diff options
| -rw-r--r-- | core/io/image.cpp | 6 | ||||
| -rw-r--r-- | doc/classes/Animation.xml | 16 | ||||
| -rw-r--r-- | doc/classes/BaseMaterial3D.xml | 14 | ||||
| -rw-r--r-- | doc/classes/CanvasTexture.xml | 11 | ||||
| -rw-r--r-- | doc/classes/Light3D.xml | 2 | ||||
| -rw-r--r-- | doc/classes/Node3D.xml | 1 | ||||
| -rw-r--r-- | doc/classes/OmniLight3D.xml | 1 | ||||
| -rw-r--r-- | doc/classes/ProjectSettings.xml | 4 | ||||
| -rw-r--r-- | doc/classes/SpotLight3D.xml | 2 | ||||
| -rw-r--r-- | doc/classes/StandardMaterial3D.xml | 2 | ||||
| -rw-r--r-- | doc/classes/Viewport.xml | 2 | ||||
| -rw-r--r-- | drivers/vulkan/vulkan_context.cpp | 9 | ||||
| -rw-r--r-- | editor/plugins/visual_shader_editor_plugin.cpp | 130 | ||||
| -rw-r--r-- | modules/csg/doc_classes/CSGShape3D.xml | 5 | ||||
| -rw-r--r-- | modules/glslang/register_types.cpp | 4 | ||||
| -rw-r--r-- | modules/upnp/doc_classes/UPNP.xml | 2 | ||||
| -rw-r--r-- | scene/resources/visual_shader_nodes.cpp | 59 |
17 files changed, 166 insertions, 104 deletions
diff --git a/core/io/image.cpp b/core/io/image.cpp index 3450eb7abd..16dd66fc98 100644 --- a/core/io/image.cpp +++ b/core/io/image.cpp @@ -2862,6 +2862,9 @@ void Image::_repeat_pixel_over_subsequent_memory(uint8_t *p_pixel, int p_pixel_s } void Image::fill(const Color &p_color) { + if (data.size() == 0) { + return; + } ERR_FAIL_COND_MSG(!_can_modify(format), "Cannot fill in compressed or custom image formats."); uint8_t *dst_data_ptr = data.ptrw(); @@ -2875,6 +2878,9 @@ void Image::fill(const Color &p_color) { } void Image::fill_rect(const Rect2i &p_rect, const Color &p_color) { + if (data.size() == 0) { + return; + } ERR_FAIL_COND_MSG(!_can_modify(format), "Cannot fill rect in compressed or custom image formats."); Rect2i r = Rect2i(0, 0, width, height).intersection(p_rect.abs()); diff --git a/doc/classes/Animation.xml b/doc/classes/Animation.xml index df0fb11ac7..008296713d 100644 --- a/doc/classes/Animation.xml +++ b/doc/classes/Animation.xml @@ -26,6 +26,7 @@ [/csharp] [/codeblocks] Animations are just data containers, and must be added to nodes such as an [AnimationPlayer] to be played back. Animation tracks have different types, each with its own set of dedicated methods. Check [enum TrackType] to see available types. + [b]Note:[/b] For 3D position/rotation/scale, using the dedicated [constant TYPE_POSITION_3D], [constant TYPE_ROTATION_3D] and [constant TYPE_SCALE_3D] track types instead of [constant TYPE_VALUE] is recommended for performance reasons. </description> <tutorials> <link title="Animation documentation index">$DOCS_URL/tutorials/animation/index.html</link> @@ -209,6 +210,7 @@ <param index="1" name="time" type="float" /> <param index="2" name="amount" type="float" /> <description> + Inserts a key in a given blend shape track. Returns the key index. </description> </method> <method name="clear"> @@ -223,6 +225,8 @@ <param index="1" name="fps" type="int" default="120" /> <param index="2" name="split_tolerance" type="float" default="4.0" /> <description> + Compress the animation and all its tracks in-place. This will make [method track_is_compressed] return [code]true[/code] once called on this [Animation]. Compressed tracks require less memory to be played, and are designed to be used for complex 3D animations (such as cutscenes) imported from external 3D software. Compression is lossy, but the difference is usually not noticeable in real world conditions. + [b]Note:[/b] Compressed tracks have various limitations (such as not being editable from the editor), so only use compressed animations if you actually need them. </description> </method> <method name="copy_track"> @@ -278,6 +282,7 @@ <param index="1" name="time" type="float" /> <param index="2" name="position" type="Vector3" /> <description> + Inserts a key in a given 3D position track. Returns the key index. </description> </method> <method name="remove_track"> @@ -293,6 +298,7 @@ <param index="1" name="time" type="float" /> <param index="2" name="rotation" type="Quaternion" /> <description> + Inserts a key in a given 3D rotation track. Returns the key index. </description> </method> <method name="scale_track_insert_key"> @@ -301,6 +307,7 @@ <param index="1" name="time" type="float" /> <param index="2" name="scale" type="Vector3" /> <description> + Inserts a key in a given 3D scale track. Returns the key index. </description> </method> <method name="track_find_key" qualifiers="const"> @@ -385,6 +392,7 @@ <return type="bool" /> <param index="0" name="track_idx" type="int" /> <description> + Returns [code]true[/code] if the track is compressed, [code]false[/code] otherwise. See also [method compress]. </description> </method> <method name="track_is_enabled" qualifiers="const"> @@ -569,15 +577,19 @@ </signals> <constants> <constant name="TYPE_VALUE" value="0" enum="TrackType"> - Value tracks set values in node properties, but only those which can be Interpolated. + Value tracks set values in node properties, but only those which can be interpolated. For 3D position/rotation/scale, using the dedicated [constant TYPE_POSITION_3D], [constant TYPE_ROTATION_3D] and [constant TYPE_SCALE_3D] track types instead of [constant TYPE_VALUE] is recommended for performance reasons. </constant> <constant name="TYPE_POSITION_3D" value="1" enum="TrackType"> + 3D position track (values are stored in [Vector3]s). </constant> <constant name="TYPE_ROTATION_3D" value="2" enum="TrackType"> + 3D rotation track (values are stored in [Quaternion]s). </constant> <constant name="TYPE_SCALE_3D" value="3" enum="TrackType"> + 3D scale track (values are stored in [Vector3]s). </constant> <constant name="TYPE_BLEND_SHAPE" value="4" enum="TrackType"> + Blend shape track. </constant> <constant name="TYPE_METHOD" value="5" enum="TrackType"> Method tracks call functions with given arguments per key. @@ -598,7 +610,7 @@ Linear interpolation. </constant> <constant name="INTERPOLATION_CUBIC" value="2" enum="InterpolationType"> - Cubic interpolation. + Cubic interpolation. This looks smoother than linear interpolation, but is more expensive to interpolate. Stick to [constant INTERPOLATION_LINEAR] for complex 3D animations imported from external software, even if it requires using a higher animation framerate in return. </constant> <constant name="INTERPOLATION_LINEAR_ANGLE" value="3" enum="InterpolationType"> Linear interpolation with shortest path rotation. diff --git a/doc/classes/BaseMaterial3D.xml b/doc/classes/BaseMaterial3D.xml index dbc7d0fb29..de980eab0c 100644 --- a/doc/classes/BaseMaterial3D.xml +++ b/doc/classes/BaseMaterial3D.xml @@ -115,7 +115,7 @@ The color used by the backlight effect. Represents the light passing through an object. </member> <member name="backlight_enabled" type="bool" setter="set_feature" getter="get_feature" default="false"> - If [code]true[/code], the backlight effect is enabled. + If [code]true[/code], the backlight effect is enabled. See also [member subsurf_scatter_transmittance_enabled]. </member> <member name="backlight_texture" type="Texture2D" setter="set_texture" getter="get_texture"> Texture used to control the backlight effect per-pixel. Added to [member backlight]. @@ -289,6 +289,7 @@ [b]Note:[/b] If [member detail_enabled] is [code]true[/code], the [member detail_albedo] texture is drawn [i]below[/i] the [member normal_texture]. To display a normal map [i]above[/i] the [member detail_albedo] texture, use [member detail_normal] instead. </member> <member name="orm_texture" type="Texture2D" setter="set_texture" getter="get_texture"> + The Occlusion/Roughness/Metallic texture to use. This is a more efficient replacement of [member ao_texture], [member roughness_texture] and [member metallic_texture] in [ORMMaterial3D]. Ambient occlusion is stored in the red channel. Roughness map is stored in the green channel. Metallic map is stored in the blue channel. The alpha channel is ignored. </member> <member name="particles_anim_h_frames" type="int" setter="set_particles_anim_h_frames" getter="get_particles_anim_h_frames"> The number of horizontal frames in the particle sprite sheet. Only enabled when using [constant BILLBOARD_PARTICLES]. See [member billboard_mode]. @@ -350,13 +351,13 @@ </member> <member name="specular_mode" type="int" setter="set_specular_mode" getter="get_specular_mode" enum="BaseMaterial3D.SpecularMode" default="0"> The method for rendering the specular blob. See [enum SpecularMode]. - [b]Note:[/b] Only applies to the specular blob. Does not affect specular reflections from the Sky, SSR, or ReflectionProbes. + [b]Note:[/b] [member specular_mode] only applies to the specular blob. It does not affect specular reflections from the sky, screen-space reflections, [VoxelGI], SDFGI or [ReflectionProbe]s. To disable reflections from these sources as well, set [member metallic_specular] to [code]0.0[/code] instead. </member> <member name="subsurf_scatter_enabled" type="bool" setter="set_feature" getter="get_feature" default="false"> If [code]true[/code], subsurface scattering is enabled. Emulates light that penetrates an object's surface, is scattered, and then emerges. </member> <member name="subsurf_scatter_skin_mode" type="bool" setter="set_flag" getter="get_flag" default="false"> - If [code]true[/code], subsurface scattering will use a special mode optimized for the color and density of human skin. + If [code]true[/code], subsurface scattering will use a special mode optimized for the color and density of human skin, such as boosting the intensity of the red channel in subsurface