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clip.cpp
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clip.cpp
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#include <stdlib.h>
#include <mapbox/geometry/point.hpp>
#include <mapbox/geometry/multi_polygon.hpp>
#include <mapbox/geometry/wagyu/wagyu.hpp>
#include <limits.h>
#include "geometry.hpp"
#include "errors.hpp"
#include "compression.hpp"
#include "mvt.hpp"
static std::vector<std::pair<double, double>> clip_poly1(std::vector<std::pair<double, double>> &geom,
long long minx, long long miny, long long maxx, long long maxy,
long long ax, long long ay, long long bx, long long by, drawvec &edge_nodes,
bool prevent_simplify_shared_nodes);
drawvec simple_clip_poly(drawvec &geom, long long minx, long long miny, long long maxx, long long maxy,
long long ax, long long ay, long long bx, long long by, drawvec &edge_nodes, bool prevent_simplify_shared_nodes) {
drawvec out;
if (prevent_simplify_shared_nodes) {
geom = remove_noop(geom, VT_POLYGON, 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;
}
}
std::vector<std::pair<double, double>> tmp;
for (size_t k = i; k < j; k++) {
double x = geom[k].x;
double y = geom[k].y;
tmp.emplace_back(x, y);
}
tmp = clip_poly1(tmp, minx, miny, maxx, maxy, ax, ay, bx, by, edge_nodes, prevent_simplify_shared_nodes);
if (tmp.size() > 0) {
if (tmp[0].first != tmp[tmp.size() - 1].first || tmp[0].second != tmp[tmp.size() - 1].second) {
fprintf(stderr, "Internal error: Polygon ring not closed\n");
exit(EXIT_FAILURE);
}
}
for (size_t k = 0; k < tmp.size(); k++) {
if (k == 0) {
out.push_back(draw(VT_MOVETO, std::round(tmp[k].first), std::round(tmp[k].second)));
} else {
out.push_back(draw(VT_LINETO, std::round(tmp[k].first), std::round(tmp[k].second)));
}
}
i = j - 1;
} else {
fprintf(stderr, "Unexpected operation in polygon %d\n", (int) geom[i].op);
exit(EXIT_IMPOSSIBLE);
}
}
return out;
}
drawvec simple_clip_poly(drawvec &geom, long long minx, long long miny, long long maxx, long long maxy, bool prevent_simplify_shared_nodes) {
drawvec dv;
return simple_clip_poly(geom, minx, miny, maxx, maxy, minx, miny, maxx, maxy, dv, prevent_simplify_shared_nodes);
}
drawvec simple_clip_poly(drawvec &geom, int z, int buffer, drawvec &edge_nodes, bool prevent_simplify_shared_nodes) {
long long area = 1LL << (32 - z);
long long clip_buffer = buffer * area / 256;
return simple_clip_poly(geom, -clip_buffer, -clip_buffer, area + clip_buffer, area + clip_buffer,
0, 0, area, area, edge_nodes, prevent_simplify_shared_nodes);
}
drawvec clip_point(drawvec &geom, int z, long long buffer) {
long long min = 0;
long long area = 1LL << (32 - z);
min -= buffer * area / 256;
area += buffer * area / 256;
return clip_point(geom, min, min, area, area);
}
drawvec clip_point(drawvec &geom, long long minx, long long miny, long long maxx, long long maxy) {
drawvec out;
