/// <summary>
        /// Adds a key frame for the specified bone.
        /// </summary>
        /// <param name="boneIndex">The index of the bone.</param>
        /// <param name="time">The time of the key frame.</param>
        /// <param name="boneTransform">The bone transform.</param>
        /// <exception cref="ArgumentOutOfRangeException">
        /// <paramref name="boneIndex"/> is out of range.
        /// </exception>
        public void AddKeyFrame(int boneIndex, TimeSpan time, SrtTransform boneTransform)
        {
            if (boneIndex < 0)
            {
                throw new ArgumentOutOfRangeException("boneIndex", "boneIndex must not be negative.");
            }

            Unfreeze();
            EnsurePreprocessingData();

            // Get channel with key frames.
            List <BoneKeyFrameSRT> channel;

            if (!_preprocessData.Channels.TryGetValue(boneIndex, out channel))
            {
                // Create a new key frame list.
                channel = new List <BoneKeyFrameSRT>();
                _preprocessData.Channels.Add(boneIndex, channel);
            }

            // Add key frame to bone channel.
            channel.Add(new BoneKeyFrameSRT {
                Time = time, Transform = boneTransform
            });
        }
        /// <summary>
        /// Gets the bone transform for a certain time considering key frame interpolation.
        /// </summary>
        /// <param name="channelIndex">The index in <see cref="_channels"/>.</param>
        /// <param name="timeIndex">The index in <see cref="_times"/>.</param>
        /// <param name="time">The animation time.</param>
        /// <returns>The animation value.</returns>
        private SrtTransform GetBoneTransform(int channelIndex, int timeIndex, TimeSpan time)
        {
            // Get index in the key frames list using the _indices lookup table.
            int keyFrameIndex = _indices[timeIndex * _channels.Length + channelIndex];

            if (EnableInterpolation && keyFrameIndex + 1 < ((Array)_keyFrames[channelIndex]).Length)
            {
                // ----- Key frame interpolation.
                // Get the key frame before and after the specified time.
                TimeSpan     previousTime, nextTime;
                SrtTransform previousTransform, nextTransform;
                GetBoneKeyFrames(channelIndex, keyFrameIndex, out previousTime, out previousTransform, out nextTime, out nextTransform);

                float parameter = (float)(time.Ticks - previousTime.Ticks) / (nextTime - previousTime).Ticks;
                SrtTransform.Interpolate(ref previousTransform, ref nextTransform, parameter, ref previousTransform);
                return(previousTransform);
            }

            // ----- No key frame interpolation.
            //TimeSpan time;
            SrtTransform transform;

            GetBoneKeyFrame(channelIndex, keyFrameIndex, out time, out transform);
            return(transform);
        }
Example #3
0
        /// <summary>
        /// Applies max velocity limit to the given bone transform.
        /// </summary>
        /// <param name="originalTransform">
        /// In: The original bone transform.
        /// </param>
        /// <param name="targetTransform">
        /// In: The target bone transform.<br/>
        /// Out: The limited bone transform.
        /// </param>
        /// <param name="maxRotationAngle">The max rotation angle.</param>
        internal void LimitBoneTransform(ref SrtTransform originalTransform, ref SrtTransform targetTransform, float maxRotationAngle)
        {
            if (maxRotationAngle < ConstantsF.Pi)
            {
                // Compute relative rotation.
                var rotationChange = targetTransform.Rotation * originalTransform.Rotation.Conjugated;

                // Make sure we rotate around the shortest arc.
                if (Quaternion.Dot(originalTransform.Rotation, targetTransform.Rotation) < 0)
                {
                    rotationChange = -rotationChange;
                }

                if (rotationChange.Angle > maxRotationAngle && !rotationChange.V.IsNumericallyZero)
                {
                    // ReSharper disable EmptyGeneralCatchClause
                    try
                    {
                        // Limit rotation.
                        rotationChange.Angle     = maxRotationAngle;
                        targetTransform.Rotation = rotationChange * originalTransform.Rotation;
                    }
                    catch
                    {
                        // rotationChange.Angle = xxx. Can cause DivideByZeroException or similar.
                        // The !rotationChange.V.IsNumericallyZero should avoid this. But just to go sure.
                    }
                    // ReSharper restore EmptyGeneralCatchClause
                }
            }
        }
        /// <summary>
        /// Gets two bone key frame for a given channel and key frame index.
        /// </summary>
        /// <param name="channelIndex">The index in <see cref="_channels"/>.</param>
        /// <param name="keyFrameIndex">The index of the first key frame.</param>
        /// <param name="time0">The time of the first key frame.</param>
        /// <param name="transform0">The transform of the first key frame.</param>
        /// <param name="time1">The time of the second key frame.</param>
        /// <param name="transform1">The transform of the second key frame.</param>
        private void GetBoneKeyFrames(int channelIndex, int keyFrameIndex,
                                      out TimeSpan time0, out SrtTransform transform0,
                                      out TimeSpan time1, out SrtTransform transform1)
        {
            Debug.Assert(keyFrameIndex + 1 < ((Array)_keyFrames[channelIndex]).Length, "Call GetBoneKeyFrame() instead of GetBoneKeyFrames()!");

            var boneKeyFrameType = _keyFrameTypes[channelIndex];

            if (boneKeyFrameType == BoneKeyFrameType.R)
            {
                var keyFrames = (BoneKeyFrameR[])_keyFrames[channelIndex];

                var keyFrame = keyFrames[keyFrameIndex];
                time0                  = keyFrame.Time;
                transform0.Scale       = Vector3.One;
                transform0.Rotation    = keyFrame.Rotation;
                transform0.Translation = Vector3.Zero;

