From 2449b581dd96378ad67c85f64b026e3bcebc7061 Mon Sep 17 00:00:00 2001 From: Marcel Admiraal Date: Sun, 30 May 2021 18:35:52 +0100 Subject: [PATCH] Fix multiple issues with CSGPolygon --- modules/csg/csg_shape.cpp | 701 ++++++++++--------------- modules/csg/csg_shape.h | 7 +- modules/csg/doc_classes/CSGPolygon.xml | 42 +- 3 files changed, 288 insertions(+), 462 deletions(-) diff --git a/modules/csg/csg_shape.cpp b/modules/csg/csg_shape.cpp index 65529798240..3841a8ebf18 100644 --- a/modules/csg/csg_shape.cpp +++ b/modules/csg/csg_shape.cpp @@ -29,7 +29,6 @@ /*************************************************************************/ #include "csg_shape.h" -#include "scene/3d/path.h" void CSGShape::set_use_collision(bool p_enable) { if (use_collision == p_enable) { @@ -1745,109 +1744,80 @@ CSGTorus::CSGTorus() { /////////////// CSGBrush *CSGPolygon::_build_brush() { - // set our bounding box - - if (polygon.size() < 3) { - return memnew(CSGBrush); - } - - Vector final_polygon = polygon; - - if (Triangulate::get_area(final_polygon) > 0) { - final_polygon.invert(); - } - - Vector triangles = Geometry::triangulate_polygon(final_polygon); - - if (triangles.size() < 3) { - return memnew(CSGBrush); - } - - Path *path = nullptr; - Ref curve; - - // get bounds for our polygon - Vector2 final_polygon_min; - Vector2 final_polygon_max; - for (int i = 0; i < final_polygon.size(); i++) { - Vector2 p = final_polygon[i]; - if (i == 0) { - final_polygon_min = p; - final_polygon_max = final_polygon_min; - } else { - if (p.x < final_polygon_min.x) { - final_polygon_min.x = p.x; - } - if (p.y < final_polygon_min.y) { - final_polygon_min.y = p.y; - } - - if (p.x > final_polygon_max.x) { - final_polygon_max.x = p.x; - } - if (p.y > final_polygon_max.y) { - final_polygon_max.y = p.y; - } - } - } - Vector2 final_polygon_size = final_polygon_max - final_polygon_min; - - if (mode == MODE_PATH) { - if (!has_node(path_node)) { - return memnew(CSGBrush); - } - Node *n = get_node(path_node); - if (!n) { - return memnew(CSGBrush); - } - path = Object::cast_to(n); - if (!path) { - return memnew(CSGBrush); - } - - if (path != path_cache) { - if (path_cache) { - path_cache->disconnect("tree_exited", this, "_path_exited"); - path_cache->disconnect("curve_changed", this, "_path_changed"); - path_cache = nullptr; - } - - path_cache = path; - - path_cache->connect("tree_exited", this, "_path_exited"); - path_cache->connect("curve_changed", this, "_path_changed"); - } - curve = path->get_curve(); - if (curve.is_null()) { - return memnew(CSGBrush); - } - if (curve->get_baked_length() <= 0) { - return memnew(CSGBrush); - } - } CSGBrush *brush = memnew(CSGBrush); - int face_count = 0; + if (polygon.size() < 3) { + return brush; + } + // Triangulate polygon shape. + Vector shape_polygon = polygon; + if (Triangulate::get_area(shape_polygon) > 0) { + shape_polygon.invert(); + } + int shape_sides = shape_polygon.size(); + Vector shape_faces = Geometry::triangulate_polygon(shape_polygon); + ERR_FAIL_COND_V_MSG(shape_faces.size() < 3, brush, "Failed to triangulate CSGPolygon"); + + // Get polygon enclosing Rect2. + Rect2 shape_rect(shape_polygon[0], Vector2()); + for (int i = 1; i < shape_sides; i++) { + shape_rect.expand_to(shape_polygon[i]); + } + + // If MODE_PATH, check if curve has changed. + Ref curve; + if (mode == MODE_PATH) { + Path *current_path = Object::cast_to(get_node_or_null(path_node)); + if (path != current_path) { + if (path) { + path->disconnect("tree_exited", this, "_path_exited"); + path->disconnect("curve_changed", this, "_path_changed"); + } + path = current_path; + if (path) { + path->connect("tree_exited", this, "_path_exited"); + path->connect("curve_changed", this, "_path_changed"); + } + } + + if (!path) { + return brush; + } + + curve = path->get_curve(); + if (curve.is_null() || curve->get_point_count() < 2) { + return brush; + } + } + + // Calculate the number of extrusions, ends and faces. + int extrusions = 0; + int extrusion_face_count = shape_sides * 2; + int end_count = 0; + int shape_face_count = shape_faces.size() / 3; switch (mode) { case MODE_DEPTH: - face_count = triangles.size() * 2 / 3 + (final_polygon.size()) * 2; + extrusions = 1; + end_count = 2; break; case MODE_SPIN: - face_count = (spin_degrees < 360 ? triangles.size() * 2 / 3 : 0) + (final_polygon.size()) * 2 * spin_sides; + extrusions = spin_sides; + if (spin_degrees < 360) { + end_count = 2; + } break; case MODE_PATH: { - float bl = curve->get_baked_length(); - int splits = MAX(2, Math::ceil(bl / path_interval)); - if (path_joined) { - face_count = splits * final_polygon.size() * 2; - } else { - face_count = triangles.size() * 2 / 3 + splits * final_polygon.size() * 2; + extrusions = Math::ceil(1.0 * curve->get_point_count() / path_interval); + if (!path_joined) { + end_count = 2; + extrusions -= 1; } } break; } + int face_count = extrusions * extrusion_face_count + end_count * shape_face_count; - bool invert_val = is_inverting_faces(); + // Initialize variables used to create the mesh. Ref material = get_material(); PoolVector faces; @@ -1858,362 +1828,216 @@ CSGBrush *CSGPolygon::_build_brush() { faces.resize(face_count * 3); uvs.resize(face_count * 3); - smooth.resize(face_count); materials.resize(face_count); invert.resize(face_count); - AABB aabb; //must be computed - { - PoolVector::Write facesw = faces.write(); - PoolVector::Write uvsw = uvs.write(); - PoolVector::Write smoothw = smooth.write(); - PoolVector>::Write materialsw = materials.write(); - PoolVector::Write invertw = invert.write(); + PoolVector::Write facesw = faces.write(); + PoolVector::Write uvsw = uvs.write(); + PoolVector::Write smoothw = smooth.write(); + PoolVector>::Write materialsw = materials.write(); + PoolVector::Write invertw = invert.write(); - int face = 0; + int face = 0; + Transform base_xform; + Transform current_xform; + Transform previous_xform; + double u_step = 1.0 / extrusions; + double v_step = 1.0 / shape_sides; + double spin_step = Math::deg2rad(spin_degrees / spin_sides); + double extrusion_step = 1.0 / extrusions; + if (mode == MODE_PATH) { + if (path_joined) { + extrusion_step = 1.0 / (extrusions - 1); + } + extrusion_step *= curve->get_baked_length(); + } + + if (mode == MODE_PATH) { + if (!path_local) { + base_xform = path->get_global_transform(); + } + + Vector3 current_point = curve->interpolate_baked(0); + Vector3 next_point = curve->interpolate_baked(extrusion_step); + Vector3 current_up = Vector3(0, 1, 0); + Vector3 direction = next_point - current_point; + + if (path_joined) { + Vector3 last_point = curve->interpolate_baked(curve->get_baked_length()); + direction = next_point - last_point; + } + + switch (path_rotation) { + case PATH_ROTATION_POLYGON: + direction = Vector3(0, 0, -1); + break; + case PATH_ROTATION_PATH: + break; + case PATH_ROTATION_PATH_FOLLOW: + current_up = curve->interpolate_baked_up_vector(0); + break; + } + + Transform facing = Transform().looking_at(direction, current_up); + current_xform = base_xform.translated(current_point) * facing; + } + + // Create the mesh. + if (end_count > 0) { + // Add front end face. + for (int face_idx = 0; face_idx < shape_face_count; face_idx++) { + for (int face_vertex_idx = 0; face_vertex_idx < 3; face_vertex_idx++) { + // We need to reverse the