scattering. </member> <member name="subsurf_scatter_strength" type="float" setter="set_subsurface_scattering_strength" getter="get_subsurface_scattering_strength" default="0.0"> The strength of the subsurface scattering effect. @@ -365,14 +366,19 @@ Texture used to control the subsurface scattering strength. Stored in the red texture channel. Multiplied by [member subsurf_scatter_strength]. </member> <member name="subsurf_scatter_transmittance_boost" type="float" setter="set_transmittance_boost" getter="get_transmittance_boost" default="0.0"> + The intensity of the subsurface scattering transmittance effect. </member> <member name="subsurf_scatter_transmittance_color" type="Color" setter="set_transmittance_color" getter="get_transmittance_color" default="Color(1, 1, 1, 1)"> + The color to multiply the subsurface scattering transmittance effect with. Ignored if [member subsurf_scatter_skin_mode] is [code]true[/code]. </member> <member name="subsurf_scatter_transmittance_depth" type="float" setter="set_transmittance_depth" getter="get_transmittance_depth" default="0.1"> + The depth of the subsurface scattering transmittance effect. </member> <member name="subsurf_scatter_transmittance_enabled" type="bool" setter="set_feature" getter="get_feature" default="false"> + If [code]true[/code], enables subsurface scattering transmittance. Only effective if [member subsurf_scatter_enabled] is [code]true[/code]. See also [member backlight_enabled]. </member> <member name="subsurf_scatter_transmittance_texture" type="Texture2D" setter="set_texture" getter="get_texture"> + The texture to use for multiplying the intensity of the subsurface scattering transmitteance intensity. See also [member subsurf_scatter_texture]. Ignored if [member subsurf_scatter_skin_mode] is [code]true[/code]. </member> <member name="texture_filter" type="int" setter="set_texture_filter" getter="get_texture_filter" enum="BaseMaterial3D.TextureFilter" default="3"> Filter flags for the texture. See [enum TextureFilter] for options. @@ -385,6 +391,7 @@ If [code]true[/code], transparency is enabled on the body. See also [member blend_mode]. </member> <member name="use_particle_trails" type="bool" setter="set_flag" getter="get_flag" default="false"> + If [code]true[/code], enables parts of the shader required for [GPUParticles3D] trails to function. This also requires using a mesh with appropriate skinning, such as [RibbonTrailMesh] or [TubeTrailMesh]. Enabling this feature outside of materials used in [GPUParticles3D] meshes will break material rendering. </member> <member name="use_point_size" type="bool" setter="set_flag" getter="get_flag" default="false"> If [code]true[/code], render point size can be changed. @@ -682,6 +689,7 @@ Enables the skin mode for subsurface scattering which is used to improve the look of subsurface scattering when used for human skin. </constant> <constant name="FLAG_PARTICLE_TRAILS_MODE" value="19" enum="Flags"> + Enables parts of the shader required for [GPUParticles3D] trails to function. This also requires using a mesh with appropriate skinning, such as [RibbonTrailMesh] or [TubeTrailMesh]. Enabling this feature outside of materials used in [GPUParticles3D] meshes will break material rendering. </constant> <constant name="FLAG_ALBEDO_TEXTURE_MSDF" value="20" enum="Flags"> Enables multichannel signed distance field rendering shader. diff --git a/doc/classes/CanvasTexture.xml b/doc/classes/CanvasTexture.xml index ac18c2d474..2dc83790c7 100644 --- a/doc/classes/CanvasTexture.xml +++ b/doc/classes/CanvasTexture.xml @@ -1,25 +1,36 @@ <?xml version="1.0" encoding="UTF-8" ?> <class name="CanvasTexture" inherits="Texture2D" version="4.0" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:noNamespaceSchemaLocation="../class.xsd"> <brief_description> + Texture with optional normal and specular maps for use in 2D rendering. </brief_description> <description> + [CanvasTexture] is an alternative to [ImageTexture] for 2D rendering. It allows using normal maps and specular maps in any node that inherits from [CanvasItem]. [CanvasTexture] also allows overriding the texture's filter and repeat mode independently of the node's properties (or the project settings). + [b]Note:[/b] [CanvasTexture] cannot be used in 3D rendering. For physically-based materials in 3D, use [BaseMaterial3D] instead. </description> <tutorials> </tutorials> <members> <member name="diffuse_texture" type="Texture2D" setter="set_diffuse_texture" getter="get_diffuse_texture"> + The diffuse (color) texture to use. This is the main texture you want to set in most cases. </member> <member name="normal_texture" type="Texture2D" setter="set_normal_texture" getter="get_normal_texture"> + The normal map texture to use. Only has a visible effect if [Light2D]s are affecting this [CanvasTexture]. + [b]Note:[/b] Godot expects the normal map to use X+, Y+, and Z+ coordinates. See [url=http://wiki.polycount.com/wiki/Normal_Map_Technical_Details#Common_Swizzle_Coordinates]this page[/url] for a comparison of normal map coordinates expected by popular engines. </member> <member name="specular_color" type="Color" setter="set_specular_color" getter="get_specular_color" default="Color(1, 1, 1, 1)"> + The multiplier for specular reflection colors. The [Light2D]'s color is also taken into account when determining the reflection color. Only has a visible effect if [Light2D]s are affecting this [CanvasTexture]. </member> <member name="specular_shininess" type="float" setter="set_specular_shininess" getter="get_specular_shininess" default="1.0"> + The specular exponent for [Light2D] specular reflections. Higher values result in a more glossy/"wet" look, with reflections becoming more localized and less visible overall. The default value of [code]1.0[/code] disables specular reflections entirely. Only has a visible effect if [Light2D]s are affecting this [CanvasTexture]. </member> <member name="specular_texture" type="Texture2D" setter="set_specular_texture" getter="get_specular_texture"> + The specular map to use for [Light2D] specular reflections. This should be a grayscale or colored texture, with brighter areas resulting in a higher [member specular_shininess] value. Using a colored [member specular_texture] allows controlling specular shininess on a per-channel basis. Only has a visible effect if [Light2D]s are affecting this [CanvasTexture]. </member> <member name="texture_filter" type="int" setter="set_texture_filter" getter="get_texture_filter" enum="CanvasItem.TextureFilter" default="0"> + The texture filtering mode to use when drawing this [CanvasTexture]. </member> <member name="texture_repeat" type="int" setter="set_texture_repeat" getter="get_texture_repeat" enum="CanvasItem.TextureRepeat" default="0"> + The texture repeat mode to use when drawing this [CanvasTexture]. </member> </members> </class> diff --git a/doc/classes/Light3D.xml b/doc/classes/Light3D.xml index e9ebbc0a41..60e20cd97d 100644 --- a/doc/classes/Light3D.xml +++ b/doc/classes/Light3D.xml @@ -55,6 +55,7 @@ </member> <member name="light_angular_distance" type="float" setter="set_param" getter="get_param" default="0.0"> The light's angular size in degrees. Increasing this will make shadows softer at greater distances. Only available for [DirectionalLight3D]s. For reference, the Sun from the Earth is approximately [code]0.5[/code]. + [b]Note:[/b] [member light_angular_distance] is not affected by [member Node3D.scale] (the light's scale or its parent's scale). </member> <member name="light_bake_mode" type="int" setter="set_bake_mode" getter="get_bake_mode" enum="Light3D.BakeMode" default="2"> The light's bake mode. This will affect the global illumination techniques that have an effect on the light's rendering. See [enum BakeMode]. @@ -91,6 +92,7 @@ </member> <member name="light_size" type="float" setter="set_param" getter="get_param" default="0.0"> The size of the light in Godot units. Only available for [OmniLight3D]s and [SpotLight3D]s. Increasing this value will make the light fade out slower and shadows appear blurrier. This can be used to simulate area lights to an extent. + [b]Note:[/b] [member light_size] is not affected by [member Node3D.scale] (the light's scale or its parent's scale). </member> <member name="light_specular" type="float" setter="set_param" getter="get_param" default="0.5"> The intensity of the specular blob in objects affected by the light. At [code]0[/code], the light becomes a pure diffuse light. When not baking emission, this can be used to avoid unrealistic reflections when placing lights above an emissive surface. diff --git a/doc/classes/Node3D.xml b/doc/classes/Node3D.xml index 3df7ec931f..bc2570b183 100644 --- a/doc/classes/Node3D.xml +++ b/doc/classes/Node3D.xml @@ -296,6 +296,7 @@ <member name="scale" type="Vector3" setter="set_scale" getter="get_scale" default="Vector3(1, 1, 1)"> Scale part of the local transformation. [b]Note:[/b] Mixed negative scales in 3D are not decomposable from the transformation matrix. Due to the way scale is represented with transformation matrices in Godot, the scale values will either be all positive or all negative. + [b]Note:[/b] Not all nodes are visually scaled by the [member scale] property. For example, [Light3D]s are not visually affected by [member scale]. </member> <member name="top_level" type="bool" setter="set_as_top_level" getter="is_set_as_top_level" default="false"> If [code]true[/code], the node will not inherit its transformations from its parent. Node transformations are only in global space. diff --git