                keyFrame               = keyFrames[keyFrameIndex + 1];
                time1                  = keyFrame.Time;
                transform1.Scale       = Vector3.One;
                transform1.Rotation    = keyFrame.Rotation;
                transform1.Translation = Vector3.Zero;
            }
            else if (boneKeyFrameType == BoneKeyFrameType.RT)
            {
                var keyFrames = (BoneKeyFrameRT[])_keyFrames[channelIndex];

                var keyFrame = keyFrames[keyFrameIndex];
                time0                  = keyFrame.Time;
                transform0.Scale       = Vector3.One;
                transform0.Rotation    = keyFrame.Rotation;
                transform0.Translation = keyFrame.Translation;

                keyFrame               = keyFrames[keyFrameIndex + 1];
                time1                  = keyFrame.Time;
                transform1.Scale       = Vector3.One;
                transform1.Rotation    = keyFrame.Rotation;
                transform1.Translation = keyFrame.Translation;
            }
            else
            {
                var keyFrames = (BoneKeyFrameSRT[])_keyFrames[channelIndex];

                var keyFrame = keyFrames[keyFrameIndex];
                time0      = keyFrame.Time;
                transform0 = keyFrame.Transform;

                keyFrame   = keyFrames[keyFrameIndex + 1];
                time1      = keyFrame.Time;
                transform1 = keyFrame.Transform;
            }
        }
Example #5
0
        /// <summary>
        /// Converts the bind pose matrices to SRT transforms.
        /// </summary>
        /// <param name="bindPoses">The bind pose matrices.</param>
        /// <returns>The equivalent SRT transforms.</returns>
        private static IList <SrtTransform> ConvertToSrt(IList <Matrix> bindPoses)
        {
            var numberOfBones = bindPoses.Count;
            var result        = new SrtTransform[numberOfBones];

            for (int i = 0; i < numberOfBones; i++)
            {
                result[i] = SrtTransform.FromMatrix(bindPoses[i]);
            }

            return(result);
        }
    /// <summary>
    /// Updates the absolute bone pose for the specified bone.
    /// </summary>
    /// <param name="boneIndex">The index of the bone.</param>
    private void UpdateBonePoseAbsolute(int boneIndex)
    {
      if (_isBonePoseAbsoluteDirty[boneIndex])
      {
        lock (_syncRoot)
        {
          if (_isBonePoseAbsoluteDirty[boneIndex])
          {
            // Make sure relative bone pose is up-to-date.
            UpdateBonePoseRelative(boneIndex);

            int parentIndex = _skeletonPose.Skeleton.GetParent(boneIndex);
            if (parentIndex < 0)
            {
              // No parent.
              _bonePoseAbsolute[boneIndex] = _bonePoseRelative[boneIndex];
            }
            else
            {
              // Make sure parent is up-to-date. (Recursively update ancestors.)
              UpdateBonePoseAbsolute(parentIndex);

              //_bonePoseAbsolute[boneIndex] = _bonePoseAbsolute[parentIndex] * _bonePoseRelative[boneIndex];
              SrtTransform.Multiply(ref _bonePoseAbsolute[parentIndex], ref _bonePoseRelative[boneIndex],
                                    out _bonePoseAbsolute[boneIndex]);
            }


            Thread.MemoryBarrier();
#else
            Interlocked.MemoryBarrier();


            _isBonePoseAbsoluteDirty[boneIndex] = false;
          }
        }
      }
    }
    /// <summary>
    /// Updates the relative bone pose for the specified bone.
    /// </summary>
    /// <param name="boneIndex">The index of the bone.</param>
    private void UpdateBonePoseRelative(int boneIndex)
    {
      if (_isBonePoseRelativeDirty[boneIndex])
      {
        lock (_syncRoot)
        {
          if (_isBonePoseRelativeDirty[boneIndex])
          {
            // _bonePoseRelative[boneIndex] = _skeletonPose.Skeleton.BindPosesRelative[boneIndex] * _skeletonPose.BoneTransforms[boneIndex];
            SrtTransform.Multiply(ref _skeletonPose.Skeleton.BindPosesRelative[boneIndex],
                                  ref _skeletonPose.BoneTransforms[boneIndex], out _bonePoseRelative[boneIndex]);


            Thread.MemoryBarrier();
#else
            Interlocked.MemoryBarrier();


            _isBonePoseRelativeDirty[boneIndex] = false;
          }
        }
      }
    }
Example #8
0
 /// <summary>
 /// Sets the bone transform of the specified bone.
 /// </summary>
 /// <param name="boneIndex">The index of the bone.</param>
 /// <param name="boneTransform">The bone transform.</param>
 public void SetBoneTransform(int boneIndex, SrtTransform boneTransform)
 {
     BoneTransforms[boneIndex] = boneTransform;
     Invalidate(boneIndex);
 }
Example #9
0
        /// <summary>
        /// Called when <see cref="IKSolver.Solve"/> is called.
        /// </summary>
        /// <param name="deltaTime">The current time step (in seconds).</param>
        protected override void OnSolve(float deltaTime)
        {
            // Get cosine of limit or -1 if unlimited.
            float cosLimits = -1;

            if (0 <= Limit && Limit < ConstantsF.PiOver2)
            {
                cosLimits = (float)Math.Cos(Limit);
            }

            var skeleton    = SkeletonPose.Skeleton;
            int parentIndex = skeleton.GetParent(BoneIndex);

            // Bone pose without a bone transform.
            var unanimatedBonePoseAbsolute = SkeletonPose.GetBonePoseAbsolute(parentIndex) * skeleton.GetBindPoseRelative(BoneIndex);

            // Target position and direction in bone space.
            var targetPositionLocal = unanimatedBonePoseAbsolute.ToLocalPosition(Target);
            var targetDirection     = targetPositionLocal - EyeOffset;

            if (!targetDirection.TryNormalize())
            {
                return;
            }

