
c1 = simple_clip_poly(geoms[i], minx, miny, maxx, midy, prevent[P_SIMPLIFY_EDGE_NODES]);
c2 = simple_clip_poly(geoms[i], minx, midy, maxx, maxy, prevent[P_SIMPLIFY_EDGE_NODES]);
} else {
c1 = simple_clip_poly(geoms[i], minx, miny, midx, maxy, prevent[P_SIMPLIFY_EDGE_NODES]);
c2 = simple_clip_poly(geoms[i], midx, miny, maxx, maxy, prevent[P_SIMPLIFY_EDGE_NODES]);
}
if (c1.size() >= geoms[i].size()) {
fprintf(stderr, "Subdividing complex polygon failed\n");
} else {
out.push_back(c1);
}
if (c2.size() >= geoms[i].size()) {
fprintf(stderr, "Subdividing complex polygon failed\n");
} else {
out.push_back(c2);
}
again = true;
} else {
out.push_back(geoms[i]);
}
}
if (!again) {
return out;
}
geoms = out;
}
}
#endif
drawvec stairstep(drawvec &geom, int z, int detail) {
drawvec out;
double scale = 1 << (32 - detail - z);
for (size_t i = 0; i < geom.size(); i++) {
geom[i].x = std::round(geom[i].x / scale);
geom[i].y = std::round(geom[i].y / scale);
}
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_MOVETO) {
out.push_back(geom[i]);
} else if (out.size() > 0) {
long long x0 = out[out.size() - 1].x;
long long y0 = out[out.size() - 1].y;
long long x1 = geom[i].x;
long long y1 = geom[i].y;
bool swap = false;
if (y0 < y1) {
swap = true;
std::swap(x0, x1);
std::swap(y0, y1);
}
long long xx = x0, yy = y0;
long long dx = std::abs(x1 - x0);
long long sx = (x0 < x1) ? 1 : -1;
long long dy = std::abs(y1 - y0);
long long sy = (y0 < y1) ? 1 : -1;
long long err = ((dx > dy) ? dx : -dy) / 2;
int last = -1;
drawvec tmp;
tmp.push_back(draw(VT_LINETO, xx, yy));
while (xx != x1 || yy != y1) {
long long e2 = err;
if (e2 > -dx) {
err -= dy;
xx += sx;
if (last == 1) {
tmp[tmp.size() - 1] = draw(VT_LINETO, xx, yy);
} else {
tmp.push_back(draw(VT_LINETO, xx, yy));
}
last = 1;
}
if (e2 < dy) {
err += dx;
yy += sy;
if (last == 2) {
tmp[tmp.size() - 1] = draw(VT_LINETO, xx, yy);
} else {
tmp.push_back(draw(VT_LINETO, xx, yy));
}
last = 2;
}
}
if (swap) {
for (size_t j = tmp.size(); j > 0; j--) {
out.push_back(tmp[j - 1]);
}
} else {
for (size_t j = 0; j < tmp.size(); j++) {
out.push_back(tmp[j]);
}
}
// out.push_back(draw(VT_LINETO, xx, yy));
} else {
fprintf(stderr, "Can't happen: stairstepping lineto with no moveto\n");
exit(EXIT_IMPOSSIBLE);
}
}
for (size_t i = 0; i < out.size(); i++) {
out[i].x *= 1 << (32 - detail - z);
out[i].y *= 1 << (32 - detail - z);
}
return out;
}
// https://github.com/Turfjs/turf/blob/master/packages/turf-center-of-mass/index.ts
//
// The MIT License (MIT)
//
// Copyright (c) 2019 Morgan Herlocker
//
// Permission is hereby granted, free of charge, to any person obtaining a copy of
// this software and associated documentation files (the "Software"), to deal in
// the Software without restriction, including without limitation the rights to
// use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
// the Software, and to permit persons to whom the Software is furnished to do so,
// subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
// FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
// COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
// IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
// CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
draw centerOfMass(const drawvec &dv, size_t start, size_t end, draw centre) {
std::vector<draw> coords;
for (size_t i = start; i < end; i++) {
coords.push_back(dv[i]);
}
// First, we neutralize the feature (set it around coordinates [0,0]) to prevent rounding errors
// We take any point to translate all the points around 0
draw translation = centre;
double sx = 0;
double sy = 0;
double sArea = 0;
draw pi, pj;
double xi, xj, yi, yj, a;
std::vector<draw> neutralizedPoints;
for (size_t i = 0; i < coords.size(); i++) {
neutralizedPoints.push_back(draw(coords[i].op, coords[i].x - translation.x, coords[i].y - translation.y));
}
for (size_t i = 0; i < coords.size() - 1; i++) {
// pi is the current point
pi = neutralizedPoints[i];
xi = pi.x;
yi = pi.y;
// pj is the next point (pi+1)
pj = neutralizedPoints[i + 1];
xj = pj.x;
yj = pj.y;
// a is the common factor to compute the signed area and the final coordinates
a = xi * yj - xj * yi;
// sArea is the sum used to compute the signed area
sArea += a;
// sx and sy are the sums used to compute the final coordinates
sx += (xi + xj) * a;
sy += (yi + yj) * a;
}
// Shape has no area: fallback on turf.centroid
if (sArea == 0) {
return centre;
} else {
// Compute the signed area, and factorize 1/6A
double area = sArea * 0.5;
double areaFactor = 1 / (6 * area);