rotation of the shape face vertices. + int index = shape_faces[face_idx * 3 + 2 - face_vertex_idx]; + Point2 p = shape_polygon[index]; + Point2 uv = (p - shape_rect.position) / shape_rect.size; + + // Use the left side of the bottom half of the y-inverted texture. + uv.x = uv.x / 2; + uv.y = 1 - (uv.y / 2); + + facesw[face * 3 + face_vertex_idx] = current_xform.xform(Vector3(p.x, p.y, 0)); + uvsw[face * 3 + face_vertex_idx] = uv; + } + + smoothw[face] = false; + materialsw[face] = material; + invertw[face] = invert_faces; + face++; + } + } + + // Add extrusion faces. + for (int x0 = 0; x0 < extrusions; x0++) { + previous_xform = current_xform; switch (mode) { case MODE_DEPTH: { - //add triangles, front and back - for (int i = 0; i < 2; i++) { - for (int j = 0; j < triangles.size(); j += 3) { - for (int k = 0; k < 3; k++) { - int src[3] = { 0, i == 0 ? 1 : 2, i == 0 ? 2 : 1 }; - Vector2 p = final_polygon[triangles[j + src[k]]]; - Vector3 v = Vector3(p.x, p.y, 0); - if (i == 0) { - v.z -= depth; - } - facesw[face * 3 + k] = v; - uvsw[face * 3 + k] = (p - final_polygon_min) / final_polygon_size; - if (i == 0) { - uvsw[face * 3 + k].x = 1.0 - uvsw[face * 3 + k].x; /* flip x */ - } - } - - smoothw[face] = false; - materialsw[face] = material; - invertw[face] = invert_val; - face++; - } - } - - //add triangles for depth - for (int i = 0; i < final_polygon.size(); i++) { - int i_n = (i + 1) % final_polygon.size(); - - Vector3 v[4] = { - Vector3(final_polygon[i].x, final_polygon[i].y, -depth), - Vector3(final_polygon[i_n].x, final_polygon[i_n].y, -depth), - Vector3(final_polygon[i_n].x, final_polygon[i_n].y, 0), - Vector3(final_polygon[i].x, final_polygon[i].y, 0), - }; - - Vector2 u[4] = { - Vector2(0, 0), - Vector2(0, 1), - Vector2(1, 1), - Vector2(1, 0) - }; - - // face 1 - facesw[face * 3 + 0] = v[0]; - facesw[face * 3 + 1] = v[1]; - facesw[face * 3 + 2] = v[2]; - - uvsw[face * 3 + 0] = u[0]; - uvsw[face * 3 + 1] = u[1]; - uvsw[face * 3 + 2] = u[2]; - - smoothw[face] = smooth_faces; - invertw[face] = invert_val; - materialsw[face] = material; - - face++; - - // face 2 - facesw[face * 3 + 0] = v[2]; - facesw[face * 3 + 1] = v[3]; - facesw[face * 3 + 2] = v[0]; - - uvsw[face * 3 + 0] = u[2]; - uvsw[face * 3 + 1] = u[3]; - uvsw[face * 3 + 2] = u[0]; - - smoothw[face] = smooth_faces; - invertw[face] = invert_val; - materialsw[face] = material; - - face++; - } - + current_xform.translate(Vector3(0, 0, -depth)); } break; case MODE_SPIN: { - for (int i = 0; i < spin_sides; i++) { - float inci = float(i) / spin_sides; - float inci_n = float((i + 1)) / spin_sides; - - float angi = -(inci * spin_degrees / 360.0) * Math_PI * 2.0; - float angi_n = -(inci_n * spin_degrees / 360.0) * Math_PI * 2.0; - - Vector3 normali = Vector3(Math::cos(angi), 0, Math::sin(angi)); - Vector3 normali_n = Vector3(Math::cos(angi_n), 0, Math::sin(angi_n)); - - //add triangles for depth - for (int j = 0; j < final_polygon.size(); j++) { - int j_n = (j + 1) % final_polygon.size(); - - Vector3 v[4] = { - Vector3(normali.x * final_polygon[j].x, final_polygon[j].y, normali.z * final_polygon[j].x), - Vector3(normali.x * final_polygon[j_n].x, final_polygon[j_n].y, normali.z * final_polygon[j_n].x), - Vector3(normali_n.x * final_polygon[j_n].x, final_polygon[j_n].y, normali_n.z * final_polygon[j_n].x), - Vector3(normali_n.x * final_polygon[j].x, final_polygon[j].y, normali_n.z * final_polygon[j].x), - }; - - Vector2 u[4] = { - Vector2(0, 0), - Vector2(0, 1), - Vector2(1, 1), - Vector2(1, 0) - }; - - // face 1 - facesw[face * 3 + 0] = v[0]; - facesw[face * 3 + 1] = v[2]; - facesw[face * 3 + 2] = v[1]; - - uvsw[face * 3 + 