            // The axes of the view space (where forward is -z, relative to bone space).
            Vector3 forward = Forward;
            Vector3 up      = Up;
            Vector3 side    = Vector3.Cross(up, -forward);

            // This matrix converts from view space to bone space (in other words, it
            // rotates the -z direction into the view direction).
            var boneFromView = new Matrix(side.X, up.X, -forward.X,
                                          side.Y, up.Y, -forward.Y,
                                          side.Z, up.Z, -forward.Z);

            // Get the components of the target direction relative to the view space axes.
            float targetUp      = Vector3.Dot(targetDirection, up);
            float targetSide    = Vector3.Dot(targetDirection, side);
            float targetForward = Vector3.Dot(targetDirection, forward);

            // Limit rotations of the desired up and side vector.
            // The target forward direction is inverted if necessary. (If limited the bone
            // does not never rotate back.)
            if (cosLimits > 0)
            {
                cosLimits = (float)Math.Sqrt(1 - cosLimits * cosLimits);
                if (targetUp > 0 && targetUp > cosLimits)
                {
                    targetUp = cosLimits;
                }
                else if (targetUp < 0 && -targetUp > cosLimits)
                {
                    targetUp = -cosLimits;
                }

                if (targetSide > 0 && targetSide > cosLimits)
                {
                    targetSide = cosLimits;
                }
                else if (targetSide < 0 && -targetSide > cosLimits)
                {
                    targetSide = -cosLimits;
                }

                targetForward = Math.Abs(targetForward);
            }

            // Make new target direction vector that conforms to the limits.
            targetDirection = Math.Sign(targetForward)
                              * forward * (float)Math.Sqrt(Math.Max(0, 1 - targetUp * targetUp - targetSide * targetSide))
                              + side * targetSide + up * targetUp;

            Debug.Assert(targetDirection.IsNumericallyNormalized);

            // Make axes of desired view space.
            forward = targetDirection;
            side    = Vector3.Cross(up, -forward);
            if (!side.TryNormalize())
            {
                return;
            }

            up = Vector3.Cross(side, forward);
            Debug.Assert(up.IsNumericallyNormalized);

            // Create new view space matrix.
            var boneFromNewView = new Matrix(
                side.X, up.X, -forward.X,
                side.Y, up.Y, -forward.Y,
                side.Z, up.Z, -forward.Z);

            // Apply a bone transform that rotates the rest view space to the desired view space.
            Quaternion boneTransform = Quaternion.CreateFromRotationMatrix(boneFromNewView * boneFromView.Transposed);

            var startTransform  = SkeletonPose.GetBoneTransform(BoneIndex);
            var lookAtTransform = new SrtTransform(startTransform.Scale, boneTransform, startTransform.Translation);

            // Apply weight.
            if (RequiresBlending())
            {
                BlendBoneTransform(ref startTransform, ref lookAtTransform);
            }

            // Apply angular velocity limit.
            float maxRotationAngle;

            if (RequiresLimiting(deltaTime, out maxRotationAngle))
            {
                LimitBoneTransform(ref startTransform, ref lookAtTransform, maxRotationAngle);
            }

            SkeletonPose.SetBoneTransform(BoneIndex, lookAtTransform);
        }
    /// <summary>
    /// Updates all bone transformations.
    /// </summary>
    public void Update()
    {
      // This method updates does not check the individual dirty flags. If something is
      // dirty all transforms are updated. Checking the dirty flags makes the average 
      // case (whole skeleton is animated) a lot slower.
      if (_isDirty)
      {
        lock (_syncRoot)
        {
          if (_isDirty)
          {
            var skeleton = _skeletonPose.Skeleton;
            int numberOfBones = skeleton.NumberOfBones;

            // ----- Update dirty relative bone poses.
            var boneTransforms = _skeletonPose.BoneTransforms;

            var bindPosesRelative = skeleton.BindPosesRelative;

            for (int i = 0; i < numberOfBones; i++)
            {
              //_bonePoseRelative[i] = bindPosesRelative[i] * boneTransforms[i];
              SrtTransform.Multiply(ref bindPosesRelative[i], ref boneTransforms[i], out _bonePoseRelative[i]);
            }

            // ----- Update dirty absolute bone poses.
            _bonePoseAbsolute[0] = _bonePoseRelative[0];
            for (int i = 1; i < numberOfBones; i++)
            {
              int parentIndex = skeleton.GetParent(i);

              //_bonePoseAbsolute[i] = _bonePoseAbsolute[parentIndex] * _bonePoseRelative[i];
              SrtTransform.Multiply(ref _bonePoseAbsolute[parentIndex], ref _bonePoseRelative[i],
                                    out _bonePoseAbsolute[i]);
            }

            // ----- Update skinning matrices (either the Matrix or the XNA variant).
            if (_skinningMatrices != null)
            {
              for (int i = 0; i < numberOfBones; i++)
              {
                //_skinningMatrices[i] = _bonePoseAbsolute[i] * skeleton.BindPosesAbsoluteInverse[i];
                SrtTransform.Multiply(ref _bonePoseAbsolute[i], ref skeleton.BindPosesAbsoluteInverse[i],
                                      out _skinningMatrices[i]);
              }
            }


            if (_skinningMatricesXna != null)
            {
              if (_skinningMatrices != null)
              {
                for (int i = 0; i < numberOfBones; i++)
                  _skinningMatricesXna[i] = (Matrix)_skinningMatrices[i];
              }
              else
              {
                for (int i = 0; i < numberOfBones; i++)
                {
                  //_skinningMatricesXna[i] = _bonePoseAbsolute[i] * skeleton.BindPosesAbsoluteInverse[i];
                  SrtTransform.Multiply(ref _bonePoseAbsolute[i], ref skeleton.BindPosesAbsoluteInverse[i],
                                        out _skinningMatricesXna[i]);
                }
              }
            }