a/doc/classes/OmniLight3D.xml b/doc/classes/OmniLight3D.xml index ce63dbdbc1..193ae8deeb 100644 --- a/doc/classes/OmniLight3D.xml +++ b/doc/classes/OmniLight3D.xml @@ -15,6 +15,7 @@ </member> <member name="omni_range" type="float" setter="set_param" getter="get_param" default="5.0"> The light's radius. Note that the effectively lit area may appear to be smaller depending on the [member omni_attenuation] in use. No matter the [member omni_attenuation] in use, the light will never reach anything outside this radius. + [b]Note:[/b] [member omni_range] is not affected by [member Node3D.scale] (the light's scale or its parent's scale). </member> <member name="omni_shadow_mode" type="int" setter="set_shadow_mode" getter="get_shadow_mode" enum="OmniLight3D.ShadowMode" default="1"> See [enum ShadowMode]. diff --git a/doc/classes/ProjectSettings.xml b/doc/classes/ProjectSettings.xml index a8080c70c6..e2502f1fb8 100644 --- a/doc/classes/ProjectSettings.xml +++ b/doc/classes/ProjectSettings.xml @@ -1811,7 +1811,9 @@ Another way to combat specular aliasing is to enable [member rendering/anti_aliasing/screen_space_roughness_limiter/enabled]. </member> <member name="rendering/anti_aliasing/quality/use_debanding" type="bool" setter="" getter="" default="false"> - If [code]true[/code], uses a fast post-processing dithering filter on the default screen [Viewport] to make banding significantly less visible. In some cases, the dithering pattern may be slightly noticable. Note that this will make losslessly compressed (PNG etc.) screenshots larger. + If [code]true[/code], uses a fast post-processing filter to make banding significantly less visible in 3D. 2D rendering is [i]not[/i] affected by debanding unless the [member Environment.background_mode] is [constant Environment.BG_CANVAS]. + In some cases, debanding may introduce a slightly noticeable dithering pattern. It's recommended to enable debanding only when actually needed since the dithering pattern will make lossless-compressed screenshots larger. + [b]Note:[/b] This property is only read when the project starts. To set debanding at run-time, set [member Viewport.use_debanding] on the root [Viewport] instead. </member> <member name="rendering/anti_aliasing/quality/use_taa" type="bool" setter="" getter="" default="false"> Enables Temporal Anti-Aliasing for the default screen [Viewport]. TAA works by jittering the camera and accumulating the images of the last rendered frames, motion vector rendering is used to account for camera and object motion. Enabling TAA can make the image blurrier, which is partially counteracted by automatically using a negative mipmap LOD bias (see [member rendering/textures/default_filters/texture_mipmap_bias]). diff --git a/doc/classes/SpotLight3D.xml b/doc/classes/SpotLight3D.xml index 62cb55daec..28e2ef0d95 100644 --- a/doc/classes/SpotLight3D.xml +++ b/doc/classes/SpotLight3D.xml @@ -14,6 +14,7 @@ <member name="shadow_bias" type="float" setter="set_param" getter="get_param" overrides="Light3D" default="0.03" /> <member name="spot_angle" type="float" setter="set_param" getter="get_param" default="45.0"> The spotlight's angle in degrees. + [b]Note:[/b] [member spot_angle] is not affected by [member Node3D.scale] (the light's scale or its parent's scale). </member> <member name="spot_angle_attenuation" type="float" setter="set_param" getter="get_param" default="1.0"> The spotlight's angular attenuation curve. @@ -23,6 +24,7 @@ </member> <member name="spot_range" type="float" setter="set_param" getter="get_param" default="5.0"> The maximal range that can be reached by the spotlight. Note that the effectively lit area may appear to be smaller depending on the [member spot_attenuation] in use. No matter the [member spot_attenuation] in use, the light will never reach anything outside this range. + [b]Note:[/b] [member spot_range] is not affected by [member Node3D.scale] (the light's scale or its parent's scale). </member> </members> </class> diff --git a/doc/classes/StandardMaterial3D.xml b/doc/classes/StandardMaterial3D.xml index bd6e5cdfa2..0f6a3168eb 100644 --- a/doc/classes/StandardMaterial3D.xml +++ b/doc/classes/StandardMaterial3D.xml @@ -4,7 +4,7 @@ Physically based rendering (PBR) material that can be applied to 3D objects. </brief_description> <description> - StandardMaterial3D's properties are inherited from [BaseMaterial3D]. + [StandardMaterial3D]'s properties are inherited from [BaseMaterial3D]. [StandardMaterial3D] uses separate textures for ambient occlusion, roughness and metallic maps. To use a single ORM map for all 3 textures, use an [ORMMaterial3D] instead. </description> <tutorials> <link title="Standard Material 3D and ORM Material 3D">$DOCS_URL/tutorials/3d/standard_material_3d.html</link> diff --git a/doc/classes/Viewport.xml b/doc/classes/Viewport.xml index fce94fe567..5706d098e8 100644 --- a/doc/classes/Viewport.xml +++ b/doc/classes/Viewport.xml @@ -306,6 +306,8 @@ If [code]true[/code], the viewport should render its background as transparent. </member> <member name="use_debanding" type="bool" setter="set_use_debanding" getter="is_using_debanding" default="false"> + If [code]true[/code], uses a fast post-processing filter to make banding significantly less visible in 3D. 2D rendering is [i]not[/i] affected by debanding unless the [member Environment.background_mode] is [constant Environment.BG_CANVAS]. See also [member ProjectSettings.rendering/anti_aliasing/quality/use_debanding]. + In some cases, debanding may introduce a slightly noticeable dithering pattern. It's recommended to enable debanding only when actually needed since the dithering pattern will make lossless-compressed screenshots larger. </member> <member name="use_occlusion_culling" type="bool" setter="set_use_occlusion_culling" getter="is_using_occlusion_culling" default="false"> If [code]true[/code], [OccluderInstance3D] nodes will be usable for occlusion culling in 3D for this viewport. For the root viewport, [member ProjectSettings.rendering/occlusion_culling/use_occlusion_culling] must be set to [code]true[/code] instead. diff --git a/drivers/vulkan/vulkan_context.cpp b/drivers/vulkan/vulkan_context.cpp index 688efa42e1..9ee5a67471 100644 --- a/drivers/vulkan/vulkan_context.cpp +++ b/drivers/vulkan/vulkan_context.cpp @@ -717,9 +717,12 @@ Error VulkanContext::_check_capabilities() { VkPhysicalDeviceProperties2 physicalDeviceProperties{}; void *nextptr = nullptr; - subgroupProperties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_SUBGROUP_PROPERTIES; - subgroupProperties.pNext = nextptr; - nextptr = &subgroupProperties; + if (!(vulkan_major == 1 && vulkan_minor == 0)) { + subgroupProperties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_SUBGROUP_PROPERTIES; + subgroupProperties.pNext = nextptr; + + nextptr = &subgroupProperties; + } if (multiview_capabilities.is_supported) { multiviewProperties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_MULTIVIEW_PROPERTIES; diff --git a/editor/plugins/visual_shader_editor_plugin.cpp b/editor/plugins/visual_shader_editor_plugin.cpp index 8355f64fe5..d9f8d28067 100644 --- a/editor/plugins/visual_shader_editor_plugin.cpp +++ b/editor/plugins/visual_shader_editor_plugin.cpp @@ -5087,23 +5087,23 @@ VisualShaderEditor::VisualShaderEditor() { const String &compare_func_desc = TTR("Returns the boolean result of the %s comparison between two parameters."); - add_options.push_back(AddOption("Equal", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Equal (==)")), { VisualShaderNodeCompare::FUNC_EQUAL }, VisualShaderNode::PORT_TYPE_BOOLEAN)); - add_options.push_back(AddOption("GreaterThan", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Greater Than (>)")), { VisualShaderNodeCompare::FUNC_GREATER_THAN }, VisualShaderNode::PORT_TYPE_BOOLEAN)); - add_options.push_back(AddOption("GreaterThanEqual", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Greater Than or Equal (>=)")), { VisualShaderNodeCompare::FUNC_GREATER_THAN_EQUAL }, VisualShaderNode::PORT_TYPE_BOOLEAN)); + add_options.push_back(AddOption("Equal (==)", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Equal (==)")), { VisualShaderNodeCompare::FUNC_EQUAL }, VisualShaderNode::PORT_TYPE_BOOLEAN)); + add_options.push_back(AddOption("GreaterThan (>)", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Greater Than (>)")), { VisualShaderNodeCompare::FUNC_GREATER_THAN }, VisualShaderNode::PORT_TYPE_BOOLEAN)); + add_options.push_back(AddOption("GreaterThanEqual (>=)", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Greater Than or Equal (>=)")), { VisualShaderNodeCompare::FUNC_GREATER_THAN_EQUAL }, VisualShaderNode::PORT_TYPE_BOOLEAN)); add_options.push_back(AddOption("If", "Conditional/Functions", "VisualShaderNodeIf", TTR("Returns an associated vector if the provided scalars are equal, greater or less."), {}, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("IsInf", "Conditional/Functions", "VisualShaderNodeIs", TTR("Returns the boolean result of the comparison between INF and a scalar parameter."), { VisualShaderNodeIs::FUNC_IS_INF }, VisualShaderNode::PORT_TYPE_BOOLEAN)); add_options.push_back(AddOption("IsNaN", "Conditional/Functions", "VisualShaderNodeIs", TTR("Returns the boolean result of the comparison between NaN and a scalar parameter."), { VisualShaderNodeIs::FUNC_IS_NAN }, VisualShaderNode::PORT_TYPE_BOOLEAN)); - add_options.push_back(AddOption("LessThan", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Less Than (<)")), { VisualShaderNodeCompare::FUNC_LESS_THAN }, VisualShaderNode::PORT_TYPE_BOOLEAN)); - add_options.push_back(AddOption("LessThanEqual", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Less Than or Equal (<=)")), { VisualShaderNodeCompare::FUNC_LESS_THAN_EQUAL }, VisualShaderNode::PORT_TYPE_BOOLEAN)); - add_options.push_back(AddOption("NotEqual", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Not Equal (!