/* * Copyright (c) Contributors, http://opensimulator.org/ * See CONTRIBUTORS.TXT for a full list of copyright holders. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of the OpenSimulator Project nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE DEVELOPERS ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE CONTRIBUTORS BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ using System; using System.Collections.Generic; using System.Drawing; using System.IO; using System.Linq; using System.Threading; using System.Xml; using System.Xml.Serialization; using OpenMetaverse; using OpenMetaverse.Packets; using OpenSim.Framework; using OpenSim.Region.Framework.Interfaces; using OpenSim.Region.Physics.Manager; using OpenSim.Region.Framework.Scenes.Serialization; namespace OpenSim.Region.Framework.Scenes { [Flags] public enum scriptEvents { None = 0, attach = 1, collision = 16, collision_end = 32, collision_start = 64, control = 128, dataserver = 256, email = 512, http_response = 1024, land_collision = 2048, land_collision_end = 4096, land_collision_start = 8192, at_target = 16384, at_rot_target = 16777216, listen = 32768, money = 65536, moving_end = 131072, moving_start = 262144, not_at_rot_target = 524288, not_at_target = 1048576, remote_data = 8388608, run_time_permissions = 268435456, state_entry = 1073741824, state_exit = 2, timer = 4, touch = 8, touch_end = 536870912, touch_start = 2097152, object_rez = 4194304 } struct scriptPosTarget { public Vector3 targetPos; public float tolerance; public uint handle; } struct scriptRotTarget { public Quaternion targetRot; public float tolerance; public uint handle; } public delegate void PrimCountTaintedDelegate(); /// /// A scene object group is conceptually an object in the scene. The object is constituted of SceneObjectParts /// (often known as prims), one of which is considered the root part. /// public partial class SceneObjectGroup : EntityBase, ISceneObject { // private PrimCountTaintedDelegate handlerPrimCountTainted = null; /// /// Signal whether the non-inventory attributes of any prims in the group have changed /// since the group's last persistent backup /// private bool m_hasGroupChanged = false; private long timeFirstChanged; private long timeLastChanged; /// /// This indicates whether the object has changed such that it needs to be repersisted to permenant storage /// (the database). /// /// /// Ultimately, this should be managed such that region modules can change it at the end of a set of operations /// so that either all changes are preserved or none at all. However, currently, a large amount of internal /// code will set this anyway when some object properties are changed. /// public bool HasGroupChanged { set { if (value) { timeLastChanged = DateTime.Now.Ticks; if (!m_hasGroupChanged) timeFirstChanged = DateTime.Now.Ticks; } m_hasGroupChanged = value; // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: HasGroupChanged set to {0} for {1} {2}", m_hasGroupChanged, Name, LocalId); } get { return m_hasGroupChanged; } } /// /// Has the group changed due to an unlink operation? We record this in order to optimize deletion, since /// an unlinked group currently has to be persisted to the database before we can perform an unlink operation. /// public bool HasGroupChangedDueToDelink { get; private set; } private bool isTimeToPersist() { if (IsSelected || IsDeleted || IsAttachment) return false; if (!m_hasGroupChanged) return false; if (m_scene.ShuttingDown) return true; long currentTime = DateTime.Now.Ticks; if (currentTime - timeLastChanged > m_scene.m_dontPersistBefore || currentTime - timeFirstChanged > m_scene.m_persistAfter) return true; return false; } /// /// Is this scene object acting as an attachment? /// public bool IsAttachment { get; set; } /// /// The avatar to which this scene object is attached. /// /// /// If we're not attached to an avatar then this is UUID.Zero /// public UUID AttachedAvatar { get; set; } /// /// Attachment point of this scene object to an avatar. /// /// /// 0 if we're not attached to anything /// public uint AttachmentPoint { get { return m_rootPart.Shape.State; } set { IsAttachment = value != 0; m_rootPart.Shape.State = (byte)value; } } /// /// If this scene object has an attachment point then indicate whether there is a point where /// attachments are perceivable by avatars other than the avatar to which this object is attached. /// /// /// HUDs are not perceivable by other avatars. /// public bool HasPrivateAttachmentPoint { get { return AttachmentPoint >= (uint)OpenMetaverse.AttachmentPoint.HUDCenter2 && AttachmentPoint <= (uint)OpenMetaverse.AttachmentPoint.HUDBottomRight; } } public void ClearPartAttachmentData() { AttachmentPoint = 0; // Even though we don't use child part state parameters for attachments any more, we still need to set // these to zero since having them non-zero in rezzed scene objects will crash some clients. Even if // we store them correctly, scene objects that we receive from elsewhere might not. foreach (SceneObjectPart part in Parts) part.Shape.State = 0; } /// /// Is this scene object phantom? /// /// /// Updating must currently take place through UpdatePrimFlags() /// public bool IsPhantom { get { return (RootPart.Flags & PrimFlags.Phantom) != 0; } } /// /// Does this scene object use physics? /// /// /// Updating must currently take place through UpdatePrimFlags() /// public bool UsesPhysics { get { return (RootPart.Flags & PrimFlags.Physics) != 0; } } /// /// Is this scene object temporary? /// /// /// Updating must currently take place through UpdatePrimFlags() /// public bool IsTemporary { get { return (RootPart.Flags & PrimFlags.TemporaryOnRez) != 0; } } public bool IsVolumeDetect { get { return RootPart.VolumeDetectActive; } } private Vector3 lastPhysGroupPos; private Quaternion lastPhysGroupRot; private bool m_isBackedUp; protected MapAndArray m_parts = new MapAndArray(); protected ulong m_regionHandle; protected SceneObjectPart m_rootPart; // private Dictionary m_scriptEvents = new Dictionary(); private Dictionary m_targets = new Dictionary(); private Dictionary m_rotTargets = new Dictionary(); private bool m_scriptListens_atTarget; private bool m_scriptListens_notAtTarget; private bool m_scriptListens_atRotTarget; private bool m_scriptListens_notAtRotTarget; internal Dictionary m_savedScriptState; #region Properties /// /// The name of an object grouping is always the same as its root part /// public override string Name { get { return RootPart.Name; } set { RootPart.Name = value; } } public string Description { get { return RootPart.Description; } set { RootPart.Description = value; } } /// /// Added because the Parcel code seems to use it /// but not sure a object should have this /// as what does it tell us? that some avatar has selected it (but not what Avatar/user) /// think really there should be a list (or whatever) in each scenepresence /// saying what prim(s) that user has selected. /// protected bool m_isSelected = false; /// /// Number of prims in this group /// public int PrimCount { get { return m_parts.Count; } } public Quaternion GroupRotation { get { return m_rootPart.RotationOffset; } } public Vector3 GroupScale { get { Vector3 minScale = new Vector3(Constants.RegionSize, Constants.RegionSize, Constants.RegionSize); Vector3 maxScale = Vector3.Zero; Vector3 finalScale = new Vector3(0.5f, 0.5f, 0.5f); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; Vector3 partscale = part.Scale; Vector3 partoffset = part.OffsetPosition; minScale.X = (partscale.X + partoffset.X < minScale.X) ? partscale.X + partoffset.X : minScale.X; minScale.Y = (partscale.Y + partoffset.Y < minScale.Y) ? partscale.Y + partoffset.Y : minScale.Y; minScale.Z = (partscale.Z + partoffset.Z < minScale.Z) ? partscale.Z + partoffset.Z : minScale.Z; maxScale.X = (partscale.X + partoffset.X > maxScale.X) ? partscale.X + partoffset.X : maxScale.X; maxScale.Y = (partscale.Y + partoffset.Y > maxScale.Y) ? partscale.Y + partoffset.Y : maxScale.Y; maxScale.Z = (partscale.Z + partoffset.Z > maxScale.Z) ? partscale.Z + partoffset.Z : maxScale.Z; } finalScale.X = (minScale.X > maxScale.X) ? minScale.X : maxScale.X; finalScale.Y = (minScale.Y > maxScale.Y) ? minScale.Y : maxScale.Y; finalScale.Z = (minScale.Z > maxScale.Z) ? minScale.Z : maxScale.Z; return finalScale; } } public UUID GroupID { get { return m_rootPart.GroupID; } set { m_rootPart.GroupID = value; } } public SceneObjectPart[] Parts { get { return m_parts.GetArray(); } } public bool ContainsPart(UUID partID) { return m_parts.ContainsKey(partID); } /// /// The root part of this scene object /// public SceneObjectPart RootPart { get { return m_rootPart; } } public ulong RegionHandle { get { return m_regionHandle; } set { m_regionHandle = value; SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].RegionHandle = value; } } /// /// Check both the attachment property and the relevant properties of the underlying root part. /// /// /// This is necessary in some cases, particularly when a scene object has just crossed into a region and doesn't /// have the IsAttachment property yet checked. /// /// FIXME: However, this should be fixed so that this property /// propertly reflects the underlying status. /// /// public bool IsAttachmentCheckFull() { return (IsAttachment || (m_rootPart.Shape.PCode == 9 && m_rootPart.Shape.State != 0)); } /// /// The absolute position of this scene object in the scene /// public override Vector3 AbsolutePosition { get { return m_rootPart.GroupPosition; } set { Vector3 val = value; if (Scene != null) { if ((Scene.TestBorderCross(val - Vector3.UnitX, Cardinals.E) || Scene.TestBorderCross(val + Vector3.UnitX, Cardinals.W) || Scene.TestBorderCross(val - Vector3.UnitY, Cardinals.N) || Scene.TestBorderCross(val + Vector3.UnitY, Cardinals.S)) && !IsAttachmentCheckFull() && (!Scene.LoadingPrims)) { m_scene.CrossPrimGroupIntoNewRegion(val, this, true); } } if (RootPart.GetStatusSandbox()) { if (Util.GetDistanceTo(RootPart.StatusSandboxPos, value) > 10) { RootPart.ScriptSetPhysicsStatus(false); if (Scene != null) Scene.SimChat(Utils.StringToBytes("Hit Sandbox Limit"), ChatTypeEnum.DebugChannel, 0x7FFFFFFF, RootPart.AbsolutePosition, Name, UUID, false); return; } } SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].GroupPosition = val; //if (m_rootPart.PhysActor != null) //{ //m_rootPart.PhysActor.Position = //new PhysicsVector(m_rootPart.GroupPosition.X, m_rootPart.GroupPosition.Y, //m_rootPart.GroupPosition.Z); //m_scene.PhysicsScene.AddPhysicsActorTaint(m_rootPart.PhysActor); //} if (Scene != null) Scene.EventManager.TriggerParcelPrimCountTainted(); } } public override uint LocalId { get { return m_rootPart.LocalId; } set { m_rootPart.LocalId = value; } } public override UUID UUID { get { return m_rootPart.UUID; } set { lock (m_parts.SyncRoot) { m_parts.Remove(m_rootPart.UUID); m_rootPart.UUID = value; m_parts.Add(value, m_rootPart); } } } public UUID LastOwnerID { get { return m_rootPart.LastOwnerID; } set { m_rootPart.LastOwnerID = value; } } public UUID OwnerID { get { return m_rootPart.OwnerID; } set { m_rootPart.OwnerID = value; } } public float Damage { get { return m_rootPart.Damage; } set { m_rootPart.Damage = value; } } public Color Color { get { return m_rootPart.Color; } set { m_rootPart.Color = value; } } public string Text { get { string returnstr = m_rootPart.Text; if (returnstr.Length > 255) { returnstr = returnstr.Substring(0, 255); } return returnstr; } set { m_rootPart.Text = value; } } protected virtual bool InSceneBackup { get { return true; } } private bool m_passCollision; public bool PassCollision { get { return m_passCollision; } set { m_passCollision = value; HasGroupChanged = true; } } public bool IsSelected { get { return m_isSelected; } set { m_isSelected = value; // Tell physics engine that group is selected PhysicsActor pa = m_rootPart.PhysActor; if (pa != null) { pa.Selected = value; // Pass it on to the children. SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart child = parts[i]; PhysicsActor childPa = child.PhysActor; if (childPa != null) childPa.Selected = value; } } } } private SceneObjectPart m_PlaySoundMasterPrim = null; public SceneObjectPart PlaySoundMasterPrim { get { return m_PlaySoundMasterPrim; } set { m_PlaySoundMasterPrim = value; } } private List m_PlaySoundSlavePrims = new List(); public List PlaySoundSlavePrims { get { return m_PlaySoundSlavePrims; } set { m_PlaySoundSlavePrims = value; } } private SceneObjectPart m_LoopSoundMasterPrim = null; public SceneObjectPart LoopSoundMasterPrim { get { return m_LoopSoundMasterPrim; } set { m_LoopSoundMasterPrim = value; } } private List m_LoopSoundSlavePrims = new List(); public List LoopSoundSlavePrims { get { return m_LoopSoundSlavePrims; } set { m_LoopSoundSlavePrims = value; } } /// /// The UUID for the region this object is in. /// public UUID RegionUUID { get { if (m_scene != null) { return m_scene.RegionInfo.RegionID; } return UUID.Zero; } } /// /// The item ID that this object was rezzed from, if applicable. /// /// /// If not applicable will be UUID.Zero /// public UUID FromItemID { get; set; } /// /// The folder ID that this object was rezzed from, if applicable. /// /// /// If not applicable will be UUID.Zero /// public UUID FromFolderID { get; set; } #endregion // ~SceneObjectGroup() // { // //m_log.DebugFormat("[SCENE OBJECT GROUP]: Destructor called for {0}, local id {1}", Name, LocalId); // Console.WriteLine("Destructor called for {0}, local id {1}", Name, LocalId); // } #region Constructors /// /// Constructor /// public SceneObjectGroup() { } /// /// This constructor creates a SceneObjectGroup using a pre-existing SceneObjectPart. /// The original SceneObjectPart will be used rather than a copy, preserving /// its existing localID and UUID. /// public SceneObjectGroup(SceneObjectPart part) { SetRootPart(part); } /// /// Constructor. This object is added to the scene later via AttachToScene() /// public SceneObjectGroup(UUID ownerID, Vector3 pos, Quaternion rot, PrimitiveBaseShape shape) { SetRootPart(new SceneObjectPart(ownerID, shape, pos, rot, Vector3.Zero)); } /// /// Constructor. /// public SceneObjectGroup(UUID ownerID, Vector3 pos, PrimitiveBaseShape shape) : this(ownerID, pos, Quaternion.Identity, shape) { } public void LoadScriptState(XmlDocument doc) { XmlNodeList nodes = doc.GetElementsByTagName("SavedScriptState"); if (nodes.Count > 0) { if (m_savedScriptState == null) m_savedScriptState = new Dictionary(); foreach (XmlNode node in nodes) { if (node.Attributes["UUID"] != null) { UUID itemid = new UUID(node.Attributes["UUID"].Value); if (itemid != UUID.Zero) m_savedScriptState[itemid] = node.InnerXml; } } } } /// /// Hooks this object up to the backup event so that it is persisted to the database when the update thread executes. /// public virtual void AttachToBackup() { if (InSceneBackup) { //m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Attaching object {0} {1} to scene presistence sweep", Name, UUID); if (!m_isBackedUp) m_scene.EventManager.OnBackup += ProcessBackup; m_isBackedUp = true; } } /// /// Attach this object to a scene. It will also now appear to agents. /// /// public void AttachToScene(Scene scene) { m_scene = scene; RegionHandle = m_scene.RegionInfo.RegionHandle; if (m_rootPart.Shape.PCode != 9 || m_rootPart.Shape.State == 0) m_rootPart.ParentID = 0; if (m_rootPart.LocalId == 0) m_rootPart.LocalId = m_scene.AllocateLocalId(); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (Object.ReferenceEquals(part, m_rootPart)) continue; if (part.LocalId == 0) part.LocalId = m_scene.AllocateLocalId(); part.ParentID = m_rootPart.LocalId; //m_log.DebugFormat("[SCENE]: Given local id {0} to part {1}, linknum {2}, parent {3} {4}", part.LocalId, part.UUID, part.LinkNum, part.ParentID, part.ParentUUID); } ApplyPhysics(); // Don't trigger the update here - otherwise some client issues occur when multiple updates are scheduled // for the same object with very different properties. The caller must schedule the update. //ScheduleGroupForFullUpdate(); } public EntityIntersection TestIntersection(Ray hRay, bool frontFacesOnly, bool faceCenters) { // We got a request from the inner_scene to raytrace along the Ray hRay // We're going to check all of the prim in this group for intersection with the ray // If we get a result, we're going to find the closest result to the origin of the ray // and send back the intersection information back to the innerscene. EntityIntersection result = new EntityIntersection(); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; // Temporary commented to stop compiler warning //Vector3 partPosition = // new Vector3(part.AbsolutePosition.X, part.AbsolutePosition.Y, part.AbsolutePosition.Z); Quaternion parentrotation = GroupRotation; // Telling the prim to raytrace. //EntityIntersection inter = part.TestIntersection(hRay, parentrotation); EntityIntersection inter = part.TestIntersectionOBB(hRay, parentrotation, frontFacesOnly, faceCenters); // This may need to be updated to the maximum draw distance possible.. // We might (and probably will) be checking for prim creation from other sims // when the camera crosses the border. float idist = Constants.RegionSize; if (inter.HitTF) { // We need to find the closest prim to return to the testcaller along the ray if (inter.distance < idist) { result.HitTF = true; result.ipoint = inter.ipoint; result.obj = part; result.normal = inter.normal; result.distance = inter.distance; } } } return result; } /// /// Gets a vector representing the size of the bounding box containing all the prims in the group /// Treats all prims as rectangular, so no shape (cut etc) is taken into account /// offsetHeight is the offset in the Z axis from the centre of the bounding box to the centre of the root prim /// /// public void GetAxisAlignedBoundingBoxRaw(out float minX, out float maxX, out float minY, out float maxY, out float minZ, out float maxZ) { maxX = -256f; maxY = -256f; maxZ = -256f; minX = 256f; minY = 256f; minZ = 8192f; SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; Vector3 worldPos = part.GetWorldPosition(); Vector3 offset = worldPos - AbsolutePosition; Quaternion worldRot; if (part.ParentID == 0) worldRot = part.RotationOffset; else worldRot = part.GetWorldRotation(); Vector3 frontTopLeft; Vector3 frontTopRight; Vector3 frontBottomLeft; Vector3 frontBottomRight; Vector3 backTopLeft; Vector3 backTopRight; Vector3 backBottomLeft; Vector3 backBottomRight; Vector3 orig = Vector3.Zero; frontTopLeft.X = orig.X - (part.Scale.X / 2); frontTopLeft.Y = orig.Y - (part.Scale.Y / 2); frontTopLeft.Z = orig.Z + (part.Scale.Z / 2); frontTopRight.X = orig.X - (part.Scale.X / 2); frontTopRight.Y = orig.Y + (part.Scale.Y / 2); frontTopRight.Z = orig.Z + (part.Scale.Z / 2); frontBottomLeft.X = orig.X - (part.Scale.X / 2); frontBottomLeft.Y = orig.Y - (part.Scale.Y / 2); frontBottomLeft.Z = orig.Z - (part.Scale.Z / 2); frontBottomRight.X = orig.X - (part.Scale.X / 2); frontBottomRight.Y = orig.Y + (part.Scale.Y / 2); frontBottomRight.Z = orig.Z - (part.Scale.Z / 2); backTopLeft.X = orig.X + (part.Scale.X / 2); backTopLeft.Y = orig.Y - (part.Scale.Y / 2); backTopLeft.Z = orig.Z + (part.Scale.Z / 2); backTopRight.X = orig.X + (part.Scale.X / 2); backTopRight.Y = orig.Y + (part.Scale.Y / 2); backTopRight.Z = orig.Z + (part.Scale.Z / 2); backBottomLeft.X = orig.X + (part.Scale.X / 2); backBottomLeft.Y = orig.Y - (part.Scale.Y / 2); backBottomLeft.Z = orig.Z - (part.Scale.Z / 2); backBottomRight.X = orig.X + (part.Scale.X / 2); backBottomRight.Y = orig.Y + (part.Scale.Y / 2); backBottomRight.Z = orig.Z - (part.Scale.Z / 2); frontTopLeft = frontTopLeft * worldRot; frontTopRight = frontTopRight * worldRot; frontBottomLeft = frontBottomLeft * worldRot; frontBottomRight = frontBottomRight * worldRot; backBottomLeft = backBottomLeft * worldRot; backBottomRight = backBottomRight * worldRot; backTopLeft = backTopLeft * worldRot; backTopRight = backTopRight * worldRot; frontTopLeft += offset; frontTopRight += offset; frontBottomLeft += offset; frontBottomRight += offset; backBottomLeft += offset; backBottomRight += offset; backTopLeft += offset; backTopRight += offset; if (frontTopRight.X > maxX) maxX = frontTopRight.X; if (frontTopLeft.X > maxX) maxX = frontTopLeft.X; if (frontBottomRight.X > maxX) maxX = frontBottomRight.X; if (frontBottomLeft.X > maxX) maxX = frontBottomLeft.X; if (backTopRight.X > maxX) maxX = backTopRight.X; if (backTopLeft.X > maxX) maxX = backTopLeft.X; if (backBottomRight.X > maxX) maxX = backBottomRight.X; if (backBottomLeft.X > maxX) maxX = backBottomLeft.X; if (frontTopRight.X < minX) minX = frontTopRight.X; if (frontTopLeft.X < minX) minX = frontTopLeft.X; if (frontBottomRight.X < minX) minX = frontBottomRight.X; if (frontBottomLeft.X < minX) minX = frontBottomLeft.X; if (backTopRight.X < minX) minX = backTopRight.X; if (backTopLeft.X < minX) minX = backTopLeft.X; if (backBottomRight.X < minX) minX = backBottomRight.X; if (backBottomLeft.X < minX) minX = backBottomLeft.X; // if (frontTopRight.Y > maxY) maxY = frontTopRight.Y; if (frontTopLeft.Y > maxY) maxY = frontTopLeft.Y; if (frontBottomRight.Y > maxY) maxY = frontBottomRight.Y; if (frontBottomLeft.Y > maxY) maxY = frontBottomLeft.Y; if (backTopRight.Y > maxY) maxY = backTopRight.Y; if (backTopLeft.Y > maxY) maxY = backTopLeft.Y; if (backBottomRight.Y > maxY) maxY = backBottomRight.Y; if (backBottomLeft.Y > maxY) maxY = backBottomLeft.Y; if (frontTopRight.Y < minY) minY = frontTopRight.Y; if (frontTopLeft.Y < minY) minY = frontTopLeft.Y; if (frontBottomRight.Y < minY) minY = frontBottomRight.Y; if (frontBottomLeft.Y < minY) minY = frontBottomLeft.Y; if (backTopRight.Y < minY) minY = backTopRight.Y; if (backTopLeft.Y < minY) minY = backTopLeft.Y; if (backBottomRight.Y < minY) minY = backBottomRight.Y; if (backBottomLeft.Y < minY) minY = backBottomLeft.Y; // if (frontTopRight.Z > maxZ) maxZ = frontTopRight.Z; if (frontTopLeft.Z > maxZ) maxZ = frontTopLeft.Z; if (frontBottomRight.Z > maxZ) maxZ = frontBottomRight.Z; if (frontBottomLeft.Z > maxZ) maxZ = frontBottomLeft.Z; if (backTopRight.Z > maxZ) maxZ = backTopRight.Z; if (backTopLeft.Z > maxZ) maxZ = backTopLeft.Z; if (backBottomRight.Z > maxZ) maxZ = backBottomRight.Z; if (backBottomLeft.Z > maxZ) maxZ = backBottomLeft.Z; if (frontTopRight.Z < minZ) minZ = frontTopRight.Z; if (frontTopLeft.Z < minZ) minZ = frontTopLeft.Z; if (frontBottomRight.Z < minZ) minZ = frontBottomRight.Z; if (frontBottomLeft.Z < minZ) minZ = frontBottomLeft.Z; if (backTopRight.Z < minZ) minZ = backTopRight.Z; if (backTopLeft.Z < minZ) minZ = backTopLeft.Z; if (backBottomRight.Z < minZ) minZ = backBottomRight.Z; if (backBottomLeft.Z < minZ) minZ = backBottomLeft.Z; } } public Vector3 GetAxisAlignedBoundingBox(out float offsetHeight) { float minX; float maxX; float minY; float maxY; float minZ; float maxZ; GetAxisAlignedBoundingBoxRaw(out minX, out maxX, out minY, out maxY, out minZ, out maxZ); Vector3 boundingBox = new Vector3(maxX - minX, maxY - minY, maxZ - minZ); offsetHeight = 0; float lower = (minZ * -1); if (lower > maxZ) { offsetHeight = lower - (boundingBox.Z / 2); } else if (maxZ > lower) { offsetHeight = maxZ - (boundingBox.Z / 2); offsetHeight *= -1; } // m_log.InfoFormat("BoundingBox is {0} , {1} , {2} ", boundingBox.X, boundingBox.Y, boundingBox.Z); return boundingBox; } #endregion public void SaveScriptedState(XmlTextWriter writer) { XmlDocument doc = new XmlDocument(); Dictionary states = new Dictionary(); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { Dictionary pstates = parts[i].Inventory.GetScriptStates(); foreach (KeyValuePair kvp in pstates) states.Add(kvp.Key, kvp.Value); } if (states.Count > 0) { // Now generate the necessary XML wrappings writer.WriteStartElement(String.Empty, "GroupScriptStates", String.Empty); foreach (UUID itemid in states.Keys) { doc.LoadXml(states[itemid]); writer.WriteStartElement(String.Empty, "SavedScriptState", String.Empty); writer.WriteAttributeString(String.Empty, "UUID", String.Empty, itemid.ToString()); writer.WriteRaw(doc.DocumentElement.OuterXml); // Writes ScriptState element writer.WriteEndElement(); // End of SavedScriptState } writer.WriteEndElement(); // End of GroupScriptStates } } /// /// /// /// private void SetPartAsNonRoot(SceneObjectPart part) { part.ParentID = m_rootPart.LocalId; part.ClearUndoState(); } public ushort GetTimeDilation() { return Utils.FloatToUInt16(m_scene.TimeDilation, 0.0f, 1.0f); } /// /// Set a part to act as the root part for this scene object /// /// public void SetRootPart(SceneObjectPart part) { if (part == null) throw new ArgumentNullException("Cannot give SceneObjectGroup a null root SceneObjectPart"); part.SetParent(this); m_rootPart = part; if (!IsAttachment) part.ParentID = 0; part.LinkNum = 0; m_parts.Add(m_rootPart.UUID, m_rootPart); } /// /// Add a new part to this scene object. The part must already be correctly configured. /// /// public void AddPart(SceneObjectPart part) { part.SetParent(this); part.LinkNum = m_parts.Add(part.UUID, part); if (part.LinkNum == 2) RootPart.LinkNum = 1; } /// /// Make sure that every non root part has the proper parent root part local id /// private void UpdateParentIDs() { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (part.UUID != m_rootPart.UUID) part.ParentID = m_rootPart.LocalId; } } public void RegenerateFullIDs() { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].UUID = UUID.Random(); } // helper provided for parts. public int GetSceneMaxUndo() { if (m_scene != null) return m_scene.MaxUndoCount; return 5; } // justincc: I don't believe this hack is needed any longer, especially since the physics // parts of set AbsolutePosition were already commented out. By changing HasGroupChanged to false // this method was preventing proper reload of scene objects. // dahlia: I had to uncomment it, without it meshing was failing on some prims and objects // at region startup // teravus: After this was removed from the linking algorithm, Linked prims no longer collided // properly when non-physical if they havn't been moved. This breaks ALL builds. // see: http://opensimulator.org/mantis/view.php?id=3108 // Here's the deal, this is ABSOLUTELY CRITICAL so the physics scene gets the update about the // position of linkset prims. IF YOU CHANGE THIS, YOU MUST TEST colliding with just linked and // unmoved prims! As soon as you move a Prim/group, it will collide properly because Absolute // Position has been set! public void ResetChildPrimPhysicsPositions() { AbsolutePosition = AbsolutePosition; // could someone in the know please explain how this works? // teravus: AbsolutePosition is NOT a normal property! // the code in the getter of AbsolutePosition is significantly different then the code in the setter! // jhurliman: Then why is it a property instead of two methods? } public UUID GetPartsFullID(uint localID) { SceneObjectPart part = GetChildPart(localID); if (part != null) { return part.UUID; } return UUID.Zero; } public void ObjectGrabHandler(uint localId, Vector3 offsetPos, IClientAPI remoteClient) { if (m_rootPart.LocalId == localId) { OnGrabGroup(offsetPos, remoteClient); } else { SceneObjectPart part = GetChildPart(localId); OnGrabPart(part, offsetPos, remoteClient); } } public virtual void OnGrabPart(SceneObjectPart part, Vector3 offsetPos, IClientAPI remoteClient) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Processing OnGrabPart for {0} on {1} {2}, offsetPos {3}", // remoteClient.Name, part.Name, part.LocalId, offsetPos); part.StoreUndoState(); part.OnGrab(offsetPos, remoteClient); } public virtual void OnGrabGroup(Vector3 offsetPos, IClientAPI remoteClient) { m_scene.EventManager.TriggerGroupGrab(UUID, offsetPos, remoteClient.AgentId); } /// /// Delete this group from its scene. /// /// /// This only handles the in-world consequences of deletion (e.g. any avatars sitting on it are forcibly stood /// up and all avatars receive notification of its removal. Removal of the scene object from database backup /// must be handled by the caller. /// /// If true then deletion is not broadcast to clients public void DeleteGroupFromScene(bool silent) { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; Scene.ForEachRootScenePresence(delegate(ScenePresence avatar) { if (avatar.ParentID == LocalId) avatar.StandUp(); if (!silent) { part.ClearUpdateSchedule(); if (part == m_rootPart) { if (!IsAttachment || AttachedAvatar == avatar.ControllingClient.AgentId || !HasPrivateAttachmentPoint) avatar.ControllingClient.SendKillObject(m_regionHandle, new List { part.LocalId }); } } }); } } public void AddScriptLPS(int count) { m_scene.SceneGraph.AddToScriptLPS(count); } public void AddActiveScriptCount(int count) { SceneGraph d = m_scene.SceneGraph; d.AddActiveScripts(count); } public void aggregateScriptEvents() { PrimFlags objectflagupdate = (PrimFlags)RootPart.GetEffectiveObjectFlags(); scriptEvents aggregateScriptEvents = 0; SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (part == null) continue; if (part != RootPart) part.Flags = objectflagupdate; aggregateScriptEvents |= part.AggregateScriptEvents; } m_scriptListens_atTarget = ((aggregateScriptEvents & scriptEvents.at_target) != 0); m_scriptListens_notAtTarget = ((aggregateScriptEvents & scriptEvents.not_at_target) != 0); if (!m_scriptListens_atTarget && !m_scriptListens_notAtTarget) { lock (m_targets) m_targets.Clear(); m_scene.RemoveGroupTarget(this); } m_scriptListens_atRotTarget = ((aggregateScriptEvents & scriptEvents.at_rot_target) != 0); m_scriptListens_notAtRotTarget = ((aggregateScriptEvents & scriptEvents.not_at_rot_target) != 0); if (!m_scriptListens_atRotTarget && !m_scriptListens_notAtRotTarget) { lock (m_rotTargets) m_rotTargets.Clear(); m_scene.RemoveGroupTarget(this); } ScheduleGroupForFullUpdate(); } public void SetText(string text, Vector3 color, double alpha) { Color = Color.FromArgb(0xff - (int) (alpha * 0xff), (int) (color.X * 0xff), (int) (color.Y * 0xff), (int) (color.Z * 0xff)); Text = text; HasGroupChanged = true; m_rootPart.ScheduleFullUpdate(); } /// /// Apply physics to this group /// public void ApplyPhysics() { // Apply physics to the root prim m_rootPart.ApplyPhysics(m_rootPart.GetEffectiveObjectFlags(), m_rootPart.VolumeDetectActive); // Apply physics to child prims SceneObjectPart[] parts = m_parts.GetArray(); if (parts.Length > 1) { for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (part.LocalId != m_rootPart.LocalId) part.ApplyPhysics(m_rootPart.GetEffectiveObjectFlags(), part.VolumeDetectActive); } // Hack to get the physics scene geometries in the right spot ResetChildPrimPhysicsPositions(); } } public void SetOwnerId(UUID userId) { ForEachPart(delegate(SceneObjectPart part) { part.OwnerID = userId; }); } public void ForEachPart(Action whatToDo) { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) whatToDo(parts[i]); } #region Events /// /// Processes backup. /// /// public virtual void ProcessBackup(ISimulationDataService datastore, bool forcedBackup) { if (!m_isBackedUp) { // m_log.DebugFormat( // "[WATER WARS]: Ignoring backup of {0} {1} since object is not marked to be backed up", Name, UUID); return; } if (IsDeleted || UUID == UUID.Zero) { // m_log.DebugFormat( // "[WATER WARS]: Ignoring backup of {0} {1} since object is marked as already deleted", Name, UUID); return; } // Since this is the top of the section of call stack for backing up a particular scene object, don't let // any exception propogate upwards. try { if (!m_scene.ShuttingDown) // if shutting down then there will be nothing to handle the return so leave till next restart { ILandObject parcel = m_scene.LandChannel.GetLandObject( m_rootPart.GroupPosition.X, m_rootPart.GroupPosition.Y); if (parcel != null && parcel.LandData != null && parcel.LandData.OtherCleanTime != 0) { if (parcel.LandData.OwnerID != OwnerID && (parcel.LandData.GroupID != GroupID || parcel.LandData.GroupID == UUID.Zero)) { if ((DateTime.UtcNow - RootPart.Rezzed).TotalMinutes > parcel.LandData.OtherCleanTime) { DetachFromBackup(); m_log.DebugFormat( "[SCENE OBJECT GROUP]: Returning object {0} due to parcel autoreturn", RootPart.UUID); m_scene.AddReturn(OwnerID == GroupID ? LastOwnerID : OwnerID, Name, AbsolutePosition, "parcel autoreturn"); m_scene.DeRezObjects(null, new List() { RootPart.LocalId }, UUID.Zero, DeRezAction.Return, UUID.Zero); return; } } } } if (m_scene.UseBackup && HasGroupChanged) { // don't backup while it's selected or you're asking for changes mid stream. if (isTimeToPersist() || forcedBackup) { // m_log.DebugFormat( // "[SCENE]: Storing {0}, {1} in {2}", // Name, UUID, m_scene.RegionInfo.RegionName); SceneObjectGroup backup_group = Copy(false); backup_group.RootPart.Velocity = RootPart.Velocity; backup_group.RootPart.Acceleration = RootPart.Acceleration; backup_group.RootPart.AngularVelocity = RootPart.AngularVelocity; backup_group.RootPart.ParticleSystem = RootPart.ParticleSystem; HasGroupChanged = false; HasGroupChangedDueToDelink = false; m_scene.EventManager.TriggerOnSceneObjectPreSave(backup_group, this); datastore.StoreObject(backup_group, m_scene.RegionInfo.RegionID); backup_group.ForEachPart(delegate(SceneObjectPart part) { part.Inventory.ProcessInventoryBackup(datastore); }); backup_group = null; } // else // { // m_log.DebugFormat( // "[SCENE]: Did not update persistence of object {0} {1}, selected = {2}", // Name, UUID, IsSelected); // } } } catch (Exception e) { m_log.ErrorFormat( "[SCENE]: Storing of {0}, {1} in {2} failed with exception {3}{4}", Name, UUID, m_scene.RegionInfo.RegionName, e.Message, e.StackTrace); } } #endregion /// /// Send the parts of this SOG to a single client /// /// /// Used when the client initially connects and when client sends RequestPrim packet /// /// public void SendFullUpdateToClient(IClientAPI remoteClient) { RootPart.SendFullUpdate(remoteClient); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (part != RootPart) part.SendFullUpdate(remoteClient); } } #region Copying /// /// Duplicates this object, including operations such as physics set up and attaching to the backup event. /// /// True if the duplicate will immediately be in the scene, false otherwise /// public SceneObjectGroup Copy(bool userExposed) { SceneObjectGroup dupe = (SceneObjectGroup)MemberwiseClone(); dupe.m_isBackedUp = false; dupe.m_parts = new MapAndArray(); // Warning, The following code related to previousAttachmentStatus is needed so that clones of // attachments do not bordercross while they're being duplicated. This is hacktastic! // Normally, setting AbsolutePosition will bordercross a prim if it's outside the region! // unless IsAttachment is true!, so to prevent border crossing, we save it's attachment state // (which should be false anyway) set it as an Attachment and then set it's Absolute Position, // then restore it's attachment state // This is only necessary when userExposed is false! bool previousAttachmentStatus = dupe.IsAttachment; if (!userExposed) dupe.IsAttachment = true; dupe.AbsolutePosition = new Vector3(AbsolutePosition.X, AbsolutePosition.Y, AbsolutePosition.Z); if (!userExposed) { dupe.IsAttachment = previousAttachmentStatus; } dupe.CopyRootPart(m_rootPart, OwnerID, GroupID, userExposed); dupe.m_rootPart.LinkNum = m_rootPart.LinkNum; if (userExposed) dupe.m_rootPart.TrimPermissions(); List partList = new List(m_parts.GetArray()); partList.Sort(delegate(SceneObjectPart p1, SceneObjectPart p2) { return p1.LinkNum.CompareTo(p2.LinkNum); } ); foreach (SceneObjectPart part in partList) { SceneObjectPart newPart; if (part.UUID != m_rootPart.UUID) { newPart = dupe.CopyPart(part, OwnerID, GroupID, userExposed); newPart.LinkNum = part.LinkNum; } else { newPart = dupe.m_rootPart; } // Need to duplicate the physics actor as well PhysicsActor originalPartPa = part.PhysActor; if (originalPartPa != null && userExposed) { PrimitiveBaseShape pbs = newPart.Shape; newPart.PhysActor = m_scene.PhysicsScene.AddPrimShape( string.Format("{0}/{1}", newPart.Name, newPart.UUID), pbs, newPart.AbsolutePosition, newPart.Scale, newPart.RotationOffset, originalPartPa.IsPhysical, newPart.LocalId); newPart.DoPhysicsPropertyUpdate(originalPartPa.IsPhysical, true); } } if (userExposed) { dupe.UpdateParentIDs(); dupe.HasGroupChanged = true; dupe.AttachToBackup(); ScheduleGroupForFullUpdate(); } return dupe; } /// /// Copy the given part as the root part of this scene object. /// /// /// /// public void CopyRootPart(SceneObjectPart part, UUID cAgentID, UUID cGroupID, bool userExposed) { SetRootPart(part.Copy(m_scene.AllocateLocalId(), OwnerID, GroupID, 0, userExposed)); } public void ScriptSetPhysicsStatus(bool usePhysics) { UpdatePrimFlags(RootPart.LocalId, usePhysics, IsTemporary, IsPhantom, IsVolumeDetect); } public void ScriptSetTemporaryStatus(bool makeTemporary) { UpdatePrimFlags(RootPart.LocalId, UsesPhysics, makeTemporary, IsPhantom, IsVolumeDetect); } public void ScriptSetPhantomStatus(bool makePhantom) { UpdatePrimFlags(RootPart.LocalId, UsesPhysics, IsTemporary, makePhantom, IsVolumeDetect); } public void ScriptSetVolumeDetect(bool makeVolumeDetect) { UpdatePrimFlags(RootPart.LocalId, UsesPhysics, IsTemporary, IsPhantom, makeVolumeDetect); /* ScriptSetPhantomStatus(false); // What ever it was before, now it's not phantom anymore if (PhysActor != null) // Should always be the case now { PhysActor.SetVolumeDetect(param); } if (param != 0) AddFlag(PrimFlags.Phantom); ScheduleFullUpdate(); */ } public void applyImpulse(Vector3 impulse) { if (IsAttachment) { ScenePresence avatar = m_scene.GetScenePresence(AttachedAvatar); if (avatar != null) { avatar.PushForce(impulse); } } else { PhysicsActor pa = RootPart.PhysActor; if (pa != null) { pa.AddForce(impulse, true); m_scene.PhysicsScene.AddPhysicsActorTaint(pa); } } } public void applyAngularImpulse(Vector3 impulse) { PhysicsActor pa = RootPart.PhysActor; if (pa != null) { if (!IsAttachment) { pa.AddAngularForce(impulse, true); m_scene.PhysicsScene.AddPhysicsActorTaint(pa); } } } public void setAngularImpulse(Vector3 impulse) { PhysicsActor pa = RootPart.PhysActor; if (pa != null) { if (!IsAttachment) { pa.Torque = impulse; m_scene.PhysicsScene.AddPhysicsActorTaint(pa); } } } public Vector3 GetTorque() { PhysicsActor pa = RootPart.PhysActor; if (pa != null) { if (!IsAttachment) { Vector3 torque = pa.Torque; return torque; } } return Vector3.Zero; } public void moveToTarget(Vector3 target, float tau) { if (IsAttachment) { ScenePresence avatar = m_scene.GetScenePresence(AttachedAvatar); if (avatar != null) { avatar.MoveToTarget(target, false, false); } } else { PhysicsActor pa = RootPart.PhysActor; if (pa != null) { pa.PIDTarget = target; pa.PIDTau = tau; pa.PIDActive = true; } } } public void stopMoveToTarget() { PhysicsActor pa = RootPart.PhysActor; if (pa != null) pa.PIDActive = false; } /// /// Uses a PID to attempt to clamp the object on the Z axis at the given height over tau seconds. /// /// Height to hover. Height of zero disables hover. /// Determines what the height is relative to /// Number of seconds over which to