            Thread.MemoryBarrier();
#else
            Interlocked.MemoryBarrier();


            _isBonePoseRelativeDirty.SetAll(false);
            _isBonePoseAbsoluteDirty.SetAll(false);
            _isSkinningMatrixDirty.SetAll(false);
            _isDirty = false;
          }
        }
      }
    }
Example #11
0
        /// <summary>
        /// Initializes the skeleton.
        /// </summary>
        /// <param name="boneParents">The bone parents.</param>
        /// <param name="boneNames">The bone names.</param>
        /// <param name="bindPosesRelative">The bind poses.</param>
        /// <exception cref="ArgumentNullException">
        /// <paramref name="boneParents"/>, <paramref name="boneNames"/> or
        /// <paramref name="bindPosesRelative"/> is <see langword="null"/>.
        /// </exception>
        /// <exception cref="ArgumentException">
        /// Either the given lists are empty, have different length, or the
        /// <paramref name="boneParents"/> are invalid (parent bones must come be before their child
        /// bones).
        /// </exception>
        internal void Initialize(IList <int> boneParents, IList <string> boneNames, IList <SrtTransform> bindPosesRelative)
        {
            if (boneParents == null)
            {
                throw new ArgumentNullException("boneParents");
            }
            if (boneNames == null)
            {
                throw new ArgumentNullException("boneNames");
            }
            if (bindPosesRelative == null)
            {
                throw new ArgumentNullException("bindPosesRelative");
            }

            var numberOfBones = boneParents.Count;

            if (numberOfBones == 0)
            {
                throw new ArgumentException("boneParents list must not be empty.");
            }
            if (boneNames.Count == 0)
            {
                throw new ArgumentException("boneNames list must not be empty.");
            }
            if (bindPosesRelative.Count == 0)
            {
                throw new ArgumentException("bindPosesRelative list must not be empty.");
            }
            if (numberOfBones != boneNames.Count || numberOfBones != bindPosesRelative.Count)
            {
                throw new ArgumentException("The lists must have the same number of elements.");
            }

            // Check if bone parents come before children. This ordering also forbids cycles.
            for (int index = 0; index < numberOfBones; index++)
            {
                var parentIndex = boneParents[index];
                if (parentIndex >= index)
                {
                    throw new ArgumentException("Invalid boneParents list. Parent bones must have a lower index than child bones.");
                }
            }

            // Build list of bone nodes.
            Bones = new Bone[numberOfBones];
            var children = new List <int>();

            for (int index = 0; index < numberOfBones; index++)
            {
                Bone bone = new Bone();

                // Set parent index.
                int parentIndex = boneParents[index];
                if (parentIndex < -1)
                {
                    parentIndex = -1;
                }

                bone.Parent = parentIndex;

                // Create array of child indices.
                children.Clear();
                for (int childIndex = index + 1; childIndex < numberOfBones; childIndex++)
                {
                    if (boneParents[childIndex] == index)
                    {
                        children.Add(childIndex);
                    }
                }

                if (children.Count > 0)
                {
                    bone.Children = children.ToArray();
                }

                Bones[index] = bone;
            }

            // Initialize bone name/index dictionary.
            if (BoneNames == null)
            {
                BoneNames = new Dictionary <string, int>(numberOfBones);
            }
            else
            {
                BoneNames.Clear();
            }

            for (int index = 0; index < numberOfBones; index++)
            {
                var name = boneNames[index];
                if (name != null)
                {
                    BoneNames[name] = index;
                }
            }

            // Copy relative bind poses.
            if (BindPosesRelative == null)
            {
                BindPosesRelative = new SrtTransform[numberOfBones];
            }

            for (int index = 0; index < numberOfBones; index++)
            {
                BindPosesRelative[index] = bindPosesRelative[index];
            }

            // Initialize absolute bind poses (inverse).
            if (BindPosesAbsoluteInverse == null)
            {
                BindPosesAbsoluteInverse = new SrtTransform[numberOfBones];
            }

            // First store the non-inverted BindTransforms in model space.
            BindPosesAbsoluteInverse[0] = BindPosesRelative[0];
            for (int index = 1; index < numberOfBones; index++)
            {
                var parentIndex = Bones[index].Parent;

                //BindPosesAbsoluteInverse[index] = BindPosesAbsoluteInverse[parentIndex] * BindPosesRelative[index];
                SrtTransform.Multiply(ref BindPosesAbsoluteInverse[parentIndex], ref BindPosesRelative[index], out BindPosesAbsoluteInverse[index]);
            }

            // Invert matrices.
            for (int index = 0; index < numberOfBones; index++)
            {
                BindPosesAbsoluteInverse[index].Invert();
            }
        }
Example #12
0
        /// <summary>
        /// Called when <see cref="IKSolver.Solve"/> is called.
        /// </summary>
        /// <param name="deltaTime">The current time step (in seconds).</param>
        protected override void OnSolve(float deltaTime)
        {
            UpdateDerivedValues();

            if (_totalChainLength == 0)
            {
                return;
            }

            var skeleton = SkeletonPose.Skeleton;

            // Make a local copy of the absolute bone poses. The following operations will be performed
            // on the data in _bone and not on the skeleton pose.
            var numberOfBones = _boneIndices.Count;

            for (int i = 0; i < numberOfBones; i++)
            {
                _bones[i] = SkeletonPose.GetBonePoseAbsolute(_boneIndices[i]);
            }