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].x >= minx && geom[i].y >= miny && geom[i].x <= maxx && geom[i].y <= maxy) {
out.push_back(geom[i]);
}
}
return out;
}
drawvec clip_lines(drawvec &geom, int z, long long buffer) {
long long min = 0;
long long area = 1LL << (32 - z);
min -= buffer * area / 256;
area += buffer * area / 256;
return clip_lines(geom, min, min, area, area);
}
drawvec clip_lines(drawvec &geom, long long minx, long long miny, long long maxx, long long maxy) {
drawvec out;
for (size_t i = 0; i < geom.size(); i++) {
if (i > 0 && (geom[i - 1].op == VT_MOVETO || geom[i - 1].op == VT_LINETO) && geom[i].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, minx, miny, maxx, maxy);
if (c > 1) { // clipped
out.push_back(draw(VT_MOVETO, x1, y1));
out.push_back(draw(VT_LINETO, x2, y2));
out.push_back(draw(VT_MOVETO, geom[i].x, geom[i].y));
} else if (c == 1) { // unchanged
out.push_back(geom[i]);
} else { // clipped away entirely
out.push_back(draw(VT_MOVETO, geom[i].x, geom[i].y));
}
} else {
out.push_back(geom[i]);
}
}
return out;
}
#define INSIDE 0
#define LEFT 1
#define RIGHT 2
#define BOTTOM 4
#define TOP 8
static int computeOutCode(long long x, long long y, long long xmin, long long ymin, long long xmax, long long ymax) {
int code = INSIDE;
if (x < xmin) {
code |= LEFT;
} else if (x > xmax) {
code |= RIGHT;
}
if (y < ymin) {
code |= BOTTOM;
} else if (y > ymax) {
code |= TOP;
}
return code;
}
int clip(long long *x0, long long *y0, long long *x1, long long *y1, long long xmin, long long ymin, long long xmax, long long ymax) {
int outcode0 = computeOutCode(*x0, *y0, xmin, ymin, xmax, ymax);
int outcode1 = computeOutCode(*x1, *y1, xmin, ymin, xmax, ymax);
int accept = 0;
int changed = 0;
while (1) {
if (!(outcode0 | outcode1)) { // Bitwise OR is 0. Trivially accept and get out of loop
accept = 1;
break;
} else if (outcode0 & outcode1) { // Bitwise AND is not 0. Trivially reject and get out of loop
break;
} else {
// failed both tests, so calculate the line segment to clip
// from an outside point to an intersection with clip edge
long long x = *x0, y = *y0;
// At least one endpoint is outside the clip rectangle; pick it.
int outcodeOut = outcode0 ? outcode0 : outcode1;
// XXX truncating division
// Now find the intersection point;
// use formulas y = y0 + slope * (x - x0), x = x0 + (1 / slope) * (y - y0)
if (outcodeOut & TOP) { // point is above the clip rectangle
x = *x0 + (*x1 - *x0) * (ymax - *y0) / (*y1 - *y0);
y = ymax;
} else if (outcodeOut & BOTTOM) { // point is below the clip rectangle
x = *x0 + (*x1 - *x0) * (ymin - *y0) / (*y1 - *y0);
y = ymin;
} else if (outcodeOut & RIGHT) { // point is to the right of clip rectangle
y = *y0 + (*y1 - *y0) * (xmax - *x0) / (*x1 - *x0);
x = xmax;
} else if (outcodeOut & LEFT) { // point is to the left of clip rectangle
y = *y0 + (*y1 - *y0) * (xmin - *x0) / (*x1 - *x0);
x = xmin;
}
// Now we move outside point to intersection point to clip
// and get ready for next pass.