=)")), { VisualShaderNodeCompare::FUNC_NOT_EQUAL }, VisualShaderNode::PORT_TYPE_BOOLEAN)); - add_options.push_back(AddOption("Switch", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated 3D vector if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("Switch2D", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated 2D vector if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("SwitchBool", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated boolean if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_BOOLEAN }, VisualShaderNode::PORT_TYPE_BOOLEAN)); - add_options.push_back(AddOption("SwitchFloat", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated floating-point scalar if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_FLOAT }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("SwitchInt", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated integer scalar if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_INT }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("SwitchTransform", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated transform if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_TRANSFORM }, VisualShaderNode::PORT_TYPE_TRANSFORM)); - - add_options.push_back(AddOption("Compare", "Conditional/Common", "VisualShaderNodeCompare", TTR("Returns the boolean result of the comparison between two parameters."), {}, VisualShaderNode::PORT_TYPE_BOOLEAN)); + add_options.push_back(AddOption("LessThan (<)", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Less Than (<)")), { VisualShaderNodeCompare::FUNC_LESS_THAN }, VisualShaderNode::PORT_TYPE_BOOLEAN)); + add_options.push_back(AddOption("LessThanEqual (<=)", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Less Than or Equal (<=)")), { VisualShaderNodeCompare::FUNC_LESS_THAN_EQUAL }, VisualShaderNode::PORT_TYPE_BOOLEAN)); + add_options.push_back(AddOption("NotEqual (!=)", "Conditional/Functions", "VisualShaderNodeCompare", vformat(compare_func_desc, TTR("Not Equal (!=)")), { VisualShaderNodeCompare::FUNC_NOT_EQUAL }, VisualShaderNode::PORT_TYPE_BOOLEAN)); + add_options.push_back(AddOption("Switch (==)", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated 3D vector if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("Switch2D (==)", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated 2D vector if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("SwitchBool (==)", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated boolean if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_BOOLEAN }, VisualShaderNode::PORT_TYPE_BOOLEAN)); + add_options.push_back(AddOption("SwitchFloat (==)", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated floating-point scalar if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_FLOAT }, VisualShaderNode::PORT_TYPE_SCALAR)); + add_options.push_back(AddOption("SwitchInt (==)", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated integer scalar if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_INT }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("SwitchTransform (==)", "Conditional/Functions", "VisualShaderNodeSwitch", TTR("Returns an associated transform if the provided boolean value is true or false."), { VisualShaderNodeSwitch::OP_TYPE_TRANSFORM }, VisualShaderNode::PORT_TYPE_TRANSFORM)); + + add_options.push_back(AddOption("Compare (==)", "Conditional/Common", "VisualShaderNodeCompare", TTR("Returns the boolean result of the comparison between two parameters."), {}, VisualShaderNode::PORT_TYPE_BOOLEAN)); add_options.push_back(AddOption("Is", "Conditional/Common", "VisualShaderNodeIs", TTR("Returns the boolean result of the comparison between INF (or NaN) and a scalar parameter."), {}, VisualShaderNode::PORT_TYPE_BOOLEAN)); add_options.push_back(AddOption("BooleanConstant", "Conditional/Variables", "VisualShaderNodeBooleanConstant", TTR("Boolean constant."), {}, VisualShaderNode::PORT_TYPE_BOOLEAN)); @@ -5308,7 +5308,7 @@ VisualShaderEditor::VisualShaderEditor() { add_options.push_back(AddOption("EmitParticle", "Particles", "VisualShaderNodeParticleEmit", "", {}, -1, TYPE_FLAGS_PROCESS | TYPE_FLAGS_PROCESS_CUSTOM | TYPE_FLAGS_COLLIDE, Shader::MODE_PARTICLES)); add_options.push_back(AddOption("ParticleAccelerator", "Particles", "VisualShaderNodeParticleAccelerator", "", {}, VisualShaderNode::PORT_TYPE_VECTOR_3D, TYPE_FLAGS_PROCESS, Shader::MODE_PARTICLES)); add_options.push_back(AddOption("ParticleRandomness", "Particles", "VisualShaderNodeParticleRandomness", "", {}, VisualShaderNode::PORT_TYPE_SCALAR, TYPE_FLAGS_EMIT | TYPE_FLAGS_PROCESS | TYPE_FLAGS_COLLIDE, Shader::MODE_PARTICLES)); - add_options.push_back(AddOption("MultiplyByAxisAngle", "Particles/Transform", "VisualShaderNodeParticleMultiplyByAxisAngle", TTR("A node for help to multiply a position input vector by rotation using specific axis. Intended to work with emitters."), {}, VisualShaderNode::PORT_TYPE_VECTOR_3D, TYPE_FLAGS_EMIT | TYPE_FLAGS_PROCESS | TYPE_FLAGS_COLLIDE, Shader::MODE_PARTICLES)); + add_options.push_back(AddOption("MultiplyByAxisAngle (*)", "Particles/Transform", "VisualShaderNodeParticleMultiplyByAxisAngle", TTR("A node for help to multiply a position input vector by rotation using specific axis. Intended to work with emitters."), {}, VisualShaderNode::PORT_TYPE_VECTOR_3D, TYPE_FLAGS_EMIT | TYPE_FLAGS_PROCESS | TYPE_FLAGS_COLLIDE, Shader::MODE_PARTICLES)); add_options.push_back(AddOption("BoxEmitter", "Particles/Emitters", "VisualShaderNodeParticleBoxEmitter", "", {}, VisualShaderNode::PORT_TYPE_VECTOR_3D, TYPE_FLAGS_EMIT, Shader::MODE_PARTICLES)); add_options.push_back(AddOption("MeshEmitter", "Particles/Emitters", "VisualShaderNodeParticleMeshEmitter", "", {}, VisualShaderNode::PORT_TYPE_VECTOR_3D, TYPE_FLAGS_EMIT, Shader::MODE_PARTICLES)); @@ -5359,10 +5359,10 @@ VisualShaderEditor::VisualShaderEditor() { add_options.push_back(AddOption("Max", "Scalar/Functions", "VisualShaderNodeFloatOp", TTR("Returns the greater of two values."), { VisualShaderNodeFloatOp::OP_MAX }, VisualShaderNode::PORT_TYPE_SCALAR)); add_options.push_back(AddOption("Min", "Scalar/Functions", "VisualShaderNodeFloatOp", TTR("Returns the lesser of two values."), { VisualShaderNodeFloatOp::OP_MIN }, VisualShaderNode::PORT_TYPE_SCALAR)); add_options.push_back(AddOption("Mix", "Scalar/Functions", "VisualShaderNodeMix", TTR("Linear interpolation between two scalars."), { VisualShaderNodeMix::OP_TYPE_SCALAR }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("MultiplyAdd", "Scalar/Functions", "VisualShaderNodeMultiplyAdd", TTR("Performs a fused multiply-add operation (a * b + c) on scalars."), { VisualShaderNodeMultiplyAdd::OP_TYPE_SCALAR }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("Negate", "Scalar/Functions", "VisualShaderNodeFloatFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeFloatFunc::FUNC_NEGATE }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("Negate", "Scalar/Functions", "VisualShaderNodeIntFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeIntFunc::FUNC_NEGATE }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("OneMinus", "Scalar/Functions", "VisualShaderNodeFloatFunc", TTR("1.0 - scalar"), { VisualShaderNodeFloatFunc::FUNC_ONEMINUS }, VisualShaderNode::PORT_TYPE_SCALAR)); + add_options.push_back(AddOption("MultiplyAdd (a * b + c)", "Scalar/Functions", "VisualShaderNodeMultiplyAdd", TTR("Performs a fused multiply-add operation (a * b + c) on scalars."), { VisualShaderNodeMultiplyAdd::OP_TYPE_SCALAR }, VisualShaderNode::PORT_TYPE_SCALAR)); + add_options.push_back(AddOption("Negate (*-1)", "Scalar/Functions", "VisualShaderNodeFloatFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeFloatFunc::FUNC_NEGATE }, VisualShaderNode::PORT_TYPE_SCALAR)); + add_options.push_back(AddOption("Negate (*-1)", "Scalar/Functions", "VisualShaderNodeIntFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeIntFunc::FUNC_NEGATE }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("OneMinus (1-)", "Scalar/Functions", "VisualShaderNodeFloatFunc", TTR("1.0 - scalar"), { VisualShaderNodeFloatFunc::FUNC_ONEMINUS }, VisualShaderNode::PORT_TYPE_SCALAR)); add_options.push_back(AddOption("Pow", "Scalar/Functions", "VisualShaderNodeFloatOp", TTR("Returns the value of the first parameter raised to the power of the second."), { VisualShaderNodeFloatOp::OP_POW }, VisualShaderNode::PORT_TYPE_SCALAR)); add_options.push_back(AddOption("Radians", "Scalar/Functions", "VisualShaderNodeFloatFunc", TTR("Converts a quantity in degrees to radians."), { VisualShaderNodeFloatFunc::FUNC_RADIANS }, VisualShaderNode::PORT_TYPE_SCALAR)); add_options.push_back(AddOption("Reciprocal", "Scalar/Functions", "VisualShaderNodeFloatFunc", TTR("1.0 / scalar"), { VisualShaderNodeFloatFunc::FUNC_RECIPROCAL }, VisualShaderNode::PORT_TYPE_SCALAR)); @@ -5381,21 +5381,21 @@ VisualShaderEditor::VisualShaderEditor() { add_options.push_back(AddOption("TanH", "Scalar/Functions", "VisualShaderNodeFloatFunc", TTR("Returns the hyperbolic tangent of the parameter."), { VisualShaderNodeFloatFunc::FUNC_TANH }, VisualShaderNode::PORT_TYPE_SCALAR)); add_options.push_back(AddOption("Trunc", "Scalar/Functions", "VisualShaderNodeFloatFunc", TTR("Finds