Unity信号干扰shader(参照崩坏3源码翻译剧情对话效果)_program "vp" {-程序员宅基地
技术标签: 电视故障 信号干扰 Shader 崩坏 电视扭曲
最近做的项目是二次元,二次元的标杆就是崩坏3,效果真的好
学习崩坏3里面shader最好的方法就是看源码
可以AssetStudio来看资源,因为崩坏3资源是没有加密直接可以看
不过shader源码是已经编译好的,其实大概算法都在
我已经研究角色身上的shader,这个有空写博客,用到顶点绘制的工具来填充颜色来处理阴影
这次我参考崩坏里面的信号干扰的shader
之前搞个一个类似信号干扰
https://blog.csdn.net/SnoopyNa2Co3/article/details/84673736
下面效果
我看了一下没有特别的算法,那个噪音的都是经验公式,了解的话可以自行搜索一下
下面是编译过的shader
Shader "miHoYo/UI/Image TV Distortion" {
Properties {
_MainTex ("Sprite Texture", 2D) = "white" { }
_Color ("Tint", Color) = (1,1,1,1)
_StencilComp ("Stencil Comparison", Float) = 8
_Stencil ("Stencil ID", Float) = 0
_StencilOp ("Stencil Operation", Float) = 0
_StencilWriteMask ("Stencil Write Mask", Float) = 255
_StencilReadMask ("Stencil Read Mask", Float) = 255
_ColorMask ("Color Mask", Float) = 15
_BackgroundColor ("Barckground Color (RGBA)", Color) = (0,0,0,1)
_AdjustColor ("Adjust Color (RGB)", Color) = (0,0,0,1)
_DistortionTex ("Distortion Tex (RG)", 2D) = "gray" { }
_DistortionFrequency ("Distortion Frequency", Float) = 1
_DistortionAmplitude ("Distortion Amplitude", Range(0, 1)) = 1
_DistortionAnmSpeed ("Distortion Animation Speed", Float) = 1
_ColorScatterStrength ("Color Scatter Strength", Range(-0.1, 0.1)) = 0.01
_NoiseTex ("Noise Tex (RGB)", 2D) = "black" { }
_NoiseAnmSpeed ("Noise Animation Speed", Float) = 1
_NoiseStrength ("Noise Strength", Float) = 1
_BloomFactor ("Bloom Factor", Float) = 1
[Toggle(RECT_MASK)] _RectMask ("Rect Mask", Float) = 0
_RMRect ("Rect Mask Rect", Vector) = (0,0,1,1)
_RMTransitWidth ("Rect Mask Transit Width", Vector) = (0,0,0,0)
}
SubShader {
Tags { "CanUseSpriteAtlas" = "true" "IGNOREPROJECTOR" = "true" "PreviewType" = "Plane" "QUEUE" = "Transparent+1" "RenderType" = "Transparent" }
Pass {
Tags { "CanUseSpriteAtlas" = "true" "IGNOREPROJECTOR" = "true" "PreviewType" = "Plane" "QUEUE" = "Transparent+1" "RenderType" = "Transparent" }
ZClip Off
ZTest Off
ZWrite Off
Cull Off
GpuProgramID 59740
Program "vp" {
SubProgram "gles hw_tier00 " {
"#version 100
#ifdef VERTEX
attribute vec4 _glesVertex;
attribute vec4 _glesColor;
attribute vec4 _glesMultiTexCoord0;
uniform highp vec4 _Time;
uniform highp vec4 _SinTime;
uniform highp vec4 _CosTime;
uniform highp mat4 unity_ObjectToWorld;
uniform highp mat4 unity_MatrixVP;
uniform mediump float _DistortionFrequency;
uniform mediump float _DistortionAnmSpeed;
uniform highp vec4 _NoiseTex_ST;
uniform highp float _NoiseAnmSpeed;