reach target public void SetHoverHeight(float height, PIDHoverType hoverType, float tau) { PhysicsActor pa = RootPart.PhysActor; if (pa != null) { if (height != 0f) { pa.PIDHoverHeight = height; pa.PIDHoverType = hoverType; pa.PIDTau = tau; pa.PIDHoverActive = true; } else { pa.PIDHoverActive = false; } } } /// /// Set the owner of the root part. /// /// /// /// public void SetRootPartOwner(SceneObjectPart part, UUID cAgentID, UUID cGroupID) { part.LastOwnerID = part.OwnerID; part.OwnerID = cAgentID; part.GroupID = cGroupID; if (part.OwnerID != cAgentID) { // Apply Next Owner Permissions if we're not bypassing permissions if (!m_scene.Permissions.BypassPermissions()) ApplyNextOwnerPermissions(); } part.ScheduleFullUpdate(); } /// /// Make a copy of the given part. /// /// /// /// public SceneObjectPart CopyPart(SceneObjectPart part, UUID cAgentID, UUID cGroupID, bool userExposed) { SceneObjectPart newPart = part.Copy(m_scene.AllocateLocalId(), OwnerID, GroupID, m_parts.Count, userExposed); AddPart(newPart); SetPartAsNonRoot(newPart); return newPart; } /// /// Reset the UUIDs for all the prims that make up this group. /// /// /// This is called by methods which want to add a new group to an existing scene, in order /// to ensure that there are no clashes with groups already present. /// public void ResetIDs() { lock (m_parts.SyncRoot) { List partsList = new List(m_parts.GetArray()); m_parts.Clear(); foreach (SceneObjectPart part in partsList) { part.ResetIDs(part.LinkNum); // Don't change link nums m_parts.Add(part.UUID, part); } } } /// /// /// /// public void ServiceObjectPropertiesFamilyRequest(IClientAPI remoteClient, UUID AgentID, uint RequestFlags) { remoteClient.SendObjectPropertiesFamilyData(RootPart, RequestFlags); // remoteClient.SendObjectPropertiesFamilyData(RequestFlags, RootPart.UUID, RootPart.OwnerID, RootPart.GroupID, RootPart.BaseMask, // RootPart.OwnerMask, RootPart.GroupMask, RootPart.EveryoneMask, RootPart.NextOwnerMask, // RootPart.OwnershipCost, RootPart.ObjectSaleType, RootPart.SalePrice, RootPart.Category, // RootPart.CreatorID, RootPart.Name, RootPart.Description); } public void SetPartOwner(SceneObjectPart part, UUID cAgentID, UUID cGroupID) { part.OwnerID = cAgentID; part.GroupID = cGroupID; } #endregion public override void Update() { // Check that the group was not deleted before the scheduled update // FIXME: This is merely a temporary measure to reduce the incidence of failure when // an object has been deleted from a scene before update was processed. // A more fundamental overhaul of the update mechanism is required to eliminate all // the race conditions. if (IsDeleted) return; // Even temporary objects take part in physics (e.g. temp-on-rez bullets) //if ((RootPart.Flags & PrimFlags.TemporaryOnRez) != 0) // return; // If we somehow got here to updating the SOG and its root part is not scheduled for update, // check to see if the physical position or rotation warrant an update. if (m_rootPart.UpdateFlag == UpdateRequired.NONE) { bool UsePhysics = ((RootPart.Flags & PrimFlags.Physics) != 0); if (UsePhysics && !AbsolutePosition.ApproxEquals(lastPhysGroupPos, 0.02f)) { m_rootPart.UpdateFlag = UpdateRequired.TERSE; lastPhysGroupPos = AbsolutePosition; } if (UsePhysics && !GroupRotation.ApproxEquals(lastPhysGroupRot, 0.1f)) { m_rootPart.UpdateFlag = UpdateRequired.TERSE; lastPhysGroupRot = GroupRotation; } } SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (!IsSelected) part.UpdateLookAt(); part.SendScheduledUpdates(); } } /// /// Schedule a full update for this scene object to all interested viewers. /// /// /// Ultimately, this should be managed such that region modules can invoke it at the end of a set of operations /// so that either all changes are sent at once. However, currently, a large amount of internal /// code will set this anyway when some object properties are changed. /// public void ScheduleGroupForFullUpdate() { // if (IsAttachment) // m_log.DebugFormat("[SOG]: Scheduling full update for {0} {1}", Name, LocalId); checkAtTargets(); RootPart.ScheduleFullUpdate(); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (part != RootPart) part.ScheduleFullUpdate(); } } /// /// Schedule a terse update for this scene object to all interested viewers. /// /// /// Ultimately, this should be managed such that region modules can invoke it at the end of a set of operations /// so that either all changes are sent at once. However, currently, a large amount of internal /// code will set this anyway when some object properties are changed. /// public void ScheduleGroupForTerseUpdate() { // m_log.DebugFormat("[SOG]: Scheduling terse update for {0} {1}", Name, UUID); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].ScheduleTerseUpdate(); } /// /// Immediately send a full update for this scene object. /// public void SendGroupFullUpdate() { if (IsDeleted) return; // m_log.DebugFormat("[SOG]: Sending immediate full group update for {0} {1}", Name, UUID); RootPart.SendFullUpdateToAllClients(); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (part != RootPart) part.SendFullUpdateToAllClients(); } } /// /// Immediately send an update for this scene object's root prim only. /// This is for updates regarding the object as a whole, and none of its parts in particular. /// Note: this may not be used by opensim (it probably should) but it's used by /// external modules. /// public void SendGroupRootTerseUpdate() { if (IsDeleted) return; RootPart.SendTerseUpdateToAllClients(); } public void QueueForUpdateCheck() { if (m_scene == null) // Need to check here as it's null during object creation return; m_scene.SceneGraph.AddToUpdateList(this); } /// /// Immediately send a terse update for this scene object. /// public void SendGroupTerseUpdate() { if (IsDeleted) return; SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].SendTerseUpdateToAllClients(); } /// /// Send metadata about the root prim (name, description, sale price, permissions, etc.) to a client. /// /// public void SendPropertiesToClient(IClientAPI client) { m_rootPart.SendPropertiesToClient(client); } #region SceneGroupPart Methods /// /// Get the child part by LinkNum /// /// /// null if no child part with that linknum or child part public SceneObjectPart GetLinkNumPart(int linknum) { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { if (parts[i].LinkNum == linknum) return parts[i]; } return null; } /// /// Get a part with a given UUID /// /// /// null if a child part with the primID was not found public SceneObjectPart GetChildPart(UUID primID) { SceneObjectPart childPart; m_parts.TryGetValue(primID, out childPart); return childPart; } /// /// Get a part with a given local ID /// /// /// null if a child part with the local ID was not found public SceneObjectPart GetChildPart(uint localID) { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { if (parts[i].LocalId == localID) return parts[i]; } return null; } /// /// Does this group contain the child prim /// should be able to remove these methods once we have a entity index in scene /// /// /// public bool HasChildPrim(UUID primID) { return m_parts.ContainsKey(primID); } /// /// Does this group contain the child prim /// should be able to remove these methods once we have a entity index in scene /// /// /// public bool HasChildPrim(uint localID) { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { if (parts[i].LocalId == localID) return true; } return false; } #endregion #region Packet Handlers /// /// Link the prims in a given group to this group /// /// /// Do not call this method directly - use Scene.LinkObjects() instead to avoid races between threads. /// FIXME: There are places where scripts call these methods directly without locking. This is a potential race condition. /// /// The group of prims which should be linked to this group public void LinkToGroup(SceneObjectGroup objectGroup) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Linking group with root part {0}, {1} to group with root part {2}, {3}", // objectGroup.RootPart.Name, objectGroup.RootPart.UUID, RootPart.Name, RootPart.UUID); // Linking to ourselves is not a valid operation. if (objectGroup == this) return; SceneObjectPart linkPart = objectGroup.m_rootPart; Vector3 oldGroupPosition = linkPart.GroupPosition; Quaternion oldRootRotation = linkPart.RotationOffset; linkPart.OffsetPosition = linkPart.GroupPosition - AbsolutePosition; linkPart.ParentID = m_rootPart.LocalId; linkPart.GroupPosition = AbsolutePosition; Vector3 axPos = linkPart.OffsetPosition; Quaternion parentRot = m_rootPart.RotationOffset; axPos *= Quaternion.Inverse(parentRot); linkPart.OffsetPosition = axPos; Quaternion oldRot = linkPart.RotationOffset; Quaternion newRot = Quaternion.Inverse(parentRot) * oldRot; linkPart.RotationOffset = newRot; linkPart.ParentID = m_rootPart.LocalId; if (m_rootPart.LinkNum == 0) m_rootPart.LinkNum = 1; lock (m_parts.SyncRoot) { int linkNum = PrimCount + 1; m_parts.Add(linkPart.UUID, linkPart); linkPart.SetParent(this); linkPart.CreateSelected = true; linkPart.LinkNum = linkNum++; linkPart.UpdatePrimFlags(UsesPhysics, IsTemporary, IsPhantom, IsVolumeDetect); SceneObjectPart[] ogParts = objectGroup.Parts; Array.Sort(ogParts, delegate(SceneObjectPart a, SceneObjectPart b) { return a.LinkNum - b.LinkNum; }); for (int i = 0; i < ogParts.Length; i++) { SceneObjectPart part = ogParts[i]; if (part.UUID != objectGroup.m_rootPart.UUID) LinkNonRootPart(part, oldGroupPosition, oldRootRotation, linkNum++); part.ClearUndoState(); } } m_scene.UnlinkSceneObject(objectGroup, true); objectGroup.IsDeleted = true; objectGroup.m_parts.Clear(); // Can't do this yet since backup still makes use of the root part without any synchronization // objectGroup.m_rootPart = null; AttachToBackup(); // Here's