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Looking to do classic OpenGL mouse picking in ES. I'd prefer not to use third party libs, GLU ports and OpenGL name stacks, etc, are out. This pretty much leaves inverse view transformation and ray intersection, correct?

I've gotten pretty far with the help of: http://trac.bookofhook.com/bookofhook/trac.cgi/wiki/MousePicking http://eigenclass.blogspot.com/2008/10/opengl-es-picking-using-ray-boundingbox.html

. . .but I'm not there yet. This also reeks of THERE MUST BE AN EASIER WAY!!

Here is some code:

    -(void)handleTouch:(CGPoint)point {
    GLfloat width = backingWidth;
    GLfloat height = backingHeight;
    GLfloat x = point.x;
    GLfloat y = point.y;
    GLfloat z = 0.0f;

    //viewport -> normalized dev coord -> clip
    GLfloat n[] = {
        2 * x / width - 1,
        2 * y / height,
        2 * z - 1,
        1
    };

    float fov = 45.0f * (M_PI / 180.0f);
    float near = 0.01, far = 10.0f;
    float aspect = (float)backingWidth / (float)backingHeight;
    float top = tan(fov) * near;
    //float bottom = -top;
    //float left = aspect * bottom;
    float right = aspect * top;

    //I'm a viewing volume symmetric projection matrix
    GLfloat P[] = {
        near / right, 0, 0, 0,
        0, near / top, 0, 0,
        0, 0, -(far + near) / (far - near), (-2 * far * near) / (far - near),
        0, 0, -1, 0
    };

    GLfloat Pminus1[] = {
        1/P[0], 0, 0, 0,
        0, 1/P[5], 0, 0,
        0, 0, 0, 1/P[14],
        0, 0, 1/P[11], -(P[10]/ (P[11]*P[14]))
    };

    //clip -> view
    GLfloat v[] = {
        Pminus1[0] * n[0] + Pminus1[1] * n[1] + Pminus1[2] * n[2] + Pminus1[3] * n[3],
        Pminus1[4] * n[0] + Pminus1[5] * n[1] + Pminus1[6] * n[2] + Pminus1[7] * n[3],
        Pminus1[8] * n[0] + Pminus1[9] * n[1] + Pminus1[10] * n[2] + Pminus1[11] * n[3],
        Pminus1[12] * n[0] + Pminus1[13] * n[1] + Pminus1[14] * n[2] + Pminus1[15] * n[3]
    };

    //view -> world
    GLfloat Rt[] = {
        mv[0], mv[4], mv[8],
        mv[1], mv[5], mv[9],
        mv[2], mv[6], mv[10]
    };

    GLfloat tPrime[] = {
        Rt[0] * mv[3] + Rt[1] * mv[7] + Rt[2] * mv[11],
        Rt[3] * mv[3] + Rt[4] * mv[7] + Rt[5] * mv[11],
        Rt[6] * mv[3] + Rt[7] * mv[7] + Rt[8] * mv[11]
    };

    GLfloat Mminus1[] = {
        Rt[0], Rt[1], Rt[2], -(tPrime[0]),
        Rt[3], Rt[4], Rt[5], -(tPrime[1]),
        Rt[6], Rt[7], Rt[8], -(tPrime[2]),
        0, 0, 0, 1
    };

    //point in world space
    GLfloat w[] = {
        Mminus1[0] * v[0] + Mminus1[1] * v[1] + Mminus1[2] * v[2] + Mminus1[3] * v[3],
        Mminus1[4] * v[0] + Mminus1[5] * v[1] + Mminus1[6] * v[2] + Mminus1[7] * v[3],
        Mminus1[8] * v[0] + Mminus1[9] * v[1] + Mminus1[10] * v[2] + Mminus1[11] * v[3],
        Mminus1[12] * v[0] + Mminus1[13] * v[1] + Mminus1[14] * v[2] + Mminus1[15] * v[3]
    };

    //r = a + t(w - a)
    GLfloat a[] = {0.0f, -0.1f, 0.0f};
    GLfloat wminusa[] = {w[0] - a[0], w[1] - a[1], w[2] - a[2]};

    vector[0] = a[0];
    vector[1] = a[1],
    vector[2] = a[2];
    vector[3] = w[0];
    vector[4] = w[1];
    vector[5] = -10.0f;

    //3 non-colinear points on the plane 
    GLfloat p1[] = {rect.origin.x, rect.origin.y, 0};
    GLfloat p2[] = {rect.origin.x + rect.size.width, rect.origin.y, 0};
    GLfloat p3[] = {rect.origin.x + rect.size.width, rect.origin.y + rect.size.height, 0};

