void PhysicsFrameSplineEditor::addControlPoint() {
    if (m_spline.control.size() == 0) {
        m_spline.append(CFrame());
    } else if (m_spline.control.size() == 1) {
        // Adding the 2nd point
        CFrame f = m_spline.control.last();
        f.translation += f.lookVector();
        m_spline.append(f);

        resizeControlPointDropDown(m_spline.control.size());
        // Select the new point
        setSelectedControlPointIndex(m_selectedControlPointIndex + 1);
    } else {
        // Adding between two points
        float t0 = m_spline.time[m_selectedControlPointIndex];
        float newT = t0;
        float evalT = 0;
        if (m_selectedControlPointIndex < m_spline.control.size() - 1) {
            // Normal interval
            newT = m_spline.time[m_selectedControlPointIndex + 1];
            evalT = (t0 + newT) / 2;
        } else if (m_spline.extrapolationMode == SplineExtrapolationMode::CYCLIC) {
            // After the end on a cyclic spline
            newT = m_spline.getFinalInterval() + t0;
            evalT = (t0 + newT) / 2;
        } else {
            // After the end on a non-cyclic spline of length at least
            // 2; assume that we want to step the distance of the previous
            // interval
            newT = evalT = 2.0f * t0 - m_spline.time[m_selectedControlPointIndex - 1];
        }

        const PhysicsFrame f = m_spline.evaluate(evalT);
        m_spline.control.insert(m_selectedControlPointIndex + 1, f);
        m_spline.time.insert(m_selectedControlPointIndex + 1, newT);

        // Select the new point
        resizeControlPointDropDown(m_spline.control.size());
        setSelectedControlPointIndex(m_selectedControlPointIndex + 1);

        // Fix the rest of the times to be offset by the inserted duration
        float shift = newT - t0;
        for (int i = m_selectedControlPointIndex + 1; i < m_spline.time.size(); ++i) {
            m_spline.time[i] += shift;
        }
        
    }

}
Ejemplo n.º 2
0
void AudioDevice::simulate
(const float    dt, 
 const float    timeScaleAtListener, 
 const CFrame&  wsListenerFrame,
 const Vector3& wsListenerVelocity) {

    m_listenerPosition = wsListenerFrame.translation;

    if (m_engine) {
        m_engine->setListenerPosition
            (g3dToirrKlang(wsListenerFrame.translation), 
             g3dToirrKlang(wsListenerFrame.lookVector()), 
             g3dToirrKlang(wsListenerVelocity),
             g3dToirrKlang(wsListenerFrame.upVector()));
    }

    m_timeScaleAtListener = timeScaleAtListener;
    if (m_music) {
        m_music->setPlaybackSpeed(speedAdjust(timeScaleAtListener));
        if (m_music->isFinished()) {
            m_music->drop();
            m_music = NULL;
        }
    }

    // Update already-playing 3D sounds
    for (int s = 0; s < m_active3D.size(); ++s) {
        ISound* sound = m_active3D[s];
        if (sound->isFinished()) {
            // End
            m_active3D.fastRemove(s);
            --s;
        } else {
            sound->setPosition(sound->getPosition() + dt * sound->getVelocity());
        }
    }
}
Ejemplo n.º 3
0
void ShadowMap::computeMatrices
(const shared_ptr<Light>& light, 
 AABox          sceneBounds,
 CFrame&        lightFrame,
 Projection&    lightProjection,
 Matrix4&       lightProjectionMatrix,
 float          lightProjX,
 float          lightProjY,
 float          lightProjNearMin,
 float          lightProjFarMax,
 float          intensityCutoff) {

    if (! sceneBounds.isFinite() || sceneBounds.isEmpty()) {
        // Produce some reasonable bounds
        sceneBounds = AABox(Point3(-20, -20, -20), Point3(20, 20, 20));
    }

    lightFrame = light->frame();

    if (light->type() == Light::Type::DIRECTIONAL) {
        Point3 center = sceneBounds.center();
        if (! center.isFinite()) {
            center = Point3::zero();
        }
        // Move directional light away from the scene.  It must be far enough to see all objects
        lightFrame.translation = -lightFrame.lookVector() * 
            min(1e6f, max(sceneBounds.extent().length() / 2.0f, lightProjNearMin, 30.0f)) + center;
    }

    const CFrame& f = lightFrame;

    float lightProjNear = finf();
    float lightProjFar  = 0.0f;

    // TODO: for a spot light, only consider objects this light can see

    // Find nearest and farthest corners of the scene bounding box
    for (int c = 0; c < 8; ++c) {
        const Vector3&  v        = sceneBounds.corner(c);
        const float     distance = -f.pointToObjectSpace(v).z;

        lightProjNear  = min(lightProjNear, distance);
        lightProjFar   = max(lightProjFar, distance);
    }
    
    // Don't let the near get too close to the source, and obey
    // the specified hint.
    lightProjNear = max(lightProjNearMin, lightProjNear);

    // Don't bother tracking shadows past the effective radius
    lightProjFar = min(light->effectSphere(intensityCutoff).radius, lightProjFar);
    lightProjFar = max(lightProjNear + 0.1f, min(lightProjFarMax, lightProjFar));

    debugAssert(lightProjNear < lightProjFar);

    if (light->type() != Light::Type::DIRECTIONAL) {
        // TODO: Square spot

        // Spot light; we can set the lightProj bounds intelligently

        alwaysAssertM(light->spotHalfAngle() <= halfPi(), "Spot light with shadow map and greater than 180-degree bounds");

        // The cutoff is half the angle of extent (See the Red Book, page 193)
        const float angle = light->spotHalfAngle();

        lightProjX = tan(angle) * lightProjNear;
      
        // Symmetric in x and y
        lightProjY = lightProjX;

        lightProjectionMatrix = 
            Matrix4::perspectiveProjection
            (-lightProjX, lightProjX, -lightProjY, 
             lightProjY, lightProjNear, lightProjFar);

    } else if (light->type() == Light::Type::DIRECTIONAL) {
        // Directional light

        // Construct a projection and view matrix for the camera so we can 
        // render the scene from the light's point of view
        //
        // Since we're working with a directional light, 
        // we want to make the center of projection for the shadow map
        // be in the direction of the light but at a finite distance 
        // to preserve z precision.
        
        lightProjectionMatrix = 
            Matrix4::orthogonalProjection
            (-lightProjX, lightProjX, -lightProjY, 
             lightProjY, lightProjNear, lightProjFar);

    } else {
        // Omni light.  Nothing good can happen here, but at least we
        // generate something

        lightProjectionMatrix =
            Matrix4::perspectiveProjection
            (-lightProjX, lightProjX, -lightProjY, 
             lightProjY, lightProjNear, lightProjFar);
    }

    float fov = atan2(lightProjX, lightProjNear) * 2.0f;
    lightProjection.setFieldOfView(fov, FOVDirection::HORIZONTAL);
    lightProjection.setNearPlaneZ(-lightProjNear);
    lightProjection.setFarPlaneZ(-lightProjFar);
}