大氣散射OpenGL 3.3

Question

我目前正在嘗試將肖恩·奧尼爾的着色器轉換為版本330，因此我可以在我正在編寫的應用程序中嘗試它。 我對已棄用的函數有一些問題，所以我替換了它們，但我幾乎全新的glsl，所以我可能在某個地方犯了一個錯誤。

原始着色器可以在這里找到： http ： //www.gamedev.net/topic/592043-solved-trying-to-use-atmospheric-scattering-oneill-2004-but-get-black-sphere/

我試圖改變它們的可怕嘗試：

頂點着色器：

#version 330 core

// Input vertex data, different for all executions of this shader.
layout(location = 0) in vec3 vertexPosition_modelspace;
layout(location = 2) in vec3 vertexNormal_modelspace;



uniform vec3 v3CameraPos;       // The camera's current position
uniform vec3 v3LightPos;        // The direction vector to the light source
uniform vec3 v3InvWavelength;   // 1 / pow(wavelength, 4) for the red, green, and blue channels
uniform float fCameraHeight;    // The camera's current height
uniform float fCameraHeight2;   // fCameraHeight^2
uniform float fOuterRadius;     // The outer (atmosphere) radius
uniform float fOuterRadius2;    // fOuterRadius^2
uniform float fInnerRadius;     // The inner (planetary) radius
uniform float fInnerRadius2;    // fInnerRadius^2
uniform float fKrESun;          // Kr * ESun
uniform float fKmESun;          // Km * ESun
uniform float fKr4PI;           // Kr * 4 * PI
uniform float fKm4PI;           // Km * 4 * PI
uniform float fScale;           // 1 / (fOuterRadius - fInnerRadius)
uniform float fScaleDepth;      // The scale depth (i.e. the altitude at which the atmosphere's average density is found)
uniform float fScaleOverScaleDepth; // fScale / fScaleDepth

const int nSamples = 2;
const float fSamples = 2.0;

invariant out vec3 v3Direction;

// Values that stay constant for the whole mesh.
uniform mat4 MVP;
uniform mat4 V;
uniform mat4 M;
uniform vec3 LightPosition_worldspace;



 out vec4    dgl_SecondaryColor;
 out vec4   dgl_Color;


float scale(float fCos)
{
float x = 1.0 - fCos;
return fScaleDepth * exp(-0.00287 + x*(0.459 + x*(3.83 + x*(-6.80 + x*5.25))));
}


void main(void)
{

    //gg_FrontColor = vec3(1.0, 0.0, 0.0);
        //gg_FrontSecondaryColor = vec3(0.0, 1.0, 0.0);

// Get the ray from the camera to the vertex, and its length (which is the far point of the ray passing through the atmosphere)
vec3 v3Pos = vertexPosition_modelspace;
vec3 v3Ray = v3Pos - v3CameraPos;
float fFar = length(v3Ray);
v3Ray /= fFar;

// Calculate the ray's starting position, then calculate its scattering offset
vec3 v3Start = v3CameraPos;
float fHeight = length(v3Start);
float fDepth = exp(fScaleOverScaleDepth * (fInnerRadius - fCameraHeight));
float fStartAngle = dot(v3Ray, v3Start) / fHeight;
float fStartOffset = fDepth*scale(fStartAngle);

// Initialize the scattering loop variables
gl_FrontColor = vec4(0.0, 0.0, 0.0, 0.0);
gl_FrontSecondaryColor = vec4(0.0, 0.0, 0.0, 0.0);

float fSampleLength = fFar / fSamples;
float fScaledLength = fSampleLength * fScale;
vec3 v3SampleRay = v3Ray * fSampleLength;
vec3 v3SamplePoint = v3Start + v3SampleRay * 0.5;

// Now loop through the sample rays
vec3 v3FrontColor = vec3(0.2, 0.1, 0.0);
for(int i=0; i<nSamples; i++)
{
    float fHeight = length(v3SamplePoint);
    float fDepth = exp(fScaleOverScaleDepth * (fInnerRadius - fHeight));
    float fLightAngle = dot(v3LightPos, v3SamplePoint) / fHeight;
    float fCameraAngle = dot(v3Ray, v3SamplePoint) / fHeight;
    float fScatter = (fStartOffset + fDepth*(scale(fLightAngle) - scale(fCameraAngle)));
    vec3 v3Attenuate = exp(-fScatter * (v3InvWavelength * fKr4PI + fKm4PI));
    v3FrontColor += v3Attenuate * (fDepth * fScaledLength);
    v3SamplePoint += v3SampleRay;
}