the truncated value of the parameter."), { VisualShaderNodeFloatFunc::FUNC_TRUNC }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("Add", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Sums two floating-point scalars."), { VisualShaderNodeFloatOp::OP_ADD }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("Add", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Sums two integer scalars."), { VisualShaderNodeIntOp::OP_ADD }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("BitwiseAND", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise AND (a & b) operation for two integers."), { VisualShaderNodeIntOp::OP_BITWISE_AND }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("BitwiseLeftShift", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise left shift (a << b) operation on the integer."), { VisualShaderNodeIntOp::OP_BITWISE_LEFT_SHIFT }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("BitwiseOR", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise OR (a | b) operation for two integers."), { VisualShaderNodeIntOp::OP_BITWISE_OR }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("BitwiseRightShift", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise right shift (a >> b) operation on the integer."), { VisualShaderNodeIntOp::OP_BITWISE_RIGHT_SHIFT }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("BitwiseXOR", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise XOR (a ^ b) operation on the integer."), { VisualShaderNodeIntOp::OP_BITWISE_XOR }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("Divide", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Divides two floating-point scalars."), { VisualShaderNodeFloatOp::OP_DIV }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("Divide", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Divides two integer scalars."), { VisualShaderNodeIntOp::OP_DIV }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("Multiply", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Multiplies two floating-point scalars."), { VisualShaderNodeFloatOp::OP_MUL }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("Multiply", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Multiplies two integer scalars."), { VisualShaderNodeIntOp::OP_MUL }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("Add (+)", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Sums two floating-point scalars."), { VisualShaderNodeFloatOp::OP_ADD }, VisualShaderNode::PORT_TYPE_SCALAR)); + add_options.push_back(AddOption("Add (+)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Sums two integer scalars."), { VisualShaderNodeIntOp::OP_ADD }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("BitwiseAND (&)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise AND (a & b) operation for two integers."), { VisualShaderNodeIntOp::OP_BITWISE_AND }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("BitwiseLeftShift (<<)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise left shift (a << b) operation on the integer."), { VisualShaderNodeIntOp::OP_BITWISE_LEFT_SHIFT }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("BitwiseOR (|)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise OR (a | b) operation for two integers."), { VisualShaderNodeIntOp::OP_BITWISE_OR }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("BitwiseRightShift (>>)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise right shift (a >> b) operation on the integer."), { VisualShaderNodeIntOp::OP_BITWISE_RIGHT_SHIFT }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("BitwiseXOR (^)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the result of bitwise XOR (a ^ b) operation on the integer."), { VisualShaderNodeIntOp::OP_BITWISE_XOR }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("Divide (/)", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Divides two floating-point scalars."), { VisualShaderNodeFloatOp::OP_DIV }, VisualShaderNode::PORT_TYPE_SCALAR)); + add_options.push_back(AddOption("Divide (/)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Divides two integer scalars."), { VisualShaderNodeIntOp::OP_DIV }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("Multiply (*)", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Multiplies two floating-point scalars."), { VisualShaderNodeFloatOp::OP_MUL }, VisualShaderNode::PORT_TYPE_SCALAR)); + add_options.push_back(AddOption("Multiply (*)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Multiplies two integer scalars."), { VisualShaderNodeIntOp::OP_MUL }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); add_options.push_back(AddOption("Remainder", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Returns the remainder of the two floating-point scalars."), { VisualShaderNodeFloatOp::OP_MOD }, VisualShaderNode::PORT_TYPE_SCALAR)); add_options.push_back(AddOption("Remainder", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Returns the remainder of the two integer scalars."), { VisualShaderNodeIntOp::OP_MOD }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); - add_options.push_back(AddOption("Subtract", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Subtracts two floating-point scalars."), { VisualShaderNodeFloatOp::OP_SUB }, VisualShaderNode::PORT_TYPE_SCALAR)); - add_options.push_back(AddOption("Subtract", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Subtracts two integer scalars."), { VisualShaderNodeIntOp::OP_SUB }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); + add_options.push_back(AddOption("Subtract (-)", "Scalar/Operators", "VisualShaderNodeFloatOp", TTR("Subtracts two floating-point scalars."), { VisualShaderNodeFloatOp::OP_SUB }, VisualShaderNode::PORT_TYPE_SCALAR)); + add_options.push_back(AddOption("Subtract (-)", "Scalar/Operators", "VisualShaderNodeIntOp", TTR("Subtracts two integer scalars."), { VisualShaderNodeIntOp::OP_SUB }, VisualShaderNode::PORT_TYPE_SCALAR_INT)); add_options.push_back(AddOption("FloatConstant", "Scalar/Variables", "VisualShaderNodeFloatConstant", TTR("Scalar floating-point constant."), {}, VisualShaderNode::PORT_TYPE_SCALAR)); add_options.push_back(AddOption("IntConstant", "Scalar/Variables", "VisualShaderNodeIntConstant", TTR("Scalar integer constant."), {}, VisualShaderNode::PORT_TYPE_SCALAR_INT)); @@ -5452,12 +5452,12 @@ VisualShaderEditor::VisualShaderEditor() { add_options.push_back(AddOption("Inverse", "Transform/Functions", "VisualShaderNodeTransformFunc", TTR("Calculates the inverse of a transform."), { VisualShaderNodeTransformFunc::FUNC_INVERSE }, VisualShaderNode::PORT_TYPE_TRANSFORM)); add_options.push_back(AddOption("Transpose", "Transform/Functions", "VisualShaderNodeTransformFunc", TTR("Calculates the transpose of a transform."), { VisualShaderNodeTransformFunc::FUNC_TRANSPOSE }, VisualShaderNode::PORT_TYPE_TRANSFORM)); - add_options.push_back(AddOption("Add", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Sums two transforms."), { VisualShaderNodeTransformOp::OP_ADD }, VisualShaderNode::PORT_TYPE_TRANSFORM)); - add_options.push_back(AddOption("Divide", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Divides two transforms."), { VisualShaderNodeTransformOp::OP_A_DIV_B }, VisualShaderNode::PORT_TYPE_TRANSFORM)); - add_options.push_back(AddOption("Multiply", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Multiplies two transforms."), { VisualShaderNodeTransformOp::OP_AxB }, VisualShaderNode::PORT_TYPE_TRANSFORM)); - add_options.push_back(AddOption("MultiplyComp", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Performs per-component multiplication of two transforms."), { VisualShaderNodeTransformOp::OP_AxB_COMP }, VisualShaderNode::PORT_TYPE_TRANSFORM)); - add_options.push_back(AddOption("Subtract", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Subtracts two transforms."), { VisualShaderNodeTransformOp::OP_A_MINUS_B }, VisualShaderNode::PORT_TYPE_TRANSFORM)); - add_options.push_back(AddOption("TransformVectorMult", "Transform/Operators", "VisualShaderNodeTransformVecMult", TTR("Multiplies vector by transform."), {}, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("Add (+)", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Sums two transforms."), { VisualShaderNodeTransformOp::OP_ADD }, VisualShaderNode::PORT_TYPE_TRANSFORM)); + add_options.push_back(AddOption("Divide (/)", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Divides two transforms."), { VisualShaderNodeTransformOp::OP_A_DIV_B }, VisualShaderNode::PORT_TYPE_TRANSFORM)); + add_options.push_back(AddOption("Multiply (*)", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Multiplies two transforms."), { VisualShaderNodeTransformOp::OP_AxB }, VisualShaderNode::PORT_TYPE_TRANSFORM)); + add_options.push_back(AddOption("MultiplyComp (*)", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Performs per-component multiplication of two transforms."), { VisualShaderNodeTransformOp::OP_AxB_COMP }, VisualShaderNode::PORT_TYPE_TRANSFORM)); + add_options.push_back(AddOption("Subtract (-)", "Transform/Operators", "VisualShaderNodeTransformOp", TTR("Subtracts two transforms."), { VisualShaderNodeTransformOp::OP_A_MINUS_B }, VisualShaderNode::PORT_TYPE_TRANSFORM)); + add_options.push_back(AddOption("TransformVectorMult (*)", "Transform/Operators", "VisualShaderNodeTransformVecMult", TTR("Multiplies vector by transform."), {}, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("TransformConstant", "Transform/Variables", "VisualShaderNodeTransformConstant", TTR("Transform