            // Calculate the position at the tip of the last bone.
            // If TipOffset is not 0, then we can rotate the last bone.
            // If TipOffset is 0, then the last bone defines the tip but is not rotated.
            // --> numberOfBones is set to the number of affected bones.
            Vector3 tipAbsolute;

            if (TipOffset.IsNumericallyZero)
            {
                numberOfBones--;
                tipAbsolute = SkeletonPose.GetBonePoseAbsolute(TipBoneIndex).Translation;
            }
            else
            {
                tipAbsolute = SkeletonPose.GetBonePoseAbsolute(TipBoneIndex).ToParentPosition(TipOffset);
            }

            // The root bone rotation that aligns the whole chain with the target.
            Quaternion chainRotation = Quaternion.Identity;
            Vector3    boneToTarget, boneToTip;
            float      remainingChainLength = _totalChainLength;

            // Apply the soft limit to the distance to the IK goal
            //vecToIkGoal = Target - _bones[0].Translation;
            //distToIkGoal = vecToIkGoal.Length;
            //// Limit the extension to 98% and ramp it up over 5% of the chains length
            //vecToIkGoal *= (LimitValue(distToIkGoal, _totalChainLength * 0.98f, _totalChainLength * 0.08f)) / distToIkGoal;
            //Vector3 goalPosition = _bones[0].Translation + vecToIkGoal;

            var targetAbsolute = Target;

            // This algorithms iterates once over all bones from root to tip.
            for (int i = 0; i < numberOfBones; i++)
            {
                if (i > 0)
                {
                    // Transform the bone position by the overall chain offset.
                    var translation = _bones[0].Translation
                                      + chainRotation.Rotate(_bones[i].Translation - _bones[0].Translation);
                    _bones[i] = new SrtTransform(_bones[i].Scale, _bones[i].Rotation, translation);
                }

                // The bone to tip vector of the aligned chain (without other IK rotations!).
                boneToTip = tipAbsolute - _bones[i].Translation;
                float boneToTipLength = boneToTip.Length;
                boneToTip /= boneToTipLength; // TODO: Check for division by 0?

                if (i > 0)
                {
                    // Calculate the new absolute bone position.
                    var translation = _bones[i - 1].ToParentPosition(skeleton.GetBindPoseRelative(_boneIndices[i]).Translation);
                    _bones[i] = new SrtTransform(_bones[i].Scale, _bones[i].Rotation, translation);
                }

                // The bone to target vector of the new chain configuration.
                boneToTarget = targetAbsolute - _bones[i].Translation;
                float boneToTargetLength = boneToTarget.Length;
                boneToTarget /= boneToTargetLength;

                if (i == 0)
                {
                    // This is the first bone: Compute rotation that aligns the whole initial chain with
                    // the target.
                    chainRotation = Quaternion.CreateFromRotationMatrix(boneToTip, boneToTarget);

                    // Update tip.
                    tipAbsolute = _bones[i].Translation + (boneToTarget * boneToTipLength);

                    // Apply chainRotation to root bone.
                    _bones[i] = new SrtTransform(_bones[i].Scale, chainRotation * _bones[i].Rotation, _bones[i].Translation);
                }
                else
                {
                    // Apply the chain alignment rotation. Also the parent bones have changed, so we apply
                    // an additional rotation that accounts for the ancestor rotations. This additional
                    // rotation aligns the last bone with the target.
                    // TODO: Find an explanation/derivation of this additional rotation.
                    _bones[i] = new SrtTransform(
                        _bones[i].Scale,
                        Quaternion.CreateFromRotationMatrix(boneToTip, boneToTarget) * chainRotation * _bones[i].Rotation,
                        _bones[i].Translation);
                }

                // Now, solve the bone using trigonometry.
                // The last bone was already aligned with the target. For the second last bone we use
                // the law of cosines. For all other bones we use the complicated steps described in the
                // GPG article.
                if (i <= numberOfBones - 2)
                {
                    // Length of chain after this bone.
                    remainingChainLength -= _boneLengths[i];

                    // The direction of the current bone. For the tip bone we use the TipOffset.
                    Vector3 boneDirection;
                    if (i != TipBoneIndex)
                    {
                        boneDirection = _bones[i].Rotation.Rotate(skeleton.GetBindPoseRelative(_boneIndices[i + 1]).Translation);
                    }
                    else
                    {
                        boneDirection = _bones[i].Rotation.Rotate(TipOffset);
                    }

                    if (!boneDirection.TryNormalize())
                    {
                        continue;
                    }

                    // The bone rotates around an axis normal to the bone to target direction and the bone
                    // vector.
                    Vector3 rotationAxis = Vector3.Cross(boneToTarget, boneDirection);
                    if (!rotationAxis.TryNormalize())
                    {
                        continue; // TODO: If this happens, can we choose a useful direction?
                    }
                    // The current angle between bone direction and bone to target vector.
                    float currentAngle = (float)Math.Acos(MathHelper.Clamp(Vector3.Dot(boneDirection, boneToTarget), -1, 1));

                    // Side lengths of the involved triangles.
                    var a = _boneLengths[i];
                    var b = boneToTargetLength;
                    var c = remainingChainLength;
                    var d = boneToTipLength;

                    float desiredAngle;
                    if (i == numberOfBones - 2)
                    {
                        // Use trigonometry (law of cosines) to determine the desired angle.
                        desiredAngle = (float)Math.Acos(MathHelper.Clamp((a * a + b * b - c * c) / (2 * a * b), -1.0f, 1.0f));
                    }
                    else
                    {
                        // The maximal angle that this bone can have where the chain still reaches the tip.
                        float maxTipAngle;
                        if (boneToTipLength > remainingChainLength)
                        {
                            maxTipAngle = (float)Math.Acos(MathHelper.Clamp((a * a + d * d - c * c) / (2 * a * d), -1.0f, 1.0f));
                        }
                        else
                        {
                            // Tip is very near and this bone can bend more than 180�. Add additional chain length
                            // in radians.
                            maxTipAngle  = (float)Math.Acos(MathHelper.Clamp((a * 0.5f) / remainingChainLength, 0.0f, 1.0f));
                            maxTipAngle += ((c - d) / a);
                        }