uniform lowp vec4 _Color;
varying lowp vec4 xlv_COLOR;
varying mediump vec2 xlv_TEXCOORD0;
varying mediump vec2 xlv_TEXCOORD1;
varying mediump vec2 xlv_TEXCOORD2;
void main ()
{
highp vec2 tmpvar_1;
tmpvar_1 = _glesMultiTexCoord0.xy;
lowp vec4 tmpvar_2;
mediump vec2 tmpvar_3;
mediump vec2 tmpvar_4;
mediump vec2 tmpvar_5;
highp vec4 tmpvar_6;
tmpvar_6.w = 1.0;
tmpvar_6.xyz = _glesVertex.xyz;
tmpvar_3 = tmpvar_1;
highp vec2 tmpvar_7;
tmpvar_7.x = (_Time.y * _DistortionAnmSpeed);
tmpvar_7.y = (_glesMultiTexCoord0.y * _DistortionFrequency);
tmpvar_4 = tmpvar_7;
tmpvar_5 = ((_glesMultiTexCoord0.xy * _NoiseTex_ST.xy) + _NoiseTex_ST.zw);
highp vec3 tmpvar_8;
tmpvar_8 = fract((sin(
(_SinTime.w * vec3(12.9898, 78.233, 45.5432))
) * 43758.55));
highp vec3 tmpvar_9;
tmpvar_9 = fract((sin(
(_CosTime.x * vec3(12.9898, 78.233, 45.5432))
) * 43758.55));
tmpvar_5.x = (tmpvar_5.x + ((tmpvar_8.x + tmpvar_9.x) * _NoiseAnmSpeed));
highp vec3 tmpvar_10;
tmpvar_10 = fract((sin(
(_SinTime.x * vec3(12.9898, 78.233, 45.5432))
) * 43758.55));
highp vec3 tmpvar_11;
tmpvar_11 = fract((sin(
(_CosTime.w * vec3(12.9898, 78.233, 45.5432))
) * 43758.55));
tmpvar_5.y = (tmpvar_5.y + ((tmpvar_10.x + tmpvar_11.x) * _NoiseAnmSpeed));
tmpvar_2 = (_glesColor * _Color);
gl_Position = (unity_MatrixVP * (unity_ObjectToWorld * tmpvar_6));
xlv_COLOR = tmpvar_2;
xlv_TEXCOORD0 = tmpvar_3;
xlv_TEXCOORD1 = tmpvar_4;
xlv_TEXCOORD2 = tmpvar_5;
}
#endif
#ifdef FRAGMENT
uniform mediump vec4 _BackgroundColor;
uniform mediump vec3 _AdjustColor;
uniform sampler2D _DistortionTex;
uniform mediump float _DistortionAmplitude;
uniform mediump float _ColorScatterStrength;
uniform sampler2D _NoiseTex;
uniform mediump float _NoiseStrength;
uniform sampler2D _MainTex;
varying lowp vec4 xlv_COLOR;
varying mediump vec2 xlv_TEXCOORD0;
varying mediump vec2 xlv_TEXCOORD1;
varying mediump vec2 xlv_TEXCOORD2;
void main ()
{
lowp vec4 tmpvar_1;
mediump vec4 color_2;
mediump float offset_3;
lowp float tmpvar_4;
tmpvar_4 = (texture2D (_DistortionTex, xlv_TEXCOORD1) - 0.498).x;
offset_3 = tmpvar_4;
offset_3 = (offset_3 * _DistortionAmplitude);
color_2.yz = vec2(0.0, 0.0);
mediump vec2 tmpvar_5;
tmpvar_5.y = 0.0;
tmpvar_5.x = _ColorScatterStrength;
lowp vec4 tmpvar_6;
mediump vec2 P_7;
P_7 = ((xlv_TEXCOORD0 + offset_3) + tmpvar_5);
tmpvar_6 = texture2D (_MainTex, P_7);
color_2.xw = tmpvar_6.xw;
lowp vec4 tmpvar_8;
mediump vec2 P_9;
