17 files changed, 396 insertions, 232 deletions

diff --git a/doc/classes/BaseMaterial3D.xml b/doc/classes/BaseMaterial3D.xml
index 33a129a48e..2262c4fe47 100644
--- a/doc/classes/BaseMaterial3D.xml
+++ b/doc/classes/BaseMaterial3D.xml
@@ -82,7 +82,7 @@
 			The hashing scale for Alpha Hash. Recommended values between [code]0[/code] and [code]2[/code].
 		</member>
 		<member name="alpha_scissor_threshold" type="float" setter="set_alpha_scissor_threshold" getter="get_alpha_scissor_threshold">
-			Threshold at which the alpha scissor will discard values.
+			Threshold at which the alpha scissor will discard values. Higher values will result in more pixels being discarded. If the material becomes too opaque at a distance, try increasing [member alpha_scissor_threshold]. If the material disappears at a distance, try decreasing [member alpha_scissor_threshold].
 		</member>
 		<member name="anisotropy" type="float" setter="set_anisotropy" getter="get_anisotropy" default="0.0">
 			The strength of the anisotropy effect. This is multiplied by [member anisotropy_flowmap]'s alpha channel if a texture is defined there and the texture contains an alpha channel.
diff --git a/doc/classes/CPUParticles3D.xml b/doc/classes/CPUParticles3D.xml
index 99fd0501fc..6b39c08b3f 100644
--- a/doc/classes/CPUParticles3D.xml
+++ b/doc/classes/CPUParticles3D.xml
@@ -123,13 +123,16 @@
 			Minimum particle animation speed.
 		</member>
 		<member name="color" type="Color" setter="set_color" getter="get_color" default="Color(1, 1, 1, 1)">
-			Each particle's initial color. To have particle display color in a [BaseMaterial3D] make sure to set [member BaseMaterial3D.vertex_color_use_as_albedo] to [code]true[/code].
+			Each particle's initial color.
+			[b]Note:[/b] [member color] multiplies the particle mesh's vertex colors. To have a visible effect on a [BaseMaterial3D], [member BaseMaterial3D.vertex_color_use_as_albedo] [i]must[/i] be [code]true[/code]. For a [ShaderMaterial], [code]ALBEDO *= COLOR.rgb;[/code] must be inserted in the shader's [code]fragment()[/code] function. Otherwise, [member color] will have no visible effect.
 		</member>
 		<member name="color_initial_ramp" type="Gradient" setter="set_color_initial_ramp" getter="get_color_initial_ramp">
 			Each particle's initial color will vary along this [GradientTexture1D] (multiplied with [member color]).
+			[b]Note:[/b] [member color_initial_ramp] multiplies the particle mesh's vertex colors. To have a visible effect on a [BaseMaterial3D], [member BaseMaterial3D.vertex_color_use_as_albedo] [i]must[/i] be [code]true[/code]. For a [ShaderMaterial], [code]ALBEDO *= COLOR.rgb;[/code] must be inserted in the shader's [code]fragment()[/code] function. Otherwise, [member color_initial_ramp] will have no visible effect.
 		</member>
 		<member name="color_ramp" type="Gradient" setter="set_color_ramp" getter="get_color_ramp">
 			Each particle's color will vary along this [GradientTexture1D] over its lifetime (multiplied with [member color]).
+			[b]Note:[/b] [member color_ramp] multiplies the particle mesh's vertex colors. To have a visible effect on a [BaseMaterial3D], [member BaseMaterial3D.vertex_color_use_as_albedo] [i]must[/i] be [code]true[/code]. For a [ShaderMaterial], [code]ALBEDO *= COLOR.rgb;[/code] must be inserted in the shader's [code]fragment()[/code] function. Otherwise, [member color_ramp] will have no visible effect.
 		</member>
 		<member name="damping_curve" type="Curve" setter="set_param_curve" getter="get_param_curve">
 			Damping will vary along this [Curve].
@@ -151,6 +154,7 @@
 		</member>
 		<member name="emission_colors" type="PackedColorArray" setter="set_emission_colors" getter="get_emission_colors" default="PackedColorArray()">
 			Sets the [Color]s to modulate particles by when using [constant EMISSION_SHAPE_POINTS] or [constant EMISSION_SHAPE_DIRECTED_POINTS].
+			[b]Note:[/b] [member emission_colors] multiplies the particle mesh's vertex colors. To have a visible effect on a [BaseMaterial3D], [member BaseMaterial3D.vertex_color_use_as_albedo] [i]must[/i] be [code]true[/code]. For a [ShaderMaterial], [code]ALBEDO *= COLOR.rgb;[/code] must be inserted in the shader's [code]fragment()[/code] function. Otherwise, [member emission_colors] will have no visible effect.
 		</member>
 		<member name="emission_normals" type="PackedVector3Array" setter="set_emission_normals" getter="get_emission_normals">
 			Sets the direction the particles will be emitted in when using [constant EMISSION_SHAPE_DIRECTED_POINTS].
diff --git a/doc/classes/ParticleProcessMaterial.xml b/doc/classes/ParticleProcessMaterial.xml
index 1526658eed..a41207e9b3 100644
--- a/doc/classes/ParticleProcessMaterial.xml
+++ b/doc/classes/ParticleProcessMaterial.xml
@@ -129,13 +129,16 @@
 			Should collision take scale into account.
 		</member>
 		<member name="color" type="Color" setter="set_color" getter="get_color" default="Color(1, 1, 1, 1)">
-			Each particle's initial color. If the [GPUParticles2D]'s [code]texture[/code] is defined, it will be multiplied by this color. To have particle display color in a [BaseMaterial3D] make sure to set [member BaseMaterial3D.vertex_color_use_as_albedo] to [code]true[/code].
+			Each particle's initial color. If the [GPUParticles2D]'s [code]texture[/code] is defined, it will be multiplied by this color.
+			[b]Note:[/b] [member color] multiplies the particle mesh's vertex colors. To have a visible effect on a [BaseMaterial3D], [member BaseMaterial3D.vertex_color_use_as_albedo] [i]must[/i] be [code]true[/code]. For a [ShaderMaterial], [code]ALBEDO *= COLOR.rgb;[/code] must be inserted in the shader's [code]fragment()[/code] function. Otherwise, [member color] will have no visible effect.
 		</member>
 		<member name="color_initial_ramp" type="Texture2D" setter="set_color_initial_ramp" getter="get_color_initial_ramp">
 			Each particle's initial color will vary along this [GradientTexture1D] (multiplied with [member color]).
+			[b]Note:[/b] [member color_initial_ramp] multiplies the particle mesh's vertex colors. To have a visible effect on a [BaseMaterial3D], [member BaseMaterial3D.vertex_color_use_as_albedo] [i]must[/i] be [code]true[/code]. For a [ShaderMaterial], [code]ALBEDO *= COLOR.rgb;[/code] must be inserted in the shader's [code]fragment()[/code] function. Otherwise, [member color_initial_ramp] will have no visible effect.
 		</member>
 		<member name="color_ramp" type="Texture2D" setter="set_color_ramp" getter="get_color_ramp">
 			Each particle's color will vary along this [GradientTexture1D] over its lifetime (multiplied with [member color]).
+			[b]Note:[/b] [member color_ramp] multiplies the particle mesh's vertex colors. To have a visible effect on a [BaseMaterial3D], [member BaseMaterial3D.vertex_color_use_as_albedo] [i]must[/i] be [code]true[/code]. For a [ShaderMaterial], [code]ALBEDO *= COLOR.rgb;[/code] must be inserted in the shader's [code]fragment()[/code] function. Otherwise, [member color_ramp] will have no visible effect.
 		</member>
 		<member name="damping_curve" type="Texture2D" setter="set_param_texture" getter="get_param_texture">
 			Damping will vary along this [CurveTexture].
@@ -154,6 +157,7 @@
 		</member>
 		<member name="emission_color_texture" type="Texture2D" setter="set_emission_color_texture" getter="get_emission_color_texture">
 			Particle color will be modulated by color determined by sampling this texture at the same point as the [member emission_point_texture].
+			[b]Note:[/b] [member emission_color_texture] multiplies the particle mesh's vertex colors. To have a visible effect on a [BaseMaterial3D], [member BaseMaterial3D.vertex_color_use_as_albedo] [i]must[/i] be [code]true[/code]. For a [ShaderMaterial], [code]ALBEDO *= COLOR.rgb;[/code] must be inserted in the shader's [code]fragment()[/code] function. Otherwise, [member emission_color_texture] will have no visible effect.
 		</member>
 		<member name="emission_normal_texture" type="Texture2D" setter="set_emission_normal_texture" getter="get_emission_normal_texture">
 			Particle velocity and rotation will be set by sampling this texture at the same point as the [member emission_point_texture]. Used only in [constant EMISSION_SHAPE_DIRECTED_POINTS]. Can be created automatically from mesh or node by selecting "Create Emission Points from Mesh/Node" under the "Particles" tool in the toolbar.
diff --git a/drivers/vulkan/vulkan_context.cpp b/drivers/vulkan/vulkan_context.cpp
index afc3e78372..b52179b4f3 100644
--- a/drivers/vulkan/vulkan_context.cpp
+++ b/drivers/vulkan/vulkan_context.cpp
@@ -1436,6 +1436,24 @@ bool VulkanContext::_use_validation_layers() {
 	return Engine::get_singleton()->is_validation_layers_enabled();
 }
 
