// Copyright (c) 2019 Lawnjelly // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // The above copyright notice and this permission notice shall be included in all // copies or substantial portions of the Software. // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE // SOFTWARE. #include "lroom_converter.h" #include "lroom_manager.h" #include "lportal.h" #include "scene/3d/mesh_instance.h" #include "core/math/quick_hull.h" #include "ldebug.h" #include "scene/3d/light.h" // save typing, I am lazy #define LMAN m_pManager #define LROOMLIST m_pRoomList void LRoomConverter::Convert(LRoomManager &manager, bool bVerbose, bool bPreparationRun, bool bDeleteLights, bool bSingleRoomMode) { m_bFinalRun = (bPreparationRun == false); m_bDeleteLights = bDeleteLights; m_bSingleRoomMode = bSingleRoomMode; // This just is simply used to set how much debugging output .. more during conversion, less during running // except when requested by explicitly clearing this flag. Lawn::LDebug::m_bRunning = (bVerbose == false); if (!m_bFinalRun) { LPRINT(5, "running convert PREPARATION RUN"); } else { LPRINT(5, "running convert"); } LMAN = &manager; LROOMLIST = manager.GetRoomList(); // force clear all arrays manager.ReleaseResources(true); int count = CountRooms(); //int num_global_lights = LMAN->m_Lights.size(); // make sure bitfield is right size for number of rooms LMAN->m_BF_visible_rooms.Create(count); LMAN->m_LightRender.m_BF_Temp_Visible_Rooms.Create(count); LMAN->m_Rooms.resize(count); m_TempRooms.clear(true); m_TempRooms.resize(count); Convert_Rooms(); Convert_Portals(); Convert_Bounds(); // make sure manager bitfields are the correct size for number of objects int num_sobs = LMAN->m_SOBs.size(); LPRINT(5,"Total SOBs " + itos(num_sobs)); LMAN->m_BF_caster_SOBs.Create(num_sobs); LMAN->m_BF_visible_SOBs.Create(num_sobs); LMAN->m_BF_master_SOBs.Create(num_sobs); LMAN->m_BF_master_SOBs_prev.Create(num_sobs); LMAN->m_LightRender.m_BF_Temp_SOBs.Create(num_sobs); LMAN->m_BF_ActiveLights.Create(LMAN->m_Lights.size()); LMAN->m_BF_ActiveLights_prev.Create(LMAN->m_Lights.size()); LMAN->m_BF_ProcessedLights.Create(LMAN->m_Lights.size()); // must be done after the bitfields Convert_Lights(); Convert_ShadowCasters(); Convert_AreaLights(); // hide all in preparation for first frame //LMAN->ShowAll(false); // temp rooms no longer needed m_TempRooms.clear(true); // clear out the local room lights, leave only global lights //LMAN->m_Lights.resize(num_global_lights); Lawn::LDebug::m_bRunning = true; } int LRoomConverter::Convert_Rooms_Recursive(Node * pParent, int count, int area) { for (int n=0; nget_child_count(); n++) { Node * pChild = pParent->get_child(n); if (Node_IsRoom(pChild)) { Spatial * pSpat = Object::cast_to(pChild); assert (pSpat); Convert_Room(pSpat, count++, area); } else if (Node_IsArea(pChild)) { // get the area name String szArea = LPortal::FindNameAfter(pChild, "area_"); // find or create an area with this name int area_child = Area_FindOrCreate(szArea); count = Convert_Rooms_Recursive(pChild, count, area_child); } } return count; } void LRoomConverter::Convert_Rooms() { LPRINT(5,"Convert_Rooms"); // allow faking a single room in single room mode if (m_bSingleRoomMode) { Spatial * pSpat = Object::cast_to(LROOMLIST); if (!pSpat) return; // add a default area int area = Area_FindOrCreate("default"); Convert_Room(pSpat, 0, area); return; } // first find all room empties and convert to LRooms int count = 0; int area = -1; count = Convert_Rooms_Recursive(LROOMLIST, count, area); } int LRoomConverter::Area_FindOrCreate(String szName) { for (int n=0; nm_Areas.size(); n++) { if (LMAN->m_Areas[n].m_szName == szName) return n; } // create LArea area; area.Create(szName); LMAN->m_Areas.push_back(area); return