    //location plane normal vector, Ax + By + Cz + D = 0
    GLfloat lp[] = {
        p1[1] * (p2[2] - p3[2]) + p2[1] * (p3[2] - p1[2]) + p3[1] * (p1[2] - p2[2]),
        p1[2] * (p2[0] - p3[0]) + p2[2] * (p3[0] - p1[0]) + p3[2] * (p1[0] - p2[0]),
        p1[0] * (p2[1] - p3[1]) + p2[0] * (p3[1] - p1[1]) + p3[0] * (p1[1] - p2[1]),
        -(p1[0] * (((p2[1] * p3[2]) - (p3[1] * p2[2]))) + p2[0] * (((p3[1] * p1[2]) - (p1[1] * p3[2]))) + p3[0] * (((p1[1] * p2[2]) - (p2[1] * p1[2]))))
    };

    GLfloat PnRd = (lp[0] * wminusa[0]) + (lp[1] * wminusa[1]) + (lp[2] * wminusa[2]);
    if(PnRd != 0) {
        GLfloat PnR0D = -((lp[0] * a[0]) + (lp[1] * a[1]) + (lp[2] * a[2]) + lp[3]);
        if(PnR0D != 0) {
            GLfloat t = PnR0D / PnRd;
            if(t >= 0) {
                GLfloat p[] = {
                    a[0] + wminusa[0] * t,
                    a[1] + wminusa[1] * t,
                    a[2] + wminusa[2] * t
                };
                if(p[0] > rect.origin.x &&
                   p[0] < rect.origin.x + rect.size.width &&
                   p[1] > rect.origin.y &&
                   p[1] < rect.origin.y + rect.size.height)
                    NSLog(@"BOOM!!!");
            }
        }
    }
}
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3 Answers 3

This post is very hard to follow. I'm attempting to roll my own on iOS 5 with GLKView; I've worked out how to touch detect pixel RGBA as I describe here, now I'm trying to work out how to quickly change the colours of my scene objects to be unique, to accompany this method.

share|improve this answer

I managed to fix it:

-(void)view2WorldPoint:(CGPoint)point :(GLfloat*)worldPoint {
    // this is the inverse translation of the modelview
    GLfloat width = (GLfloat)backingWidth;
    GLfloat height = (GLfloat)backingHeight;

    float clickX = point.x;
    float clickY = point.y;
    float clickZ = 0.0f;

    NSLog(@"click point : x = %f, y = %f, z = %f", clickX, clickY, clickZ);

    //  NSLog(@"Me : x = %f, y = %f, z = %f", a[0], a[1], a[2]);
    //  NSLog(@"Dev : x = %f, y = %f, z = %f", squareX, squareY, squareZ);

    //viewport -> normalized device coord -> clip
    GLfloat n[] = {
        2 * clickX / width - 1,
        2 * (480-clickY) / height - 1,
        2 * clickZ - 1,
        1
    };
    //  NSLog(@"Obj : x = %f, y = %f, z = %f", rect.origin.x, rect.origin.y, -0.5);
    //  NSLog(@"N : x = %f, y = %f, z = %f", n[0], n[1], n[2]); 

    //I'm a viewing volume symmetric projection matrix
    //  GLfloat P[] = {
    //      near / right, 0, 0, 0,
    //      0, near / top, 0, 0,
    //      0, 0, -(far + near) / (far - near), (-2 * far * near) / (far - near),
    //      0, 0, -1, 0
    //  };
    GLfloat P[16];
    glGetFloatv(GL_PROJECTION_MATRIX, P);
    //  [self dumpMatrix:P :@"P"];

    GLfloat Pminus1[] = {
        1/P[0], 0, 0, 0,
        0, 1/P[5], 0, 0,
        0, 0, 0, 1/P[11],
        0, 0, 1/P[14], -(P[10]/ (P[11]*P[14]))
    };

    //  [self dumpMatrix:Pminus1 :@"P-1"];

    //clip -> view
    GLfloat v[] = {
        (Pminus1[0] * n[0]) + (Pminus1[1] * n[1]) + (Pminus1[2]  * n[2]) + (Pminus1[3] * n[3]),
        (Pminus1[4] * n[0]) + (Pminus1[5] * n[1]) + (Pminus1[6]  * n[2]) + (Pminus1[7] * n[3]),
        (Pminus1[8] * n[0]) + (Pminus1[9] * n[1]) + (Pminus1[10] * n[2]) + (Pminus1[11] * n[3]),
        (Pminus1[12] * n[0]) + (Pminus1[13] * n[1]) + (Pminus1[14] * n[2]) + (Pminus1[15] * n[3])
    };