0] = u[0]; - uvsw[face * 3 + 1] = u[2]; - uvsw[face * 3 + 2] = u[1]; - - smoothw[face] = smooth_faces; - invertw[face] = invert_val; - materialsw[face] = material; - - face++; - - // face 2 - facesw[face * 3 + 0] = v[2]; - facesw[face * 3 + 1] = v[0]; - facesw[face * 3 + 2] = v[3]; - - uvsw[face * 3 + 0] = u[2]; - uvsw[face * 3 + 1] = u[0]; - uvsw[face * 3 + 2] = u[3]; - - smoothw[face] = smooth_faces; - invertw[face] = invert_val; - materialsw[face] = material; - - face++; - } - - if (i == 0 && spin_degrees < 360) { - for (int j = 0; j < triangles.size(); j += 3) { - for (int k = 0; k < 3; k++) { - int src[3] = { 0, 2, 1 }; - Vector2 p = final_polygon[triangles[j + src[k]]]; - Vector3 v = Vector3(p.x, p.y, 0); - facesw[face * 3 + k] = v; - uvsw[face * 3 + k] = (p - final_polygon_min) / final_polygon_size; - } - - smoothw[face] = false; - materialsw[face] = material; - invertw[face] = invert_val; - face++; - } - } - - if (i == spin_sides - 1 && spin_degrees < 360) { - for (int j = 0; j < triangles.size(); j += 3) { - for (int k = 0; k < 3; k++) { - int src[3] = { 0, 1, 2 }; - Vector2 p = final_polygon[triangles[j + src[k]]]; - Vector3 v = Vector3(normali_n.x * p.x, p.y, normali_n.z * p.x); - facesw[face * 3 + k] = v; - uvsw[face * 3 + k] = (p - final_polygon_min) / final_polygon_size; - uvsw[face * 3 + k].x = 1.0 - uvsw[face * 3 + k].x; /* flip x */ - } - - smoothw[face] = false; - materialsw[face] = material; - invertw[face] = invert_val; - face++; - } - } - } + current_xform.rotate(Vector3(0, 1, 0), spin_step); } break; case MODE_PATH: { - float bl = curve->get_baked_length(); - int splits = MAX(2, Math::ceil(bl / path_interval)); - float u1 = 0.0; - float u2 = path_continuous_u ? 0.0 : 1.0; - - Transform path_to_this; - if (!path_local) { - // center on paths origin - path_to_this = get_global_transform().affine_inverse() * path->get_global_transform(); - } - - Transform prev_xf; - - Vector3 lookat_dir; - - if (path_rotation == PATH_ROTATION_POLYGON) { - lookat_dir = (path->get_global_transform().affine_inverse() * get_global_transform()).xform(Vector3(0, 0, -1)); - } else { - Vector3 p1, p2; - p1 = curve->interpolate_baked(0); - p2 = curve->interpolate_baked(0.1); - lookat_dir = (p2 - p1).normalized(); - } - - for (int i = 0; i <= splits; i++) { - float ofs = i * path_interval; - if (ofs > bl) { - ofs = bl; - } - if (i == splits && path_joined) { - ofs = 0.0; - } - - Transform xf; - xf.origin = curve->interpolate_baked(ofs); - - Vector3 local_dir; - - if (path_rotation == PATH_ROTATION_PATH_FOLLOW && ofs > 0) { - //before end - Vector3 p1 = curve->interpolate_baked(ofs - 0.1); - Vector3 p2 = curve->interpolate_baked(ofs); - local_dir = (p2 - p1).normalized(); - + double previous_offset = x0 * extrusion_step; + double current_offset = (x0 + 1) * extrusion_step; + double next_offset = (x0 + 2) * extrusion_step; + if (x0 == extrusions - 1) { + if (path_joined) { + current_offset = 0; + next_offset = extrusion_step; } else { - local_dir = lookat_dir; + next_offset = current_offset; } - - xf = xf.looking_at(xf.origin + local_dir, Vector3(0, 1, 0)); - Basis rot(Vector3(0, 0, 1), curve->interpolate_baked_tilt(ofs)); - - xf = xf * rot; //post mult - - xf = path_to_this * xf; - - if (i > 0) { - if (path_continuous_u) { - u1 = u2; - u2 += (prev_xf.origin - xf.origin).length(); - }; - - //put triangles where they belong - //add triangles for depth - for (int j = 0; j < final_polygon.size(); j++) { - int j_n = (j + 1) % final_polygon.size(); - - Vector3 v[4] = { - prev_xf.xform(Vector3(final_polygon[j].x, final_polygon[j].y, 0)), - prev_xf.xform(Vector3(final_polygon[j_n].x, final_polygon[j_n].y, 