ScriptableRenderPipeline/MaterialGraphProject/Assets/NewNodes/Editor/Kill/POMNode.cs


								using System.Reflection;

								using UnityEngine;


								/*namespace UnityEditor.ShaderGraph

								{

								    [Title("OLD", "ParallaxOcclusionMapping")]

								    public class ParallaxOcclusionMappingNode : CodeFunctionNode

								    {

								        protected override MethodInfo GetFunctionToConvert()

								        {

								            return GetType().GetMethod("Unity_POM", BindingFlags.Static | BindingFlags.NonPublic);

								        }


								        static string Unity_POM(

								            [Slot(1, Binding.None)] Texture2D tex,

								            [Slot(2, Binding.None)] Vector1 heightScale,

								            [Slot(3, Binding.MeshUV0)] Vector2 UVs,

								            [Slot(4, Binding.TangentSpaceViewDirection)] Vector3 viewTangentSpace,

								            [Slot(5, Binding.WorldSpaceNormal)] Vector3 worldSpaceNormal,

								            [Slot(6, Binding.WorldSpaceViewDirection)] Vector3 worldSpaceViewDirection,

								            [Slot(7, Binding.None)] out Vector2 result)

								        {

								            result = Vector2.zero;


								            return

								                @"

								{

								    float2 height_map_dimensions = float2(256.0f, 256.0f);      //HARDCODE

								    //height_map.tex.GetDimensions(height_map_dimensions.x, height_map_dimensions.y);


								    float2 texcoord= UVs;


								    // Compute the current gradients:

								    float2 texcoords_per_size = texcoord * height_map_dimensions;


								    // Compute all 4 derivatives in x and y in a single instruction to optimize:

								    float2 dx, dy;

								    float4 temp_ddx = ddx(float4(texcoords_per_size, texcoord));

								    dx.xy = temp_ddx.zw;

								    float4 temp_ddy = ddy(float4(texcoords_per_size, texcoord));

								    dy.xy = temp_ddy.zw;


								    // Start the current sample located at the input texture coordinate, which would correspond

								    // to computing a bump mapping result:

								    float2 result_texcoord = texcoord;


								    float height_scale_value = heightScale;

								    float height_scale_adjust = height_scale_value;


								    float per_pixel_height_scale_value = height_scale_value * heightScale;


								    // Parallax occlusion mapping offset computation

								    //--------------


								    // Utilize dynamic flow control to change the number of samples per ray

								    // depending on the viewing angle for the surface. Oblique angles require

								    // smaller step sizes to achieve more accurate precision for computing displacement.

								    // We express the sampling rate as a linear function of the angle between

								    // the geometric normal and the view direction ray:

								    float max_samples = 30.0f;

								    float min_samples = 4.0f;


								    float view_dot_normal= dot(worldSpaceNormal, worldSpaceViewDirection);


								    int number_of_steps = (int)lerp(max_samples, min_samples, saturate(view_dot_normal));


								    // Intersect the view ray with the height field profile along the direction of

								    // the parallax offset ray (computed in the vertex shader. Note that the code is

								    // designed specifically to take advantage of the dynamic flow control constructs

								    // in HLSL and is very sensitive to specific syntax. When converting to other examples,

								    // if still want to use dynamic flow control in the resulting assembly shader,

								    // care must be applied.

								    //

								    // In the below steps we approximate the height field profile as piecewise linear

								    // curve. We find the pair of endpoints between which the intersection between the

								    // height field profile and the view ray is found and then compute line segment

								    // intersection for the view ray and the line segment formed by the two endpoints.

								    // This intersection is the displacement offset from the original texture coordinate.

								    // See the above SI3D 06 paper for more details about the process and derivation.

								    //


								    float current_height = 0.0;

								    float step_size = 1.0 / (float)number_of_steps;


								    float previous_height = 1.0;

								    float next_height = 0.0;


								    int step_index = 0;


								    // Optimization: this should move to vertex shader, however, we compute it here for simplicity of

								    // integration into our shaders for now.

								    float3 normalized_view_dir_in_tangent_space = normalize(viewTangentSpace.xyz);


								    // Compute initial parallax displacement direction:

								    float2 parallax_direction = normalize(viewTangentSpace.xy);


								    // The length of this vector determines the furthest amount of displacement:

								    float parallax_direction_length = length(normalized_view_dir_in_tangent_space);


								    float max_parallax_amount = sqrt(parallax_direction_length * parallax_direction_length - viewTangentSpace.z * viewTangentSpace.z) / viewTangentSpace.z;


								    // Compute the actual reverse parallax displacement vector:

								    float2 parallax_offset_in_tangent_space = parallax_direction * max_parallax_amount;


								    // Need to scale the amount of displacement to account for different height ranges

								    // in height maps. This is controlled by an artist-editable parameter:

								    parallax_offset_in_tangent_space *= saturate(heightScale);

								    float2 texcoord_offset_per_step = step_size * parallax_offset_in_tangent_space;


								    float2 current_texcoord_offset = texcoord;

								    float current_bound = 1.0;

								    float current_parallax_amount = 0.0;


								    float2 pt1 = 0;

								    float2 pt2 = 0;


								    float2 temp_texcoord_offset = 0;


								    while (step_index < number_of_steps)

								    {

								        current_texcoord_offset -= texcoord_offset_per_step;


								        // Sample height map which in this case is stored in the alpha channel of the normal map:

								        current_height = tex2Dgrad(tex, current_texcoord_offset, dx, dy).r;


								        current_bound -= step_size;


								        if (current_height > current_bound)

								        {

								            pt1 = float2(current_bound, current_height);

								            pt2 = float2(current_bound + step_size, previous_height);

								            temp_texcoord_offset = current_texcoord_offset - texcoord_offset_per_step;

								            step_index = number_of_steps + 1;

								        }

								        else

								        {

								            step_index++;

								            previous_height = current_height;

								        }

								     }   // End of while ( step_index < number_of_steps)


								    float delta2 = pt2.x - pt2.y;

								    float delta1 = pt1.x - pt1.y;


								    float denominator = delta2 - delta1;


								    // SM 3.0 and above requires a check for divide by zero since that operation

								    // will generate an 'Inf' number instead of 0

								    if (denominator== 0.0f)

								    {

								        current_parallax_amount= 0.0f;

								    }

								    else

								    {

								        current_parallax_amount= (pt1.x* delta2 - pt2.x* delta1) / denominator;

								    }


								    float2 parallax_offset = parallax_offset_in_tangent_space * (1.0f - current_parallax_amount);


								    // The computed texture offset for the displaced point on the pseudo-extruded surface:

								    float2 parallaxed_texcoord = texcoord - parallax_offset;


								    result = parallaxed_texcoord;

								}

								";

								        }

								    }

								}*/