/*************************************************************************/ /* curve_editor_plugin.cpp */ /*************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* https://godotengine.org */ /*************************************************************************/ /* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */ /* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md). */ /* */ /* 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. */ /*************************************************************************/ #include "curve_editor_plugin.h" #include "core/core_string_names.h" #include "core/os/input.h" #include "core/os/keyboard.h" #include "editor/editor_scale.h" #include "core/class_db.h" #include "core/math/color.h" #include "core/error_macros.h" #include "core/image.h" #include "core/math/math_defs.h" #include "core/math/math_funcs.h" #include "core/math/rect2.h" #include "core/os/input_event.h" #include "core/os/memory.h" #include "core/resource.h" #include "core/string_name.h" #include "core/typedefs.h" #include "core/undo_redo.h" #include "core/variant.h" #include "editor/editor_node.h" #include "editor/editor_settings.h" #include "scene/2d/canvas_item.h" #include "scene/gui/popup_menu.h" #include "scene/resources/font.h" #include "scene/resources/texture.h" CurveEditor::CurveEditor() { _selected_point = -1; _hover_point = -1; _selected_tangent = TANGENT_NONE; _hover_radius = 6; _tangents_length = 40; _dragging = false; _has_undo_data = false; set_focus_mode(FOCUS_ALL); set_clip_contents(true); _context_menu = memnew(PopupMenu); _context_menu->connect("id_pressed", this, "_on_context_menu_item_selected"); add_child(_context_menu); _presets_menu = memnew(PopupMenu); _presets_menu->set_name("_presets_menu"); _presets_menu->add_item(TTR("Flat 0"), PRESET_FLAT0); _presets_menu->add_item(TTR("Flat 1"), PRESET_FLAT1); _presets_menu->add_item(TTR("Linear"), PRESET_LINEAR); _presets_menu->add_item(TTR("Ease In"), PRESET_EASE_IN); _presets_menu->add_item(TTR("Ease Out"), PRESET_EASE_OUT); _presets_menu->add_item(TTR("Smoothstep"), PRESET_SMOOTHSTEP); _presets_menu->connect("id_pressed", this, "_on_preset_item_selected"); _context_menu->add_child(_presets_menu); } void CurveEditor::set_curve(Ref curve) { if (curve == _curve_ref) { return; } if (_curve_ref.is_valid()) { _curve_ref->disconnect(CoreStringNames::get_singleton()->changed, this, "_curve_changed"); _curve_ref->disconnect(Curve::SIGNAL_RANGE_CHANGED, this, "_curve_changed"); } _curve_ref = curve; if (_curve_ref.is_valid()) { _curve_ref->connect(CoreStringNames::get_singleton()->changed, this, "_curve_changed"); _curve_ref->connect(Curve::SIGNAL_RANGE_CHANGED, this, "_curve_changed"); } _selected_point = -1; _hover_point = -1; _selected_tangent = TANGENT_NONE; update(); // Note: if you edit a curve, then set another, and try to undo, // it will normally apply on the previous curve, but you won't see it } Size2 CurveEditor::get_minimum_size() const { return Vector2(64, 150) * EDSCALE; } void CurveEditor::_notification(int p_what) { if (p_what == NOTIFICATION_DRAW) { _draw(); } } void CurveEditor::on_gui_input(const Ref &p_event) { Ref mb_ref = p_event; if (mb_ref.is_valid()) { const InputEventMouseButton &mb = **mb_ref; if (mb.is_pressed() && !