+VkExtent2D VulkanContext::_compute_swapchain_extent(const VkSurfaceCapabilitiesKHR &p_surf_capabilities, int *p_window_width, int *p_window_height) const {
+	// Width and height are either both 0xFFFFFFFF, or both not 0xFFFFFFFF.
+	if (p_surf_capabilities.currentExtent.width == 0xFFFFFFFF) {
+		// If the surface size is undefined, the size is set to the size
+		// of the images requested, which must fit within the minimum and
+		// maximum values.
+		VkExtent2D extent = {};
+		extent.width = CLAMP((uint32_t)(*p_window_width), p_surf_capabilities.minImageExtent.width, p_surf_capabilities.maxImageExtent.width);
+		extent.height = CLAMP((uint32_t)(*p_window_height), p_surf_capabilities.minImageExtent.height, p_surf_capabilities.maxImageExtent.height);
+		return extent;
+	} else {
+		// If the surface size is defined, the swap chain size must match.
+		*p_window_width = p_surf_capabilities.currentExtent.width;
+		*p_window_height = p_surf_capabilities.currentExtent.height;
+		return p_surf_capabilities.currentExtent;
+	}
+}
+
 Error VulkanContext::_window_create(DisplayServer::WindowID p_window_id, DisplayServer::VSyncMode p_vsync_mode, VkSurfaceKHR p_surface, int p_width, int p_height) {
 	ERR_FAIL_COND_V(windows.has(p_window_id), ERR_INVALID_PARAMETER);
 
@@ -1576,32 +1594,7 @@ Error VulkanContext::_update_swap_chain(Window *window) {
 		ERR_FAIL_V(ERR_CANT_CREATE);
 	}
 
-	VkExtent2D swapchainExtent;
-	// Width and height are either both 0xFFFFFFFF, or both not 0xFFFFFFFF.
-	if (surfCapabilities.currentExtent.width == 0xFFFFFFFF) {
-		// If the surface size is undefined, the size is set to the size
-		// of the images requested, which must fit within the minimum and
-		// maximum values.
-		swapchainExtent.width = window->width;
-		swapchainExtent.height = window->height;
-
-		if (swapchainExtent.width < surfCapabilities.minImageExtent.width) {
-			swapchainExtent.width = surfCapabilities.minImageExtent.width;
-		} else if (swapchainExtent.width > surfCapabilities.maxImageExtent.width) {
-			swapchainExtent.width = surfCapabilities.maxImageExtent.width;
-		}
-
-		if (swapchainExtent.height < surfCapabilities.minImageExtent.height) {
-			swapchainExtent.height = surfCapabilities.minImageExtent.height;
-		} else if (swapchainExtent.height > surfCapabilities.maxImageExtent.height) {
-			swapchainExtent.height = surfCapabilities.maxImageExtent.height;
-		}
-	} else {
-		// If the surface size is defined, the swap chain size must match.
-		swapchainExtent = surfCapabilities.currentExtent;
-		window->width = surfCapabilities.currentExtent.width;
-		window->height = surfCapabilities.currentExtent.height;
-	}
+	VkExtent2D swapchainExtent = _compute_swapchain_extent(surfCapabilities, &window->width, &window->height);
 
 	if (window->width == 0 || window->height == 0) {
 		free(presentModes);
diff --git a/drivers/vulkan/vulkan_context.h b/drivers/vulkan/vulkan_context.h
index 5cc3b515d9..9889cf336b 100644
--- a/drivers/vulkan/vulkan_context.h
+++ b/drivers/vulkan/vulkan_context.h
@@ -266,6 +266,8 @@ protected:
 
 	Error _get_preferred_validation_layers(uint32_t *count, const char *const **names);
 
+	virtual VkExtent2D _compute_swapchain_extent(const VkSurfaceCapabilitiesKHR &p_surf_capabilities, int *p_window_width, int *p_window_height) const;
+
 public:
 	// Extension calls.
 	VkResult vkCreateRenderPass2KHR(VkDevice device, const VkRenderPassCreateInfo2 *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkRenderPass *pRenderPass);
diff --git a/editor/editor_themes.cpp b/editor/editor_themes.cpp
index 827a657a31..d20caef51c 100644
--- a/editor/editor_themes.cpp
+++ b/editor/editor_themes.cpp
@@ -476,6 +476,7 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 	const Color font_color = mono_color.lerp(base_color, 0.25);
 	const Color font_hover_color = mono_color.lerp(base_color, 0.125);
 	const Color font_focus_color = mono_color.lerp(base_color, 0.125);
+	const Color font_hover_pressed_color = font_hover_color.lerp(accent_color, 0.74);
 	const Color font_disabled_color = Color(mono_color.r, mono_color.g, mono_color.b, 0.3);
 	const Color font_readonly_color = Color(mono_color.r, mono_color.g, mono_color.b, 0.65);
 	const Color font_placeholder_color = Color(mono_color.r, mono_color.g, mono_color.b, 0.6);
@@ -750,6 +751,7 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 
 	theme->set_color("font_color", "MenuButton", font_color);
 	theme->set_color("font_hover_color", "MenuButton", font_hover_color);
+	theme->set_color("font_hover_pressed_color", "MenuButton", font_hover_pressed_color);
 	theme->set_color("font_focus_color", "MenuButton", font_focus_color);
 