                        // The maximal angle that this bone can have where the chain still reaches the target.
                        float maxTargetAngle;
                        if (boneToTargetLength > remainingChainLength)
                        {
                            maxTargetAngle = (float)Math.Acos(MathHelper.Clamp((a * a + b * b - c * c) / (2 * a * b), -1.0f, 1.0f));
                        }
                        else
                        {
                            // Target is very near and this bone can bend more than 180�. Add additional chain
                            // length in radians.
                            maxTargetAngle  = (float)Math.Acos(MathHelper.Clamp((a * 0.5f) / remainingChainLength, 0.0f, 1.0f));
                            maxTargetAngle += ((c - b) / a);
                        }

                        // If we set the desired angle to maxTargetAngle, the remain bones must be all
                        // stretched. We want to keep the chain appearance, therefore, we set a smaller angle.
                        // The new angle relative to the final remaining chain should have the same ratio as the
                        // current angle to the current remaining chain.
                        if (!Numeric.IsZero(maxTipAngle))
                        {
                            desiredAngle = maxTargetAngle * (currentAngle / maxTipAngle);
                        }
                        else
                        {
                            desiredAngle = maxTargetAngle; // Avoiding divide by zero.
                        }
                    }

                    // The rotation angle that we have to apply.
                    float deltaAngle = desiredAngle - currentAngle;

                    // Apply the rotation to the current bones
                    _bones[i] = new SrtTransform(
                        _bones[i].Scale,
                        (Quaternion.CreateFromRotationMatrix(rotationAxis, deltaAngle) * _bones[i].Rotation).Normalized,
                        _bones[i].Translation);
                }
            }

            bool  requiresBlending = RequiresBlending();
            float maxRotationAngle;
            bool  requiresLimiting = RequiresLimiting(deltaTime, out maxRotationAngle);

            if (requiresBlending || requiresLimiting)
            {
                // We have to blend the computed results with the original bone transforms.

                // Get original bone transforms.
                for (int i = 0; i < numberOfBones; i++)
                {
                    _originalBoneTransforms.Add(SkeletonPose.GetBoneTransform(_boneIndices[i]));
                }

                for (int i = 0; i < numberOfBones; i++)
                {
                    int boneIndex = _boneIndices[i];

                    var originalBoneTransform = _originalBoneTransforms[i];

                    // Set absolute bone pose and let the skeleton compute the bone transform for us.
                    SkeletonPose.SetBoneRotationAbsolute(boneIndex, _bones[i].Rotation);
                    var targetBoneTransform = SkeletonPose.GetBoneTransform(boneIndex);

                    // Apply weight.
                    if (requiresBlending)
                    {
                        BlendBoneTransform(ref originalBoneTransform, ref targetBoneTransform);
                    }

                    // Apply angular velocity limit.
                    if (requiresLimiting)
                    {
                        LimitBoneTransform(ref originalBoneTransform, ref targetBoneTransform, maxRotationAngle);
                    }

                    // Set final bone transform.
                    SkeletonPose.SetBoneTransform(boneIndex, targetBoneTransform);
                }

                _originalBoneTransforms.Clear();
            }
            else
            {
                // Weight is 1 and angular velocity limit is not active.
                // --> Just copy the compute rotations.

                for (int i = 0; i < numberOfBones; i++)
                {
                    int boneIndex = _boneIndices[i];
                    SkeletonPose.SetBoneRotationAbsolute(boneIndex, _bones[i].Rotation);
                }
            }
        }
Example #13
0
        /// <summary>
        /// Draws the skeleton bones, bone space axes and bone names for debugging.
        /// (Only available in the XNA-compatible build.)
        /// </summary>
        /// <param name="skeletonPose">The skeleton pose.</param>
        /// <param name="graphicsDevice">The graphics device.</param>
        /// <param name="effect">
        /// A <see cref="BasicEffect"/> instance. The effect parameters <see cref="BasicEffect.World"/>,
        /// <see cref="BasicEffect.View"/>, and <see cref="BasicEffect.Projection"/> must be
        /// correctly initialized before this method is called.
        /// </param>
        /// <param name="axisLength">The visible length of the bone space axes.</param>
        /// <param name="spriteBatch">
        /// A <see cref="SpriteBatch"/>. Can be <see langword="null"/> to skip text rendering.
        /// </param>
        /// <param name="spriteFont">
        /// A <see cref="SpriteFont"/>. Can be <see langword="null"/> to skip text rendering.
        /// </param>
        /// <param name="color">The color for the bones and the bone names.</param>
        /// <remarks>
        /// <para>
        /// This method is available only in the XNA-compatible build of the DigitalRune.Animation.dll.
        /// </para>
        /// <para>
        /// This method draws the skeleton for debugging. It draws a line for each bone and the bone
        /// name. At the bone origin it draws 3 lines (red, green, blue) that visualize the bone
        /// space axes (x, y, z).
        /// </para>
        /// </remarks>
        /// <exception cref="ArgumentNullException">
        /// <paramref name="skeletonPose"/>, <paramref name="graphicsDevice"/> or
        /// <paramref name="effect"/> is <see langword="null"/>.
        /// </exception>
        public static void DrawBones(this SkeletonPose skeletonPose, GraphicsDevice graphicsDevice,
                                     BasicEffect effect, float axisLength, SpriteBatch spriteBatch, SpriteFont spriteFont, Color color)
        {
            if (skeletonPose == null)
            {
                throw new ArgumentNullException("skeletonPose");
            }
            if (graphicsDevice == null)
            {
                throw new ArgumentNullException("graphicsDevice");
            }
            if (effect == null)
            {
                throw new ArgumentNullException("effect");
            }

            var oldVertexColorEnabled = effect.VertexColorEnabled;

            effect.VertexColorEnabled = true;