P_9 = (xlv_TEXCOORD0 + offset_3);
tmpvar_8 = texture2D (_MainTex, P_9);
color_2.yw = (color_2.yw + tmpvar_8.yw);
mediump vec2 tmpvar_10;
tmpvar_10.y = 0.0;
tmpvar_10.x = _ColorScatterStrength;
lowp vec4 tmpvar_11;
mediump vec2 P_12;
P_12 = ((xlv_TEXCOORD0 + offset_3) - tmpvar_10);
tmpvar_11 = texture2D (_MainTex, P_12);
color_2.zw = (color_2.zw + tmpvar_11.zw);
color_2.xyz = (color_2.xyz * xlv_COLOR.xyz);
color_2.w = clamp (color_2.w, 0.0, 1.0);
mediump vec4 tmpvar_13;
if ((color_2.w < 0.5)) {
tmpvar_13 = _BackgroundColor;
} else {
tmpvar_13 = color_2;
};
color_2.w = tmpvar_13.w;
color_2.xyz = (1.0 - ((1.0 - tmpvar_13.xyz) * (1.0 - _AdjustColor)));
lowp vec4 tmpvar_14;
tmpvar_14 = texture2D (_NoiseTex, xlv_TEXCOORD2);
color_2.xyz = (1.0 - ((1.0 - color_2.xyz) * (1.0 -
(tmpvar_14 * _NoiseStrength)
.xyz)));
tmpvar_1 = color_2;
gl_FragData[0] = tmpvar_1;
}就不多说如果会shader应该会翻译上面的shader,就直接放出来,里面有一些注释方便学习
下面直接放我根据上面源码实现的unity shader
Shader "Custom/TVDistortion"
{
Properties
{
_MainTex("Sprite Texture", 2D) = "white" { }
_Color("Tint", Color) = (1,1,1,1)
_BackgroundColor("Barckground Color (RGBA)", Color) = (0,0,0,1)
_AdjustColor("Adjust Color (RGB)", Color) = (0,0,0,1)
_DistortionTex("Distortion Tex (RG)", 2D) = "gray" { }
_DistortionFrequency("Distortion Frequency", Float) = 1
_DistortionAmplitude("Distortion Amplitude", Range(0, 1)) = 1
_DistortionAnmSpeed("Distortion Animation Speed", Float) = 1
_ColorScatterStrength("Color Scatter Strength", Range(-0.1, 0.1)) = 0.01
_NoiseTex("Noise Tex (RGB)", 2D) = "black" { }
_NoiseAnmSpeed("Noise Animation Speed", Float) = 1
_NoiseStrength("Noise Strength", Float) = 1
}
SubShader
{
Pass
{
ZTest Always Cull Off ZWrite Off
CGPROGRAM
#pragma vertex vert
#pragma fragment frag
#pragma target 3.0
#pragma multi_compile_fog
#include "UnityCG.cginc"
struct appdata
{
float4 vertex : POSITION;
float2 uv : TEXCOORD0;
};
struct v2f
{
float4 uv : TEXCOORD0;
float4 Color : COLOR;
float4 Distortion_UV : TEXCOORD1;
float4 Noise_UV : TEXCOORD2;
UNITY_FOG_COORDS(1)
float4 vertex : SV_POSITION;
};
sampler2D _MainTex;
float4 _MainTex_ST;
float4 _Color;
float4 _BackgroundColor;
float4 _AdjustColor;
sampler2D _DistortionTex;
float _DistortionFrequency;
float _DistortionAmplitude;
float _DistortionAnmSpeed;
float _ColorScatterStrength;
sampler2D _NoiseTex;
float4 _NoiseTex_ST;
float _NoiseAnmSpeed;
float _NoiseStrength;
v2f vert(appdata v)
{
v2f o;
o.uv.xy = v.uv.xy;