 	theme->set_stylebox("MenuHover", "EditorStyles", style_widget_hover);
@@ -763,6 +765,7 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 
 	theme->set_color("font_color", "Button", font_color);
 	theme->set_color("font_hover_color", "Button", font_hover_color);
+	theme->set_color("font_hover_pressed_color", "Button", font_hover_pressed_color);
 	theme->set_color("font_focus_color", "Button", font_focus_color);
 	theme->set_color("font_pressed_color", "Button", accent_color);
 	theme->set_color("font_disabled_color", "Button", font_disabled_color);
@@ -815,6 +818,7 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 
 	theme->set_color("font_color", "MenuBar", font_color);
 	theme->set_color("font_hover_color", "MenuBar", font_hover_color);
+	theme->set_color("font_hover_pressed_color", "MenuBar", font_hover_pressed_color);
 	theme->set_color("font_focus_color", "MenuBar", font_focus_color);
 	theme->set_color("font_pressed_color", "MenuBar", accent_color);
 	theme->set_color("font_disabled_color", "MenuBar", font_disabled_color);
@@ -851,6 +855,7 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 
 	theme->set_color("font_color", "OptionButton", font_color);
 	theme->set_color("font_hover_color", "OptionButton", font_hover_color);
+	theme->set_color("font_hover_pressed_color", "OptionButton", font_hover_pressed_color);
 	theme->set_color("font_focus_color", "OptionButton", font_focus_color);
 	theme->set_color("font_pressed_color", "OptionButton", accent_color);
 	theme->set_color("font_disabled_color", "OptionButton", font_disabled_color);
@@ -885,6 +890,7 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 
 	theme->set_color("font_color", "CheckButton", font_color);
 	theme->set_color("font_hover_color", "CheckButton", font_hover_color);
+	theme->set_color("font_hover_pressed_color", "CheckButton", font_hover_pressed_color);
 	theme->set_color("font_focus_color", "CheckButton", font_focus_color);
 	theme->set_color("font_pressed_color", "CheckButton", accent_color);
 	theme->set_color("font_disabled_color", "CheckButton", font_disabled_color);
@@ -921,6 +927,7 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 
 	theme->set_color("font_color", "CheckBox", font_color);
 	theme->set_color("font_hover_color", "CheckBox", font_hover_color);
+	theme->set_color("font_hover_pressed_color", "CheckBox", font_hover_pressed_color);
 	theme->set_color("font_focus_color", "CheckBox", font_focus_color);
 	theme->set_color("font_pressed_color", "CheckBox", accent_color);
 	theme->set_color("font_disabled_color", "CheckBox", font_disabled_color);
@@ -1478,6 +1485,7 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 	theme->set_stylebox("focus", "LinkButton", style_empty);
 	theme->set_color("font_color", "LinkButton", font_color);
 	theme->set_color("font_hover_color", "LinkButton", font_hover_color);
+	theme->set_color("font_hover_pressed_color", "LinkButton", font_hover_pressed_color);
 	theme->set_color("font_focus_color", "LinkButton", font_focus_color);
 	theme->set_color("font_pressed_color", "LinkButton", accent_color);
 	theme->set_color("font_disabled_color", "LinkButton", font_disabled_color);
@@ -1508,8 +1516,8 @@ Ref<Theme> create_editor_theme(const Ref<Theme> p_theme) {
 	control_editor_popup_style->set_default_margin(SIDE_BOTTOM, default_margin_size * EDSCALE);
 	control_editor_popup_style->set_border_width_all(0);
 
-	theme->set_stylebox("panel", "ControlEditorPopupButton", control_editor_popup_style);
-	theme->set_type_variation("ControlEditorPopupButton", "PopupPanel");
+	theme->set_stylebox("panel", "ControlEditorPopupPanel", control_editor_popup_style);
+	theme->set_type_variation("ControlEditorPopupPanel", "PopupPanel");
 
 	// SpinBox
 	theme->set_icon("updown", "SpinBox", theme->get_icon(SNAME("GuiSpinboxUpdown"), SNAME("EditorIcons")));
diff --git a/editor/plugins/animation_tree_editor_plugin.cpp b/editor/plugins/animation_tree_editor_plugin.cpp
index bce4c9de8e..ed231c446b 100644
--- a/editor/plugins/animation_tree_editor_plugin.cpp
+++ b/editor/plugins/animation_tree_editor_plugin.cpp
@@ -59,10 +59,11 @@ void AnimationTreeEditor::edit(AnimationTree *p_tree) {
 	Vector<String> path;
 	if (tree && tree->has_meta("_tree_edit_path")) {
 		path = tree->get_meta("_tree_edit_path");
-		edit_path(path);
 	} else {
 		current_root = ObjectID();
 	}
+
+	edit_path(path);
 }
 
 void AnimationTreeEditor::_path_button_pressed(int p_path) {
@@ -129,6 +130,11 @@ void AnimationTreeEditor::edit_path(const Vector<String> &p_path) {
 	} else {
 		current_root = ObjectID();
 		edited_path = button_path;
+
+		for (int i = 0; i < editors.size(); i++) {
+			editors[i]->edit(Ref<AnimationNode>());
+			editors[i]->hide();
+		}
 	}
 
 	_update_path();
diff --git a/editor/plugins/control_editor_plugin.cpp b/editor/plugins/control_editor_plugin.cpp
index 69f32a3a98..bb6092755e 100644
--- a/editor/plugins/control_editor_plugin.cpp
+++ b/editor/plugins/control_editor_plugin.cpp
@@ -523,7 +523,7 @@ ControlEditorPopupButton::ControlEditorPopupButton() {
 	set_focus_mode(FOCUS_NONE);
 