if (outcodeOut == outcode0) {
*x0 = x;
*y0 = y;
outcode0 = computeOutCode(*x0, *y0, xmin, ymin, xmax, ymax);
changed = 1;
} else {
*x1 = x;
*y1 = y;
outcode1 = computeOutCode(*x1, *y1, xmin, ymin, xmax, ymax);
changed = 1;
}
}
}
if (accept == 0) {
return 0;
} else {
return changed + 1;
}
}
static void decode_clipped(mapbox::geometry::multi_polygon<long long> &t, drawvec &out, double scale) {
out.clear();
for (size_t i = 0; i < t.size(); i++) {
for (size_t j = 0; j < t[i].size(); j++) {
drawvec ring;
for (size_t k = 0; k < t[i][j].size(); k++) {
ring.push_back(draw((k == 0) ? VT_MOVETO : VT_LINETO, std::round(t[i][j][k].x / scale), std::round(t[i][j][k].y / scale)));
}
if (ring.size() > 0 && ring[ring.size() - 1] != ring[0]) {
fprintf(stderr, "Had to close ring\n");
ring.push_back(draw(VT_LINETO, ring[0].x, ring[0].y));
}
double area = get_area(ring, 0, ring.size());
if ((j == 0 && area < 0) || (j != 0 && area > 0)) {
fprintf(stderr, "Ring area has wrong sign: %f for %zu\n", area, j);
exit(EXIT_IMPOSSIBLE);
}
for (size_t k = 0; k < ring.size(); k++) {
out.push_back(ring[k]);
}
}
}
}
drawvec clean_or_clip_poly(drawvec &geom, int z, int buffer, bool clip, bool try_scaling) {
geom = remove_noop(geom, VT_POLYGON, 0);
mapbox::geometry::multi_polygon<long long> result;
double scale = 16.0;
if (!try_scaling) {
scale = 1.0;
}
bool again = true;
while (again) {
mapbox::geometry::wagyu::wagyu<long long> wagyu;
again = 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;
}
}
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 * scale, geom[k].y * scale));
}
if (lr.size() >= 3) {
wagyu.add_ring(lr);
}
}
i = j - 1;
}
}
if (clip) {
long long area = 0xFFFFFFFF;
if (z != 0) {
area = 1LL << (32 - z);
}
long long clip_buffer = buffer * area / 256;
mapbox::geometry::linear_ring<long long> lr;
lr.push_back(mapbox::geometry::point<long long>(scale * -clip_buffer, scale * -clip_buffer));
lr.push_back(mapbox::geometry::point<long long>(scale * -clip_buffer, scale * (area + clip_buffer)));
lr.push_back(mapbox::geometry::point<long long>(scale * (area + clip_buffer), scale * (area + clip_buffer)));
lr.push_back(mapbox::geometry::point<long long>(scale * (area + clip_buffer), scale * -clip_buffer));
lr.push_back(mapbox::geometry::point<long long>(scale * -clip_buffer, scale * -clip_buffer));
wagyu.add_ring(lr, mapbox::geometry::wagyu::polygon_type_clip);
}
try {
result.clear();
wagyu.execute(mapbox::geometry::wagyu::clip_type_union, result, mapbox::geometry::wagyu::fill_type_positive, mapbox::geometry::wagyu::fill_type_positive);
} catch (std::runtime_error &e) {
FILE *f = fopen("/tmp/wagyu.log", "w");
fprintf(f, "%s\n", e.what());
fprintf(stderr, "%s\n", e.what());
fprintf(f, "[");
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;
if (i != 0) {
fprintf(f, ",");
}
fprintf(f, "[");
for (size_t k = i; k < j; k++) {
lr.push_back(mapbox::geometry::point<long long>(geom[k].x, geom[k].y));
if (k != i) {
fprintf(f, ",");
}
fprintf(f, "[%lld,%lld]", geom[k].x, geom[k].y);
}
fprintf(f, "]");
if (lr.size() >= 3) {
}
}
i = j - 1;
}
}
fprintf(f, "]");
fprintf(f, "\n\n\n\n\n");
fclose(f);
fprintf(stderr, "Internal error: Polygon cleaning failed. Log in /tmp/wagyu.log\n");
exit(EXIT_IMPOSSIBLE);
}
if (scale != 1) {
for (auto const &outer : result) {
for (auto const &ring : outer) {
for (auto const &p : ring) {
if (p.x / scale != std::round(p.x / scale) ||
p.y / scale != std::round(p.y / scale)) {
scale = 1;
again = true;
break;
}
}
}
}
}
}
drawvec ret;
decode_clipped(result, ret, scale);
return ret;
}
void to_tile_scale(drawvec &geom, int z, int detail) {
if (32 - detail - z < 0) {
for (size_t i = 0; i < geom.size(); i++) {
geom[i].x = std::round((double) geom[i].x * (1LL << (-(32 - detail - z))));
