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* Update release number to 87.
Public Issues:
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to the same subpass dependency (public pull request 756).
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document (public issue 769)
* Fix links in <<VK_NVX_raytracing>> extension (public pull request 805).
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- does not close this, however).
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Internal Issues:
* Clarify that the compressed texture formats corresponding to
<<features-features-textureCompressionETC2>>,
<<features-features-textureCompressionASTC_LDR>>, and
<<features-features-textureCompressionBC>> is not contingent on the
feature bits, and may be supported even if the features are not enabled
(internal issue 663).
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<<interfaces-builtin-variables, Built-In Variables>> section (internal
issue 1173).
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before use in the flink:vkAllocateDescriptorSets section (internal issue
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attribute set in the Makefile, rather than the explicit [%inline]
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that all implementations must support at least one queue family, and
that every queue family must contain at least one queue.
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conformance tests.
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New Extensions:
* `<<VK_FUCHSIA_imagepipe_surface>>`
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include::meta/VK_NV_viewport_swizzle.txt[]
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*Last Modified Date*::
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2016-12-22
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*Interactions and External Dependencies*::
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- This extension requires pname:multiViewport and pname:geometryShader
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features to be useful.
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*Contributors*::
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- Daniel Koch, NVIDIA
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- Jeff Bolz, NVIDIA
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This extension provides a new per-viewport swizzle that can modify the
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position of primitives sent to each viewport.
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New viewport swizzle state is added for each viewport, and a new position
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vector is computed for each vertex by selecting from and optionally negating
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any of the four components of the original position vector.
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This new viewport swizzle is useful for a number of algorithms, including
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single-pass cubemap rendering (broadcasting a primitive to multiple faces
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and reorienting the vertex position for each face) and voxel rasterization.
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The per-viewport component remapping and negation provided by the swizzle
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allows application code to re-orient three-dimensional geometry with a view
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along any of the *X*, *Y*, or *Z* axes.
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If a perspective projection and depth buffering is required, [eq]#1/W#
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buffering should be used, as described in the single-pass cubemap rendering
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example in the "`Issues`" section below.
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=== New Object Types
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None.
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=== New Enum Constants
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* Extending elink:VkStructureType:
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** ename:VK_STRUCTURE_TYPE_PIPELINE_VIEWPORT_SWIZZLE_STATE_CREATE_INFO_NV
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=== New Enums
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* elink:VkViewportCoordinateSwizzleNV
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* elink:VkPipelineViewportSwizzleStateCreateFlagsNV
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=== New Structures
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* slink:VkViewportSwizzleNV
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* slink:VkPipelineViewportSwizzleStateCreateInfoNV
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=== New Functions
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None.
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=== Issues
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1) Where does viewport swizzling occur in the pipeline?
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*RESOLVED*: Despite being associated with the viewport, viewport swizzling
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must happen prior to the viewport transform.
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In particular, it needs to be performed before clipping and perspective
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division.
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The viewport mask expansion (`<<VK_NV_viewport_array2>>`) and the viewport
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swizzle could potentially be performed before or after transform feedback,
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but feeding back several viewports worth of primitives with different
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swizzles doesn't seem particularly useful.
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This specification applies the viewport mask and swizzle after transform
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feedback, and makes primitive queries only count each primitive once.
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2) Any interesting examples of how this extension,
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`<<VK_NV_viewport_array2>>`, and `<<VK_NV_geometry_shader_passthrough>>` can
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be used together in practice?
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*RESOLVED*: One interesting use case for this extension is for single-pass
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rendering to a cubemap.
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In this example, the application would attach a cubemap texture to a layered
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FBO where the six cube faces are treated as layers.
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Vertices are sent through the vertex shader without applying a projection
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matrix, where the code:gl_Position output is [eq]#(x,y,z,1)# and the center
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of the cubemap is at [eq]#(0,0,0)#.
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With unextended Vulkan, one could have a conventional instanced geometry
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shader that looks something like the following:
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[source,c]
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---------------------------------------------------
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layout(invocations = 6) in; // separate invocation per face
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layout(triangles) in;
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layout(triangle_strip) out;
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layout(max_vertices = 3) out;
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in Inputs {
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vec2 texcoord;
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vec3 normal;
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vec4 baseColor;
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} v[];
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out Outputs {
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vec2 texcoord;
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vec3 normal;
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vec4 baseColor;
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};
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void main()
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{
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int face = gl_InvocationID; // which face am I?
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// Project gl_Position for each vertex onto the cube map face.
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vec4 positions[3];
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for (int i = 0; i < 3; i++) {
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positions[i] = rotate(gl_in[i].gl_Position, face);
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}
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// If the primitive doesn't project onto this face, we're done.