 	popup_panel = memnew(PopupPanel);
-	popup_panel->set_theme_type_variation("ControlEditorPopupButton");
+	popup_panel->set_theme_type_variation("ControlEditorPopupPanel");
 	add_child(popup_panel);
 	popup_panel->connect("about_to_popup", callable_mp(this, &ControlEditorPopupButton::_popup_visibility_changed).bind(true));
 	popup_panel->connect("popup_hide", callable_mp(this, &ControlEditorPopupButton::_popup_visibility_changed).bind(false));
diff --git a/editor/scene_tree_dock.cpp b/editor/scene_tree_dock.cpp
index c7c713fc67..f6ecaad67b 100644
--- a/editor/scene_tree_dock.cpp
+++ b/editor/scene_tree_dock.cpp
@@ -1068,24 +1068,61 @@ void SceneTreeDock::_tool_selected(int p_tool, bool p_confirm_override) {
 			}
 		} break;
 		case TOOL_TOGGLE_SCENE_UNIQUE_NAME: {
-			List<Node *> selection = editor_selection->get_selected_node_list();
-			List<Node *>::Element *e = selection.front();
-			if (e) {
-				Ref<EditorUndoRedoManager> undo_redo = editor_data->get_undo_redo();
-				Node *node = e->get();
-				bool enabled = node->is_unique_name_in_owner();
-				if (!enabled && get_tree()->get_edited_scene_root()->get_node_or_null(UNIQUE_NODE_PREFIX + String(node->get_name())) != nullptr) {
-					accept->set_text(TTR("Another node already uses this unique name in the scene."));
+			// Enabling/disabling based on the same node based on which the checkbox in the menu is checked/unchecked.
+			List<Node *>::Element *first_selected = editor_selection->get_selected_node_list().front();
+			if (first_selected == nullptr) {
+				return;
+			}
+			bool enabling = !first_selected->get()->is_unique_name_in_owner();
+
+			List<Node *> full_selection = editor_selection->get_full_selected_node_list();
+			Ref<EditorUndoRedoManager> undo_redo = editor_data->get_undo_redo();
+
+			if (enabling) {
+				Vector<Node *> new_unique_nodes;
+				Vector<StringName> new_unique_names;
+				Vector<StringName> cant_be_set_unique_names;
+
+				for (Node *node : full_selection) {
+					if (node->is_unique_name_in_owner()) {
+						continue;
+					}
+					StringName name = node->get_name();
+					if (new_unique_names.find(name) != -1 || get_tree()->get_edited_scene_root()->get_node_or_null(UNIQUE_NODE_PREFIX + String(name)) != nullptr) {
+						cant_be_set_unique_names.push_back(name);
+					} else {
+						new_unique_nodes.push_back(node);
+						new_unique_names.push_back(name);
+					}
+				}
+
+				if (new_unique_nodes.size()) {
+					undo_redo->create_action(TTR("Enable Scene Unique Name(s)"));
+					for (Node *node : new_unique_nodes) {
+						undo_redo->add_do_method(node, "set_unique_name_in_owner", true);
+						undo_redo->add_undo_method(node, "set_unique_name_in_owner", false);
+					}
+					undo_redo->commit_action();
+				}
+
+				if (cant_be_set_unique_names.size()) {
+					String popup_text = TTR("Unique names already used by another node in the scene:");
+					popup_text += "\n";
+					for (StringName name : cant_be_set_unique_names) {
+						popup_text += "\n" + String(name);
+					}
+					accept->set_text(popup_text);
 					accept->popup_centered();
-					return;
 				}
-				if (!enabled) {
-					undo_redo->create_action(TTR("Enable Scene Unique Name"));
-				} else {
-					undo_redo->create_action(TTR("Disable Scene Unique Name"));
+			} else { // Disabling.
+				undo_redo->create_action(TTR("Disable Scene Unique Name(s)"));
+				for (Node *node : full_selection) {
+					if (!node->is_unique_name_in_owner()) {
+						continue;
+					}
+					undo_redo->add_do_method(node, "set_unique_name_in_owner", false);
+					undo_redo->add_undo_method(node, "set_unique_name_in_owner", true);
 				}
-				undo_redo->add_do_method(node, "set_unique_name_in_owner", !enabled);
-				undo_redo->add_undo_method(node, "set_unique_name_in_owner", enabled);
 				undo_redo->commit_action();
 			}
 		} break;
@@ -2821,14 +2858,26 @@ void SceneTreeDock::_tree_rmb(const Vector2 &p_menu_pos) {
 			menu->add_separator();
 			menu->add_icon_shortcut(get_theme_icon(SNAME("CopyNodePath"), SNAME("EditorIcons")), ED_GET_SHORTCUT("scene_tree/copy_node_path"), TOOL_COPY_NODE_PATH);
 		}
+	}
 
-		if (selection[0]->get_owner() == EditorNode::get_singleton()->get_edited_scene()) {
-			// Only for nodes owned by the edited scene root.
+	if (profile_allow_editing) {
+		// Allow multi-toggling scene unique names but only if all selected nodes are owned by the edited scene root.
+		bool all_owned = true;
+		for (Node *node : full_selection) {
+			if (node->get_owner() != EditorNode::get_singleton()->get_edited_scene()) {
+				all_owned = false;
+				break;
+			}
+		}
+		if (all_owned) {
 			menu->add_separator();
 			menu->add_icon_check_item(get_theme_icon(SNAME("SceneUniqueName"), SNAME("EditorIcons")), TTR("Access as Scene Unique Name"), TOOL_TOGGLE_SCENE_UNIQUE_NAME);
+			// Checked based on `selection[0]` because `full_selection` has undesired ordering.
 			menu->set_item_checked(menu->get_item_index(TOOL_TOGGLE_SCENE_UNIQUE_NAME), selection[0]->is_unique_name_in_owner());
 		}
+	}
 
+	if (selection.size() == 1) {
 		bool is_external = (!selection[0]->get_scene_file_path().is_empty());
 		if (is_external) {
 			bool is_inherited = selection[0]->get_scene_inherited_state() != nullptr;
diff --git a/modules/gltf/doc_classes/GLTFCamera.xml b/modules/gltf/doc_classes/GLTFCamera.xml
index b90abd105d..49efaa1564 100644
--- a/modules/gltf/doc_classes/GLTFCamera.xml
+++ b/modules/gltf/doc_classes/GLTFCamera.xml
@@ -10,6 +10,34 @@
 		<link title="GLTF camera detailed specification">https://registry.khronos.org/glTF/specs/2.0/glTF-2.0.html#reference-camera</link>
 		<link title="GLTF camera spec and example file">https://github.com/KhronosGroup/glTF-Tutorials/blob/master/gltfTutorial/gltfTutorial_015_SimpleCameras.md</link>
 	</tutorials>
+	<methods>
+		<method name="from_dictionary" qualifiers="static">
+			<return type="GLTFCamera" />
+			<param index="0" name="dictionary" type="Dictionary" />
+			<description>
+				Creates a new GLTFCamera instance by parsing the given [Dictionary].
+			</description>
+		</method>
+		<method name="from_node" qualifiers="static">
+			<return type="GLTFCamera" />
+			<param index="0" name="camera_node" type="Camera3D" />
+			<description>
+				Create a new GLTFCamera instance from the given Godot [Camera3D] node.
+			</description>
+		</method>
+		<method name="to_dictionary" qualifiers="const">
+			<return type="Dictionary" />
+			<description>
+				Serializes this GLTFCamera instance into a [Dictionary].
+			</description>
+		</method>
+		<method name="to_node" qualifiers="const">
+			<return type="Camera3D" />
+			<description>
+				Converts this GLTFCamera instance into a Godot [Camera3D] node.
+			</description>
+		</method>
+	</methods>
 	<members>
 		<member name="depth_far" type="float" setter="set_depth_far" getter="get_depth_far" default="4000.0">
 			The distance to the far culling boundary for this camera relative to its local Z axis, in meters. This maps to GLTF's [code]zfar[/code] property.
diff --git a/modules/gltf/doc_classes/GLTFLight.xml b/modules/gltf/doc_classes/GLTFLight.xml
index db2dfb487a..7fd59e14bc 100644
--- a/modules/gltf/doc_classes/GLTFLight.xml
+++ b/modules/gltf/doc_classes/GLTFLight.xml
@@ -9,6 +9,34 @@
 	<tutorials>
 		<link title="KHR_lights_punctual GLTF extension spec">https://github.com/KhronosGroup/glTF/blob/main/extensions/2.0/Khronos/KHR_lights_punctual</link>
 	</tutorials>
+	<methods>
+		<method name="from_dictionary" qualifiers="static">
+			<return type="GLTFLight" />
+			<param index="0" name="dictionary" type="Dictionary" />
+			<description>
+				Creates a new GLTFLight instance by parsing the given [Dictionary].
+			</description>
+		</method>
+		<method name="from_node" qualifiers="static">
+			<return type="GLTFLight" />
+			<param index="0" name="light_node" type="Light3D" />
+			<description>
+				Create a new GLTFLight instance from the given Godot [Light3D] node.
+			</description>
+		</method>
+		<method name="to_dictionary" qualifiers="const">
+			<return type="Dictionary" />
+			<description>
+				Serializes this GLTFLight instance into a [Dictionary].
+			</description>
+		</method>
+		<method name="to_node" qualifiers="const">
+			<return type="Light3D" />
+			<description>
+				Converts this GLTFLight instance into a Godot [Light3D] node.
+			</description>
+		</method>
+	</methods>
 	<members>
 		<member name="color" type="Color" setter="set_color" getter="get_color" default="Color(1, 1, 1, 1)">
 			The [Color] of the light. Defaults to white. A black color causes the light to have no effect.
diff --git a/modules/gltf/extensions/gltf_light.cpp b/modules/gltf/extensions/gltf_light.cpp
index af21a4e804..ab5a15c671 100644
--- a/modules/gltf/extensions/gltf_light.cpp
+++ b/modules/gltf/extensions/gltf_light.cpp
@@ -31,6 +31,12 @@
 #include "gltf_light.h"
 