constant."), {}, VisualShaderNode::PORT_TYPE_TRANSFORM)); add_options.push_back(AddOption("TransformParameter", "Transform/Variables", "VisualShaderNodeTransformParameter", TTR("Transform parameter."), {}, VisualShaderNode::PORT_TYPE_TRANSFORM)); @@ -5573,21 +5573,21 @@ VisualShaderEditor::VisualShaderEditor() { add_options.push_back(AddOption("MixS", "Vector/Functions", "VisualShaderNodeMix", TTR("Linear interpolation between two vectors using scalar."), { VisualShaderNodeMix::OP_TYPE_VECTOR_2D_SCALAR }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); add_options.push_back(AddOption("MixS", "Vector/Functions", "VisualShaderNodeMix", TTR("Linear interpolation between two vectors using scalar."), { VisualShaderNodeMix::OP_TYPE_VECTOR_3D_SCALAR }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("MixS", "Vector/Functions", "VisualShaderNodeMix", TTR("Linear interpolation between two vectors using scalar."), { VisualShaderNodeMix::OP_TYPE_VECTOR_4D_SCALAR }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("MultiplyAdd", "Vector/Functions", "VisualShaderNodeMultiplyAdd", TTR("Performs a fused multiply-add operation (a * b + c) on vectors."), { VisualShaderNodeMultiplyAdd::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("MultiplyAdd", "Vector/Functions", "VisualShaderNodeMultiplyAdd", TTR("Performs a fused multiply-add operation (a * b + c) on vectors."), { VisualShaderNodeMultiplyAdd::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("MultiplyAdd", "Vector/Functions", "VisualShaderNodeMultiplyAdd", TTR("Performs a fused multiply-add operation (a * b + c) on vectors."), { VisualShaderNodeMultiplyAdd::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("Negate", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeVectorFunc::FUNC_NEGATE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("Negate", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeVectorFunc::FUNC_NEGATE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("Negate", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeVectorFunc::FUNC_NEGATE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); + add_options.push_back(AddOption("MultiplyAdd (a * b + c)", "Vector/Functions", "VisualShaderNodeMultiplyAdd", TTR("Performs a fused multiply-add operation (a * b + c) on vectors."), { VisualShaderNodeMultiplyAdd::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("MultiplyAdd (a * b + c)", "Vector/Functions", "VisualShaderNodeMultiplyAdd", TTR("Performs a fused multiply-add operation (a * b + c) on vectors."), { VisualShaderNodeMultiplyAdd::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("MultiplyAdd (a * b + c)", "Vector/Functions", "VisualShaderNodeMultiplyAdd", TTR("Performs a fused multiply-add operation (a * b + c) on vectors."), { VisualShaderNodeMultiplyAdd::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); + add_options.push_back(AddOption("Negate (*-1)", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeVectorFunc::FUNC_NEGATE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("Negate (*-1)", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeVectorFunc::FUNC_NEGATE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("Negate (*-1)", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the opposite value of the parameter."), { VisualShaderNodeVectorFunc::FUNC_NEGATE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); add_options.push_back(AddOption("Normalize", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Calculates the normalize product of vector."), { VisualShaderNodeVectorFunc::FUNC_NORMALIZE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); add_options.push_back(AddOption("Normalize", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Calculates the normalize product of vector."), { VisualShaderNodeVectorFunc::FUNC_NORMALIZE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("Normalize", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Calculates the normalize product of vector."), { VisualShaderNodeVectorFunc::FUNC_NORMALIZE, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("OneMinus", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("1.0 - vector"), { VisualShaderNodeVectorFunc::FUNC_ONEMINUS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("OneMinus", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("1.0 - vector"), { VisualShaderNodeVectorFunc::FUNC_ONEMINUS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("OneMinus", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("1.0 - vector"), { VisualShaderNodeVectorFunc::FUNC_ONEMINUS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("Pow", "Vector/Functions", "VisualShaderNodeVectorOp", TTR("Returns the value of the first parameter raised to the power of the second."), { VisualShaderNodeVectorOp::OP_POW, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("Pow", "Vector/Functions", "VisualShaderNodeVectorOp", TTR("Returns the value of the first parameter raised to the power of the second."), { VisualShaderNodeVectorOp::OP_POW, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("Pow", "Vector/Functions", "VisualShaderNodeVectorOp", TTR("Returns the value of the first parameter raised to the power of the second."), { VisualShaderNodeVectorOp::OP_POW, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); + add_options.push_back(AddOption("OneMinus (1-)", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("1.0 - vector"), { VisualShaderNodeVectorFunc::FUNC_ONEMINUS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("OneMinus (1-)", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("1.0 - vector"), { VisualShaderNodeVectorFunc::FUNC_ONEMINUS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("OneMinus (1-)", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("1.0 - vector"), { VisualShaderNodeVectorFunc::FUNC_ONEMINUS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); + add_options.push_back(AddOption("Pow (^)", "Vector/Functions", "VisualShaderNodeVectorOp", TTR("Returns the value of the first parameter raised to the power of the second."), { VisualShaderNodeVectorOp::OP_POW, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("Pow (^)", "Vector/Functions", "VisualShaderNodeVectorOp", TTR("Returns the value of the first parameter raised to the power of the second."), { VisualShaderNodeVectorOp::OP_POW, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("Pow (^)", "Vector/Functions", "VisualShaderNodeVectorOp", TTR("Returns the value of the first parameter raised to the power of the second."), { VisualShaderNodeVectorOp::OP_POW, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); add_options.push_back(AddOption("Radians", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Converts a quantity in degrees to radians."), { VisualShaderNodeVectorFunc::FUNC_RADIANS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); add_options.push_back(AddOption("Radians", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Converts a quantity in degrees to radians."), { VisualShaderNodeVectorFunc::FUNC_RADIANS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("Radians", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Converts a quantity in degrees to radians."), { VisualShaderNodeVectorFunc::FUNC_RADIANS, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); @@ -5632,9 +5632,9 @@ VisualShaderEditor::VisualShaderEditor() { add_options.push_back(AddOption("StepS", "Vector/Functions", "VisualShaderNodeStep", TTR("Step function( scalar(edge), vector(x) ).\n\nReturns 0.0 if 'x' is smaller than 'edge' and otherwise 1.0."), { VisualShaderNodeStep::OP_TYPE_VECTOR_2D_SCALAR }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); add_options.push_back(AddOption("StepS", "Vector/Functions", "VisualShaderNodeStep", TTR("Step function( scalar(edge), vector(x) ).\n\nReturns 0.0 if 'x' is smaller than 'edge' and otherwise 1.0."), { VisualShaderNodeStep::OP_TYPE_VECTOR_3D_SCALAR }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("StepS", "Vector/Functions", "VisualShaderNodeStep", TTR("Step function( scalar(edge), vector(x) ).\n\nReturns 0.0 if 'x' is smaller than 'edge' and otherwise 1.0."), { VisualShaderNodeStep::OP_TYPE_VECTOR_4D_SCALAR }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("Sum", "Vector/Functions", "VisualShaderNodeDerivativeFunc", TTR("(Fragment/Light mode only) (Vector) Sum of absolute derivative in 'x' and 'y'."), { VisualShaderNodeDerivativeFunc::FUNC_SUM, VisualShaderNodeDerivativeFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D, TYPE_FLAGS_FRAGMENT | TYPE_FLAGS_LIGHT, -1, true)); - add_options.push_back(AddOption("Sum", "Vector/Functions", "VisualShaderNodeDerivativeFunc", TTR("(Fragment/Light mode only) (Vector) Sum of absolute derivative in 'x' and 'y'."), { VisualShaderNodeDerivativeFunc::FUNC_SUM, VisualShaderNodeDerivativeFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D, TYPE_FLAGS_FRAGMENT | TYPE_FLAGS_LIGHT, -1, true)); - add_options.push_back(AddOption("Sum", "Vector/Functions", "VisualShaderNodeDerivativeFunc", TTR("(Fragment/Light mode only) (Vector) Sum of absolute derivative in 'x' and 'y'."), { VisualShaderNodeDerivativeFunc::FUNC_SUM, VisualShaderNodeDerivativeFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D, TYPE_FLAGS_FRAGMENT | TYPE_FLAGS_LIGHT, -1, true)); + add_options.push_back(AddOption("Sum (+)", "Vector/Functions", "VisualShaderNodeDerivativeFunc", TTR("(Fragment/Light mode only) (Vector) Sum of absolute derivative in 'x' and 