geom[i].y = std::round((double) geom[i].y * (1LL << (-(32 - detail - z))));
}
} else {
for (size_t i = 0; i < geom.size(); i++) {
geom[i].x = std::round((double) geom[i].x / (1LL << (32 - detail - z)));
geom[i].y = std::round((double) geom[i].y / (1LL << (32 - detail - z)));
}
}
}
drawvec from_tile_scale(drawvec const &geom, int z, int detail) {
drawvec out;
for (size_t i = 0; i < geom.size(); i++) {
draw d = geom[i];
d.x *= (1LL << (32 - detail - z));
d.y *= (1LL << (32 - detail - z));
out.push_back(d);
}
return out;
}
drawvec remove_noop(drawvec geom, int type, int shift) {
// first pass: remove empty linetos
long long ox = 0, oy = 0;
drawvec out;
for (size_t i = 0; i < geom.size(); i++) {
long long nx = std::round((double) geom[i].x / (1LL << shift));
long long ny = std::round((double) geom[i].y / (1LL << shift));
if (geom[i].op == VT_LINETO && nx == ox && ny == oy) {
continue;
}
if (geom[i].op == VT_CLOSEPATH) {
out.push_back(geom[i]);
} else { /* moveto or lineto */
out.push_back(geom[i]);
ox = nx;
oy = ny;
}
}
// second pass: remove unused movetos
if (type != VT_POINT) {
geom = out;
out.resize(0);
for (size_t i = 0; i < geom.size(); i++) {
if (geom[i].op == VT_MOVETO) {
if (i + 1 >= geom.size()) {
// followed by end-of-geometry: not needed
continue;
}
if (geom[i + 1].op == VT_MOVETO) {
// followed by another moveto: not needed
continue;
}
if (geom[i + 1].op == VT_CLOSEPATH) {
// followed by closepath: not possible
fprintf(stderr, "Shouldn't happen\n");
i++; // also remove unused closepath
continue;
}
}
out.push_back(geom[i]);
}
}
// second pass: remove empty movetos
if (type == VT_LINE) {
geom = out;
out.resize(0);
for (size_t i = 0; i < geom.size(); i++) {
if (i > 1 && geom[i].op == VT_MOVETO) {
if (geom[i - 1].op == VT_LINETO &&
std::round((double) geom[i - 1].x / (1LL << shift)) == std::round((double) geom[i].x / (1LL << shift)) &&
std::round((double) geom[i - 1].y / (1LL << shift)) == std::round((double) geom[i].y / (1LL << shift))) {
continue;
}
}
out.push_back(geom[i]);
}
}
return out;
}
double get_area_scaled(const drawvec &geom, size_t i, size_t j) {
const double max_exact_double = (double) ((1LL << 53) - 1);
// keep scaling the geometry down until we can calculate its area without overflow
for (long long scale = 2; scale < (1LL << 30); scale *= 2) {
long long bx = geom[i].x;
long long by = geom[i].y;
bool again = false;
// https://en.wikipedia.org/wiki/Shoelace_formula
double area = 0;
for (size_t k = i; k < j; k++) {
area += (double) ((geom[k].x - bx) / scale) * (double) ((geom[i + ((k - i + 1) % (j - i))].y - by) / scale);
if (std::fabs(area) >= max_exact_double) {
again = true;
break;
}
area -= (double) ((geom[k].y - by) / scale) * (double) ((geom[i + ((k - i + 1) % (j - i))].x - bx) / scale);
if (std::fabs(area) >= max_exact_double) {
again = true;
break;
}
}
if (again) {
continue;
} else {
area /= 2;
return area * scale * scale;
}
}
fprintf(stderr, "get_area_scaled: can't happen\n");
exit(EXIT_IMPOSSIBLE);
}
double get_area(const drawvec &geom, size_t i, size_t j) {
const double max_exact_double = (double) ((1LL << 53) - 1);
// Coordinates in `geom` are 40-bit integers, so there is no good way
// to multiply them without possible precision loss. Since they probably
// do not use the full precision, shift them nearer to the origin so
// their product is more likely to be exactly representable as a double.
//
// (In practice they are actually 34-bit integers: 32 bits for the
// Mercator world plane, plus another two bits so features can stick
// off either the left or right side. But that is still too many bits
// for the product to fit either in a 64-bit long long or in a
// double where the largest exact integer is 2^53.)