_dragging) { Vector2 mpos = mb.get_position(); _selected_tangent = get_tangent_at(mpos); if (_selected_tangent == TANGENT_NONE) { set_selected_point(get_point_at(mpos)); } switch (mb.get_button_index()) { case BUTTON_RIGHT: _context_click_pos = mpos; open_context_menu(get_global_transform().xform(mpos)); break; case BUTTON_MIDDLE: remove_point(_hover_point); break; case BUTTON_LEFT: _dragging = true; break; } } if (!mb.is_pressed() && _dragging && mb.get_button_index() == BUTTON_LEFT) { _dragging = false; if (_has_undo_data) { UndoRedo &ur = *EditorNode::get_singleton()->get_undo_redo(); ur.create_action(_selected_tangent == TANGENT_NONE ? TTR("Modify Curve Point") : TTR("Modify Curve Tangent")); ur.add_do_method(*_curve_ref, "_set_data", _curve_ref->get_data()); ur.add_undo_method(*_curve_ref, "_set_data", _undo_data); // Note: this will trigger one more "changed" signal even if nothing changes, // but it's ok since it would have fired every frame during the drag anyways ur.commit_action(); _has_undo_data = false; } } } Ref mm_ref = p_event; if (mm_ref.is_valid()) { const InputEventMouseMotion &mm = **mm_ref; Vector2 mpos = mm.get_position(); if (_dragging && _curve_ref.is_valid()) { if (_selected_point != -1) { Curve &curve = **_curve_ref; if (!_has_undo_data) { // Save full curve state before dragging points, // because this operation can modify their order _undo_data = curve.get_data(); _has_undo_data = true; } const float curve_amplitude = curve.get_max_value() - curve.get_min_value(); // Snap to "round" coordinates when holding Ctrl. // Be more precise when holding Shift as well. float snap_threshold; if (mm.get_control()) { snap_threshold = mm.get_shift() ? 0.025 : 0.1; } else { snap_threshold = 0.0; } if (_selected_tangent == TANGENT_NONE) { // Drag point Vector2 point_pos = get_world_pos(mpos).snapped(Vector2(snap_threshold, snap_threshold * curve_amplitude)); int i = curve.set_point_offset(_selected_point, point_pos.x); // The index may change if the point is dragged across another one set_hover_point_index(i); set_selected_point(i); // This is to prevent the user from losing a point out of view. if (point_pos.y < curve.get_min_value()) { point_pos.y = curve.get_min_value(); } else if (point_pos.y > curve.get_max_value()) { point_pos.y = curve.get_max_value(); } curve.set_point_value(_selected_point, point_pos.y); } else { // Drag tangent const Vector2 point_pos = curve.get_point_position(_selected_point); const Vector2 control_pos = get_world_pos(mpos).snapped(Vector2(snap_threshold, snap_threshold * curve_amplitude)); Vector2 dir = (control_pos - point_pos).normalized(); real_t tangent; if (!Math::is_zero_approx(dir.x)) { tangent = dir.y / dir.x; } else { tangent = 9999 * (dir.y >= 0 ? 1 : -1); } bool link = !Input::get_singleton()->is_key_pressed(KEY_SHIFT); if (_selected_tangent == TANGENT_LEFT) { curve.set_point_left_tangent(_selected_point, tangent); // Note: if a tangent is set to linear, it shouldn't be linked to the other if (link && _selected_point != (curve.get_point_count() - 1) && curve.get_point_right_mode(_selected_point) != Curve::TANGENT_LINEAR) { curve.set_point_right_tangent(_selected_point, tangent); } } else { curve.set_point_right_tangent(_selected_point, tangent); if (link && _selected_point != 0 && curve.get_point_left_mode(_selected_point) != Curve::TANGENT_LINEAR) { curve.set_point_left_tangent(_selected_point, tangent); } } } } } else { set_hover_point_index(get_point_at(mpos)); } } Ref key_ref = p_event; if (key_ref.is_valid()) { const InputEventKey &key = **key_ref; if (key.is_pressed() && _selected_point != -1) { if (key.get_scancode() == KEY_DELETE) { remove_point(_selected_point); } } } } void CurveEditor::on_preset_item_selected(int