'y'."), { VisualShaderNodeDerivativeFunc::FUNC_SUM, VisualShaderNodeDerivativeFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D, TYPE_FLAGS_FRAGMENT | TYPE_FLAGS_LIGHT, -1, true)); + add_options.push_back(AddOption("Sum (+)", "Vector/Functions", "VisualShaderNodeDerivativeFunc", TTR("(Fragment/Light mode only) (Vector) Sum of absolute derivative in 'x' and 'y'."), { VisualShaderNodeDerivativeFunc::FUNC_SUM, VisualShaderNodeDerivativeFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D, TYPE_FLAGS_FRAGMENT | TYPE_FLAGS_LIGHT, -1, true)); + add_options.push_back(AddOption("Sum (+)", "Vector/Functions", "VisualShaderNodeDerivativeFunc", TTR("(Fragment/Light mode only) (Vector) Sum of absolute derivative in 'x' and 'y'."), { VisualShaderNodeDerivativeFunc::FUNC_SUM, VisualShaderNodeDerivativeFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D, TYPE_FLAGS_FRAGMENT | TYPE_FLAGS_LIGHT, -1, true)); add_options.push_back(AddOption("Tan", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the tangent of the parameter."), { VisualShaderNodeVectorFunc::FUNC_TAN, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); add_options.push_back(AddOption("Tan", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the tangent of the parameter."), { VisualShaderNodeVectorFunc::FUNC_TAN, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("Tan", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Returns the tangent of the parameter."), { VisualShaderNodeVectorFunc::FUNC_TAN, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); @@ -5645,21 +5645,21 @@ VisualShaderEditor::VisualShaderEditor() { add_options.push_back(AddOption("Trunc", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Finds the truncated value of the parameter."), { VisualShaderNodeVectorFunc::FUNC_TRUNC, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("Trunc", "Vector/Functions", "VisualShaderNodeVectorFunc", TTR("Finds the truncated value of the parameter."), { VisualShaderNodeVectorFunc::FUNC_TRUNC, VisualShaderNodeVectorFunc::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("Add", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Adds 2D vector to 2D vector."), { VisualShaderNodeVectorOp::OP_ADD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("Add", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Adds 3D vector to 3D vector."), { VisualShaderNodeVectorOp::OP_ADD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("Add", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Adds 4D vector to 4D vector."), { VisualShaderNodeVectorOp::OP_ADD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("Divide", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Divides 2D vector by 2D vector."), { VisualShaderNodeVectorOp::OP_DIV, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("Divide", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Divides 3D vector by 3D vector."), { VisualShaderNodeVectorOp::OP_DIV, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("Divide", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Divides 4D vector by 4D vector."), { VisualShaderNodeVectorOp::OP_DIV, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("Multiply", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Multiplies 2D vector by 2D vector."), { VisualShaderNodeVectorOp::OP_MUL, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("Multiply", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Multiplies 3D vector by 3D vector."), { VisualShaderNodeVectorOp::OP_MUL, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("Multiply", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Multiplies 4D vector by 4D vector."), { VisualShaderNodeVectorOp::OP_MUL, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); + add_options.push_back(AddOption("Add (+)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Adds 2D vector to 2D vector."), { VisualShaderNodeVectorOp::OP_ADD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("Add (+)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Adds 3D vector to 3D vector."), { VisualShaderNodeVectorOp::OP_ADD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("Add (+)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Adds 4D vector to 4D vector."), { VisualShaderNodeVectorOp::OP_ADD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); + add_options.push_back(AddOption("Divide (/)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Divides 2D vector by 2D vector."), { VisualShaderNodeVectorOp::OP_DIV, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("Divide (/)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Divides 3D vector by 3D vector."), { VisualShaderNodeVectorOp::OP_DIV, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("Divide (/)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Divides 4D vector by 4D vector."), { VisualShaderNodeVectorOp::OP_DIV, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); + add_options.push_back(AddOption("Multiply (*)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Multiplies 2D vector by 2D vector."), { VisualShaderNodeVectorOp::OP_MUL, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("Multiply (*)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Multiplies 3D vector by 3D vector."), { VisualShaderNodeVectorOp::OP_MUL, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("Multiply (*)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Multiplies 4D vector by 4D vector."), { VisualShaderNodeVectorOp::OP_MUL, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); add_options.push_back(AddOption("Remainder", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Returns the remainder of the two 2D vectors."), { VisualShaderNodeVectorOp::OP_MOD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); add_options.push_back(AddOption("Remainder", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Returns the remainder of the two 3D vectors."), { VisualShaderNodeVectorOp::OP_MOD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); add_options.push_back(AddOption("Remainder", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Returns the remainder of the two 4D vectors."), { VisualShaderNodeVectorOp::OP_MOD, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); - add_options.push_back(AddOption("Subtract", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Subtracts 2D vector from 2D vector."), { VisualShaderNodeVectorOp::OP_SUB, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); - add_options.push_back(AddOption("Subtract", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Subtracts 3D vector from 3D vector."), { VisualShaderNodeVectorOp::OP_SUB, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); - add_options.push_back(AddOption("Subtract", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Subtracts 4D vector from 4D vector."), { VisualShaderNodeVectorOp::OP_SUB, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); + add_options.push_back(AddOption("Subtract (-)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Subtracts 2D vector from 2D vector."), { VisualShaderNodeVectorOp::OP_SUB, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_2D }, VisualShaderNode::PORT_TYPE_VECTOR_2D)); + add_options.push_back(AddOption("Subtract (-)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Subtracts 3D vector from 3D vector."), { VisualShaderNodeVectorOp::OP_SUB, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_3D }, VisualShaderNode::PORT_TYPE_VECTOR_3D)); + add_options.push_back(AddOption("Subtract (-)", "Vector/Operators", "VisualShaderNodeVectorOp", TTR("Subtracts 4D vector from 4D vector."), { VisualShaderNodeVectorOp::OP_SUB, VisualShaderNodeVectorOp::OP_TYPE_VECTOR_4D }, VisualShaderNode::PORT_TYPE_VECTOR_4D)); add_options.push_back(AddOption("Vector2Constant", "Vector/Variables", "VisualShaderNodeVec2Constant", TTR("2D vector constant."), {}, VisualShaderNode::PORT_TYPE_VECTOR_2D)); add_options.push_back(AddOption("Vector2Parameter", "Vector/Variables", "VisualShaderNodeVec2Parameter", TTR("2D vector parameter."), {}, VisualShaderNode::PORT_TYPE_VECTOR_2D)); diff --git a/modules/csg/doc_classes/CSGShape3D.xml b/modules/csg/doc_classes/CSGShape3D.xml index 7e92d667b3..06f8f5a403 100644 --- a/modules/csg/doc_classes/CSGShape3D.xml +++ b/modules/csg/doc_classes/CSGShape3D.xml @@ -64,9 +64,10 @@ A contact is detected if object A is in any of the layers that object B scans, or object B is in any layer scanned by object A. See [url=$DOCS_URL/tutorials/physics/physics_introduction.html#collision-layers-and-masks]Collision layers and masks[/url] in the documentation for more information. </member> <member name="collision_mask" type="int" setter="set_collision_mask" getter="get_collision_mask" default="1"> - The physics layers this CSG shape scans for collisions. See [url=$DOCS_URL/tutorials/physics/physics_introduction.html#collision-layers-and-masks]Collision layers and masks[/url] in the documentation for more information. + The physics layers this CSG shape scans for collisions. Only effective if [member use_collision] is [code]true[/code]. See [url=$DOCS_URL/tutorials/physics/physics_introduction.html#collision-layers-and-masks]Collision layers and masks[/url] in the documentation for more information. </member> <member name="collision_priority" type="float" setter="set_collision_priority" getter="get_collision_priority" default="1.0"> + The priority used to solve colliding when occurring penetration. Only effective if [member use_collision] is [code]true[/code]. The higher the priority is, the lower the penetration into the object will be. This can for