 void GLTFLight::_bind_methods() {
+	ClassDB::bind_static_method("GLTFLight", D_METHOD("from_node", "light_node"), &GLTFLight::from_node);
+	ClassDB::bind_method(D_METHOD("to_node"), &GLTFLight::to_node);
+
+	ClassDB::bind_static_method("GLTFLight", D_METHOD("from_dictionary", "dictionary"), &GLTFLight::from_dictionary);
+	ClassDB::bind_method(D_METHOD("to_dictionary"), &GLTFLight::to_dictionary);
+
 	ClassDB::bind_method(D_METHOD("get_color"), &GLTFLight::get_color);
 	ClassDB::bind_method(D_METHOD("set_color", "color"), &GLTFLight::set_color);
 	ClassDB::bind_method(D_METHOD("get_intensity"), &GLTFLight::get_intensity);
@@ -99,3 +105,116 @@ float GLTFLight::get_outer_cone_angle() {
 void GLTFLight::set_outer_cone_angle(float p_outer_cone_angle) {
 	outer_cone_angle = p_outer_cone_angle;
 }
+
+Ref<GLTFLight> GLTFLight::from_node(const Light3D *p_light) {
+	Ref<GLTFLight> l;
+	l.instantiate();
+	l->color = p_light->get_color();
+	if (cast_to<DirectionalLight3D>(p_light)) {
+		l->light_type = "directional";
+		const DirectionalLight3D *light = cast_to<const DirectionalLight3D>(p_light);
+		l->intensity = light->get_param(DirectionalLight3D::PARAM_ENERGY);
+		l->range = FLT_MAX; // Range for directional lights is infinite in Godot.
+	} else if (cast_to<const OmniLight3D>(p_light)) {
+		l->light_type = "point";
+		const OmniLight3D *light = cast_to<const OmniLight3D>(p_light);
+		l->range = light->get_param(OmniLight3D::PARAM_RANGE);
+		l->intensity = light->get_param(OmniLight3D::PARAM_ENERGY);
+	} else if (cast_to<const SpotLight3D>(p_light)) {
+		l->light_type = "spot";
+		const SpotLight3D *light = cast_to<const SpotLight3D>(p_light);
+		l->range = light->get_param(SpotLight3D::PARAM_RANGE);
+		l->intensity = light->get_param(SpotLight3D::PARAM_ENERGY);
+		l->outer_cone_angle = Math::deg_to_rad(light->get_param(SpotLight3D::PARAM_SPOT_ANGLE));
+		// This equation is the inverse of the import equation (which has a desmos link).
+		float angle_ratio = 1 - (0.2 / (0.1 + light->get_param(SpotLight3D::PARAM_SPOT_ATTENUATION)));
+		angle_ratio = MAX(0, angle_ratio);
+		l->inner_cone_angle = l->outer_cone_angle * angle_ratio;
+	}
+	return l;
+}
+
+Light3D *GLTFLight::to_node() const {
+	if (light_type == "directional") {
+		DirectionalLight3D *light = memnew(DirectionalLight3D);
+		light->set_param(Light3D::PARAM_ENERGY, intensity);
+		light->set_color(color);
+		return light;
+	}
+	const float range = CLAMP(this->range, 0, 4096);
+	if (light_type == "point") {
+		OmniLight3D *light = memnew(OmniLight3D);
+		light->set_param(OmniLight3D::PARAM_ENERGY, intensity);
+		light->set_param(OmniLight3D::PARAM_RANGE, range);
+		light->set_color(color);
+		return light;
+	}
+	if (light_type == "spot") {
+		SpotLight3D *light = memnew(SpotLight3D);
+		light->set_param(SpotLight3D::PARAM_ENERGY, intensity);
+		light->set_param(SpotLight3D::PARAM_RANGE, range);
+		light->set_param(SpotLight3D::PARAM_SPOT_ANGLE, Math::rad_to_deg(outer_cone_angle));
+		light->set_color(color);
+		// Line of best fit derived from guessing, see https://www.desmos.com/calculator/biiflubp8b
+		// The points in desmos are not exact, except for (1, infinity).
+		float angle_ratio = inner_cone_angle / outer_cone_angle;
+		float angle_attenuation = 0.2 / (1 - angle_ratio) - 0.1;
+		light->set_param(SpotLight3D::PARAM_SPOT_ATTENUATION, angle_attenuation);
+		return light;
+	}
+	return memnew(Light3D);
+}
+
+Ref<GLTFLight> GLTFLight::from_dictionary(const Dictionary p_dictionary) {
+	ERR_FAIL_COND_V_MSG(!p_dictionary.has("type"), Ref<GLTFLight>(), "Failed to parse GLTF light, missing required field 'type'.");
+	Ref<GLTFLight> light;
+	light.instantiate();
+	const String &type = p_dictionary["type"];
+	light->light_type = type;
+
+	if (p_dictionary.has("color")) {
+		const Array &arr = p_dictionary["color"];
+		if (arr.size() == 3) {
+			light->color = Color(arr[0], arr[1], arr[2]).linear_to_srgb();
+		} else {
+			ERR_PRINT("Error parsing GLTF light: The color must have exactly 3 numbers.");
+		}
+	}
+	if (p_dictionary.has("intensity")) {
+		light->intensity = p_dictionary["intensity"];
+	}
+	if (p_dictionary.has("range")) {
+		light->range = p_dictionary["range"];
+	}
+	if (type == "spot") {
+		const Dictionary &spot = p_dictionary["spot"];
+		light->inner_cone_angle = spot["innerConeAngle"];
+		light->outer_cone_angle = spot["outerConeAngle"];
+		if (light->inner_cone_angle >= light->outer_cone_angle) {
+			ERR_PRINT("Error parsing GLTF light: The inner angle must be smaller than the outer angle.");
+		}
+	} else if (type != "point" && type != "directional") {
+		ERR_PRINT("Error parsing GLTF light: Light type '" + type + "' is unknown.");
+	}
+	return light;
+}
+
+Dictionary GLTFLight::to_dictionary() const {
+	Dictionary d;
+	Array color_array;
+	color_array.resize(3);
+	color_array[0] = color.r;
+	color_array[1] = color.g;
+	color_array[2] = color.b;
+	d["color"] = color_array;
+	d["type"] = light_type;
+	if (light_type == "spot") {
+		Dictionary spot_dict;
+		spot_dict["innerConeAngle"] = inner_cone_angle;
+		spot_dict["outerConeAngle"] = outer_cone_angle;
+		d["spot"] = spot_dict;
+	}
+	d["intensity"] = intensity;
+	d["range"] = range;
+	return d;
+}
diff --git a/modules/gltf/extensions/gltf_light.h b/modules/gltf/extensions/gltf_light.h
index f0765a1bbc..04980e144c 100644
--- a/modules/gltf/extensions/gltf_light.h
+++ b/modules/gltf/extensions/gltf_light.h
@@ -70,6 +70,12 @@ public:
 
