コード例 #1
0
  public void updateSpringPosition() {
    if (mPrev != null && mSimulate) {
      mWorldPosition.set(mPrev.mWorldEndPosition);

      mWorldRotation.set(mRotation.getQuaternion());
      mWorldRotation.multiply(mPrev.mWorldRotation);

      MathUtil.setVectorToSumOf(
          mWorldEndPosition,
          mPrev.mWorldEndPosition,
          MathUtil.setVectorToProductOf(mTempVec1, mWorldRotation, mDirection));

      mWorldSpringRotation.set(mOriginalRotation);
      mWorldSpringRotation.multiply(mPrev.mWorldRotation);

      /* Method using only existing ngin3d (requires allocations/garbage)
       * mWorldSpringPosition.set(mPrev.mWorldEndPosition);
       * mWorldSpringPosition = mWorldSpringPosition.add(mWorldSpringRotation.applyTo(mDirection));
       * */

      // Method using new functions.
      MathUtil.setVectorToSumOf(
          mWorldSpringPosition,
          mPrev.mWorldEndPosition,
          MathUtil.setVectorToProductOf(mTempVec1, mWorldSpringRotation, mDirection));
    }
  }
コード例 #2
0
  public void updateNodeRotation() {
    if (mPrev != null && mSimulate) {
      Quaternion qRot = mRotation.getQuaternion();
      mTempQuat.set(
          mPrev.mWorldRotation.getQ0(),
          -mPrev.mWorldRotation.getQ1(),
          -mPrev.mWorldRotation.getQ2(),
          -mPrev.mWorldRotation.getQ3());
      qRot.set(mWorldRotation);
      qRot.multiply(mTempQuat);
      qRot.nor();

      /* After pointing, the rotation will have an arbitrary "roll" around
       * the "to" z-axis.  We must find the new position of the "up" vector
       * after rotation.
       */
      // Vec3 dir = qRot.applyTo(BONE_DIR);
      // Vec3 rolledUp = qRot.applyTo(BONE_ORTH);
      MathUtil.setVectorToProductOf(mTempVec1, qRot, BONE_DIR);
      MathUtil.setVectorToProductOf(mTempVec2, qRot, BONE_ORTH);

      /* We now project this vector and the original "up" vector onto a plane
       * perpendicular to the "to" vector so that we can find the extra
       * rotation needed to rotate the rolled "up" vector onto the given
       * "up" vector. Note that these vectors won't have unit length.
       */
      // Vec3 upProjected = mOrthogonalTarget.subtract(Vec3.dotProduct(mTempVec1,
      // mOrthogonalTarget), mTempVec1);
      float dot = Vec3.dotProduct(mTempVec1, mOrthogonalTarget);
      mTempVec3.set(dot * mTempVec1.x, dot * mTempVec1.y, dot * mTempVec1.z);
      MathUtil.setVectorToDifferenceOf(mTempVec4, mOrthogonalTarget, mTempVec3);

      /* Calculate the rotation bring rolledUpProjected onto upProjected.
       * Note that this rotation will be around the "to" vector (because both
       * vectors are parallel to the "to" vector after projection).
       */
      // Rotation rollRotation = Rotation.fromTo(mTempVec2, upProjected);
      // qRot.multiply(rollRotation.getQuaternion());
      MathUtil.setQuaternionFromTo(mTempQuat, mTempVec2, mTempVec4);
      qRot.multiply(mTempQuat);

      mTempRot.getQuaternion().set(qRot);
      mTempRot.getQuaternion().multiply(mPhysics.mFold);
      mActorNode.setRotation(mTempRot);
    }
  }
コード例 #3
0
  /*
   * Index represents the index of the joint (zero is the bottom joint)
   */
  public Joint(
      ActorNode actorNode,
      Joint prev,
      float x,
      float y,
      float z,
      float a,
      float b,
      float c,
      float d,
      JointPhysics physics,
      GlobalPhysics globalPhysics) {
    mActorNode = actorNode;
    mPhysics = physics;
    mGlobalPhysics = globalPhysics;
    y = 0;
    z = 0;

    mPrev = prev;
    mOriginalRotation.set(a, b, c, d);
    mRotation.set(a, b, c, d, false);
    mWorldRotation.set(a, b, c, d); // Only correct for root (others will be set on first update)
    // mDirection.set(.075f, 0f, 0f);
    mDirection.set(physics.mSpringLength, 0f, 0f);
    // mDirection.set(.05f + (float)Math.random() * 0.1f, 0f, 0f);
    mOrthogonalTarget = mOriginalRotation.applyTo(BONE_ORTH);
    if (prev != null) {
      prev.mSimulate = true;
      mPrev.mWorldEndPosition.set(x, y, z);
      Vec3 dir = new Vec3(x, y, z);
      if (dir.getLength() > 0.001f) {
        // mPrev.mDirectionVector.set(x, y, z);
        mPrev.mOrthogonalTarget = mPrev.mOriginalRotation.applyTo(BONE_ORTH);
      }
    }
    while (prev != null) {
      prev.mRootiness += 1f;
      prev = prev.mPrev;
    }
  }
コード例 #4
0
  public void updateNodePosition() {
    if (mPrev != null && mSimulate) {
      // Vec3 oldPos = new Vec3(mWorldEndPosition);
      mTempVec1.set(mWorldEndPosition);
      float damping = mPhysics.mDamping * mGlobalPhysics.mExtraDamping;
      float springStrength = mPhysics.mSpringStrength;
      for (int i = 0; i != 4; ++i) {
        mVelocity.x += mGlobalPhysics.mGravity.x;
        mVelocity.y += mGlobalPhysics.mGravity.y;
        mVelocity.z += mGlobalPhysics.mGravity.z;

        float strength = springStrength * ((1f / mRootiness) + 0.5f);

        mVelocity.x += (mWorldSpringPosition.x - mWorldEndPosition.x) * strength;
        mVelocity.y += (mWorldSpringPosition.y - mWorldEndPosition.y) * strength;
        mVelocity.z += (mWorldSpringPosition.z - mWorldEndPosition.z) * strength;

        mVelocity.x *= damping;
        mVelocity.y *= damping;
        mVelocity.z *= damping;
        mWorldEndPosition.x += 0.01f * mVelocity.x;
        mWorldEndPosition.y += 0.01f * mVelocity.y;
        mWorldEndPosition.z += 0.01f * mVelocity.z;
        if (mWorldEndPosition.z < -0.2f) {
          mWorldEndPosition.z = -0.2f;
          mVelocity.z = 0f;
        }
      }

      // Vec3 from = oldPos.subtract(mPrev.mWorldEndPosition);
      // Vec3 to = mWorldEndPosition.subtract(mPrev.mWorldEndPosition);
      // mWorldRotation.multiply(Rotation.fromTo(from, to).getQuaternion());

      // from = old_world_position - parent_end
      MathUtil.setVectorToDifferenceOf(mTempVec2, mTempVec1, mPrev.mWorldEndPosition);
      // to = new_world_position - parent_end
      MathUtil.setVectorToDifferenceOf(mTempVec3, mWorldEndPosition, mPrev.mWorldEndPosition);
      mWorldRotation.multiply(MathUtil.setQuaternionFromTo(mTempQuat, mTempVec2, mTempVec3));
    }
  }