    //  NSLog(@"v = [%f, %f, %f, %f]", v[0], v[1], v[2], v[3]);


    //  [self dumpMatrix:mv :@"mv"];

    //view -> world
    GLfloat Rt[] = {
        mv[0], mv[4], -mv[8],
        mv[1], mv[5], -mv[9],
        -mv[2], -mv[6], mv[10]
    };

    //  NSLog(@"Rt0 = [%f, %f, %f]", Rt[0], Rt[1], Rt[2]);
    //  NSLog(@"Rt1 = [%f, %f, %f]", Rt[3], Rt[4], Rt[5]);
    //  NSLog(@"Rt2 = [%f, %f, %f]", Rt[6], Rt[7], Rt[8]);

    GLfloat tPrime[] = {
        Rt[0] * mv[12] + Rt[1] * mv[13] + Rt[2] * mv[14],
        Rt[3] * mv[12] + Rt[4] * mv[13] + Rt[5] * mv[14],
        Rt[6] * mv[12] + Rt[7] * mv[13] + Rt[8] * mv[14]
    };

    //  NSLog(@"tPrime = [%f, %f, %f]", tPrime[0], tPrime[1], tPrime[2]);

    GLfloat Mminus1[] = {
        Rt[0], Rt[1], Rt[2], -(tPrime[0]),
        Rt[3], Rt[4], Rt[5], -(tPrime[1]),
        Rt[6], Rt[7], Rt[8], -(tPrime[2]),
        0, 0, 0, 1
    };

    //point in world space
    GLfloat w[] = {
        Mminus1[0] * v[0] + Mminus1[1] * v[1] + Mminus1[2] * v[2] + Mminus1[3] * v[3],
        Mminus1[4] * v[0] + Mminus1[5] * v[1] + Mminus1[6] * v[2] + Mminus1[7] * v[3],
        Mminus1[8] * v[0] + Mminus1[9] * v[1] + Mminus1[10] * v[2] + Mminus1[11] * v[3],
        Mminus1[12] * v[0] + Mminus1[13] * v[1] + Mminus1[14] * v[2] + Mminus1[15] * v[3]
    };
    NSLog(@"W : x = %f, y = %f, z = %f", w[0], w[1], w[2]);
    worldPoint[0] = w[0];
    worldPoint[1] = w[1];
    worldPoint[2] = w[2];
}
share|improve this answer
    
Actually, I don't understand why in the view -> world transformation you use negative entries (e.g. -m[8]). There shouldn't be any negative entries. Also, tPrime is wrong in my opinion. mv[12] should be mv[3], mv[13] should be mv[7] and mv[14] should be mv[11]. And mv is not declared anywhere (I assume it's the modelview). –  Marc Feb 26 '10 at 23:46
    
Agreed, I've posted a better solution. –  datafatmunger Mar 1 '10 at 14:44

Okay, okay that was still a bit buggy. Here is what is MOSTLY working now:

-(void)view2WorldPoint:(CGPoint)point :(GLfloat*)worldPoint {
    float clickX = point.x;
    float clickY = point.y;
    float clickZ = -near;

    //viewport -> normalized device coord -> clip
    GLint viewport[4];
    glGetIntegerv(GL_VIEWPORT, viewport);

    GLfloat n[] = {
        (clickX - (float)viewport[0]) / (float)viewport[2] * 2.0 - 1.0,
        -((clickY - (float)viewport[1]) / (float)viewport[3] * 2.0 - 1.0),
        2.0 * clickZ - 1.0,
        1.0
    };

    GLfloat MP[16], MPInv[16];
    MatMatMultiply(MP, projMat, modelMat);
    GenerateInverseMatrix4f(MPInv, MP); // replace this one with the whole 1/p thang?

    GLfloat w[] = {
        (MPInv[0]  * n[0]) + (MPInv[4]  * n[1]) + (MPInv[8]  * n[2]) + (MPInv[12] * n[3]),
        (MPInv[1]  * n[0]) + (MPInv[5]  * n[1]) + (MPInv[9]  * n[2]) + (MPInv[13] * n[3]),
        (MPInv[2]  * n[0]) + (MPInv[6]  * n[1]) + (MPInv[10] * n[2]) + (MPInv[14] * n[3]),
        (MPInv[3]  * n[0]) + (MPInv[7]  * n[1]) + (MPInv[11] * n[2]) + (MPInv[15] * n[3])
    };