 	float get_outer_cone_angle();
 	void set_outer_cone_angle(float p_outer_cone_angle);
+
+	static Ref<GLTFLight> from_node(const Light3D *p_light);
+	Light3D *to_node() const;
+
+	static Ref<GLTFLight> from_dictionary(const Dictionary p_dictionary);
+	Dictionary to_dictionary() const;
 };
 
 #endif // GLTF_LIGHT_H
diff --git a/modules/gltf/gltf_document.cpp b/modules/gltf/gltf_document.cpp
index 87ba1d9869..1537ee6146 100644
--- a/modules/gltf/gltf_document.cpp
+++ b/modules/gltf/gltf_document.cpp
@@ -4534,28 +4534,7 @@ Error GLTFDocument::_serialize_lights(Ref<GLTFState> state) {
 	}
 	Array lights;
 	for (GLTFLightIndex i = 0; i < state->lights.size(); i++) {
-		Dictionary d;
-		Ref<GLTFLight> light = state->lights[i];
-		Array color;
-		color.resize(3);
-		color[0] = light->color.r;
-		color[1] = light->color.g;
-		color[2] = light->color.b;
-		d["color"] = color;
-		d["type"] = light->light_type;
-		if (light->light_type == "spot") {
-			Dictionary s;
-			float inner_cone_angle = light->inner_cone_angle;
-			s["innerConeAngle"] = inner_cone_angle;
-			float outer_cone_angle = light->outer_cone_angle;
-			s["outerConeAngle"] = outer_cone_angle;
-			d["spot"] = s;
-		}
-		float intensity = light->intensity;
-		d["intensity"] = intensity;
-		float range = light->range;
-		d["range"] = range;
-		lights.push_back(d);
+		lights.push_back(state->lights[i]->to_dictionary());
 	}
 
 	Dictionary extensions;
@@ -4577,27 +4556,7 @@ Error GLTFDocument::_serialize_cameras(Ref<GLTFState> state) {
 	Array cameras;
 	cameras.resize(state->cameras.size());
 	for (GLTFCameraIndex i = 0; i < state->cameras.size(); i++) {
-		Dictionary d;
-
-		Ref<GLTFCamera> camera = state->cameras[i];
-
-		if (camera->get_perspective()) {
-			Dictionary persp;
-			persp["yfov"] = camera->get_fov();
-			persp["zfar"] = camera->get_depth_far();
-			persp["znear"] = camera->get_depth_near();
-			d["perspective"] = persp;
-			d["type"] = "perspective";
-		} else {
-			Dictionary ortho;
-			ortho["ymag"] = camera->get_size_mag();
-			ortho["xmag"] = camera->get_size_mag();
-			ortho["zfar"] = camera->get_depth_far();
-			ortho["znear"] = camera->get_depth_near();
-			d["orthographic"] = ortho;
-			d["type"] = "orthographic";
-		}
-		cameras[i] = d;
+		cameras[i] = state->cameras[i]->to_dictionary();
 	}
 
 	if (!state->cameras.size()) {
@@ -4627,35 +4586,10 @@ Error GLTFDocument::_parse_lights(Ref<GLTFState> state) {
 	const Array &lights = lights_punctual["lights"];
 
 	for (GLTFLightIndex light_i = 0; light_i < lights.size(); light_i++) {
-		const Dictionary &d = lights[light_i];
-
-		Ref<GLTFLight> light;
-		light.instantiate();
-		ERR_FAIL_COND_V(!d.has("type"), ERR_PARSE_ERROR);
-		const String &type = d["type"];
-		light->light_type = type;
-
-		if (d.has("color")) {
-			const Array &arr = d["color"];
-			ERR_FAIL_COND_V(arr.size() != 3, ERR_PARSE_ERROR);
-			const Color c = Color(arr[0], arr[1], arr[2]).linear_to_srgb();
-			light->color = c;
-		}
-		if (d.has("intensity")) {
-			light->intensity = d["intensity"];
+		Ref<GLTFLight> light = GLTFLight::from_dictionary(lights[light_i]);
+		if (light.is_null()) {
+			return Error::ERR_PARSE_ERROR;
 		}
-		if (d.has("range")) {
-			light->range = d["range"];
-		}
-		if (type == "spot") {
-			const Dictionary &spot = d["spot"];
-			light->inner_cone_angle = spot["innerConeAngle"];
-			light->outer_cone_angle = spot["outerConeAngle"];
-			ERR_CONTINUE_MSG(light->inner_cone_angle >= light->outer_cone_angle, "The inner angle must be smaller than the outer angle.");
-		} else if (type != "point" && type != "directional") {
-			ERR_CONTINUE_MSG(true, "Light type is unknown.");
-		}
-
 		state->lights.push_back(light);
 	}
 