0)), - xf.xform(Vector3(final_polygon[j_n].x, final_polygon[j_n].y, 0)), - xf.xform(Vector3(final_polygon[j].x, final_polygon[j].y, 0)), - }; - - Vector2 u[4] = { - Vector2(u1, 1), - Vector2(u1, 0), - Vector2(u2, 0), - Vector2(u2, 1) - }; - - // face 1 - facesw[face * 3 + 0] = v[0]; - facesw[face * 3 + 1] = v[1]; - facesw[face * 3 + 2] = v[2]; - - uvsw[face * 3 + 0] = u[0]; - uvsw[face * 3 + 1] = u[1]; - uvsw[face * 3 + 2] = u[2]; - - smoothw[face] = smooth_faces; - invertw[face] = invert_val; - materialsw[face] = material; - - face++; - - // face 2 - facesw[face * 3 + 0] = v[2]; - facesw[face * 3 + 1] = v[3]; - facesw[face * 3 + 2] = v[0]; - - uvsw[face * 3 + 0] = u[2]; - uvsw[face * 3 + 1] = u[3]; - uvsw[face * 3 + 2] = u[0]; - - smoothw[face] = smooth_faces; - invertw[face] = invert_val; - materialsw[face] = material; - - face++; - } - } - - if (i == 0 && !path_joined) { - for (int j = 0; j < triangles.size(); j += 3) { - for (int k = 0; k < 3; k++) { - int src[3] = { 0, 1, 2 }; - Vector2 p = final_polygon[triangles[j + src[k]]]; - Vector3 v = Vector3(p.x, p.y, 0); - facesw[face * 3 + k] = xf.xform(v); - uvsw[face * 3 + k] = (p - final_polygon_min) / final_polygon_size; - } - - smoothw[face] = false; - materialsw[face] = material; - invertw[face] = invert_val; - face++; - } - } - - if (i == splits && !path_joined) { - for (int j = 0; j < triangles.size(); j += 3) { - for (int k = 0; k < 3; k++) { - int src[3] = { 0, 2, 1 }; - Vector2 p = final_polygon[triangles[j + src[k]]]; - Vector3 v = Vector3(p.x, p.y, 0); - facesw[face * 3 + k] = xf.xform(v); - uvsw[face * 3 + k] = (p - final_polygon_min) / final_polygon_size; - uvsw[face * 3 + k].x = 1.0 - uvsw[face * 3 + k].x; /* flip x */ - } - - smoothw[face] = false; - materialsw[face] = material; - invertw[face] = invert_val; - face++; - } - } - - prev_xf = xf; } + Vector3 previous_point = curve->interpolate_baked(previous_offset); + Vector3 current_point = curve->interpolate_baked(current_offset); + Vector3 next_point = curve->interpolate_baked(next_offset); + Vector3 current_up = Vector3(0, 1, 0); + Vector3 direction = next_point - previous_point; + + switch (path_rotation) { + case PATH_ROTATION_POLYGON: + direction = Vector3(0, 0, -1); + break; + case PATH_ROTATION_PATH: + break; + case PATH_ROTATION_PATH_FOLLOW: + current_up = curve->interpolate_baked_up_vector(current_offset); + break; + } + + Transform facing = Transform().looking_at(direction, current_up); + current_xform = base_xform.translated(current_point) * facing; } break; } - if (face != face_count) { - ERR_PRINT("Face mismatch bug! fix code"); + double u0 = x0 * u_step; + double u1 = ((x0 + 1) * u_step); + if (mode == MODE_PATH && !path_continuous_u) { + u0 = 0.0; + u1 = 1.0; } - for (int i = 0; i < face_count * 3; i++) { - if (i == 0) { - aabb.position = facesw[i]; - } else { - aabb.expand_to(facesw[i]); - } - // invert UVs on the Y-axis OpenGL = upside down - uvsw[i].y = 1.0 - uvsw[i].y; + for (int y0 = 0; y0 < shape_sides; y0++) { + int y1 = (y0 + 1) % shape_sides; + // Use the top half of the texture. + double v0 = (y0 * v_step) / 2; + double v1 = ((y0 + 1) * v_step) / 2; + + Vector3 v[4] = { + previous_xform.xform(Vector3(shape_polygon[y0].x, shape_polygon[y0].y, 0)), + current_xform.xform(Vector3(shape_polygon[y0].x, shape_polygon[y0].y, 0)), + current_xform.xform(Vector3(shape_polygon[y1].x, shape_polygon[y1].y, 0)), + previous_xform.xform(Vector3(shape_polygon[y1].x, shape_polygon[y1].y, 0)), + }; + + Vector2 u[4] = { + Vector2(u0, v0), + Vector2(u1, v0), + Vector2(u1, v1), + Vector2(u0, v1), + }; + + // Face 1 + facesw[face * 3 + 0] = v[0]; + facesw[face * 3 + 