            // No font, then we don't need the sprite batch.
            if (spriteFont == null)
            {
                spriteBatch = null;
            }

            if (spriteBatch != null)
            {
                spriteBatch.Begin();
            }

            List <VertexPositionColor> vertices = new List <VertexPositionColor>();

            var skeleton = skeletonPose.Skeleton;

            for (int i = 0; i < skeleton.NumberOfBones; i++)
            {
                string       name        = skeleton.GetName(i);
                SrtTransform bonePose    = skeletonPose.GetBonePoseAbsolute(i);
                var          translation = (Vector3)bonePose.Translation;
                var          rotation    = (Quaternion)bonePose.Rotation;

                int parentIndex = skeleton.GetParent(i);
                if (parentIndex >= 0)
                {
                    // Draw line to parent joint representing the parent bone.
                    SrtTransform parentPose = skeletonPose.GetBonePoseAbsolute(parentIndex);
                    vertices.Add(new VertexPositionColor(translation, color));
                    vertices.Add(new VertexPositionColor((Vector3)parentPose.Translation, color));
                }

                // Add three lines in Red, Green and Blue.
                vertices.Add(new VertexPositionColor(translation, Color.Red));
                vertices.Add(new VertexPositionColor(translation + Vector3.Transform(Vector3.UnitX, rotation) * axisLength, Color.Red));
                vertices.Add(new VertexPositionColor(translation, Color.Green));
                vertices.Add(new VertexPositionColor(translation + Vector3.Transform(Vector3.UnitY, rotation) * axisLength, Color.Green));
                vertices.Add(new VertexPositionColor(translation, Color.Blue));
                vertices.Add(new VertexPositionColor(translation + Vector3.Transform(Vector3.UnitZ, rotation) * axisLength, Color.Blue));

                // Draw name.
                if (spriteBatch != null && !string.IsNullOrEmpty(name))
                {
                    // Compute the 3D position in view space. Text is rendered near drawn x axis.
                    Vector3 textPosition      = translation + Vector3.TransformNormal(Vector3.UnitX, bonePose) * axisLength * 0.5f;
                    var     textPositionWorld = Vector3.Transform(textPosition, effect.World);
                    var     textPositionView  = Vector3.Transform(textPositionWorld, effect.View);

                    // Check if the text is in front of the camera.
                    if (textPositionView.Z < 0)
                    {
                        // Project text position to screen.
                        Vector3 textPositionProjected = graphicsDevice.Viewport.Project(textPosition, effect.Projection, effect.View, effect.World);
                        spriteBatch.DrawString(spriteFont, name + " " + i, new Vector2(textPositionProjected.X, textPositionProjected.Y), color);
                    }
                }
            }

            if (spriteBatch != null)
            {
                spriteBatch.End();
            }

            // Draw axis lines in one batch.
            graphicsDevice.DepthStencilState = DepthStencilState.None;
            effect.CurrentTechnique.Passes[0].Apply();
            graphicsDevice.DrawUserPrimitives(PrimitiveType.LineList, vertices.ToArray(), 0, vertices.Count / 2);

            effect.VertexColorEnabled = oldVertexColorEnabled;
        }
Example #14
0
 /// <summary>
 /// Applies the weight to a given bone by blending the bone transforms.
 /// </summary>
 /// <param name="originalTransform">
 /// In: The original bone transform.
 /// </param>
 /// <param name="targetTransform">
 /// In: The target bone transform.<br/>
 /// Out: The blended bone transform.
 /// </param>
 internal void BlendBoneTransform(ref SrtTransform originalTransform, ref SrtTransform targetTransform)
 {
     targetTransform = SrtTransform.Interpolate(originalTransform, targetTransform, Weight);
 }
Example #15
0
        /// <summary>
        /// Sets the bone transform to create a desired pose in model space.
        /// </summary>
        /// <param name="skeletonPose">The skeleton pose.</param>
        /// <param name="boneIndex">The index of the bone.</param>
        /// <param name="bonePoseAbsolute">The bone pose in model space.</param>
        /// <exception cref="ArgumentNullException">
        /// <paramref name="skeletonPose" /> is <see langword="null"/>.
        /// </exception>
        public static void SetBonePoseAbsolute(this SkeletonPose skeletonPose, int boneIndex, SrtTransform bonePoseAbsolute)
        {
            if (skeletonPose == null)
            {
                throw new ArgumentNullException("skeletonPose");
            }

            var skeleton               = skeletonPose.Skeleton;
            var bindPoseRelative       = skeleton.GetBindPoseRelative(boneIndex);
            var parentIndex            = skeleton.GetParent(boneIndex);
            var parentBonePoseAbsolute = (parentIndex >= 0) ? skeletonPose.GetBonePoseAbsolute(parentIndex) : SrtTransform.Identity;

            // Solving this equation:
            // bonePoseAbsolute = parentBonePoseAbsolute * bindPoseRelative * BoneTransform;

            var boneTransform = bindPoseRelative.Inverse * parentBonePoseAbsolute.Inverse * bonePoseAbsolute;

            boneTransform.Rotation.Normalize();

            skeletonPose.SetBoneTransform(boneIndex, boneTransform);
        }
        /// <exception cref="AnimationException">
        /// This animation is not frozen. <see cref="Freeze"/> must be called before the animation can
        /// be used.
        /// </exception>
        /// <exception cref="ArgumentNullException">
        /// <paramref name="defaultSource"/>, <paramref name="defaultTarget"/> or
        /// <paramref name="result"/> is <see langword="null"/>.
        /// </exception>
        /// <inheritdoc/>
        public void GetValue(TimeSpan time, ref SkeletonPose defaultSource, ref SkeletonPose defaultTarget, ref SkeletonPose result)
        {
            if (!IsFrozen)
            {
                throw new AnimationException("This animation is not frozen. Freeze() must be called before the animation can be used.");
            }
            if (defaultSource == null)
            {
                throw new ArgumentNullException("defaultSource");
            }
            if (defaultTarget == null)
            {
                throw new ArgumentNullException("defaultTarget");
            }
            if (result == null)
            {
                throw new ArgumentNullException("result");
            }