preset_id) { ERR_FAIL_COND(preset_id < 0 || preset_id >= PRESET_COUNT); ERR_FAIL_COND(_curve_ref.is_null()); Curve &curve = **_curve_ref; Array previous_data = curve.get_data(); curve.clear_points(); switch (preset_id) { case PRESET_FLAT0: curve.add_point(Vector2(0, 0)); curve.add_point(Vector2(1, 0)); curve.set_point_right_mode(0, Curve::TANGENT_LINEAR); curve.set_point_left_mode(1, Curve::TANGENT_LINEAR); break; case PRESET_FLAT1: curve.add_point(Vector2(0, 1)); curve.add_point(Vector2(1, 1)); curve.set_point_right_mode(0, Curve::TANGENT_LINEAR); curve.set_point_left_mode(1, Curve::TANGENT_LINEAR); break; case PRESET_LINEAR: curve.add_point(Vector2(0, 0)); curve.add_point(Vector2(1, 1)); curve.set_point_right_mode(0, Curve::TANGENT_LINEAR); curve.set_point_left_mode(1, Curve::TANGENT_LINEAR); break; case PRESET_EASE_IN: curve.add_point(Vector2(0, 0)); curve.add_point(Vector2(1, 1), (curve.get_max_value() - curve.get_min_value()) * 1.4, 0); break; case PRESET_EASE_OUT: curve.add_point(Vector2(0, 0), 0, (curve.get_max_value() - curve.get_min_value()) * 1.4); curve.add_point(Vector2(1, 1)); break; case PRESET_SMOOTHSTEP: curve.add_point(Vector2(0, 0)); curve.add_point(Vector2(1, 1)); break; default: break; } UndoRedo &ur = *EditorNode::get_singleton()->get_undo_redo(); ur.create_action(TTR("Load Curve Preset")); ur.add_do_method(&curve, "_set_data", curve.get_data()); ur.add_undo_method(&curve, "_set_data", previous_data); ur.commit_action(); } void CurveEditor::_curve_changed() { update(); // Point count can change in case of undo if (_selected_point >= _curve_ref->get_point_count()) { set_selected_point(-1); } } void CurveEditor::on_context_menu_item_selected(int action_id) { switch (action_id) { case CONTEXT_ADD_POINT: add_point(_context_click_pos); break; case CONTEXT_REMOVE_POINT: remove_point(_selected_point); break; case CONTEXT_LINEAR: toggle_linear(); break; case CONTEXT_LEFT_LINEAR: toggle_linear(TANGENT_LEFT); break; case CONTEXT_RIGHT_LINEAR: toggle_linear(TANGENT_RIGHT); break; } } void CurveEditor::open_context_menu(Vector2 pos) { _context_menu->set_position(pos); _context_menu->clear(); if (_curve_ref.is_valid()) { _context_menu->add_item(TTR("Add Point"), CONTEXT_ADD_POINT); if (_selected_point >= 0) { _context_menu->add_item(TTR("Remove Point"), CONTEXT_REMOVE_POINT); if (_selected_tangent != TANGENT_NONE) { _context_menu->add_separator(); _context_menu->add_check_item(TTR("Linear"), CONTEXT_LINEAR); bool is_linear = _selected_tangent == TANGENT_LEFT ? _curve_ref->get_point_left_mode(_selected_point) == Curve::TANGENT_LINEAR : _curve_ref->get_point_right_mode(_selected_point) == Curve::TANGENT_LINEAR; _context_menu->set_item_checked(_context_menu->get_item_index(CONTEXT_LINEAR), is_linear); } else { if (_selected_point > 0 || _selected_point + 1 < _curve_ref->get_point_count()) { _context_menu->add_separator(); } if (_selected_point > 0) { _context_menu->add_check_item(TTR("Left Linear"), CONTEXT_LEFT_LINEAR); _context_menu->set_item_checked(_context_menu->get_item_index(CONTEXT_LEFT_LINEAR), _curve_ref->get_point_left_mode(_selected_point) == Curve::TANGENT_LINEAR); } if (_selected_point + 1 < _curve_ref->get_point_count()) { _context_menu->add_check_item(TTR("Right Linear"), CONTEXT_RIGHT_LINEAR); _context_menu->set_item_checked(_context_menu->get_item_index(CONTEXT_RIGHT_LINEAR), _curve_ref->get_point_right_mode(_selected_point) == Curve::TANGENT_LINEAR); } } } _context_menu->add_separator(); } _context_menu->add_submenu_item(TTR("Load