1] = v[1]; + facesw[face * 3 + 2] = v[2]; + + uvsw[face * 3 + 0] = u[0]; + uvsw[face * 3 + 1] = u[1]; + uvsw[face * 3 + 2] = u[2]; + + smoothw[face] = smooth_faces; + invertw[face] = invert_faces; + materialsw[face] = material; + + face++; + + // Face 2 + facesw[face * 3 + 0] = v[2]; + facesw[face * 3 + 1] = v[3]; + facesw[face * 3 + 2] = v[0]; + + uvsw[face * 3 + 0] = u[2]; + uvsw[face * 3 + 1] = u[3]; + uvsw[face * 3 + 2] = u[0]; + + smoothw[face] = smooth_faces; + invertw[face] = invert_faces; + materialsw[face] = material; + + face++; } } + if (end_count > 1) { + // Add back end face. + for (int face_idx = 0; face_idx < shape_face_count; face_idx++) { + for (int face_vertex_idx = 0; face_vertex_idx < 3; face_vertex_idx++) { + int index = shape_faces[face_idx * 3 + face_vertex_idx]; + Point2 p = shape_polygon[index]; + Point2 uv = (p - shape_rect.position) / shape_rect.size; + + // Use the x-inverted ride side of the bottom half of the y-inverted texture. + uv.x = 1 - uv.x / 2; + uv.y = 1 - (uv.y / 2); + + facesw[face * 3 + face_vertex_idx] = current_xform.xform(Vector3(p.x, p.y, 0)); + uvsw[face * 3 + face_vertex_idx] = uv; + } + + smoothw[face] = false; + materialsw[face] = material; + invertw[face] = invert_faces; + face++; + } + } + + ERR_FAIL_COND_V_MSG(face != face_count, brush, "Bug: Failed to create the CSGPolygon mesh correctly."); + brush->build_from_faces(faces, uvs, smooth, materials, invert); return brush; @@ -2221,10 +2045,10 @@ CSGBrush *CSGPolygon::_build_brush() { void CSGPolygon::_notification(int p_what) { if (p_what == NOTIFICATION_EXIT_TREE) { - if (path_cache) { - path_cache->disconnect("tree_exited", this, "_path_exited"); - path_cache->disconnect("curve_changed", this, "_path_changed"); - path_cache = nullptr; + if (path) { + path->disconnect("tree_exited", this, "_path_exited"); + path->disconnect("curve_changed", this, "_path_changed"); + path = nullptr; } } } @@ -2249,7 +2073,7 @@ void CSGPolygon::_path_changed() { } void CSGPolygon::_path_exited() { - path_cache = nullptr; + path = nullptr; } void CSGPolygon::_bind_methods() { @@ -2271,10 +2095,10 @@ void CSGPolygon::_bind_methods() { ClassDB::bind_method(D_METHOD("set_path_node", "path"), &CSGPolygon::set_path_node); ClassDB::bind_method(D_METHOD("get_path_node"), &CSGPolygon::get_path_node); - ClassDB::bind_method(D_METHOD("set_path_interval", "distance"), &CSGPolygon::set_path_interval); + ClassDB::bind_method(D_METHOD("set_path_interval", "path_interval"), &CSGPolygon::set_path_interval); ClassDB::bind_method(D_METHOD("get_path_interval"), &CSGPolygon::get_path_interval); - ClassDB::bind_method(D_METHOD("set_path_rotation", "mode"), &CSGPolygon::set_path_rotation); + ClassDB::bind_method(D_METHOD("set_path_rotation", "path_rotation"), &CSGPolygon::set_path_rotation); ClassDB::bind_method(D_METHOD("get_path_rotation"), &CSGPolygon::get_path_rotation); ClassDB::bind_method(D_METHOD("set_path_local", "enable"), &CSGPolygon::set_path_local); @@ -2300,11 +2124,11 @@ void CSGPolygon::_bind_methods() { ADD_PROPERTY(PropertyInfo(Variant::POOL_VECTOR2_ARRAY, "polygon"), "set_polygon", "get_polygon"); ADD_PROPERTY(PropertyInfo(Variant::INT, "mode", PROPERTY_HINT_ENUM, "Depth,Spin,Path"), "set_mode", "get_mode"); - ADD_PROPERTY(PropertyInfo(Variant::REAL, "depth", PROPERTY_HINT_EXP_RANGE, "0.001,1000.0,0.001,or_greater"), "set_depth", "get_depth"); + ADD_PROPERTY(PropertyInfo(Variant::REAL, "depth", PROPERTY_HINT_EXP_RANGE, "0.01,100.0,0.01,or_greater"), "set_depth", "get_depth"); ADD_PROPERTY(PropertyInfo(Variant::REAL, "spin_degrees", PROPERTY_HINT_RANGE, "1,360,0.1"), "set_spin_degrees", "get_spin_degrees"