    worldPoint[0] = w[0] / w[3];
    worldPoint[1] = w[1] / w[3];
    worldPoint[2] = w[2] / w[3];
}


float Determinant4f(const float m[16])
{
    return
    m[12]*m[9]*m[6]*m[3]-
    m[8]*m[13]*m[6]*m[3]-
    m[12]*m[5]*m[10]*m[3]+
    m[4]*m[13]*m[10]*m[3]+
    m[8]*m[5]*m[14]*m[3]-
    m[4]*m[9]*m[14]*m[3]-
    m[12]*m[9]*m[2]*m[7]+
    m[8]*m[13]*m[2]*m[7]+
    m[12]*m[1]*m[10]*m[7]-
    m[0]*m[13]*m[10]*m[7]-
    m[8]*m[1]*m[14]*m[7]+
    m[0]*m[9]*m[14]*m[7]+
    m[12]*m[5]*m[2]*m[11]-
    m[4]*m[13]*m[2]*m[11]-
    m[12]*m[1]*m[6]*m[11]+
    m[0]*m[13]*m[6]*m[11]+
    m[4]*m[1]*m[14]*m[11]-
    m[0]*m[5]*m[14]*m[11]-
    m[8]*m[5]*m[2]*m[15]+
    m[4]*m[9]*m[2]*m[15]+
    m[8]*m[1]*m[6]*m[15]-
    m[0]*m[9]*m[6]*m[15]-
    m[4]*m[1]*m[10]*m[15]+
    m[0]*m[5]*m[10]*m[15];
}

BOOL GenerateInverseMatrix4f(float i[16], const float m[16])
{
    float x=Determinant4f(m);
    if (x==0) return FALSE;

    i[0]= (-m[13]*m[10]*m[7] +m[9]*m[14]*m[7] +m[13]*m[6]*m[11]
           -m[5]*m[14]*m[11] -m[9]*m[6]*m[15] +m[5]*m[10]*m[15])/x;
    i[4]= ( m[12]*m[10]*m[7] -m[8]*m[14]*m[7] -m[12]*m[6]*m[11]
           +m[4]*m[14]*m[11] +m[8]*m[6]*m[15] -m[4]*m[10]*m[15])/x;
    i[8]= (-m[12]*m[9]* m[7] +m[8]*m[13]*m[7] +m[12]*m[5]*m[11]
           -m[4]*m[13]*m[11] -m[8]*m[5]*m[15] +m[4]*m[9]* m[15])/x;
    i[12]=( m[12]*m[9]* m[6] -m[8]*m[13]*m[6] -m[12]*m[5]*m[10]
           +m[4]*m[13]*m[10] +m[8]*m[5]*m[14] -m[4]*m[9]* m[14])/x;
    i[1]= ( m[13]*m[10]*m[3] -m[9]*m[14]*m[3] -m[13]*m[2]*m[11]
           +m[1]*m[14]*m[11] +m[9]*m[2]*m[15] -m[1]*m[10]*m[15])/x;
    i[5]= (-m[12]*m[10]*m[3] +m[8]*m[14]*m[3] +m[12]*m[2]*m[11]
           -m[0]*m[14]*m[11] -m[8]*m[2]*m[15] +m[0]*m[10]*m[15])/x;
    i[9]= ( m[12]*m[9]* m[3] -m[8]*m[13]*m[3] -m[12]*m[1]*m[11]
           +m[0]*m[13]*m[11] +m[8]*m[1]*m[15] -m[0]*m[9]* m[15])/x;
    i[13]=(-m[12]*m[9]* m[2] +m[8]*m[13]*m[2] +m[12]*m[1]*m[10]
           -m[0]*m[13]*m[10] -m[8]*m[1]*m[14] +m[0]*m[9]* m[14])/x;
    i[2]= (-m[13]*m[6]* m[3] +m[5]*m[14]*m[3] +m[13]*m[2]*m[7]
           -m[1]*m[14]*m[7] -m[5]*m[2]*m[15] +m[1]*m[6]* m[15])/x;
    i[6]= ( m[12]*m[6]* m[3] -m[4]*m[14]*m[3] -m[12]*m[2]*m[7]
           +m[0]*m[14]*m[7] +m[4]*m[2]*m[15] -m[0]*m[6]* m[15])/x;
    i[10]=(-m[12]*m[5]* m[3] +m[4]*m[13]*m[3] +m[12]*m[1]*m[7]
           -m[0]*m[13]*m[7] -m[4]*m[1]*m[15] +m[0]*m[5]* m[15])/x;
    i[14]=( m[12]*m[5]* m[2] -m[4]*m[13]*m[2] -m[12]*m[1]*m[6]
           +m[0]*m[13]*m[6] +m[4]*m[1]*m[14] -m[0]*m[5]* m[14])/x;
    i[3]= ( m[9]* m[6]* m[3] -m[5]*m[10]*m[3] -m[9]* m[2]*m[7]
           +m[1]*m[10]*m[7] +m[5]*m[2]*m[11] -m[1]*m[6]* m[11])/x;
    i[7]= (-m[8]* m[6]* m[3] +m[4]*m[10]*m[3] +m[8]* m[2]*m[7]
           -m[0]*m[10]*m[7] -m[4]*m[2]*m[11] +m[0]*m[6]* m[11])/x;
    i[11]=( m[8]* m[5]* m[3] -m[4]*m[9]* m[3] -m[8]* m[1]*m[7]
           +m[0]*m[9]* m[7] +m[4]*m[1]*m[11] -m[0]*m[5]* m[11])/x;
    i[15]=(-m[8]* m[5]* m[2] +m[4]*m[9]* m[2] +m[8]* m[1]*m[6]
           -m[0]*m[9]* m[6] -m[4]*m[1]*m[10] +m[0]*m[5]* m[10])/x;