//
// If the intermediate calculation still exceeds 2^53, start trying to
// recalculate the area by scaling down the geometry. This will not
// produce as precise an area, but it will still be close, and the
// sign will be correct, which is more important, since the sign
// determines the winding order of the rings. We can then use that
// sign with this generally more precise area calculation.
long long bx = geom[i].x;
long long by = geom[i].y;
// https://en.wikipedia.org/wiki/Shoelace_formula
double area = 0;
bool overflow = false;
for (size_t k = i; k < j; k++) {
area += (double) (geom[k].x - bx) * (double) (geom[i + ((k - i + 1) % (j - i))].y - by);
if (std::fabs(area) >= max_exact_double) {
overflow = true;
}
area -= (double) (geom[k].y - by) * (double) (geom[i + ((k - i + 1) % (j - i))].x - bx);
if (std::fabs(area) >= max_exact_double) {
overflow = true;
}
}
area /= 2;
if (overflow) {
double scaled_area = get_area_scaled(geom, i, j);
if ((area < 0 && scaled_area > 0) || (area > 0 && scaled_area < 0)) {
area = -area;
}
}
return area;
}
double get_mp_area(drawvec &geom) {
double ret = 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;
}
}
ret += get_area(geom, i, j);
i = j - 1;
}
}
return ret;
}
drawvec close_poly(drawvec &geom) {
drawvec out;
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 - 1 > i) {
if (geom[j - 1].x != geom[i].x || geom[j - 1].y != geom[i].y) {
fprintf(stderr, "Internal error: polygon not closed\n");
}
}
for (size_t n = i; n < j - 1; n++) {
out.push_back(geom[n]);
}
out.push_back(draw(VT_CLOSEPATH, 0, 0));
i = j - 1;
}
}
return out;
}
static bool inside(std::pair<double, double> d, int edge, long long minx, long long miny, long long maxx, long long maxy) {
switch (edge) {
case 0: // top
return d.second > miny;
case 1: // right
return d.first < maxx;
case 2: // bottom
return d.second < maxy;
case 3: // left
return d.first > minx;
}
fprintf(stderr, "internal error inside\n");
exit(EXIT_FAILURE);
}
static std::pair<double, double> intersect(std::pair<double, double> a, std::pair<double, double> b, int edge, long long minx, long long miny, long long maxx, long long maxy) {
switch (edge) {
case 0: // top
return std::pair<double, double>((a.first + (double) (b.first - a.first) * (miny - a.second) / (b.second - a.second)), miny);
case 1: // right
return std::pair<double, double>(maxx, (a.second + (double) (b.second - a.second) * (maxx - a.first) / (b.first - a.first)));
case 2: // bottom
return std::pair<double, double>((a.first + (double) (b.first - a.first) * (maxy - a.second) / (b.second - a.second)), maxy);
case 3: // left
return std::pair<double, double>(minx, (a.second + (double) (b.second - a.second) * (minx - a.first) / (b.first - a.first)));
}
fprintf(stderr, "internal error intersecting\n");
exit(EXIT_FAILURE);
}
// http://en.wikipedia.org/wiki/Sutherland%E2%80%93Hodgman_algorithm
static std::vector<std::pair<double, double>> clip_poly1(std::vector<std::pair<double, double>> &geom,
long long minx, long long miny, long long maxx, long long maxy,
long long ax, long long ay, long long bx, long long by, drawvec &edge_nodes,
bool prevent_simplify_shared_nodes) {
std::vector<std::pair<double, double>> out = geom;
for (int edge = 0; edge < 4; edge++) {
if (out.size() > 0) {
std::vector<std::pair<double, double>> in = out;
out.resize(0);
std::pair<double, double> S = in[in.size() - 1];
for (size_t e = 0; e < in.size(); e++) {
std::pair<double, double> E = in[e];