o.vertex = UnityObjectToClipPos(v.vertex);
float4 distortUV;
//扭曲图UV
distortUV.x = (_Time.y * _DistortionAnmSpeed);
distortUV.y = (v.uv.y * _DistortionFrequency);
o.Distortion_UV = distortUV;
//噪音图UV
float2 noiseUV = TRANSFORM_TEX(v.uv, _NoiseTex);
float3 noise1 = frac((sin((_SinTime.w * float3(12.9898, 78.233, 45.5432))) * 43758.55));
float3 noise2 = frac((sin((_CosTime.x * float3(12.9898, 78.233, 45.5432))) * 43758.55));
noiseUV.x = (noiseUV.x + ((noise1.x + noise2.x) * _NoiseAnmSpeed));
float3 noise3 = frac((sin((_SinTime.x * float3(12.9898, 78.233, 45.5432))) * 43758.55));
float3 noise4 = frac((sin((_CosTime.w * float3(12.9898, 78.233, 45.5432))) * 43758.55));
noiseUV.y = (noiseUV.y + ((noise3.x + noise4.x) * _NoiseAnmSpeed));
o.Noise_UV = float4(noiseUV, 0, 0);
UNITY_TRANSFER_FOG(o, o.vertex);
return o;
}
half4 frag(v2f i) : SV_Target
{
float4 color;
color.yz = float2(0.0, 0.0);
//获取扭曲图的偏移位置
half offset = (tex2D(_DistortionTex, i.Distortion_UV.xy) - 0.498).x * _DistortionAmplitude;
//颜色偏移强度(左右)
float2 ColorStrength = float2(_ColorScatterStrength, 0.0);
//红色偏移
float4 redOffset = tex2D(_MainTex, ((i.uv.xy + offset) + ColorStrength));
color.xw = redOffset.xw;
//绿色位置不变
float4 greenOffset = tex2D(_MainTex, i.uv.xy + offset);
color.yw = (color.yw + greenOffset.yw);
//蓝色偏移
float4 blueOffset = tex2D(_MainTex,(i.uv.xy + offset) - ColorStrength);
color.zw = (color.zw + blueOffset.zw);
color.w = clamp(color.w, 0.0, 1.0);
//如果是半透则使用背景颜色
if ((color.w < 0.5))
{
color = _BackgroundColor;
}
//颜色调整
color.xyz = (1.0 - ((1.0 - color.xyz) * (1.0 - _AdjustColor)));
//噪音图叠加
float4 noiseColor;
noiseColor = tex2D(_NoiseTex, i.Noise_UV.xy);
color.xyz = (1.0 - ((1.0 - color.xyz) * (1.0 -(noiseColor * _NoiseStrength).xyz)));
return color;
}
ENDCG
}
}
FallBack "Diffuse"
}
智能推荐
稀疏编码的数学基础与理论分析-程序员宅基地
文章浏览阅读290次,点赞8次,收藏10次。1.背景介绍稀疏编码是一种用于处理稀疏数据的编码技术,其主要应用于信息传输、存储和处理等领域。稀疏数据是指数据中大部分元素为零或近似于零的数据,例如文本、图像、音频、视频等。稀疏编码的核心思想是将稀疏数据表示为非零元素和它们对应的位置信息,从而减少存储空间和计算复杂度。稀疏编码的研究起源于1990年代,随着大数据时代的到来,稀疏编码技术的应用范围和影响力不断扩大。目前,稀疏编码已经成为计算...
EasyGBS国标流媒体服务器GB28181国标方案安装使用文档-程序员宅基地
文章浏览阅读217次。EasyGBS - GB28181 国标方案安装使用文档下载安装包下载,正式使用需商业授权, 功能一致在线演示在线API架构图EasySIPCMSSIP 中心信令服务, 单节点, 自带一个 Redis Server, 随 EasySIPCMS 自启动, 不需要手动运行EasySIPSMSSIP 流媒体服务, 根..._easygbs-windows-2.6.0-23042316使用文档
【Web】记录巅峰极客2023 BabyURL题目复现——Jackson原生链_原生jackson 反序列化链子-程序员宅基地
文章浏览阅读1.2k次,点赞27次,收藏7次。2023巅峰极客 BabyURL之前AliyunCTF Bypassit I这题考查了这样一条链子:其实就是Jackson的原生反序列化利用今天复现的这题也是大同小异,一起来整一下。_原生jackson 反序列化链子