@@ -4672,35 +4606,7 @@ Error GLTFDocument::_parse_cameras(Ref<GLTFState> state) {
 	const Array cameras = state->json["cameras"];
 
 	for (GLTFCameraIndex i = 0; i < cameras.size(); i++) {
-		const Dictionary &d = cameras[i];
-
-		Ref<GLTFCamera> camera;
-		camera.instantiate();
-		ERR_FAIL_COND_V(!d.has("type"), ERR_PARSE_ERROR);
-		const String &type = d["type"];
-		if (type == "perspective") {
-			camera->set_perspective(true);
-			if (d.has("perspective")) {
-				const Dictionary &persp = d["perspective"];
-				camera->set_fov(persp["yfov"]);
-				if (persp.has("zfar")) {
-					camera->set_depth_far(persp["zfar"]);
-				}
-				camera->set_depth_near(persp["znear"]);
-			}
-		} else if (type == "orthographic") {
-			camera->set_perspective(false);
-			if (d.has("orthographic")) {
-				const Dictionary &ortho = d["orthographic"];
-				camera->set_size_mag(ortho["ymag"]);
-				camera->set_depth_far(ortho["zfar"]);
-				camera->set_depth_near(ortho["znear"]);
-			}
-		} else {
-			ERR_FAIL_V_MSG(ERR_PARSE_ERROR, "Camera3D should be in 'orthographic' or 'perspective'");
-		}
-
-		state->cameras.push_back(camera);
+		state->cameras.push_back(GLTFCamera::from_dictionary(cameras[i]));
 	}
 
 	print_verbose("glTF: Total cameras: " + itos(state->cameras.size()));
@@ -5148,45 +5054,7 @@ Node3D *GLTFDocument::_generate_light(Ref<GLTFState> state, const GLTFNodeIndex
 	print_verbose("glTF: Creating light for: " + gltf_node->get_name());
 
 	Ref<GLTFLight> l = state->lights[gltf_node->light];
-
-	float intensity = l->intensity;
-	if (intensity > 10) {
-		// GLTF spec has the default around 1, but Blender defaults lights to 100.
-		// The only sane way to handle this is to check where it came from and
-		// handle it accordingly. If it's over 10, it probably came from Blender.
-		intensity /= 100;
-	}
-
-	if (l->light_type == "directional") {
-		DirectionalLight3D *light = memnew(DirectionalLight3D);
-		light->set_param(Light3D::PARAM_ENERGY, intensity);
-		light->set_color(l->color);
-		return light;
-	}
-
-	const float range = CLAMP(l->range, 0, 4096);
-	if (l->light_type == "point") {
-		OmniLight3D *light = memnew(OmniLight3D);
-		light->set_param(OmniLight3D::PARAM_ENERGY, intensity);
-		light->set_param(OmniLight3D::PARAM_RANGE, range);
-		light->set_color(l->color);
-		return light;
-	}
-	if (l->light_type == "spot") {
-		SpotLight3D *light = memnew(SpotLight3D);
-		light->set_param(SpotLight3D::PARAM_ENERGY, intensity);
-		light->set_param(SpotLight3D::PARAM_RANGE, range);
-		light->set_param(SpotLight3D::PARAM_SPOT_ANGLE, Math::rad_to_deg(l->outer_cone_angle));
-		light->set_color(l->color);
-
-		// Line of best fit derived from guessing, see https://www.desmos.com/calculator/biiflubp8b
-		// The points in desmos are not exact, except for (1, infinity).
-		float angle_ratio = l->inner_cone_angle / l->outer_cone_angle;
-		float angle_attenuation = 0.2 / (1 - angle_ratio) - 0.1;
-		light->set_param(SpotLight3D::PARAM_SPOT_ATTENUATION, angle_attenuation);
-		return light;
-	}
-	return memnew(Node3D);
+	return l->to_node();
 }
 
 Camera3D *GLTFDocument::_generate_camera(Ref<GLTFState> state, const GLTFNodeIndex node_index) {
@@ -5194,32 +5062,16 @@ Camera3D *GLTFDocument::_generate_camera(Ref<GLTFState> state, const GLTFNodeInd
 
 	ERR_FAIL_INDEX_V(gltf_node->camera, state->cameras.size(), nullptr);
 
-	Camera3D *camera = memnew(Camera3D);
 	print_verbose("glTF: Creating camera for: " + gltf_node->get_name());
 
 	Ref<GLTFCamera> c = state->cameras[gltf_node->camera];
-	camera->set_projection(c->get_perspective() ? Camera3D::PROJECTION_PERSPECTIVE : Camera3D::PROJECTION_ORTHOGONAL);
-	// GLTF spec (yfov) is in radians, Godot's camera (fov) is in degrees.
-	camera->set_fov(Math::rad_to_deg(c->get_fov()));
-	// GLTF spec (xmag and ymag) is a radius in meters, Godot's camera (size) is a diameter in meters.
-	camera->set_size(c->get_size_mag() * 2.0f);
-	camera->set_near(c->get_depth_near());
-	camera->set_far(c->get_depth_far());
-	return camera;
+	return c->to_node();
 }
 
 GLTFCameraIndex GLTFDocument::_convert_camera(Ref<GLTFState> state, Camera3D *p_camera) {
 	print_verbose("glTF: Converting camera: " + p_camera->get_name());
 
-	Ref<GLTFCamera> c;
-	c.instantiate();
-	c->set_perspective(p_camera->get_projection() == Camera3D::ProjectionType::PROJECTION_PERSPECTIVE);
-	// GLTF spec (yfov) is in radians, Godot's camera (fov) is in degrees.
-	c->set_fov(Math::deg_to_rad(p_camera->get_fov()));
-	// GLTF spec (xmag and ymag) is a radius in meters, Godot's camera (size) is a diameter in meters.
-	c->set_size_mag(p_camera->get_size() * 0.5f);
-	c->set_depth_far(p_camera->get_far());
-	c->set_depth_near(p_camera->get_near());
+	Ref<GLTFCamera> c = GLTFCamera::from_node(p_camera);
 	GLTFCameraIndex camera_index = state->cameras.size();
 	state->cameras.push_back(c);
 	return camera_index;
@@ -5228,31 +5080,7 @@ GLTFCameraIndex GLTFDocument::_convert_camera(Ref<GLTFState> state, Camera3D *p_
 GLTFLightIndex GLTFDocument::_convert_light(Ref<GLTFState> state, Light3D *p_light) {
 	print_verbose("glTF: Converting light: " + p_light->get_name());
 
-	Ref<GLTFLight> l;
-	l.instantiate();
-	l->color = p_light->get_color();
-	if (cast_to<DirectionalLight3D>(p_light)) {
-		l->light_type = "directional";
-		DirectionalLight3D *light = cast_to<DirectionalLight3D>(p_light);
-		l->intensity = light->get_param(DirectionalLight3D::PARAM_ENERGY);
-		l->range = FLT_MAX; // Range for directional lights is infinite in Godot.
-	} else if (cast_to<OmniLight3D>(p_light)) {
-		l->light_type = "point";
-		OmniLight3D *light = cast_to<OmniLight3D>(p_light);
-		l->range = light->get_param(OmniLight3D::PARAM_RANGE);
-		l->intensity = light->get_param(OmniLight3D::PARAM_ENERGY);
-	} else if (cast_to<SpotLight3D>(p_light)) {
-		l->light_type = "spot";
-		SpotLight3D *light = cast_to<SpotLight3D>(p_light);
-		l->range = light->get_param(SpotLight3D::PARAM_RANGE);
-		l->intensity = light->get_param(SpotLight3D::PARAM_ENERGY);
-		l->outer_cone_angle = Math::deg_to_rad(light->get_param(SpotLight3D::PARAM_SPOT_ANGLE));
-
-		// This equation is the inverse of the import equation (which has a desmos link).
-		float angle_ratio = 1 - (0.2 / (0.1 + light->get_param(SpotLight3D::PARAM_SPOT_ATTENUATION)));
-		angle_ratio = MAX(0, angle_ratio);
-		l->inner_cone_angle = l->outer_cone_angle * angle_ratio;
-	}
+	Ref<GLTFLight> l = GLTFLight::from_node(p_light);
 