example be used to prevent the player from breaking through the boundaries of a level. </member> <member name="operation" type="int" setter="set_operation" getter="get_operation" enum="CSGShape3D.Operation" default="0"> The operation that is performed on this shape. This is ignored for the first CSG child node as the operation is between this node and the previous child of this nodes parent. @@ -75,7 +76,7 @@ Snap makes the mesh snap to a given distance so that the faces of two meshes can be perfectly aligned. A lower value results in greater precision but may be harder to adjust. </member> <member name="use_collision" type="bool" setter="set_use_collision" getter="is_using_collision" default="false"> - Adds a collision shape to the physics engine for our CSG shape. This will always act like a static body. Note that the collision shape is still active even if the CSG shape itself is hidden. + Adds a collision shape to the physics engine for our CSG shape. This will always act like a static body. Note that the collision shape is still active even if the CSG shape itself is hidden. See also [member collision_mask] and [member collision_priority]. </member> </members> <constants> diff --git a/modules/glslang/register_types.cpp b/modules/glslang/register_types.cpp index b1c2140039..53ec0fde34 100644 --- a/modules/glslang/register_types.cpp +++ b/modules/glslang/register_types.cpp @@ -53,7 +53,6 @@ static Vector<uint8_t> _compile_shader_glsl(RenderingDevice::ShaderStage p_stage }; int ClientInputSemanticsVersion = 100; // maps to, say, #define VULKAN 100 - bool check_subgroup_support = true; // assume we support subgroups glslang::EShTargetClientVersion ClientVersion = glslang::EShTargetVulkan_1_2; glslang::EShTargetLanguageVersion TargetVersion = glslang::EShTargetSpv_1_5; @@ -63,7 +62,6 @@ static Vector<uint8_t> _compile_shader_glsl(RenderingDevice::ShaderStage p_stage if (capabilities->version_major == 1 && capabilities->version_minor == 0) { ClientVersion = glslang::EShTargetVulkan_1_0; TargetVersion = glslang::EShTargetSpv_1_0; - check_subgroup_support = false; // subgroups are not supported in Vulkan 1.0 } else if (capabilities->version_major == 1 && capabilities->version_minor == 1) { ClientVersion = glslang::EShTargetVulkan_1_1; TargetVersion = glslang::EShTargetSpv_1_3; @@ -88,7 +86,7 @@ static Vector<uint8_t> _compile_shader_glsl(RenderingDevice::ShaderStage p_stage shader.setEnvClient(glslang::EShClientVulkan, ClientVersion); shader.setEnvTarget(glslang::EShTargetSpv, TargetVersion); - if (check_subgroup_support) { + { uint32_t stage_bit = 1 << p_stage; uint32_t subgroup_in_shaders = uint32_t(p_render_device->limit_get(RD::LIMIT_SUBGROUP_IN_SHADERS)); diff --git a/modules/upnp/doc_classes/UPNP.xml b/modules/upnp/doc_classes/UPNP.xml index 4888dca822..d4054948f6 100644 --- a/modules/upnp/doc_classes/UPNP.xml +++ b/modules/upnp/doc_classes/UPNP.xml @@ -41,7 +41,7 @@ func _ready(): thread = Thread.new() - thread.start(self, "_upnp_setup", SERVER_PORT) + thread.start(_upnp_setup.bind(SERVER_PORT)) func _exit_tree(): # Wait for thread finish here to handle game exit while the thread is running. diff --git a/scene/resources/visual_shader_nodes.cpp b/scene/resources/visual_shader_nodes.cpp index a4c958d402..04637983b5 100644 --- a/scene/resources/visual_shader_nodes.cpp +++ b/scene/resources/visual_shader_nodes.cpp @@ -1642,17 +1642,20 @@ bool VisualShaderNodeLinearSceneDepth::has_output_port_preview(int p_port) const String VisualShaderNodeLinearSceneDepth::generate_code(Shader::Mode p_mode, VisualShader::Type p_type, int p_id, const String *p_input_vars, const String *p_output_vars, bool p_for_preview) const { String code; + code += " {\n"; - code += " float _log_depth = textureLod(DEPTH_TEXTURE, SCREEN_UV, 0.0).x;\n"; - code += " vec3 _depth_ndc = vec3(SCREEN_UV * 2.0 - 1.0, _log_depth);\n"; - code += " vec4 _depth_view = INV_PROJECTION_MATRIX * vec4(_depth_ndc, 1.0);\n"; - code += " _depth_view.xyz /= _depth_view.w;"; - code += vformat(" %s = -_depth_view.z;", p_output_vars[0]); + code += " float __log_depth = textureLod(DEPTH_TEXTURE, SCREEN_UV, 0.0).x;\n"; + code += " vec3 __depth_ndc = vec3(SCREEN_UV * 2.0 - 1.0, __log_depth);\n"; + code += " vec4 __depth_view = INV_PROJECTION_MATRIX * vec4(__depth_ndc, 1.0);\n"; + code += " __depth_view.xyz /= __depth_view.w;\n"; + code += vformat(" %s = -__depth_view.z;\n", p_output_vars[0]); + code += " }\n"; return code; } VisualShaderNodeLinearSceneDepth::VisualShaderNodeLinearSceneDepth() { + simple_decl = false; } ////////////// Float Op @@ -3204,6 +3207,7 @@ String VisualShaderNodeUVPolarCoord::get_output_port_name(int p_port) const { String VisualShaderNodeUVPolarCoord::generate_code(Shader::Mode p_mode, VisualShader::Type p_type, int p_id, const String *p_input_vars, const String *p_output_vars, bool p_for_preview) const { String code; + code += " {\n"; String uv; if (p_input_vars[0].is_empty()) { @@ -3220,17 +3224,18 @@ String VisualShaderNodeUVPolarCoord::generate_code(Shader::Mode p_mode, VisualSh String repeat = vformat("%s", p_input_vars[3]); if (p_mode == Shader::MODE_CANVAS_ITEM) { - code += vformat(" vec2 __dir = %s - %s;\n", uv, center); - code += " float __radius = length(__dir) * 2.0;\n"; - code += " float __angle = atan(__dir.y, __dir.x) * 1.0/(PI * 2.0);\n"; - code += vformat(" %s = mod(vec2(__radius * %s, __angle * %s), 1.0);\n", p_output_vars[0], zoom, repeat); + code += vformat(" vec2 __dir = %s - %s;\n", uv, center); + code += " float __radius = length(__dir) * 2.0;\n"; + code += " float __angle = atan(__dir.y, __dir.x) * 1.0 / (PI * 2.0);\n"; + code += vformat(" %s = mod(vec2(__radius * %s, __angle * %s), 1.0);\n", p_output_vars[0], zoom, repeat); } else { - code += vformat(" vec2 __dir = %s - %s;\n", uv, center); - code += " float __radius = length(__dir) * 2.0;\n"; - code += " float __angle = atan(__dir.y, __dir.x) * 1.0/(PI * 2.0);\n"; - code += vformat(" %s = vec2(__radius * %s, __angle * %s);\n", p_output_vars[0], zoom, repeat); + code += vformat(" vec2 __dir = %s - %s;\n", uv, center); + code += " float __radius = length(__dir) * 2.0;\n"; + code += " float __angle = atan(__dir.y, __dir.x) * 1.0 / (PI * 2.0);\n"; + code += vformat(" %s = vec2(__radius * %s, __angle * %s);\n", p_output_vars[0], zoom, repeat); } + code += " }\n"; return code; } @@ -3238,6 +3243,8 @@ VisualShaderNodeUVPolarCoord::VisualShaderNodeUVPolarCoord() { set_input_port_default_value(1, Vector2(0.5, 0.5)); // center set_input_port_default_value(2, 1.0); // zoom set_input_port_default_value(3, 1.0); // repeat + + simple_decl = false; } ////////////// Dot Product @@ -7256,22 +7263,26 @@ bool VisualShaderNodeProximityFade::has_output_port_preview(int p_port) const { String VisualShaderNodeProximityFade::generate_code(Shader::Mode p_mode, VisualShader::Type p_type, int p_id, const String *p_input_vars, const String *p_output_vars, bool p_for_preview) const { String code; + code += " {\n"; String proximity_fade_distance = vformat("%s", p_input_vars[0]); - code += " float __depth_tex = textureLod(DEPTH_TEXTURE, SCREEN_UV, 0.0).r;\n"; + code += " float __depth_tex = textureLod(DEPTH_TEXTURE, SCREEN_UV, 0.0).r;\n"; if (!RenderingServer::get_singleton()->is_low_end()) { - code += " vec4 __depth_world_pos = INV_PROJECTION_MATRIX * vec4(SCREEN_UV * 2.0 - 1.0, __depth_tex, 1.0);\n"; + code += " vec4 __depth_world_pos = INV_PROJECTION_MATRIX * vec4(SCREEN_UV * 2.0 - 1.0, __depth_tex, 1.0);\n"; } else { - code += " vec4 __depth_world_pos = INV_PROJECTION_MATRIX * vec4(vec3(SCREEN_UV, __depth_tex) * 2.0 - 1.0, 1.0);\n"; + code += " vec4 __depth_world_pos = INV_PROJECTION_MATRIX * vec4(vec3(SCREEN_UV, __depth_tex) * 2.0 - 1.0, 1.0);\n"; } - code += " __depth_world_pos.xyz /= __depth_world_pos.w;\n"; - code += vformat(" %s = clamp(1.0 - smoothstep(__depth_world_pos.z + %s, __depth_world_pos.z, VERTEX.z), 0.0, 1.0);\n", p_output_vars[0], p_input_vars[0]); + code += " __depth_world_pos.xyz /= __depth_world_pos.w;\n"; + code += vformat(" %s = clamp(1.0 - smoothstep(__depth_world_pos.z + %s, __depth_world_pos.z, VERTEX.z), 0.0, 1.0);\n", p_output_vars[0], p_input_vars[0]); + code += " }\n"; return code; } VisualShaderNodeProximityFade::VisualShaderNodeProximityFade() { set_input_port_default_value(0, 1.0); + + simple_decl = false; } ////////////// Random Range @@ -7416,11 +7427,11 @@ String VisualShaderNodeRemap::get_output_port_name(int p_port) const { String VisualShaderNodeRemap::generate_code(Shader::Mode p_mode, VisualShader::Type p_type, int p_id, const String *p_input_vars, const String *p_output_vars, bool p_for_preview) const { String code; - - code += vformat(" float _input_range = %s - %s;\n", p_input_vars[2], p_input_vars[1]); - code += vformat(" float _output_range = %s - %s;\n", p_input_vars[4], p_input_vars[3]); - code += vformat(" %s = %s + _output_range * ((%s - %s) / _input_range);\n", p_output_vars[0], p_input_vars[3], p_input_vars[0], p_input_vars[1]); - + code += " {\n"; + code += vformat(" float __input_range = %s - %s;\n", p_input_vars[2], p_input_vars[1]); + code += vformat(" float __output_range = %s - %s;\n", p_input_vars[4], p_input_vars[3]); + code += vformat(" %s = %s + __output_range * ((%s - %s) / __input_range);\n", p_output_vars[0], p_input_vars[3], p_input_vars[0], p_input_vars[1]); + code += " }\n"; return code; } @@ -7429,4 +7440,6 @@ VisualShaderNodeRemap::VisualShaderNodeRemap() { set_input_port_default_value(2, 1.0); set_input_port_default_value(3, 0.0); set_input_port_default_value(4, 1.0); + + simple_decl = false; } |