Preset"), _presets_menu->get_name()); _context_menu->set_size(Size2(0, 0)); _context_menu->popup(); } int CurveEditor::get_point_at(Vector2 pos) const { if (_curve_ref.is_null()) { return -1; } const Curve &curve = **_curve_ref; const float true_hover_radius = Math::round(_hover_radius * EDSCALE); const float r = true_hover_radius * true_hover_radius; for (int i = 0; i < curve.get_point_count(); ++i) { Vector2 p = get_view_pos(curve.get_point_position(i)); if (p.distance_squared_to(pos) <= r) { return i; } } return -1; } CurveEditor::TangentIndex CurveEditor::get_tangent_at(Vector2 pos) const { if (_curve_ref.is_null() || _selected_point < 0) { return TANGENT_NONE; } if (_selected_point != 0) { Vector2 control_pos = get_tangent_view_pos(_selected_point, TANGENT_LEFT); if (control_pos.distance_to(pos) < _hover_radius) { return TANGENT_LEFT; } } if (_selected_point != _curve_ref->get_point_count() - 1) { Vector2 control_pos = get_tangent_view_pos(_selected_point, TANGENT_RIGHT); if (control_pos.distance_to(pos) < _hover_radius) { return TANGENT_RIGHT; } } return TANGENT_NONE; } void CurveEditor::add_point(Vector2 pos) { ERR_FAIL_COND(_curve_ref.is_null()); UndoRedo &ur = *EditorNode::get_singleton()->get_undo_redo(); ur.create_action(TTR("Remove Curve Point")); Vector2 point_pos = get_world_pos(pos); if (point_pos.y < 0.0) { point_pos.y = 0.0; } else if (point_pos.y > 1.0) { point_pos.y = 1.0; } // Small trick to get the point index to feed the undo method int i = _curve_ref->add_point(point_pos); _curve_ref->remove_point(i); ur.add_do_method(*_curve_ref, "add_point", point_pos); ur.add_undo_method(*_curve_ref, "remove_point", i); ur.commit_action(); } void CurveEditor::remove_point(int index) { ERR_FAIL_COND(_curve_ref.is_null()); UndoRedo &ur = *EditorNode::get_singleton()->get_undo_redo(); ur.create_action(TTR("Remove Curve Point")); Curve::Point p = _curve_ref->get_point(index); ur.add_do_method(*_curve_ref, "remove_point", index); ur.add_undo_method(*_curve_ref, "add_point", p.pos, p.left_tangent, p.right_tangent, p.left_mode, p.right_mode); if (index == _selected_point) { set_selected_point(-1); } if (index == _hover_point) { set_hover_point_index(-1); } ur.commit_action(); } void CurveEditor::toggle_linear(TangentIndex tangent) { ERR_FAIL_COND(_curve_ref.is_null()); UndoRedo &ur = *EditorNode::get_singleton()->get_undo_redo(); ur.create_action(TTR("Toggle Curve Linear Tangent")); if (tangent == TANGENT_NONE) { tangent = _selected_tangent; } if (tangent == TANGENT_LEFT) { bool is_linear = _curve_ref->get_point_left_mode(_selected_point) == Curve::TANGENT_LINEAR; Curve::TangentMode prev_mode = _curve_ref->get_point_left_mode(_selected_point); Curve::TangentMode mode = is_linear ? Curve::TANGENT_FREE : Curve::TANGENT_LINEAR; ur.add_do_method(*_curve_ref, "set_point_left_mode", _selected_point, mode); ur.add_undo_method(*_curve_ref, "set_point_left_mode", _selected_point, prev_mode); } else { bool is_linear = _curve_ref->get_point_right_mode(_selected_point) == Curve::TANGENT_LINEAR; Curve::TangentMode prev_mode = _curve_ref->get_point_right_mode(_selected_point); Curve::TangentMode mode = is_linear ? Curve::TANGENT_FREE : Curve::TANGENT_LINEAR; ur.add_do_method(*_curve_ref, "set_point_right_mode", _selected_point, mode); ur.add_undo_method(*_curve_ref, "set_point_right_mode", _selected_point, prev_mode); } ur.commit_action(); } void CurveEditor::set_selected_point(int index) { if (index != _selected_point) { _selected_point = index; update(); } } void