#include #include #include #include #include #include #include #include #define BUFFER_OFFSET(i) ((char *)nullptr + (i)) #include struct geometry_too_long_exception : std::exception {}; using namespace mbgl; LineBucket::LineBucket(LineVertexBuffer& vertexBuffer, TriangleElementsBuffer& triangleElementsBuffer, PointElementsBuffer& pointElementsBuffer, const StyleBucketLine& properties) : properties(properties), vertexBuffer(vertexBuffer), triangleElementsBuffer(triangleElementsBuffer), pointElementsBuffer(pointElementsBuffer), vertex_start(vertexBuffer.index()), triangle_elements_start(triangleElementsBuffer.index()), point_elements_start(pointElementsBuffer.index()) { } void LineBucket::addGeometry(pbf& geom) { std::vector line; Geometry::command cmd; Coordinate coord; Geometry geometry(geom); int32_t x, y; while ((cmd = geometry.next(x, y)) != Geometry::end) { if (cmd == Geometry::move_to) { if (!line.empty()) { addGeometry(line); line.clear(); } } line.emplace_back(x, y); } if (line.size()) { addGeometry(line); } } struct TriangleElement { TriangleElement(uint16_t a, uint16_t b, uint16_t c) : a(a), b(b), c(c) {} uint16_t a, b, c; }; typedef uint16_t PointElement; void LineBucket::addGeometry(const std::vector& vertices) { // TODO: use roundLimit // const float roundLimit = geometry.round_limit; if (vertices.size() < 2) { // fprintf(stderr, "a line must have at least two vertices\n"); return; } Coordinate firstVertex = vertices.front(); Coordinate lastVertex = vertices.back(); bool closed = firstVertex.x == lastVertex.x && firstVertex.y == lastVertex.y; if (vertices.size() == 2 && closed) { // fprintf(stderr, "a line may not have coincident points\n"); return; } CapType beginCap = properties.cap; CapType endCap = closed ? CapType::Butt : properties.cap; JoinType currentJoin = JoinType::Miter; Coordinate currentVertex = Coordinate::null(), prevVertex = Coordinate::null(), nextVertex = Coordinate::null(); vec2 prevNormal = vec2::null(), nextNormal = vec2::null(); int32_t e1 = -1, e2 = -1, e3 = -1; int8_t flip = 1; double distance = 0; if (closed) { currentVertex = vertices[vertices.size() - 2]; nextNormal = util::normal(currentVertex, lastVertex); } int32_t start_vertex = (int32_t)vertexBuffer.index(); std::vector triangle_store; std::vector point_store; for (size_t i = 0; i < vertices.size(); ++i) { if (nextNormal) prevNormal = { -nextNormal.x, -nextNormal.y }; if (currentVertex) prevVertex = currentVertex; currentVertex = vertices[i]; currentJoin = properties.join; if (prevVertex) distance += util::dist(currentVertex, prevVertex); // Find the next vertex. if (i + 1 < vertices.size()) { nextVertex = vertices[i + 1]; } else { nextVertex = Coordinate::null(); } // If the line is closed, we treat the last vertex like the first vertex. if (!nextVertex && closed) { nextVertex = vertices[1]; } if (nextVertex) { // if two consecutive vertices exist, skip one if (currentVertex.x == nextVertex.x && currentVertex.y == nextVertex.y) continue; } // Calculate the normal towards the next vertex in this line. In case // there is no next vertex, pretend that the line is continuing straight, // meaning that we are just reversing the previous normal if (nextVertex) { nextNormal = util::normal(currentVertex, nextVertex); } else { nextNormal = { -prevNormal.x, -prevNormal.y }; } // If we still don't have a previous normal, this is the beginning of a // non-closed line, so we're doing a straight "join". if (!prevNormal) { prevNormal = { -nextNormal.x, -nextNormal.y }; } // Determine the normal of the join extrusion. It is the angle bisector // of the segments between the previous line and the next line. vec2 joinNormal = { prevNormal.x + nextNormal.x, prevNormal.y + nextNormal.y }; // Cross product yields 0..1 depending on whether they are parallel // or perpendicular. double joinAngularity = nextNormal.x * joinNormal.y - nextNormal.y * joinNormal.x; joinNormal.x /= joinAngularity; joinNormal.y /= joinAngularity; double roundness = std::fmax(std::abs(joinNormal.x), std::abs(joinNormal.y)); // Switch to miter joins if the angle is very low. if (currentJoin != JoinType::Miter) { if (std::fabs(joinAngularity) < 0.5 && roundness < properties.miter_limit) { currentJoin = JoinType::Miter; } } // Add offset square begin cap. if (!prevVertex && beginCap == CapType::Square) { // Add first vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos flip * (prevNormal.x + prevNormal.y), flip * (-prevNormal.x + prevNormal.y), // extrude normal 0, 0, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; // Add second vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos flip * (prevNormal.x - prevNormal.y), flip * (prevNormal.x + prevNormal.y), // extrude normal 0, 1, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; } // Add offset square end cap. else if (!nextVertex && endCap == CapType::Square) { // Add first vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos nextNormal.x - flip * nextNormal.y, flip * nextNormal.x + nextNormal.y, // extrude normal 0, 0, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; // Add second vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos nextNormal.x + flip * nextNormal.y, -flip * nextNormal.x + nextNormal.y, // extrude normal 0, 1, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; } else if (currentJoin == JoinType::Miter) { // MITER JOIN if (std::fabs(joinAngularity) < 0.01) { // The two normals are almost parallel. joinNormal.x = -nextNormal.y; joinNormal.y = nextNormal.x; } else if (roundness > properties.miter_limit) { // If the miter