 	GLTFLightIndex light_index = state->lights.size();
 	state->lights.push_back(l);
diff --git a/modules/gltf/structures/gltf_camera.cpp b/modules/gltf/structures/gltf_camera.cpp
index c492913ea7..5069f39c4b 100644
--- a/modules/gltf/structures/gltf_camera.cpp
+++ b/modules/gltf/structures/gltf_camera.cpp
@@ -31,6 +31,12 @@
 #include "gltf_camera.h"
 
 void GLTFCamera::_bind_methods() {
+	ClassDB::bind_static_method("GLTFCamera", D_METHOD("from_node", "camera_node"), &GLTFCamera::from_node);
+	ClassDB::bind_method(D_METHOD("to_node"), &GLTFCamera::to_node);
+
+	ClassDB::bind_static_method("GLTFCamera", D_METHOD("from_dictionary", "dictionary"), &GLTFCamera::from_dictionary);
+	ClassDB::bind_method(D_METHOD("to_dictionary"), &GLTFCamera::to_dictionary);
+
 	ClassDB::bind_method(D_METHOD("get_perspective"), &GLTFCamera::get_perspective);
 	ClassDB::bind_method(D_METHOD("set_perspective", "perspective"), &GLTFCamera::set_perspective);
 	ClassDB::bind_method(D_METHOD("get_fov"), &GLTFCamera::get_fov);
@@ -48,3 +54,78 @@ void GLTFCamera::_bind_methods() {
 	ADD_PROPERTY(PropertyInfo(Variant::FLOAT, "depth_far"), "set_depth_far", "get_depth_far");
 	ADD_PROPERTY(PropertyInfo(Variant::FLOAT, "depth_near"), "set_depth_near", "get_depth_near");
 }
+
+Ref<GLTFCamera> GLTFCamera::from_node(const Camera3D *p_camera) {
+	Ref<GLTFCamera> c;
+	c.instantiate();
+	c->set_perspective(p_camera->get_projection() == Camera3D::ProjectionType::PROJECTION_PERSPECTIVE);
+	// GLTF spec (yfov) is in radians, Godot's camera (fov) is in degrees.
+	c->set_fov(Math::deg_to_rad(p_camera->get_fov()));
+	// GLTF spec (xmag and ymag) is a radius in meters, Godot's camera (size) is a diameter in meters.
+	c->set_size_mag(p_camera->get_size() * 0.5f);
+	c->set_depth_far(p_camera->get_far());
+	c->set_depth_near(p_camera->get_near());
+	return c;
+}
+
+Camera3D *GLTFCamera::to_node() const {
+	Camera3D *camera = memnew(Camera3D);
+	camera->set_projection(perspective ? Camera3D::PROJECTION_PERSPECTIVE : Camera3D::PROJECTION_ORTHOGONAL);
+	// GLTF spec (yfov) is in radians, Godot's camera (fov) is in degrees.
+	camera->set_fov(Math::rad_to_deg(fov));
+	// GLTF spec (xmag and ymag) is a radius in meters, Godot's camera (size) is a diameter in meters.
+	camera->set_size(size_mag * 2.0f);
+	camera->set_near(depth_near);
+	camera->set_far(depth_far);
+	return camera;
+}
+
+Ref<GLTFCamera> GLTFCamera::from_dictionary(const Dictionary p_dictionary) {
+	ERR_FAIL_COND_V_MSG(!p_dictionary.has("type"), Ref<GLTFCamera>(), "Failed to parse GLTF camera, missing required field 'type'.");
+	Ref<GLTFCamera> camera;
+	camera.instantiate();
+	const String &type = p_dictionary["type"];
+	if (type == "perspective") {
+		camera->set_perspective(true);
+		if (p_dictionary.has("perspective")) {
+			const Dictionary &persp = p_dictionary["perspective"];
+			camera->set_fov(persp["yfov"]);
+			if (persp.has("zfar")) {
+				camera->set_depth_far(persp["zfar"]);
+			}
+			camera->set_depth_near(persp["znear"]);
+		}
+	} else if (type == "orthographic") {
+		camera->set_perspective(false);
+		if (p_dictionary.has("orthographic")) {
+			const Dictionary &ortho = p_dictionary["orthographic"];
+			camera->set_size_mag(ortho["ymag"]);
+			camera->set_depth_far(ortho["zfar"]);
+			camera->set_depth_near(ortho["znear"]);
+		}
+	} else {
+		ERR_PRINT("Error parsing GLTF camera: Camera type '" + type + "' is unknown, should be perspective or orthographic.");
+	}
+	return camera;
+}
+
+Dictionary GLTFCamera::to_dictionary() const {
+	Dictionary d;
+	if (perspective) {
+		Dictionary persp;
+		persp["yfov"] = fov;
+		persp["zfar"] = depth_far;
+		persp["znear"] = depth_near;
+		d["perspective"] = persp;
+		d["type"] = "perspective";
+	} else {
+		Dictionary ortho;
+		ortho["ymag"] = size_mag;
+		ortho["xmag"] = size_mag;
+		ortho["zfar"] = depth_far;
+		ortho["znear"] = depth_near;
+		d["orthographic"] = ortho;
+		d["type"] = "orthographic";
+	}
+	return d;
+}
diff --git a/modules/gltf/structures/gltf_camera.h b/modules/gltf/structures/gltf_camera.h
index 8e528c063f..50ae10e17a 100644
--- a/modules/gltf/structures/gltf_camera.h
+++ b/modules/gltf/structures/gltf_camera.h
@@ -63,6 +63,12 @@ public:
 	void set_depth_far(real_t p_val) { depth_far = p_val; }
 	real_t get_depth_near() const { return depth_near; }
 	void set_depth_near(real_t p_val) { depth_near = p_val; }
+
+	static Ref<GLTFCamera> from_node(const Camera3D *p_light);
+	Camera3D *to_node() const;
+
+	static Ref<GLTFCamera> from_dictionary(const Dictionary p_dictionary);
+	Dictionary to_dictionary() const;
 };
 
 #endif // GLTF_CAMERA_H
diff --git a/scene/resources/material.cpp b/scene/resources/material.cpp
index bd0e470112..32ddef1693 100644
--- a/scene/resources/material.cpp
+++ b/scene/resources/material.cpp
@@ -2971,6 +2971,8 @@ BaseMaterial3D::BaseMaterial3D(bool p_orm) :
 
 	set_transparency(TRANSPARENCY_DISABLED);
 	set_alpha_antialiasing(ALPHA_ANTIALIASING_OFF);
+	// Alpha scissor threshold of 0.5 matches the glTF specification and Label3D default.
+	// <https://www.khronos.org/registry/glTF/specs/2.0/glTF-2.0.html#_material_alphacutoff>
 	set_alpha_scissor_threshold(0.5);
 	set_alpha_hash_scale(1.0);
 	set_alpha_antialiasing_edge(0.3);