#include "app.hpp" #include "src/global-coords.hpp" #include "shaders/shader.hpp" #include "floormat/main.hpp" #include "src/RTree-search.hpp" #include "src/world.hpp" #include "src/camera-offset.hpp" #include namespace floormat { void app::do_camera(float dt, const key_set& cmds, int mods) { if (cmds[key_camera_reset]) { reset_camera_offset(); update_cursor_tile(cursor.pixel); do_mouse_move(mods); return; } Vector2d dir{}; if (cmds[key_camera_up]) dir += Vector2d{0, -1}; else if (cmds[key_camera_down]) dir += Vector2d{0, 1}; if (cmds[key_camera_left]) dir += Vector2d{-1, 0}; else if (cmds[key_camera_right]) dir += Vector2d{1, 0}; if (dir != Vector2d{}) { auto& shader = M->shader(); const auto sz = M->window_size(); constexpr double screens_per_second = 0.75; const double pixels_per_second = sz.length() / screens_per_second; auto camera_offset = shader.camera_offset(); const auto max_camera_offset = Vector2d(sz * 10); camera_offset -= dir.normalized() * (double)dt * pixels_per_second; camera_offset[0] = std::clamp(camera_offset[0], -max_camera_offset[0], max_camera_offset[0]); camera_offset[1] = std::clamp(camera_offset[1], -max_camera_offset[1], max_camera_offset[1]); shader.set_camera_offset(camera_offset, shader.depth_offset()); update_cursor_tile(cursor.pixel); do_mouse_move(mods); } } void app::reset_camera_offset() { constexpr Vector3d size = TILE_MAX_DIM20d*dTILE_SIZE*-.5; constexpr auto projected = tile_shader::project(size); M->shader().set_camera_offset(projected, 0); _z_level = 0; update_cursor_tile(cursor.pixel); } object_id app::object_at_cursor() { auto [z_min, z_max, z_cur, only] = get_z_bounds(); if (only) z_min = z_max = z_cur; const auto [minx, maxx, miny, maxy] = M->get_draw_bounds(); const auto sz = M->window_size(); auto& world = M->world(); auto& shader = M->shader(); using rtree_type = std::decay_t; using rect_type = typename rtree_type::Rect; if (cursor.pixel) { auto pos = tile_shader::project(Vector3d{0., 0., -_z_level*dTILE_SIZE[2]}); auto pixel = Vector2d{*cursor.pixel} + pos; auto coord = M->pixel_to_tile(pixel); auto tile = global_coords{coord.chunk(), coord.local(), 0}; constexpr auto eps = 1e-6f; constexpr auto m = TILE_SIZE2 * Vector2(1- eps, 1- eps); const auto tile_ = Vector2(M->pixel_to_tile_(Vector2d(pixel))); const auto curchunk = Vector2(tile.chunk()), curtile = Vector2(tile.local()); const auto subpixel_ = Vector2(std::fmod(tile_[0], 1.f), std::fmod(tile_[1], 1.f)); const auto subpixel = m * Vector2(curchunk[0] < 0 ? 1 + subpixel_[0] : subpixel_[0], curchunk[1] < 0 ? 1 + subpixel_[1] : subpixel_[1]); for (int16_t y = miny; y <= maxy; y++) for (int16_t x = minx; x <= maxx; x++) { const chunk_coords_ c_pos{x, y, _z_level}; auto* c_ = world.at(c_pos); if (!c_) continue; auto& c = *c_; c.ensure_passability(); const with_shifted_camera_offset o{shader, c_pos, {minx, miny}, {maxx, maxy}}; if (floormat_main::check_chunk_visible(shader.camera_offset(), sz)) { constexpr auto half_tile = TILE_SIZE2/2; constexpr auto chunk_size = TILE_SIZE2 * TILE_MAX_DIM; auto chunk_dist = (curchunk - Vector2(c_pos.x, c_pos.y))*chunk_size; auto t0 = chunk_dist + curtile*TILE_SIZE2 + subpixel - half_tile; auto t1 = t0+Vector2(1e-4f); const auto* rtree = c.rtree(); object_id ret = 0; rtree->Search(t0.data(), t1.data(), [&](uint64_t data, const rect_type& rect) { [[maybe_unused]] auto x = std::bit_cast(data); if (x.tag == (uint64_t)collision_type::geometry) return true; Vector2 min(rect.m_min[0], rect.m_min[1]), max(rect.m_max[0], rect.m_max[1]); if (t0 >= min && t0 <= max) { if (auto e_ = world.find_object(x.data); e_ && Vector2ui(e_->bbox_size).product() != 0) { ret = x.data; return false; } } return true; }); if (ret) return ret; } } } return 0; } void app::update_cursor_tile(const Optional& pixel) { cursor.pixel = pixel; if (pixel) { auto coord = M->pixel_to_tile(Vector2d{*pixel}); cursor.tile = global_coords{coord.chunk(), coord.local(), _z_level}; } else cursor.tile = NullOpt; } } // namespace floormat