            TimeSpan?animationTime = GetAnimationTime(time);

            if (animationTime == null)
            {
                // Animation is inactive and does not produce any output.
                if (defaultSource == result)
                {
                    return;
                }

                // Copy bone transforms of defaultSource to result for the animated channels.
                for (int i = 0; i < _channels.Length; i++)
                {
                    int boneIndex = _channels[i];
                    if (boneIndex >= result.BoneTransforms.Length)
                    {
                        break;
                    }

                    result.BoneTransforms[boneIndex] = defaultSource.BoneTransforms[boneIndex];
                }

                return;
            }

            time = animationTime.Value;

            // Clamp time to allowed range.
            var startTime = _times[0];
            var endTime   = _totalDuration;

            if (time < startTime)
            {
                time = startTime;
            }
            if (time > endTime)
            {
                time = endTime;
            }

            int timeIndex = GetTimeIndex(time);

            if (!IsAdditive)
            {
                // Evaluate animation.
                for (int channelIndex = 0; channelIndex < _channels.Length; channelIndex++)
                {
                    int boneIndex = _channels[channelIndex];
                    if (boneIndex >= result.BoneTransforms.Length)
                    {
                        break;
                    }

                    Debug.Assert(((Array)_keyFrames[channelIndex]).Length > 0, "Each channel must have at least 1 key frame.");

                    float weight = _weights[channelIndex];
                    if (weight == 0 && defaultSource != result)
                    {
                        // This channel is inactive.
                        result.BoneTransforms[boneIndex] = defaultSource.BoneTransforms[boneIndex];
                    }
                    else if (weight == 1)
                    {
                        // Channel is fully active.
                        result.BoneTransforms[boneIndex] = GetBoneTransform(channelIndex, timeIndex, time);
                    }
                    else
                    {
                        // Mix channel with source.
                        SrtTransform boneTransform = GetBoneTransform(channelIndex, timeIndex, time);
                        SrtTransform.Interpolate(ref defaultSource.BoneTransforms[boneIndex], ref boneTransform, weight, ref boneTransform);
                        result.BoneTransforms[boneIndex] = boneTransform;
                    }
                }
            }
            else
            {
                // Additive animation.
                for (int channelIndex = 0; channelIndex < _channels.Length; channelIndex++)
                {
                    int boneIndex = _channels[channelIndex];
                    if (boneIndex >= result.BoneTransforms.Length)
                    {
                        break;
                    }

                    Debug.Assert(((Array)_keyFrames[channelIndex]).Length > 0, "Each channel must have at least 1 key frame.");

                    float weight = _weights[channelIndex];
                    if (weight == 0 && defaultSource != result)
                    {
                        // Channel is inactive.
                        result.BoneTransforms[boneIndex] = defaultSource.BoneTransforms[boneIndex];
                    }
                    else if (weight == 1)
                    {
                        // Channel is fully active.
                        result.BoneTransforms[boneIndex] = defaultSource.BoneTransforms[boneIndex] * GetBoneTransform(channelIndex, timeIndex, time);
                    }
                    else
                    {
                        // Add only a part of this animation value.
                        SrtTransform boneTransform = GetBoneTransform(channelIndex, timeIndex, time);
                        SrtTransform identity      = SrtTransform.Identity;
                        SrtTransform.Interpolate(ref identity, ref boneTransform, weight, ref boneTransform);
                        result.BoneTransforms[boneIndex] = defaultSource.BoneTransforms[boneIndex] * boneTransform;
                    }
                }
            }
        }
        /// <summary>
        /// Gets one bone key frame for a given channel and key frame index.
        /// </summary>
        /// <param name="channelIndex">The index in <see cref="_channels"/>.</param>
        /// <param name="keyFrameIndex">
        /// The index in <see cref="_keyFrames"/> for the given channel.
        /// </param>
        /// <param name="time">The key frame time.</param>
        /// <param name="transform">The transform.</param>
        private void GetBoneKeyFrame(int channelIndex, int keyFrameIndex, out TimeSpan time, out SrtTransform transform)
        {
            var boneKeyFrameType = _keyFrameTypes[channelIndex];

            if (boneKeyFrameType == BoneKeyFrameType.R)
            {
                var keyFrames = (BoneKeyFrameR[])_keyFrames[channelIndex];

                var keyFrame = keyFrames[keyFrameIndex];
                time                  = keyFrame.Time;
                transform.Scale       = Vector3.One;
                transform.Rotation    = keyFrame.Rotation;
                transform.Translation = Vector3.Zero;
            }
            else if (boneKeyFrameType == BoneKeyFrameType.RT)
            {
                var keyFrames = (BoneKeyFrameRT[])_keyFrames[channelIndex];

                var keyFrame = keyFrames[keyFrameIndex];
                time                  = keyFrame.Time;
                transform.Scale       = Vector3.One;
                transform.Rotation    = keyFrame.Rotation;
                transform.Translation = keyFrame.Translation;
            }
            else
            {
                var keyFrames = (BoneKeyFrameSRT[])_keyFrames[channelIndex];

                var keyFrame = keyFrames[keyFrameIndex];
                time      = keyFrame.Time;
                transform = keyFrame.Transform;
            }
        }