if (!inside(S, edge, minx, miny, maxx, maxy)) {
// was outside the buffer
if (!inside(E, edge, minx, miny, maxx, maxy)) {
// still outside the buffer
} else if (!inside(E, edge, ax, ay, bx, by)) {
// outside the tile but inside the buffer
out.push_back(intersect(S, E, edge, minx, miny, maxx, maxy)); // on buffer edge
out.push_back(E);
} else {
out.push_back(intersect(S, E, edge, minx, miny, maxx, maxy)); // on buffer edge
if (prevent_simplify_shared_nodes) {
out.push_back(intersect(S, E, edge, ax, ay, bx, by)); // on tile boundary
edge_nodes.push_back(draw(VT_MOVETO, std::round(out.back().first), std::round(out.back().second)));
}
out.push_back(E);
}
} else if (!inside(S, edge, ax, ay, bx, by)) {
// was inside the buffer but outside the tile edge
if (!inside(E, edge, minx, miny, maxx, maxy)) {
// now outside the buffer
out.push_back(intersect(S, E, edge, minx, miny, maxx, maxy)); // on buffer edge
} else if (!inside(E, edge, ax, ay, bx, by)) {
// still outside the tile edge but inside the buffer
out.push_back(E);
} else {
// now inside the tile
if (prevent_simplify_shared_nodes) {
out.push_back(intersect(S, E, edge, ax, ay, bx, by)); // on tile boundary
edge_nodes.push_back(draw(VT_MOVETO, std::round(out.back().first), std::round(out.back().second)));
}
out.push_back(E);
}
} else {
// was inside the tile
if (!inside(E, edge, minx, miny, maxx, maxy)) {
// now outside the buffer
if (prevent_simplify_shared_nodes) {
out.push_back(intersect(S, E, edge, ax, ay, bx, by)); // on tile boundary
edge_nodes.push_back(draw(VT_MOVETO, std::round(out.back().first), std::round(out.back().second)));
}
out.push_back(intersect(S, E, edge, minx, miny, maxx, maxy)); // on buffer edge
} else if (!inside(E, edge, ax, ay, bx, by)) {
// now inside the buffer but outside the tile edge
if (prevent_simplify_shared_nodes) {
out.push_back(intersect(S, E, edge, ax, ay, bx, by)); // on tile boundary
edge_nodes.push_back(draw(VT_MOVETO, std::round(out.back().first), std::round(out.back().second)));
}
out.push_back(E);
} else {
// still inside the tile
out.push_back(E);
}
}
S = E;
}
}
}
if (out.size() > 0) {
// If the polygon begins and ends outside the edge,
// the starting and ending points will be left as the
// places where it intersects the edge. Need to add
// another point to close the loop.
if (out[0].first != out[out.size() - 1].first || out[0].second != out[out.size() - 1].second) {
out.push_back(out[0]);
}
if (out.size() < 3) {
// fprintf(stderr, "Polygon degenerated to a line segment\n");
out.clear();
return out;
}
}
return out;
}
std::string overzoom(std::string s, int oz, int ox, int oy, int nz, int nx, int ny,
int detail, int buffer, std::set<std::string> const &keep, bool do_compress,
std::vector<std::pair<unsigned, unsigned>> *next_overzoomed_tiles) {
mvt_tile tile;
try {
bool was_compressed;
if (!tile.decode(s, was_compressed)) {
fprintf(stderr, "Couldn't parse tile %d/%u/%u\n", oz, ox, oy);
exit(EXIT_MVT);
}
} catch (std::exception const &e) {
fprintf(stderr, "PBF decoding error in tile %d/%u/%u\n", oz, ox, oy);
exit(EXIT_PROTOBUF);
}
return overzoom(tile, oz, ox, oy, nz, nx, ny, detail, buffer, keep, do_compress, next_overzoomed_tiles);
}
std::string overzoom(mvt_tile tile, int oz, int ox, int oy, int nz, int nx, int ny,
int detail, int buffer, std::set<std::string> const &keep, bool do_compress,
std::vector<std::pair<unsigned, unsigned>> *next_overzoomed_tiles) {
mvt_tile outtile;