一文搞懂SpringCloud,详解干货,做好笔记_spring cloud-程序员宅基地
文章浏览阅读734次,点赞9次,收藏7次。微服务架构简单的说就是将单体应用进一步拆分,拆分成更小的服务,每个服务都是一个可以独立运行的项目。这么多小服务,如何管理他们?(服务治理 注册中心[服务注册 发现 剔除])这么多小服务,他们之间如何通讯?这么多小服务,客户端怎么访问他们?(网关)这么多小服务,一旦出现问题了,应该如何自处理?(容错)这么多小服务,一旦出现问题了,应该如何排错?(链路追踪)对于上面的问题,是任何一个微服务设计者都不能绕过去的,因此大部分的微服务产品都针对每一个问题提供了相应的组件来解决它们。_spring cloud
Js实现图片点击切换与轮播-程序员宅基地
文章浏览阅读5.9k次,点赞6次,收藏20次。Js实现图片点击切换与轮播图片点击切换<!DOCTYPE html><html> <head> <meta charset="UTF-8"> <title></title> <script type="text/ja..._点击图片进行轮播图切换
tensorflow-gpu版本安装教程(过程详细)_tensorflow gpu版本安装-程序员宅基地
文章浏览阅读10w+次,点赞245次,收藏1.5k次。在开始安装前,如果你的电脑装过tensorflow,请先把他们卸载干净,包括依赖的包(tensorflow-estimator、tensorboard、tensorflow、keras-applications、keras-preprocessing),不然后续安装了tensorflow-gpu可能会出现找不到cuda的问题。cuda、cudnn。..._tensorflow gpu版本安装
随便推点
物联网时代 权限滥用漏洞的攻击及防御-程序员宅基地
文章浏览阅读243次。0x00 简介权限滥用漏洞一般归类于逻辑问题,是指服务端功能开放过多或权限限制不严格,导致攻击者可以通过直接或间接调用的方式达到攻击效果。随着物联网时代的到来,这种漏洞已经屡见不鲜,各种漏洞组合利用也是千奇百怪、五花八门,这里总结漏洞是为了更好地应对和预防,如有不妥之处还请业内人士多多指教。0x01 背景2014年4月,在比特币飞涨的时代某网站曾经..._使用物联网漏洞的使用者
Visual Odometry and Depth Calculation--Epipolar Geometry--Direct Method--PnP_normalized plane coordinates-程序员宅基地
文章浏览阅读786次。A. Epipolar geometry and triangulationThe epipolar geometry mainly adopts the feature point method, such as SIFT, SURF and ORB, etc. to obtain the feature points corresponding to two frames of images. As shown in Figure 1, let the first image be and th_normalized plane coordinates
开放信息抽取(OIE)系统(三)-- 第二代开放信息抽取系统(人工规则, rule-based, 先抽取关系)_语义角色增强的关系抽取-程序员宅基地
文章浏览阅读708次,点赞2次,收藏3次。开放信息抽取(OIE)系统(三)-- 第二代开放信息抽取系统(人工规则, rule-based, 先关系再实体)一.第二代开放信息抽取系统背景 第一代开放信息抽取系统(Open Information Extraction, OIE, learning-based, 自学习, 先抽取实体)通常抽取大量冗余信息,为了消除这些冗余信息,诞生了第二代开放信息抽取系统。二.第二代开放信息抽取系统历史第二代开放信息抽取系统着眼于解决第一代系统的三大问题: 大量非信息性提取(即省略关键信息的提取)、_语义角色增强的关系抽取
10个顶尖响应式HTML5网页_html欢迎页面-程序员宅基地
文章浏览阅读1.1w次,点赞6次,收藏51次。快速完成网页设计,10个顶尖响应式HTML5网页模板助你一臂之力为了寻找一个优质的网页模板,网页设计师和开发者往往可能会花上大半天的时间。不过幸运的是,现在的网页设计师和开发人员已经开始共享HTML5,Bootstrap和CSS3中的免费网页模板资源。鉴于网站模板的灵活性和强大的功能,现在广大设计师和开发者对html5网站的实际需求日益增长。为了造福大众,Mockplus的小伙伴整理了2018年最..._html欢迎页面
计算机二级 考试科目,2018全国计算机等级考试调整,一、二级都增加了考试科目...-程序员宅基地
文章浏览阅读282次。原标题:2018全国计算机等级考试调整,一、二级都增加了考试科目全国计算机等级考试将于9月15-17日举行。在备考的最后冲刺阶段,小编为大家整理了今年新公布的全国计算机等级考试调整方案,希望对备考的小伙伴有所帮助,快随小编往下看吧!从2018年3月开始,全国计算机等级考试实施2018版考试大纲,并按新体系开考各个考试级别。具体调整内容如下:一、考试级别及科目1.一级新增“网络安全素质教育”科目(代..._计算机二级增报科目什么意思
conan简单使用_apt install conan-程序员宅基地
文章浏览阅读240次。conan简单使用。_apt install conan