the deal, this is ABSOLUTELY CRITICAL so the physics scene gets the update about the // position of linkset prims. IF YOU CHANGE THIS, YOU MUST TEST colliding with just linked and // unmoved prims! ResetChildPrimPhysicsPositions(); //HasGroupChanged = true; //ScheduleGroupForFullUpdate(); } /// /// Delink the given prim from this group. The delinked prim is established as /// an independent SceneObjectGroup. /// /// /// FIXME: This method should not be called directly since it bypasses update locking, allowing a potential race /// condition. But currently there is no /// alternative method that does take a lonk to delink a single prim. /// /// /// The object group of the newly delinked prim. Null if part could not be found public SceneObjectGroup DelinkFromGroup(uint partID) { return DelinkFromGroup(partID, true); } /// /// Delink the given prim from this group. The delinked prim is established as /// an independent SceneObjectGroup. /// /// /// FIXME: This method should not be called directly since it bypasses update locking, allowing a potential race /// condition. But currently there is no /// alternative method that does take a lonk to delink a single prim. /// /// /// /// The object group of the newly delinked prim. Null if part could not be found public SceneObjectGroup DelinkFromGroup(uint partID, bool sendEvents) { SceneObjectPart linkPart = GetChildPart(partID); if (linkPart != null) { return DelinkFromGroup(linkPart, sendEvents); } else { m_log.WarnFormat("[SCENE OBJECT GROUP]: " + "DelinkFromGroup(): Child prim {0} not found in object {1}, {2}", partID, LocalId, UUID); return null; } } /// /// Delink the given prim from this group. The delinked prim is established as /// an independent SceneObjectGroup. /// /// /// FIXME: This method should not be called directly since it bypasses update locking, allowing a potential race /// condition. But currently there is no /// alternative method that does take a lonk to delink a single prim. /// /// /// /// The object group of the newly delinked prim. public SceneObjectGroup DelinkFromGroup(SceneObjectPart linkPart, bool sendEvents) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Delinking part {0}, {1} from group with root part {2}, {3}", // linkPart.Name, linkPart.UUID, RootPart.Name, RootPart.UUID); linkPart.ClearUndoState(); Quaternion worldRot = linkPart.GetWorldRotation(); // Remove the part from this object lock (m_parts.SyncRoot) { m_parts.Remove(linkPart.UUID); SceneObjectPart[] parts = m_parts.GetArray(); if (parts.Length == 1 && RootPart != null) { // Single prim left RootPart.LinkNum = 0; } else { for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (part.LinkNum > linkPart.LinkNum) part.LinkNum--; } } } linkPart.ParentID = 0; linkPart.LinkNum = 0; PhysicsActor linkPartPa = linkPart.PhysActor; if (linkPartPa != null) m_scene.PhysicsScene.RemovePrim(linkPartPa); // We need to reset the child part's position // ready for life as a separate object after being a part of another object Quaternion parentRot = m_rootPart.RotationOffset; Vector3 axPos = linkPart.OffsetPosition; axPos *= parentRot; linkPart.OffsetPosition = new Vector3(axPos.X, axPos.Y, axPos.Z); linkPart.GroupPosition = AbsolutePosition + linkPart.OffsetPosition; linkPart.OffsetPosition = new Vector3(0, 0, 0); linkPart.RotationOffset = worldRot; SceneObjectGroup objectGroup = new SceneObjectGroup(linkPart); m_scene.AddNewSceneObject(objectGroup, true); if (sendEvents) linkPart.TriggerScriptChangedEvent(Changed.LINK); linkPart.Rezzed = RootPart.Rezzed; // When we delete a group, we currently have to force persist to the database if the object id has changed // (since delete works by deleting all rows which have a given object id) objectGroup.HasGroupChangedDueToDelink = true; return objectGroup; } /// /// Stop this object from being persisted over server restarts. /// /// public virtual void DetachFromBackup() { if (m_isBackedUp && Scene != null) m_scene.EventManager.OnBackup -= ProcessBackup; m_isBackedUp = false; } private void LinkNonRootPart(SceneObjectPart part, Vector3 oldGroupPosition, Quaternion oldGroupRotation, int linkNum) { Quaternion parentRot = oldGroupRotation; Quaternion oldRot = part.RotationOffset; Quaternion worldRot = parentRot * oldRot; parentRot = oldGroupRotation; Vector3 axPos = part.OffsetPosition; axPos *= parentRot; part.OffsetPosition = axPos; part.GroupPosition = oldGroupPosition + part.OffsetPosition; part.OffsetPosition = Vector3.Zero; part.RotationOffset = worldRot; part.SetParent(this); part.ParentID = m_rootPart.LocalId; m_parts.Add(part.UUID, part); part.LinkNum = linkNum; part.OffsetPosition = part.GroupPosition - AbsolutePosition; Quaternion rootRotation = m_rootPart.RotationOffset; Vector3 pos = part.OffsetPosition; pos *= Quaternion.Inverse(rootRotation); part.OffsetPosition = pos; parentRot = m_rootPart.RotationOffset; oldRot = part.RotationOffset; Quaternion newRot = Quaternion.Inverse(parentRot) * oldRot; part.RotationOffset = newRot; part.UpdatePrimFlags(UsesPhysics, IsTemporary, IsPhantom, IsVolumeDetect); } /// /// If object is physical, apply force to move it around /// If object is not physical, just put it at the resulting location /// /// Always seems to be 0,0,0, so ignoring /// New position. We do the math here to turn it into a force /// public void GrabMovement(Vector3 offset, Vector3 pos, IClientAPI remoteClient) { if (m_scene.EventManager.TriggerGroupMove(UUID, pos)) { PhysicsActor pa = m_rootPart.PhysActor; if (pa != null) { if (pa.IsPhysical) { if (!m_rootPart.BlockGrab) { Vector3 llmoveforce = pos - AbsolutePosition; Vector3 grabforce = llmoveforce; grabforce = (grabforce / 10) * pa.Mass; pa.AddForce(grabforce, true); m_scene.PhysicsScene.AddPhysicsActorTaint(pa); } } else { //NonPhysicalGrabMovement(pos); } } else { //NonPhysicalGrabMovement(pos); } } } public void NonPhysicalGrabMovement(Vector3 pos) { AbsolutePosition = pos; m_rootPart.SendTerseUpdateToAllClients(); } /// /// If object is physical, prepare for spinning torques (set flag to save old orientation) /// /// Rotation. We do the math here to turn it into a torque /// public void SpinStart(IClientAPI remoteClient) { if (m_scene.EventManager.TriggerGroupSpinStart(UUID)) { PhysicsActor pa = m_rootPart.PhysActor; if (pa != null) { if (pa.IsPhysical) { m_rootPart.IsWaitingForFirstSpinUpdatePacket = true; } } } } /// /// If object is physical, apply torque to spin it around /// /// Rotation. We do the math here to turn it into a torque /// public void SpinMovement(Quaternion newOrientation, IClientAPI remoteClient) { // The incoming newOrientation, sent by the client, "seems" to be the // desired target orientation. This needs further verification; in particular, // one would expect that the initial incoming newOrientation should be // fairly close to the original prim's physical orientation, // m_rootPart.PhysActor.Orientation. This however does not seem to be the // case (might just be an issue with different quaternions representing the // same rotation, or it might be a coordinate system issue). // // Since it's not clear what the relationship is between the PhysActor.Orientation // and the incoming orientations sent by the client, we take an alternative approach // of calculating the delta rotation between the orientations being sent by the // client. (Since a spin is invoked by ctrl+shift+drag in the client, we expect // a steady stream of several new orientations coming in from the client.) // This ensures that the delta rotations are being calculated from self-consistent // pairs of old/new rotations. Given the delta rotation, we apply a torque around // the delta rotation axis, scaled by the object mass times an arbitrary scaling // factor (to ensure the resulting torque is not "too strong" or "too weak"). // // Ideally we need to calculate (probably iteratively) the exact torque or series // of torques needed to arrive exactly at the destination orientation. However, since // it is not yet clear how to map the destination orientation (provided by the viewer) // into PhysActor orientations (needed by the physics engine), we omit this step. // This means that the resulting torque will at least be in the correct direction, // but it will result in over-shoot or under-shoot of the target orientation. // For the end user, this means that ctrl+shift+drag can be used for relative, // but not absolute, adjustments of orientation for physical prims. if (m_scene.EventManager.TriggerGroupSpin(UUID, newOrientation)) { PhysicsActor pa = m_rootPart.PhysActor; if (pa != null) { if (pa.IsPhysical) { if (m_rootPart.IsWaitingForFirstSpinUpdatePacket) { // first time initialization of "old" orientation for calculation of delta rotations m_rootPart.SpinOldOrientation = newOrientation; m_rootPart.IsWaitingForFirstSpinUpdatePacket = false; } else { // save and update old orientation Quaternion old = m_rootPart.SpinOldOrientation; m_rootPart.SpinOldOrientation = newOrientation; //m_log.Error("[SCENE OBJECT GROUP]: Old orientation is " + old); //m_log.Error("[SCENE OBJECT GROUP]: Incoming new orientation is " + newOrientation); // compute difference between previous old rotation and new incoming rotation Quaternion minimalRotationFromQ1ToQ2 = Quaternion.Inverse(old) * newOrientation; float rotationAngle; Vector3 rotationAxis; minimalRotationFromQ1ToQ2.GetAxisAngle(out rotationAxis, out rotationAngle); rotationAxis.Normalize(); //m_log.Error("SCENE OBJECT GROUP]: rotation axis is " + rotationAxis); Vector3 spinforce = new Vector3(rotationAxis.X, rotationAxis.Y, rotationAxis.Z); spinforce = (spinforce/8) * pa.Mass; // 8 is an arbitrary torque scaling factor pa.AddAngularForce(spinforce,true); m_scene.PhysicsScene.AddPhysicsActorTaint(pa); } } else { //NonPhysicalSpinMovement(pos); } } else { //NonPhysicalSpinMovement(pos); } } } /// /// Set the name of a prim /// /// /// public void SetPartName(string name, uint localID) { SceneObjectPart part = GetChildPart(localID); if (part != null) { part.Name = name; } } public void SetPartDescription(string des, uint localID) { SceneObjectPart part = GetChildPart(localID); if (part != null) { part.Description = des; } } public void SetPartText(string text, uint localID) { SceneObjectPart part = GetChildPart(localID); if (part != null) { part.SetText(text); } } public void SetPartText(string text, UUID partID) { SceneObjectPart part = GetChildPart(partID); if (part != null) { part.SetText(text); } } public string GetPartName(uint localID) { SceneObjectPart part = GetChildPart(localID); if (part != null) { return part.Name; } return String.Empty; } public string GetPartDescription(uint localID) { SceneObjectPart part = GetChildPart(localID); if (part != null) { return part.Description; } return String.Empty; } /// /// Update prim flags for this group. /// /// /// /// /// /// public void UpdatePrimFlags(uint localID, bool UsePhysics, bool SetTemporary, bool SetPhantom, bool SetVolumeDetect) { SceneObjectPart selectionPart = GetChildPart(localID); if (SetTemporary && Scene != null) { DetachFromBackup(); // Remove from database and parcel prim count // m_scene.DeleteFromStorage(UUID); m_scene.EventManager.TriggerParcelPrimCountTainted(); } if (selectionPart != null) { SceneObjectPart[] parts = m_parts.GetArray(); if (Scene != null) { for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; if (part.Scale.X > m_scene.m_maxPhys || part.Scale.Y > m_scene.m_maxPhys || part.Scale.Z > m_scene.m_maxPhys ) { UsePhysics = false; // Reset physics break; } } } for (int i = 0; i < parts.Length; i++) parts[i].UpdatePrimFlags(UsePhysics, SetTemporary, SetPhantom, SetVolumeDetect); } } public void UpdateExtraParam(uint localID, ushort type, bool inUse, byte[] data) { SceneObjectPart part = GetChildPart(localID); if (part != null) { part.UpdateExtraParam(type, inUse, data); } } /// /// Update the texture entry for this part /// /// /// public void UpdateTextureEntry(uint localID, byte[] textureEntry) { SceneObjectPart part = GetChildPart(localID); if (part != null) { part.UpdateTextureEntry(textureEntry); } } public void UpdatePermissions(UUID AgentID, byte field, uint localID, uint mask, byte addRemTF) { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].UpdatePermissions(AgentID, field, localID, mask, addRemTF); HasGroupChanged = true; // Send the group's properties to all clients once all parts are updated IClientAPI client; if (Scene.TryGetClient(AgentID, out client)) SendPropertiesToClient(client); } #endregion #region Shape /// /// /// /// public void UpdateShape(ObjectShapePacket.ObjectDataBlock shapeBlock, uint localID) { SceneObjectPart part = GetChildPart(localID); if (part != null) { part.UpdateShape(shapeBlock); PhysicsActor pa = m_rootPart.PhysActor; if (pa != null) m_scene.PhysicsScene.AddPhysicsActorTaint(pa); } } #endregion #region Resize /// /// Resize the entire group of prims. /// /// public void GroupResize(Vector3 scale) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Group resizing {0} {1} from {2} to {3}", Name, LocalId, RootPart.Scale, scale); RootPart.StoreUndoState(true); scale.X = Math.Min(scale.X, Scene.m_maxNonphys); scale.Y = Math.Min(scale.Y, Scene.m_maxNonphys); scale.Z = Math.Min(scale.Z, Scene.m_maxNonphys); PhysicsActor pa = m_rootPart.PhysActor; if (pa != null && pa.IsPhysical) { scale.X = Math.Min(scale.X, Scene.m_maxPhys); scale.Y = Math.Min(scale.Y, Scene.m_maxPhys); scale.Z = Math.Min(scale.Z, Scene.m_maxPhys); } float x = (scale.X / RootPart.Scale.X); float y = (scale.Y / RootPart.Scale.Y); float z = (scale.Z / RootPart.Scale.Z); SceneObjectPart[] parts; if (x > 1.0f || y > 1.0f || z > 1.0f) { parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart obPart = parts[i]; if (obPart.UUID != m_rootPart.UUID) { // obPart.IgnoreUndoUpdate = true; Vector3 oldSize = new Vector3(obPart.Scale); float f = 1.0f; float a = 1.0f; if (pa != null && pa.IsPhysical) { if (oldSize.X * x > m_scene.m_maxPhys) { f = m_scene.m_maxPhys / oldSize.X; a = f / x; x *= a; y *= a; z *= a; } if (oldSize.Y * y > m_scene.m_maxPhys) { f = m_scene.m_maxPhys / oldSize.Y; a = f / y; x *= a; y *= a; z *= a; } if (oldSize.Z * z > m_scene.m_maxPhys) { f = m_scene.m_maxPhys / oldSize.Z; a = f / z; x *= a; y *= a; z *= a; } } else { if (oldSize.X * x > m_scene.m_maxNonphys) { f = m_scene.m_maxNonphys / oldSize.X; a = f / x; x *= a; y *= a; z *= a; } if (oldSize.Y * y > m_scene.m_maxNonphys) { f = m_scene.m_maxNonphys / oldSize.Y; a = f / y; x *= a; y *= a; z *= a; } if (oldSize.Z * z > m_scene.m_maxNonphys) { f = m_scene.m_maxNonphys / oldSize.Z; a = f / z; x *= a; y *= a; z *= a; } } // obPart.IgnoreUndoUpdate = false; } } } Vector3 prevScale = RootPart.Scale; prevScale.X *= x; prevScale.Y *= y; prevScale.Z *= z; // RootPart.IgnoreUndoUpdate = true; RootPart.Resize(prevScale); // RootPart.IgnoreUndoUpdate = false; parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart obPart = parts[i]; if (obPart.UUID != m_rootPart.UUID) { obPart.IgnoreUndoUpdate = true; Vector3 currentpos = new Vector3(obPart.OffsetPosition); currentpos.X *= x; currentpos.Y *= y; currentpos.Z *= z; Vector3 newSize = new Vector3(obPart.Scale); newSize.X *= x; newSize.Y *= y; newSize.Z *= z; obPart.Resize(newSize); obPart.UpdateOffSet(currentpos); obPart.IgnoreUndoUpdate = false; } // obPart.IgnoreUndoUpdate = false; // obPart.StoreUndoState(); } // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Finished group resizing {0} {1} to {2}", Name, LocalId, RootPart.Scale); } #endregion #region Position /// /// Move this scene object /// /// public void UpdateGroupPosition(Vector3 pos) { // m_log.DebugFormat("[SCENE OBJECT GROUP]: Updating group position on {0} {1} to {2}", Name, LocalId, pos); RootPart.StoreUndoState(true); // SceneObjectPart[] parts = m_parts.GetArray(); // for (int i = 0; i < parts.Length; i++) // parts[i].StoreUndoState(); if (m_scene.EventManager.TriggerGroupMove(UUID, pos)) { if (IsAttachment) { m_rootPart.AttachedPos = pos; } if (RootPart.GetStatusSandbox()) { if (Util.GetDistanceTo(RootPart.StatusSandboxPos, pos) > 10) { RootPart.ScriptSetPhysicsStatus(false); pos = AbsolutePosition; Scene.SimChat(Utils.StringToBytes("Hit Sandbox Limit"), ChatTypeEnum.DebugChannel, 0x7FFFFFFF, RootPart.AbsolutePosition, Name, UUID, false); } } AbsolutePosition = pos; HasGroupChanged = true; } //we need to do a terse update even if the move wasn't allowed // so that the position is reset in the client (the object snaps back) ScheduleGroupForTerseUpdate(); } /// /// Update the position of a single part of this scene object /// /// /// public void UpdateSinglePosition(Vector3 pos, uint localID) { SceneObjectPart part = GetChildPart(localID); // SceneObjectPart[] parts = m_parts.GetArray(); // for (int i = 0; i < parts.Length; i++) // parts[i].StoreUndoState(); if (part != null) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Updating single position of {0} {1} to {2}", part.Name, part.LocalId, pos); part.StoreUndoState(false); part.IgnoreUndoUpdate = true; if (part.UUID == m_rootPart.UUID) { UpdateRootPosition(pos); } else { part.UpdateOffSet(pos); } HasGroupChanged = true; part.IgnoreUndoUpdate = false; } } /// /// Update just the root prim position in a linkset /// /// public void UpdateRootPosition(Vector3 pos) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Updating root position of {0} {1} to {2}", Name, LocalId, pos); // SceneObjectPart[] parts = m_parts.GetArray(); // for (int i = 0; i < parts.Length; i++) // parts[i].StoreUndoState(); Vector3 newPos = new Vector3(pos.X, pos.Y, pos.Z); Vector3 oldPos = new Vector3(AbsolutePosition.X + m_rootPart.OffsetPosition.X, AbsolutePosition.Y + m_rootPart.OffsetPosition.Y, AbsolutePosition.Z + m_rootPart.OffsetPosition.Z); Vector3 diff = oldPos - newPos; Vector3 axDiff = new Vector3(diff.X, diff.Y, diff.Z); Quaternion partRotation = m_rootPart.RotationOffset; axDiff *= Quaternion.Inverse(partRotation); diff = axDiff; SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart obPart = parts[i]; if (obPart.UUID != m_rootPart.UUID) obPart.OffsetPosition = obPart.OffsetPosition + diff; } AbsolutePosition = newPos; HasGroupChanged = true; ScheduleGroupForTerseUpdate(); } #endregion #region Rotation /// /// Update the rotation of the group. /// /// public void UpdateGroupRotationR(Quaternion rot) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Updating group rotation R of {0} {1} to {2}", Name, LocalId, rot); // SceneObjectPart[] parts = m_parts.GetArray(); // for (int i = 0; i < parts.Length; i++) // parts[i].StoreUndoState(); m_rootPart.StoreUndoState(true); m_rootPart.UpdateRotation(rot); PhysicsActor actor = m_rootPart.PhysActor; if (actor != null) { actor.Orientation = m_rootPart.RotationOffset; m_scene.PhysicsScene.AddPhysicsActorTaint(actor); } HasGroupChanged = true; ScheduleGroupForTerseUpdate(); } /// /// Update the position and rotation of a group simultaneously. /// /// /// public void UpdateGroupRotationPR(Vector3 pos, Quaternion rot) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Updating group rotation PR of {0} {1} to {2}", Name, LocalId, rot); // SceneObjectPart[] parts = m_parts.GetArray(); // for (int i = 0; i < parts.Length; i++) // parts[i].StoreUndoState(); RootPart.StoreUndoState(true); RootPart.IgnoreUndoUpdate = true; m_rootPart.UpdateRotation(rot); PhysicsActor actor = m_rootPart.PhysActor; if (actor != null) { actor.Orientation = m_rootPart.RotationOffset; m_scene.PhysicsScene.AddPhysicsActorTaint(actor); } if (IsAttachment) { m_rootPart.AttachedPos = pos; } AbsolutePosition = pos; HasGroupChanged = true; ScheduleGroupForTerseUpdate(); RootPart.IgnoreUndoUpdate = false; } /// /// Update the rotation of a single prim within the group. /// /// /// public void UpdateSingleRotation(Quaternion rot, uint localID) { SceneObjectPart part = GetChildPart(localID); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].StoreUndoState(); if (part != null) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Updating single rotation of {0} {1} to {2}", part.Name, part.LocalId, rot); if (part.UUID == m_rootPart.UUID) { UpdateRootRotation(rot); } else { part.UpdateRotation(rot); } } } /// /// Update the position and rotation simultaneously of a single prim within the group. /// /// /// public void UpdateSingleRotation(Quaternion rot, Vector3 pos, uint localID) { SceneObjectPart part = GetChildPart(localID); if (part != null) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Updating single position and rotation of {0} {1} to {2}", // part.Name, part.LocalId, rot); part.StoreUndoState(); part.IgnoreUndoUpdate = true; if (part.UUID == m_rootPart.UUID) { UpdateRootRotation(rot); AbsolutePosition = pos; } else { part.UpdateRotation(rot); part.OffsetPosition = pos; } part.IgnoreUndoUpdate = false; } } /// /// Update the rotation of just the root prim of a linkset. /// /// public void UpdateRootRotation(Quaternion rot) { // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Updating root rotation of {0} {1} to {2}", // Name, LocalId, rot); Quaternion axRot = rot; Quaternion oldParentRot = m_rootPart.RotationOffset; m_rootPart.StoreUndoState(); m_rootPart.UpdateRotation(rot); PhysicsActor pa = m_rootPart.PhysActor; if (pa != null) { pa.Orientation = m_rootPart.RotationOffset; m_scene.PhysicsScene.AddPhysicsActorTaint(pa); } SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart prim = parts[i]; if (prim.UUID != m_rootPart.UUID) { prim.IgnoreUndoUpdate = true; Vector3 axPos = prim.OffsetPosition; axPos *= oldParentRot; axPos *= Quaternion.Inverse(axRot); prim.OffsetPosition = axPos; Quaternion primsRot = prim.RotationOffset; Quaternion newRot = oldParentRot * primsRot; newRot = Quaternion.Inverse(axRot) * newRot; prim.RotationOffset = newRot; prim.ScheduleTerseUpdate(); prim.IgnoreUndoUpdate = false; } } // for (int i = 0; i < parts.Length; i++) // { // SceneObjectPart childpart = parts[i]; // if (childpart != m_rootPart) // { //// childpart.IgnoreUndoUpdate = false; //// childpart.StoreUndoState(); // } // } m_rootPart.ScheduleTerseUpdate(); // m_log.DebugFormat( // "[SCENE OBJECT GROUP]: Updated root rotation of {0} {1} to {2}", // Name, LocalId, rot); } #endregion internal void SetAxisRotation(int axis, int rotate10) { bool setX = false; bool setY = false; bool setZ = false; int xaxis = 2; int yaxis = 4; int zaxis = 8; setX = ((axis & xaxis) != 0) ? true : false; setY = ((axis & yaxis) != 0) ? true : false; setZ = ((axis & zaxis) != 0) ? true : false; float setval = (rotate10 > 0) ? 1f : 0f; if (setX) RootPart.RotationAxis.X = setval; if (setY) RootPart.RotationAxis.Y = setval; if (setZ) RootPart.RotationAxis.Z = setval; if (setX || setY || setZ) RootPart.SetPhysicsAxisRotation(); } public int registerRotTargetWaypoint(Quaternion target, float tolerance) { scriptRotTarget waypoint = new scriptRotTarget(); waypoint.targetRot = target; waypoint.tolerance = tolerance; uint handle = m_scene.AllocateLocalId(); waypoint.handle = handle; lock (m_rotTargets) { m_rotTargets.Add(handle, waypoint); } m_scene.AddGroupTarget(this); return (int)handle; } public void unregisterRotTargetWaypoint(int handle) { lock (m_targets) { m_rotTargets.Remove((uint)handle); if (m_targets.Count == 0) m_scene.RemoveGroupTarget(this); } } public int registerTargetWaypoint(Vector3 target, float tolerance) { scriptPosTarget waypoint = new scriptPosTarget(); waypoint.targetPos = target; waypoint.tolerance = tolerance; uint handle = m_scene.AllocateLocalId(); waypoint.handle = handle; lock (m_targets) { m_targets.Add(handle, waypoint); } m_scene.AddGroupTarget(this); return (int)handle; } public void unregisterTargetWaypoint(int handle) { lock (m_targets) { m_targets.Remove((uint)handle); if (m_targets.Count == 0) m_scene.RemoveGroupTarget(this); } } public void checkAtTargets() { if (m_scriptListens_atTarget || m_scriptListens_notAtTarget) { if (m_targets.Count > 0) { bool at_target = false; //Vector3 targetPos; //uint targetHandle; Dictionary atTargets = new Dictionary(); lock (m_targets) { foreach (uint idx in m_targets.Keys) { scriptPosTarget target = m_targets[idx]; if (Util.GetDistanceTo(target.targetPos, m_rootPart.GroupPosition) <= target.tolerance) { // trigger at_target if (m_scriptListens_atTarget) { at_target = true; scriptPosTarget att = new scriptPosTarget(); att.targetPos = target.targetPos; att.tolerance = target.tolerance; att.handle = target.handle; atTargets.Add(idx, att); } } } } if (atTargets.Count > 0) { SceneObjectPart[] parts = m_parts.GetArray(); uint[] localids = new uint[parts.Length]; for (int i = 0; i < parts.Length; i++) localids[i] = parts[i].LocalId; for (int ctr = 0; ctr < localids.Length; ctr++) { foreach (uint target in atTargets.Keys) { scriptPosTarget att = atTargets[target]; m_scene.EventManager.TriggerAtTargetEvent( localids[ctr], att.handle, att.targetPos, m_rootPart.GroupPosition); } } return; } if (m_scriptListens_notAtTarget && !at_target) { //trigger not_at_target SceneObjectPart[] parts = m_parts.GetArray(); uint[] localids = new uint[parts.Length]; for (int i = 0; i < parts.Length; i++) localids[i] = parts[i].LocalId; for (int ctr = 0; ctr < localids.Length; ctr++) { m_scene.EventManager.TriggerNotAtTargetEvent(localids[ctr]); } } } } if (m_scriptListens_atRotTarget || m_scriptListens_notAtRotTarget) { if (m_rotTargets.Count > 0) { bool at_Rottarget = false; Dictionary atRotTargets = new Dictionary(); lock (m_rotTargets) { foreach (uint idx in m_rotTargets.Keys) { scriptRotTarget target = m_rotTargets[idx]; double angle = Math.Acos( target.targetRot.X * m_rootPart.RotationOffset.X + target.targetRot.Y * m_rootPart.RotationOffset.Y + target.targetRot.Z * m_rootPart.RotationOffset.Z + target.targetRot.W * m_rootPart.RotationOffset.W) * 2; if (angle < 0) angle = -angle; if (angle > Math.PI) angle = (Math.PI * 2 - angle); if (angle <= target.tolerance) { // trigger at_rot_target if (m_scriptListens_atRotTarget) { at_Rottarget = true; scriptRotTarget att = new scriptRotTarget(); att.targetRot = target.targetRot; att.tolerance = target.tolerance; att.handle = target.handle; atRotTargets.Add(idx, att); } } } } if (atRotTargets.Count > 0) { SceneObjectPart[] parts = m_parts.GetArray(); uint[] localids = new uint[parts.Length]; for (int i = 0; i < parts.Length; i++) localids[i] = parts[i].LocalId; for (int ctr = 0; ctr < localids.Length; ctr++) { foreach (uint target in atRotTargets.Keys) { scriptRotTarget att = atRotTargets[target]; m_scene.EventManager.TriggerAtRotTargetEvent( localids[ctr], att.handle, att.targetRot, m_rootPart.RotationOffset); } } return; } if (m_scriptListens_notAtRotTarget && !at_Rottarget) { //trigger not_at_target SceneObjectPart[] parts = m_parts.GetArray(); uint[] localids = new uint[parts.Length]; for (int i = 0; i < parts.Length; i++) localids[i] = parts[i].LocalId; for (int ctr = 0; ctr < localids.Length; ctr++) { m_scene.EventManager.TriggerNotAtRotTargetEvent(localids[ctr]); } } } } } public float GetMass() { float retmass = 0f; SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) retmass += parts[i].GetMass(); return retmass; } /// /// If the object is a sculpt/mesh, retrieve the mesh data for each part and reinsert it into each shape so that /// the physics engine can use it. /// /// /// When the physics engine has finished with it, the sculpt data is discarded to save memory. /// public void CheckSculptAndLoad() { if (IsDeleted) return; if ((RootPart.GetEffectiveObjectFlags() & (uint)PrimFlags.Phantom) != 0) return; // m_log.Debug("Processing CheckSculptAndLoad for {0} {1}", Name, LocalId); SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].CheckSculptAndLoad(); } /// /// Set the user group to which this scene object belongs. /// /// /// public void SetGroup(UUID GroupID, IClientAPI client) { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) { SceneObjectPart part = parts[i]; part.SetGroup(GroupID, client); part.Inventory.ChangeInventoryGroup(GroupID); } HasGroupChanged = true; // Don't trigger the update here - otherwise some client issues occur when multiple updates are scheduled // for the same object with very different properties. The caller must schedule the update. //ScheduleGroupForFullUpdate(); } public void TriggerScriptChangedEvent(Changed val) { SceneObjectPart[] parts = m_parts.GetArray(); for (int i = 0; i < parts.Length; i++) parts[i].TriggerScriptChangedEvent(val); } /// /// Gets the number of sitting avatars. /// /// This applies to all sitting avatars whether there is a sit target set or not. /// public int GetSittingAvatarsCount() { int count = 0; Array.ForEach(m_parts.GetArray(), p => count += p.GetSittingAvatarsCount()); return count; } public override string ToString() { return String.Format("{0} {1} ({2})", Name, UUID, AbsolutePosition); } #region ISceneObject public virtual ISceneObject CloneForNewScene() { SceneObjectGroup sog = Copy(false); sog.IsDeleted = false; return sog; } public virtual string ToXml2() { return SceneObjectSerializer.ToXml2Format(this); } public virtual string ExtraToXmlString() { return "" + FromItemID.ToString() + ""; } public virtual void ExtraFromXmlString(string xmlstr) { string id = xmlstr.Substring(xmlstr.IndexOf("")); id = xmlstr.Replace("", ""); id = id.Replace("", ""); UUID uuid = UUID.Zero; UUID.TryParse(id, out uuid); FromItemID = uuid; } #endregion } }