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if (shouldCull(positions)) {
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return;
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}
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// Otherwise, emit a copy of the input primitive to the
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// appropriate face (using gl_Layer).
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for (int i = 0; i < 3; i++) {
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gl_Layer = face;
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gl_Position = positions[i];
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texcoord = v[i].texcoord;
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normal = v[i].normal;
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baseColor = v[i].baseColor;
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EmitVertex();
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}
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}
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---------------------------------------------------
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With passthrough geometry shaders, this can be done using a much simpler
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shader:
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[source,c]
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---------------------------------------------------
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layout(triangles) in;
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layout(passthrough) in Inputs {
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vec2 texcoord;
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vec3 normal;
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vec4 baseColor;
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}
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layout(passthrough) in gl_PerVertex {
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vec4 gl_Position;
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} gl_in[];
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layout(viewport_relative) out int gl_Layer;
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void main()
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{
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// Figure out which faces the primitive projects onto and
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// generate a corresponding viewport mask.
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uint mask = 0;
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for (int i = 0; i < 6; i++) {
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if (!shouldCull(face)) {
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mask |= 1U << i;
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}
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}
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gl_ViewportMask = mask;
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gl_Layer = 0;
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}
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---------------------------------------------------
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The application code is set up so that each of the six cube faces has a
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separate viewport (numbered 0 to 5).
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Each face also has a separate swizzle, programmed via the
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slink:VkPipelineViewportSwizzleStateCreateInfoNV pipeline state.
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The viewport swizzle feature performs the coordinate transformation handled
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by the code:rotate() function in the original shader.
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The code:viewport_relative layout qualifier says that the viewport number (0
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to 5) is added to the base code:gl_Layer value of 0 to determine which layer
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(cube face) the primitive should be sent to.
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Note that the use of the passed through input code:normal in this example
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suggests that the fragment shader in this example would perform an operation
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like per-fragment lighting.
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The viewport swizzle would transform the position to be face-relative, but
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code:normal would remain in the original coordinate system.
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It seems likely that the fragment shader in either version of the example
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would want to perform lighting in the original coordinate system.
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It would likely do this by reconstructing the position of the fragment in
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the original coordinate system using code:gl_FragCoord, a constant or
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uniform holding the size of the cube face, and the input
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code:gl_ViewportIndex (or code:gl_Layer), which identifies the cube face.
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Since the value of code:normal is in the original coordinate system, it
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would not need to be modified as part of this coordinate transformation.
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Note that while the code:rotate() operation in the regular geometry shader
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above could include an arbitrary post-rotation projection matrix, the
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viewport swizzle does not support arbitrary math.
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To get proper projection, [eq]#1/W# buffering should be used.
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To do this:
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. Program the viewport swizzles to move the pre-projection [eq]#W# eye
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coordinate (typically 1.0) into the [eq]#Z# coordinate of the swizzle
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output and the eye coordinate component used for depth into the [eq]#W#
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coordinate.
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For example, the viewport corresponding to the [eq]#+Z# face might use a
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swizzle of [eq]#(+X, -Y, +W, +Z)#.
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The [eq]#Z# normalized device coordinate computed after swizzling would
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then be [eq]#z'/w' = 1/Z~eye~#.
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. On NVIDIA implementations supporting floating-point depth buffers with
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values outside [eq]#[0,1]#, prevent unwanted near plane clipping by
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enabling pname:depthClampEnable.
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Ensure that the depth clamp doesn't mess up depth testing by programming
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the depth range to very large values, such as
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[eq]#pname:minDepthBounds=-z#, [eq]#pname:maxDepthBounds=+z#, where
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[eq]#z = 2^127^#.
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It should be possible to use IEEE infinity encodings also (`0xFF800000`
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for `-INF`, `0x7F800000` for `+INF`).
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Even when near/far clipping is disabled, primitives extending behind the
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eye will still be clipped because one or more vertices will have a
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negative [eq]#W# coordinate and fail [eq]#X#/[eq]#Y# clipping tests.
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+
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--
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On other implementations, scale [eq]#X#, [eq]#Y#, and [eq]#Z# eye
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coordinates so that vertices on the near plane have a post-swizzle [eq]#W#
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coordinate of 1.0.
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For example, if the near plane is at [eq]#Z~eye~ = 1/256#, scale [eq]#X#,
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[eq]#Y#, and [eq]#Z# by 256.
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--
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. Adjust depth testing to reflect the fact that [eq]#1/W# values are large
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near the eye and small away from the eye.
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Clear the depth buffer to zero (infinitely far away) and use a depth
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test of ename:VK_COMPARE_OP_GREATER instead of ename:VK_COMPARE_OP_LESS.
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=== Version History
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* Revision 1, 2016-12-22 (Piers Daniell)
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- Internal revisions
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