); ADD_PROPERTY(PropertyInfo(Variant::INT, "spin_sides", PROPERTY_HINT_RANGE, "3,64,1"), "set_spin_sides", "get_spin_sides"); ADD_PROPERTY(PropertyInfo(Variant::NODE_PATH, "path_node", PROPERTY_HINT_NODE_PATH_VALID_TYPES, "Path"), "set_path_node", "get_path_node"); - ADD_PROPERTY(PropertyInfo(Variant::REAL, "path_interval", PROPERTY_HINT_EXP_RANGE, "0.001,1000.0,0.001,or_greater"), "set_path_interval", "get_path_interval"); + ADD_PROPERTY(PropertyInfo(Variant::REAL, "path_interval", PROPERTY_HINT_RANGE, "0.1,1.0,0.05"), "set_path_interval", "get_path_interval"); ADD_PROPERTY(PropertyInfo(Variant::INT, "path_rotation", PROPERTY_HINT_ENUM, "Polygon,Path,PathFollow"), "set_path_rotation", "get_path_rotation"); ADD_PROPERTY(PropertyInfo(Variant::BOOL, "path_local"), "set_path_local", "is_path_local"); ADD_PROPERTY(PropertyInfo(Variant::BOOL, "path_continuous_u"), "set_path_continuous_u", "is_path_continuous_u"); @@ -2373,7 +2197,7 @@ float CSGPolygon::get_spin_degrees() const { return spin_degrees; } -void CSGPolygon::set_spin_sides(const int p_spin_sides) { +void CSGPolygon::set_spin_sides(int p_spin_sides) { ERR_FAIL_COND(p_spin_sides < 3); spin_sides = p_spin_sides; _make_dirty(); @@ -2395,11 +2219,12 @@ NodePath CSGPolygon::get_path_node() const { } void CSGPolygon::set_path_interval(float p_interval) { - ERR_FAIL_COND_MSG(p_interval < 0.001, "Path interval cannot be smaller than 0.001."); + ERR_FAIL_COND_MSG(p_interval <= 0 || p_interval > 1, "Path interval must be greater than 0 and less than or equal to 1.0."); path_interval = p_interval; _make_dirty(); update_gizmo(); } + float CSGPolygon::get_path_interval() const { return path_interval; } @@ -2471,10 +2296,10 @@ CSGPolygon::CSGPolygon() { spin_degrees = 360; spin_sides = 8; smooth_faces = false; - path_interval = 1; - path_rotation = PATH_ROTATION_PATH; + path_interval = 1.0; + path_rotation = PATH_ROTATION_PATH_FOLLOW; path_local = false; - path_continuous_u = false; + path_continuous_u = true; path_joined = false; - path_cache = nullptr; + path = nullptr; } diff --git a/modules/csg/csg_shape.h b/modules/csg/csg_shape.h index b5730e2b9c2..76ad791ad86 100644 --- a/modules/csg/csg_shape.h +++ b/modules/csg/csg_shape.h @@ -34,6 +34,7 @@ #define CSGJS_HEADER_ONLY #include "csg.h" +#include "scene/3d/path.h" #include "scene/3d/visual_instance.h" #include "scene/resources/concave_polygon_shape.h" #include "thirdparty/misc/mikktspace.h" @@ -170,10 +171,8 @@ public: class CSGPrimitive : public CSGShape { GDCLASS(CSGPrimitive, CSGShape); -private: - bool invert_faces; - protected: + bool invert_faces; CSGBrush *_create_brush_from_arrays(const PoolVector &p_vertices, const PoolVector &p_uv, const PoolVector &p_smooth, const PoolVector> &p_materials); static void _bind_methods(); @@ -371,7 +370,7 @@ private: PathRotation path_rotation; bool path_local; - Node *path_cache; + Path *path; bool smooth_faces; bool path_continuous_u; diff --git a/modules/csg/doc_classes/CSGPolygon.xml b/modules/csg/doc_classes/CSGPolygon.xml index 287132996fe..e5287a4a7ec 100644 --- a/modules/csg/doc_classes/CSGPolygon.xml +++ b/modules/csg/doc_classes/CSGPolygon.xml @@ -4,7 +4,7 @@ Extrudes a 2D polygon shape to create a 3D mesh. - This node takes a 2D polygon shape and extrudes it to create a 3D mesh. + An array of 2D points is extruded to quickly and easily create a variety of 3D meshes. @@ -12,63 +12,65 @@ - Extrusion depth when [member mode] is [constant MODE_DEPTH]. + When [member mode] is [constant MODE_DEPTH], the depth of the extrusion. - Material to use for the resulting mesh. + Material to use for the resulting mesh. The UV maps the top half of the