CurveEditor::set_hover_point_index(int index) { if (index != _hover_point) { _hover_point = index; update(); } } void CurveEditor::update_view_transform() { Ref font = get_font("font", "Label"); const real_t margin = font->get_height() + 2 * EDSCALE; float min_y = 0; float max_y = 1; if (_curve_ref.is_valid()) { min_y = _curve_ref->get_min_value(); max_y = _curve_ref->get_max_value(); } const Rect2 world_rect = Rect2(Curve::MIN_X, min_y, Curve::MAX_X, max_y - min_y); const Size2 view_margin(margin, margin); const Size2 view_size = get_size() - view_margin * 2; const Vector2 scale = view_size / world_rect.size; Transform2D world_trans; world_trans.translate_local(-world_rect.position - Vector2(0, world_rect.size.y)); world_trans.scale(Vector2(scale.x, -scale.y)); Transform2D view_trans; view_trans.translate_local(view_margin); _world_to_view = view_trans * world_trans; } Vector2 CurveEditor::get_tangent_view_pos(int i, TangentIndex tangent) const { Vector2 dir; if (tangent == TANGENT_LEFT) { dir = -Vector2(1, _curve_ref->get_point_left_tangent(i)); } else { dir = Vector2(1, _curve_ref->get_point_right_tangent(i)); } Vector2 point_pos = get_view_pos(_curve_ref->get_point_position(i)); Vector2 control_pos = get_view_pos(_curve_ref->get_point_position(i) + dir); return point_pos + Math::round(_tangents_length * EDSCALE) * (control_pos - point_pos).normalized(); } Vector2 CurveEditor::get_view_pos(Vector2 world_pos) const { return _world_to_view.xform(world_pos); } Vector2 CurveEditor::get_world_pos(Vector2 view_pos) const { return _world_to_view.affine_inverse().xform(view_pos); } // Uses non-baked points, but takes advantage of ordered iteration to be faster template static void plot_curve_accurate(const Curve &curve, float step, T plot_func) { if (curve.get_point_count() <= 1) { // Not enough points to make a curve, so it's just a straight line float y = curve.interpolate(0); plot_func(Vector2(0, y), Vector2(1.f, y), true); } else { Vector2 first_point = curve.get_point_position(0); Vector2 last_point = curve.get_point_position(curve.get_point_count() - 1); // Edge lines plot_func(Vector2(0, first_point.y), first_point, false); plot_func(Vector2(Curve::MAX_X, last_point.y), last_point, false); // Draw section by section, so that we get maximum precision near points. // It's an accurate representation, but slower than using the baked one. for (int i = 1; i < curve.get_point_count(); ++i) { Vector2 a = curve.get_point_position(i - 1); Vector2 b = curve.get_point_position(i); Vector2 pos = a; Vector2 prev_pos = a; float len = b.x - a.x; for (float x = step; x < len; x += step) { pos.x = a.x + x; pos.y = curve.interpolate_local_nocheck(i - 1, x); plot_func(prev_pos, pos, true); prev_pos = pos; } plot_func(prev_pos, b, true); } } } struct CanvasItemPlotCurve { CanvasItem &ci; Color color1; Color color2; CanvasItemPlotCurve(CanvasItem &p_ci, Color p_color1, Color p_color2) : ci(p_ci), color1(p_color1), color2(p_color2) {} void operator()(Vector2 pos0, Vector2 pos1, bool in_definition) { // FIXME: Using a line width greater than 1 breaks curve rendering ci.draw_line(pos0, pos1, in_definition ? color1 : color2, 1, true); } }; void CurveEditor::_draw() { if (_curve_ref.is_null()) { return; } Curve &curve = **_curve_ref; update_view_transform(); // Background Vector2 view_size = get_rect().size; draw_style_box(get_stylebox("bg", "Tree"), Rect2(Point2(), view_size)); // Grid draw_set_transform_matrix(_world_to_view); Vector2 min_edge = get_world_pos(Vector2(0, view_size.y)); Vector2 