for (auto const &layer : tile.layers) {
mvt_layer outlayer = mvt_layer();
int det = detail;
if (det <= 0) {
det = std::round(log(layer.extent) / log(2));
}
outlayer.name = layer.name;
outlayer.version = layer.version;
outlayer.extent = 1LL << det;
for (auto const &feature : layer.features) {
mvt_feature outfeature;
drawvec geom;
int t = feature.type;
// Convert feature geometry to world coordinates
long long tilesize = 1LL << (32 - oz); // source tile size in world coordinates
draw ring_closure(0, 0, 0);
for (auto const &g : feature.geometry) {
if (g.op == mvt_closepath) {
geom.push_back(ring_closure);
} else {
geom.emplace_back(g.op,
g.x * tilesize / layer.extent + ox * tilesize,
g.y * tilesize / layer.extent + oy * tilesize);
if (g.op == mvt_moveto) {
ring_closure = geom.back();
ring_closure.op = mvt_lineto;
}
}
}
// Now offset from world coordinates to output tile coordinates,
// but retain world scale, because that is what tippecanoe clipping expects
long long outtilesize = 1LL << (32 - nz); // destination tile size in world coordinates
for (auto &g : geom) {
g.x -= nx * outtilesize;
g.y -= ny * outtilesize;
}
// Clip to output tile
long long xmin = LLONG_MAX;
long long ymin = LLONG_MAX;
long long xmax = LLONG_MIN;
long long ymax = LLONG_MIN;
for (auto const &g : geom) {
xmin = std::min(xmin, g.x);
ymin = std::min(ymin, g.y);
xmax = std::max(xmax, g.x);
ymax = std::max(ymax, g.y);
}
long long b = outtilesize * buffer / 256;
if (xmax < -b || ymax < -b || xmin > outtilesize + b || ymin > outtilesize + b) {
continue;
}
if (t == VT_LINE) {
geom = clip_lines(geom, nz, buffer);
} else if (t == VT_POLYGON) {
drawvec dv;
geom = simple_clip_poly(geom, nz, buffer, dv, false);
} else if (t == VT_POINT) {
geom = clip_point(geom, nz, buffer);
}
// Scale to output tile extent
to_tile_scale(geom, nz, det);
// Clean geometries
geom = remove_noop(geom, t, 0);
if (t == VT_POLYGON) {
geom = clean_or_clip_poly(geom, 0, 0, false, false);
geom = close_poly(geom);
}
// Add geometry to output feature
outfeature.type = t;
for (auto const &g : geom) {
outfeature.geometry.emplace_back(g.op, g.x, g.y);
}
// ID and attributes, if it didn't get clipped away
if (outfeature.geometry.size() > 0) {
if (feature.has_id) {
outfeature.has_id = true;
outfeature.id = feature.id;
}
for (size_t i = 0; i + 1 < feature.tags.size(); i += 2) {
if (keep.size() == 0 || keep.find(layer.keys[feature.tags[i]]) != keep.end()) {
outlayer.tag(outfeature, layer.keys[feature.tags[i]], layer.values[feature.tags[i + 1]]);
}
}
outlayer.features.push_back(outfeature);
}
}
if (outlayer.features.size() > 0) {
outtile.layers.push_back(outlayer);
}
}
if (next_overzoomed_tiles != NULL) {
// will any child tiles have features in them?
// find out recursively from the tile we just made.
//
// (yes, we should keep them instead of remaking them
// later, but that first requires figuring out where to
// keep them.)
if (outtile.layers.size() > 0) {
for (size_t x = 0; x < 2; x++) {
for (size_t y = 0; y < 2; y++) {
std::string child = overzoom(outtile, nz, nx, ny,
nz + 1, nx * 2 + x, ny * 2 + y,
detail, buffer, keep, false, NULL);
if (child.size() > 0) {
next_overzoomed_tiles->emplace_back(nx * 2 + x, ny * 2 + y);
}
}
}
}
}
if (outtile.layers.size() > 0) {
std::string pbf = outtile.encode();
std::string compressed;
if (do_compress) {
compress(pbf, compressed, true);
} else {
compressed = pbf;
}
return compressed;
} else {
return "";
}
}