material to the extruded shape (U along the the length of the extrusions and V around the outline of the [member polygon]), the bottom-left quarter to the front end face, and the bottom-right quarter to the back end face. - Extrusion mode. + The [member mode] used to extrude the [member polygon]. - If [code]true[/code] the u component of our uv will continuously increase in unison with the distance traveled along our path when [member mode] is [constant MODE_PATH]. + When [member mode] is [constant MODE_PATH], by default, the top half of the [member material] is stretched along the entire length of the extruded shape. If [code]false[/code] the top half of the material is repeated every step of the extrusion. - Interval at which a new extrusion slice is added along the path when [member mode] is [constant MODE_PATH]. + When [member mode] is [constant MODE_PATH], the path interval or ratio of path points to extrusions. - If [code]true[/code] the start and end of our path are joined together ensuring there is no seam when [member mode] is [constant MODE_PATH]. + When [member mode] is [constant MODE_PATH], if [code]true[/code] the ends of the path are joined, by adding an extrusion between the last and first points of the path. - If [code]false[/code] we extrude centered on our path, if [code]true[/code] we extrude in relation to the position of our CSGPolygon when [member mode] is [constant MODE_PATH]. + When [member mode] is [constant MODE_PATH], if [code]true[/code] the [Transform] of the [CSGPolygon] is used as the starting point for the extrusions, not the [Transform] of the [member path_node]. - The [Shape] object containing the path along which we extrude when [member mode] is [constant MODE_PATH]. + When [member mode] is [constant MODE_PATH], the location of the [Path] object used to extrude the [member polygon]. - The method by which each slice is rotated along the path when [member mode] is [constant MODE_PATH]. + When [member mode] is [constant MODE_PATH], the [enum PathRotation] method used to rotate the [member polygon] as it is extruded. - Point array that defines the shape that we'll extrude. + The point array that defines the 2D polygon that is extruded. - Generates smooth normals so smooth shading is applied to our mesh. + If [code]true[/code], applies smooth shading to the extrusions. - Degrees to rotate our extrusion for each slice when [member mode] is [constant MODE_SPIN]. + When [member mode] is [constant MODE_SPIN], the total number of degrees the [member polygon] is rotated when extruding. - Number of extrusion when [member mode] is [constant MODE_SPIN]. + When [member mode] is [constant MODE_SPIN], the number of extrusions made. - Shape is extruded to [member depth]. + The [member polygon] shape is extruded along the negative Z axis. - Shape is extruded by rotating it around an axis. + The [member polygon] shape is extruded by rotating it around the Y axis. - Shape is extruded along a path set by a [Shape] set in [member path_node]. + The [member polygon] shape is extruded along the [Path] specified in [member path_node]. - Slice is not rotated. + The [member polygon] shape is not rotated. + [b]Note:[/b] Requires the path's Z coordinates to continually decrease to ensure viable shapes. - Slice is rotated around the up vector of the path. + The [member polygon] shape is rotated along the path, but it is not rotated around the path axis. + [b]Note:[/b] Requires the path's Z coordinates to continually decrease to ensure viable shapes. - Slice is rotate to match the path exactly. + The [member polygon] shape follows the path and its rotations around the path axis.