max_edge = get_world_pos(Vector2(view_size.x, 0)); const Color grid_color0 = get_color("mono_color", "Editor") * Color(1, 1, 1, 0.15); const Color grid_color1 = get_color("mono_color", "Editor") * Color(1, 1, 1, 0.07); draw_line(Vector2(min_edge.x, curve.get_min_value()), Vector2(max_edge.x, curve.get_min_value()), grid_color0); draw_line(Vector2(max_edge.x, curve.get_max_value()), Vector2(min_edge.x, curve.get_max_value()), grid_color0); draw_line(Vector2(0, min_edge.y), Vector2(0, max_edge.y), grid_color0); draw_line(Vector2(1, max_edge.y), Vector2(1, min_edge.y), grid_color0); float curve_height = (curve.get_max_value() - curve.get_min_value()); const Vector2 grid_step(0.25, 0.5 * curve_height); for (real_t x = 0; x < 1.0; x += grid_step.x) { draw_line(Vector2(x, min_edge.y), Vector2(x, max_edge.y), grid_color1); } for (real_t y = curve.get_min_value(); y < curve.get_max_value(); y += grid_step.y) { draw_line(Vector2(min_edge.x, y), Vector2(max_edge.x, y), grid_color1); } // Markings draw_set_transform_matrix(Transform2D()); Ref font = get_font("font", "Label"); float font_height = font->get_height(); Color text_color = get_color("font_color", "Editor"); { // X axis float y = curve.get_min_value(); Vector2 off(0, font_height - 1); draw_string(font, get_view_pos(Vector2(0, y)) + off, "0.0", text_color); draw_string(font, get_view_pos(Vector2(0.25, y)) + off, "0.25", text_color); draw_string(font, get_view_pos(Vector2(0.5, y)) + off, "0.5", text_color); draw_string(font, get_view_pos(Vector2(0.75, y)) + off, "0.75", text_color); draw_string(font, get_view_pos(Vector2(1, y)) + off, "1.0", text_color); } { // Y axis float m0 = curve.get_min_value(); float m1 = 0.5 * (curve.get_min_value() + curve.get_max_value()); float m2 = curve.get_max_value(); Vector2 off(1, -1); draw_string(font, get_view_pos(Vector2(0, m0)) + off, String::num(m0, 2), text_color); draw_string(font, get_view_pos(Vector2(0, m1)) + off, String::num(m1, 2), text_color); draw_string(font, get_view_pos(Vector2(0, m2)) + off, String::num(m2, 3), text_color); } // Draw tangents for current point if (_selected_point >= 0) { const Color tangent_color = get_color("accent_color", "Editor"); int i = _selected_point; Vector2 pos = curve.get_point_position(i); if (i != 0) { Vector2 control_pos = get_tangent_view_pos(i, TANGENT_LEFT); draw_line(get_view_pos(pos), control_pos, tangent_color, Math::round(EDSCALE), true); draw_rect(Rect2(control_pos, Vector2(1, 1)).grow(Math::round(2 * EDSCALE)), tangent_color); } if (i != curve.get_point_count() - 1) { Vector2 control_pos = get_tangent_view_pos(i, TANGENT_RIGHT); draw_line(get_view_pos(pos), control_pos, tangent_color, Math::round(EDSCALE), true); draw_rect(Rect2(control_pos, Vector2(1, 1)).grow(Math::round(2 * EDSCALE)), tangent_color); } } // Draw lines draw_set_transform_matrix(_world_to_view); const Color line_color = get_color("font_color", "Editor"); const Color edge_line_color = get_color("highlight_color", "Editor"); CanvasItemPlotCurve plot_func(*this, line_color, edge_line_color); plot_curve_accurate(curve, 4.f / view_size.x, plot_func); // Draw points draw_set_transform_matrix(Transform2D()); const Color point_color = get_color("font_color", "Editor"); const Color selected_point_color = get_color("accent_color", "Editor"); for (int i = 0; i < curve.get_point_count(); ++i) { Vector2 pos = curve.get_point_position(i); draw_rect(Rect2(get_view_pos(pos), Vector2(1, 1)).grow(Math::round(3 * EDSCALE)), i == _selected_point ? selected_point_color : point_color); // TODO Circles are prettier. Needs a fix! Or a texture //draw_circle(pos, 2, point_color); } // Hover if (_hover_point != -1) { const Color hover_color = line_color; Vector2 pos = curve.get_point_position(_hover_point); draw_rect(Rect2(get_view_pos(pos), Vector2(1, 1)).grow(Math::round(_hover_radius * EDSCALE)), hover_color, false, Math::round(EDSCALE)); } // Help text if (_selected_point > 0 && _selected_point + 1 < curve.get_point_count()) { text_color.a *= 0.4; draw_string(font, Vector2(50 * EDSCALE, font_height), TTR("Hold Shift to edit tangents individually"), text_color); } else if (curve.get_point_count() == 0) { text_color.a *= 0.4; draw_string(font, Vector2(50 * EDSCALE, font_height), TTR("Right click to add point"), text_color); } } void CurveEditor::_bind_methods() { ClassDB::bind_method(D_METHOD("_gui_input"), &CurveEditor::on_gui_input); ClassDB::bind_method(D_METHOD("_on_preset_item_selected"), &CurveEditor::on_preset_item_selected); ClassDB::bind_method(D_METHOD("_curve_changed"), &CurveEditor::_curve_changed); ClassDB::bind_method(D_METHOD("_on_context_menu_item_selected"), &CurveEditor::on_context_menu_item_selected); } //--------------- bool EditorInspectorPluginCurve::can_handle(Object *p_object) { return Object::cast_to(p_object) != nullptr; } void EditorInspectorPluginCurve::parse_begin(Object *p_object) { Curve *curve = Object::cast_to(p_object); ERR_FAIL_COND(!curve); Ref c(curve); CurveEditor *editor = memnew(CurveEditor); editor->set_curve(curve); add_custom_control(editor); } CurveEditorPlugin::CurveEditorPlugin(EditorNode *p_node) { Ref curve_plugin; curve_plugin.instance(); EditorInspector::add_inspector_plugin(curve_plugin); get_editor_interface()->get_resource_previewer()->add_preview_generator(memnew(CurvePreviewGenerator)); } //----------------------------------- // Preview generator bool CurvePreviewGenerator::handles(const String &p_type) const { return p_type == "Curve"; } Ref CurvePreviewGenerator::generate(const Ref &p_from, const Size2 &p_size) const { Ref curve_ref = p_from; ERR_FAIL_COND_V_MSG(curve_ref.is_null(), Ref(), "It's not a reference to a valid Resource object."); Curve &curve = **curve_ref; // FIXME: Should be ported to use p_size as done in b2633a97 int thumbnail_size = EditorSettings::get_singleton()->get("filesystem/file_dialog/thumbnail_size"); thumbnail_size *= EDSCALE; Ref img_ref; img_ref.instance(); Image &im = **img_ref; im.create(thumbnail_size, thumbnail_size / 2, false, Image::FORMAT_RGBA8); im.lock(); Color bg_color(0.1, 0.1, 0.1, 1.0); for (int i = 0; i < thumbnail_size; i++) { for (int j = 0; j < thumbnail_size / 2; j++) { im.set_pixel(i, j, bg_color); } } Color line_color(0.8, 0.8, 0.8, 1.0); float range_y = curve.get_max_value() - curve.get_min_value(); int prev_y = 0; for (int x = 0; x < im.get_width(); ++x) { float t = static_cast(x) / im.get_width(); float v = (curve.interpolate_baked(t) - curve.get_min_value()) / range_y; int y = CLAMP(im.get_height() - v * im.get_height(), 0, im.get_height()); // Plot point if (y >= 0 && y < im.get_height()) { im.set_pixel(x, y, line_color); } // Plot vertical line to fix discontinuity (not 100% correct but enough for a preview) if (x != 0 && Math::abs(y - prev_y) > 1) { int y0, y1; if (y < prev_y) { y0 = y; y1 = prev_y; } else { y0 = prev_y; y1 = y; } for (int ly = y0; ly < y1; ++ly) { im.set_pixel(x, ly, line_color); } } prev_y = y; } im.unlock(); Ref ptex = Ref(memnew(ImageTexture)); ptex->create_from_image(img_ref, 0); return ptex; }