// Finally, scale the Mie and Rayleigh colors and set up the varying variables for the pixel shader
gl_FrontSecondaryColor.rgb = v3FrontColor * fKmESun;
gl_FrontColor.rgb = v3FrontColor * (v3InvWavelength * fKrESun);
gl_Position =  MVP * vec4(vertexPosition_modelspace,1);
v3Direction = v3CameraPos - v3Pos;

dgl_SecondaryColor = gl_FrontSecondaryColor;
dgl_Color = gl_FrontColor;


}

片段着色器：

#version 330 core

out vec4 dgl_FragColor;

uniform vec3 v3LightPos;
uniform float g;
uniform float g2;

 invariant in vec3 v3Direction;

 in vec4    dgl_SecondaryColor;
 in vec4   dgl_Color;


uniform mat4 MV;

void main (void)
{

float fCos = dot(v3LightPos, v3Direction) / length(v3Direction);
float fMiePhase = 1.5 * ((1.0 - g2) / (2.0 + g2)) * (1.0 + fCos*fCos) / pow(1.0 + g2 - 2.0*g*fCos, 1.5);
dgl_FragColor = dgl_Color + fMiePhase * dgl_SecondaryColor;
dgl_FragColor.a = dgl_FragColor.b;



}

我寫了一個渲染球體的函數，我試圖將這個着色器渲染到它的倒置版本上，球體完全正常，有法線和全部。 我的問題是球體被渲染為全黑，因此着色器不起作用。 編輯：得到太陽畫，但天空仍然是全黑的。

這就是我試圖在主渲染循環中渲染氛圍的方式。

    glUseProgram(programAtmosphere);
    glBindTexture(GL_TEXTURE_2D, 0);
    //######################


glUniform3f(v3CameraPos, getPlayerPos().x, getPlayerPos().y, getPlayerPos().z);

glm::vec3 lightDirection = lightPos/length(lightPos);

glUniform3f(v3LightPos, lightDirection.x , lightDirection.y, lightDirection.z);

glUniform3f(v3InvWavelength, 1.0f / pow(0.650f, 4.0f), 1.0f / pow(0.570f, 4.0f), 1.0f / pow(0.475f, 4.0f));

glUniform1fARB(fCameraHeight, 10.0f+length(getPlayerPos()));

glUniform1fARB(fCameraHeight2, (10.0f+length(getPlayerPos()))*(10.0f+length(getPlayerPos())));

glUniform1fARB(fInnerRadius, 10.0f);

glUniform1fARB(fInnerRadius2, 100.0f);

glUniform1fARB(fOuterRadius, 10.25f);

glUniform1fARB(fOuterRadius2, 10.25f*10.25f);

glUniform1fARB(fKrESun, 0.0025f * 20.0f);

glUniform1fARB(fKmESun, 0.0015f * 20.0f);

glUniform1fARB(fKr4PI, 0.0025f * 4.0f * 3.141592653f);

glUniform1fARB(fKm4PI, 0.0015f * 4.0f * 3.141592653f);

glUniform1fARB(fScale, 1.0f / 0.25f);


glUniform1fARB(fScaleDepth, 0.25f);


glUniform1fARB(fScaleOverScaleDepth, 4.0f / 0.25f );


glUniform1fARB(g, -0.990f);


glUniform1f(g2, -0.990f * -0.990f);

有任何想法嗎？

編輯：更新代碼，並添加了圖片。

Answer 1

我認為存在的問題是，您寫入'FragColor'，它可能是片段着色器中的“死端”輸出變量，因為在鏈接程序之前必須將其顯式綁定到顏色編號：

glBindFragDataLocation(programAtmosphere,0,"FragColor");

或在着色器中使用它：

layout(location = 0) out vec4 FragColor

您可以嘗試使用內置輸出變量： gl_FragColor ，它是gl_FragData[0]的別名，因此與上面的綁定相同。

編輯：忘了說，當使用已棄用的內置函數時，您必須具有兼容性聲明：

#version 330 compatibility

編輯2：為了測試綁定，我會為它編寫一個常量顏色以禁用可能的計算錯誤，因為這些錯誤或零輸入可能無法產生預期的結果。