    return TRUE;
}

void MatMatMultiply(GLfloat *result, GLfloat *matrix1, GLfloat *matrix2)
{
    result[0]=matrix1[0]*matrix2[0]+
    matrix1[4]*matrix2[1]+
    matrix1[8]*matrix2[2]+
    matrix1[12]*matrix2[3];
    result[4]=matrix1[0]*matrix2[4]+
    matrix1[4]*matrix2[5]+
    matrix1[8]*matrix2[6]+
    matrix1[12]*matrix2[7];
    result[8]=matrix1[0]*matrix2[8]+
    matrix1[4]*matrix2[9]+
    matrix1[8]*matrix2[10]+
    matrix1[12]*matrix2[11];
    result[12]=matrix1[0]*matrix2[12]+
    matrix1[4]*matrix2[13]+
    matrix1[8]*matrix2[14]+
    matrix1[12]*matrix2[15];
    result[1]=matrix1[1]*matrix2[0]+
    matrix1[5]*matrix2[1]+
    matrix1[9]*matrix2[2]+
    matrix1[13]*matrix2[3];
    result[5]=matrix1[1]*matrix2[4]+
    matrix1[5]*matrix2[5]+
    matrix1[9]*matrix2[6]+
    matrix1[13]*matrix2[7];
    result[9]=matrix1[1]*matrix2[8]+
    matrix1[5]*matrix2[9]+
    matrix1[9]*matrix2[10]+
    matrix1[13]*matrix2[11];
    result[13]=matrix1[1]*matrix2[12]+
    matrix1[5]*matrix2[13]+
    matrix1[9]*matrix2[14]+
    matrix1[13]*matrix2[15];
    result[2]=matrix1[2]*matrix2[0]+
    matrix1[6]*matrix2[1]+
    matrix1[10]*matrix2[2]+
    matrix1[14]*matrix2[3];
    result[6]=matrix1[2]*matrix2[4]+
    matrix1[6]*matrix2[5]+
    matrix1[10]*matrix2[6]+
    matrix1[14]*matrix2[7];
    result[10]=matrix1[2]*matrix2[8]+
    matrix1[6]*matrix2[9]+
    matrix1[10]*matrix2[10]+
    matrix1[14]*matrix2[11];
    result[14]=matrix1[2]*matrix2[12]+
    matrix1[6]*matrix2[13]+
    matrix1[10]*matrix2[14]+
    matrix1[14]*matrix2[15];
    result[3]=matrix1[3]*matrix2[0]+
    matrix1[7]*matrix2[1]+
    matrix1[11]*matrix2[2]+
    matrix1[15]*matrix2[3];
    result[7]=matrix1[3]*matrix2[4]+
    matrix1[7]*matrix2[5]+
    matrix1[11]*matrix2[6]+
    matrix1[15]*matrix2[7];
    result[11]=matrix1[3]*matrix2[8]+
    matrix1[7]*matrix2[9]+
    matrix1[11]*matrix2[10]+
    matrix1[15]*matrix2[11];
    result[15]=matrix1[3]*matrix2[12]+
    matrix1[7]*matrix2[13]+
    matrix1[11]*matrix2[14]+
    matrix1[15]*matrix2[15];
}
share|improve this answer
2  
Thank God copy/paste exists... –  NicolasMiari Jul 8 '12 at 16:50

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