grows too large, flip the direction to make a // bevel join. joinNormal.x = (prevNormal.x - nextNormal.x) / joinAngularity; joinNormal.y = (prevNormal.y - nextNormal.y) / joinAngularity; } if (roundness > properties.miter_limit) { flip = -flip; } // Add first vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos flip * joinNormal.x, flip * joinNormal.y, // extrude normal 0, 0, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; // Add second vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos -flip * joinNormal.x, -flip * joinNormal.y, // extrude normal 0, 1, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; if ((!prevVertex && beginCap == CapType::Round) || (!nextVertex && endCap == CapType::Round)) { point_store.emplace_back(e1); } } else { // Close up the previous line // Add first vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos flip * prevNormal.y, -flip * prevNormal.x, // extrude normal 0, 0, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; // Add second vertex. e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos -flip * prevNormal.y, flip * prevNormal.x, // extrude normal 0, 1, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; prevNormal = { -nextNormal.x, -nextNormal.y }; flip = 1; // begin/end caps if ((!prevVertex && beginCap == CapType::Round) || (!nextVertex && endCap == CapType::Round)) { point_store.emplace_back(e1); } if (currentJoin == JoinType::Round) { if (prevVertex && nextVertex && (!closed || i > 0)) { point_store.emplace_back(e1); } // Reset the previous vertices so that we don't accidentally create // any triangles. e1 = -1; e2 = -1; e3 = -1; } // Start the new quad. // Add first vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos -flip * nextNormal.y, flip * nextNormal.x, // extrude normal 0, 0, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; // Add second vertex e3 = (int32_t)vertexBuffer.add(currentVertex.x, currentVertex.y, // vertex pos flip * nextNormal.y, -flip * nextNormal.x, // extrude normal 0, 1, distance) - start_vertex; // texture normal if (e1 >= 0 && e2 >= 0 && e3 >= 0) triangle_store.emplace_back(e1, e2, e3); e1 = e2; e2 = e3; } } size_t end_vertex = vertexBuffer.index(); size_t vertex_count = end_vertex - start_vertex; // Store the triangle/line groups. { if (!triangleGroups.size() || (triangleGroups.back().vertex_length + vertex_count > 65535)) { // Move to a new group because the old one can't hold the geometry. triangleGroups.emplace_back(); } triangle_group_type& group = triangleGroups.back(); for (const TriangleElement& triangle : triangle_store) { triangleElementsBuffer.add( group.vertex_length + triangle.a, group.vertex_length + triangle.b, group.vertex_length + triangle.c ); } group.vertex_length += vertex_count; group.elements_length += triangle_store.size(); } // Store the line join/cap groups. { if (!pointGroups.size() || (pointGroups.back().vertex_length + vertex_count > 65535)) { // Move to a new group because the old one can't hold the geometry. pointGroups.emplace_back(); } point_group_type& group = pointGroups.back(); for (PointElement point : point_store) { pointElementsBuffer.add(group.vertex_length + point); } group.vertex_length += vertex_count; group.elements_length += point_store.size(); } } void LineBucket::render(Painter& painter, util::ptr layer_desc, const Tile::ID& id, const mat4 &matrix) { painter.renderLine(*this, layer_desc, id, matrix); } bool LineBucket::hasData() const { return !triangleGroups.empty() || !pointGroups.empty(); } bool LineBucket::hasPoints() const { if (!pointGroups.empty()) { for (const point_group_type& group : pointGroups) { if (group.elements_length) { return true; } } } return false; } void LineBucket::drawLines(LineShader& shader) { char *vertex_index = BUFFER_OFFSET(vertex_start * vertexBuffer.itemSize); char *elements_index = BUFFER_OFFSET(triangle_elements_start * triangleElementsBuffer.itemSize); for (triangle_group_type& group : triangleGroups) { if (!group.elements_length) { continue; } group.array[0].bind(shader, vertexBuffer, triangleElementsBuffer, vertex_index); glDrawElements(GL_TRIANGLES, group.elements_length * 3, GL_UNSIGNED_SHORT, elements_index); vertex_index += group.vertex_length * vertexBuffer.itemSize; elements_index += group.elements_length * triangleElementsBuffer.itemSize; } } void LineBucket::drawLinePatterns(LinepatternShader& shader) { char *vertex_index = BUFFER_OFFSET(vertex_start * vertexBuffer.itemSize); char *elements_index = BUFFER_OFFSET(triangle_elements_start * triangleElementsBuffer.itemSize); for (triangle_group_type& group : triangleGroups) { if (!group.elements_length) { continue; } group.array[1].bind(shader, vertexBuffer, triangleElementsBuffer, vertex_index); glDrawElements(GL_TRIANGLES, group.elements_length * 3, GL_UNSIGNED_SHORT, elements_index); vertex_index += group.vertex_length * vertexBuffer.itemSize; elements_index += group.elements_length * triangleElementsBuffer.itemSize; } } void LineBucket::drawPoints(LinejoinShader& shader) { char *vertex_index = BUFFER_OFFSET(vertex_start * vertexBuffer.itemSize); char *elements_index = BUFFER_OFFSET(point_elements_start * pointElementsBuffer.itemSize); for (point_group_type& group : pointGroups) { if (!group.elements_length) { continue; } group.array[0].bind(shader, vertexBuffer, pointElementsBuffer, vertex_index); glDrawElements(GL_POINTS, group.elements_length, GL_UNSIGNED_SHORT, elements_index); vertex_index += group.vertex_length * vertexBuffer.itemSize; elements_index += group.elements_length * pointElementsBuffer.itemSize; } }