LMAN->m_Areas.size() - 1; } int LRoomConverter::FindRoom_ByName(String szName) const { for (int n=0; nm_Rooms.size(); n++) { if (LMAN->m_Rooms[n].m_szName == szName) return n; } return -1; } void LRoomConverter::Convert_Room_SetDefaultCullMask_Recursive(Node * pParent) { int nChildren = pParent->get_child_count(); for (int n=0; nget_child(n); // default cull mask should always be visible to camera and lights VisualInstance * pVI = Object::cast_to(pChild); if (pVI) { // LRoom::SoftShow(pVI, LRoom::LAYER_MASK_CAMERA | LRoom::LAYER_MASK_LIGHT); } Convert_Room_SetDefaultCullMask_Recursive(pChild); } } void LRoomConverter::Convert_Room_FindObjects_Recursive(Node * pParent, LRoom &lroom, LAABB &bb_room) { int nChildren = pParent->get_child_count(); for (int n=0; nget_child(n); // ignore invisible Spatial * pSpatialChild = Object::cast_to(pChild); if (pSpatialChild && (pSpatialChild->is_visible_in_tree() == false)) { pSpatialChild->queue_delete(); continue; } // we are not interested in portal meshes, as they will be deleted later in conversion if (Node_IsPortal(pChild)) continue; // we can optionally ignore nodes (they will still be shown / hidden with the room though) if (Node_IsIgnore(pChild)) continue; // not interested in bounds if (Node_IsBound(pChild)) continue; // lights if (Node_IsLight(pChild)) { LRoom_DetectedLight(lroom, pChild); continue; } // area if (Node_IsArea(pChild)) { LRoom_DetectedArea(lroom, pChild); continue; } VisualInstance * pVI = Object::cast_to(pChild); if (pVI) { LPRINT(2, "\t\tFound VI : " + pVI->get_name()); // update bound to find centre of room roughly AABB bb = pVI->get_transformed_aabb(); bb_room.ExpandToEnclose(bb); // store some info about the static object for use at runtime LSob sob; sob.m_ID = pVI->get_instance_id(); sob.m_aabb = bb; sob.Hidable_Create(pChild); //lroom.m_SOBs.push_back(sob); LRoom_PushBackSOB(lroom, sob); // take away layer 0 from the sob, so it can be culled effectively if (m_bFinalRun) { pVI->set_layer_mask(0); } } else { // not visual instances } // does it have further children? Convert_Room_FindObjects_Recursive(pChild, lroom, bb_room); } } // areaID could be -1 if unset bool LRoomConverter::Convert_Room(Spatial * pNode, int lroomID, int areaID) { // get the room part of the name String szFullName = pNode->get_name(); String szRoom = LPortal::FindNameAfter(pNode, "room_"); if (areaID == -1) { LPRINT(4, "Convert_Room : " + szFullName); } else { LPRINT(4, "Convert_Room : " + szFullName + " area_id " + itos(areaID)); } // get a reference to the lroom we are writing to LRoom &lroom = LMAN->m_Rooms[lroomID]; // store the godot room lroom.m_GodotID = pNode->get_instance_id(); lroom.m_RoomID = lroomID; // save the room ID on the godot room metadata // This is used when registering DOBs and teleporting them with hints // i.e. the Godot room is used to lookup the room ID of the startroom. LMAN->Meta_SetRoomNum(pNode, lroomID); // create a new LRoom to exchange the children over to, and delete the original empty lroom.m_szName = szRoom; // area if (areaID != -1) lroom.m_Areas.push_back(areaID); // keep a running bounding volume as we go through the visual instances // to determine the overall bound of the room LAABB bb_room; bb_room.SetToMaxOpposite(); // set default cull masks Convert_Room_SetDefaultCullMask_Recursive(pNode); // recursively find statics Convert_Room_FindObjects_Recursive(pNode, lroom, bb_room); // store the lroom centre and bound lroom.m_ptCentre = bb_room.FindCentre(); // bound (untested) lroom.m_AABB.position = bb_room.m_ptMins; lroom.m_AABB.size = bb_room.m_ptMaxs - bb_room.m_ptMins; LPRINT(2, "\t\t\t" + String(lroom.m_szName) + " centre " + lroom.m_ptCentre); return true; } bool LRoomConverter::Bound_AddPlaneIfUnique(LVector &planes, const Plane &p) { for (int n=0; n d) continue; float dot = p.normal.dot(o.normal); if (dot < 0.98f) continue; // match! return false; } // test // Vector3 va(1, 0, 0); // Vector3 vb(1, 0.2, 0); // vb.normalize(); // float dot = va.dot(vb); // print("va dot vb is " + String(Variant(dot))); // is unique // print("\t\t\t\tAdding bound plane : " + p); planes.push_back(p); return true; } bool LRoomConverter::Convert_Bound(LRoom &lroom, MeshInstance * pMI) { LPRINT(2, "\tCONVERT_BOUND : '" + pMI->get_name() + "' for room '" + lroom.get_name() + "'"); // some godot jiggery pokery to get the mesh verts in local space Ref rmesh = pMI->get_mesh(); Array arrays = rmesh->surface_get_arrays(0); PoolVector p_vertices = arrays[VS::ARRAY_VERTEX]; // convert to world space Transform trans = pMI->get_global_transform(); Vector points; for (int n=0; n 3) { Geometry::MeshData md; Error err = QuickHull::build(points, md); if (err == OK) { // get the planes for (int n=0; nm_SOBs.size(); n++) // { // LSob &sob = LMAN->m_SOBs[n]; // sob.Show(false); // } // // hide all lights that are non global // for (int n=0; nm_Lights.size(); n++) // { // LLight &light = LMAN->m_Lights[n]; // if (!light.IsGlobal()) // light.Show(false); // } //} void LRoomConverter::Convert_AreaLights() { // list the rooms in each area for (int a=0; am_Areas.size(); a++) { LArea &area = LMAN->m_Areas[a]; // add every room in this area to the light affected rooms list for (int r=0; rm_Rooms.size(); r++) { LRoom &room = LMAN->m_Rooms[r]; if (room.IsInArea(a)) { // add the room to the area room list if (area.m_iNumRooms == 0) area.m_iFirstRoom = LMAN->m_AreaRooms.size(); area.m_iNumRooms += 1; LMAN->m_AreaRooms.push_back(r); } } } // first identify which lights are area lights, and match area strings to area IDs for (int n=0; nm_Lights.size(); n++) { LLight &l = LMAN->m_Lights[n]; // global area light? if (!l.m_Source.IsGlobal()) continue; assert (l.m_iArea == -1); // match area string to area // find the area for (int n=0; nm_Areas.size(); n++) { if (LMAN->m_Areas[n].m_szName == l.m_szArea) { l.m_iArea = n; break; } } // area not found? if (l.m_iArea == -1) { LWARN(2, "Convert_AreaLights area not found : " + l.m_szArea); } else { LPRINT(5,"Area light " + itos (n) + " area " + l.m_szArea + " found area_id " + itos(l.m_iArea)); } } // add each light within an area to the area light list for (int a=0; am_Areas.size(); a++) { LArea &area = LMAN->m_Areas[a]; for (int n=0; nm_Lights.size(); n++) { LLight &l = LMAN->m_Lights[n]; int areaID = l.m_iArea; if (areaID != a) continue; // this light affects this area if (area.m_iNumLights == 0) area.m_iFirstLight = LMAN->m_AreaLights.size(); LMAN->m_AreaLights.push_back(n); area.m_iNumLights++; } // for n } // for a // for each global light we can calculate the affected rooms for (int n=0; nm_Lights.size(); n++) { LLight &l = LMAN->m_Lights[n]; int areaID = l.m_iArea; // not a global light if (areaID == -1) continue; LPRINT(5,"Area light " + itos (n) + " affected rooms:"); // add every room in this area to the light affected rooms list for (int r=0; rm_Rooms.size(); r++) { LRoom &room = LMAN->m_Rooms[r]; if (room.IsInArea(areaID)) { //l.AddAffectedRoom(r); // no need as this is now done by area LPRINT(5,"\t" + itos (r)); // store the global lights on the room room.m_GlobalLights.push_back(n); } } } } void LRoomConverter::Convert_Lights() { // trace local lights out from rooms and add to each room the light affects for (int n=0; nm_Lights.size(); n++) { LLight &l = LMAN->m_Lights[n]; if (l.m_Source.IsGlobal()) continue; // ignore globals .. affect all rooms Light_Trace(n); } } void LRoomConverter::Light_Trace(int iLightID) { // get the light LLight &l = LMAN->m_Lights[iLightID]; LPRINT(5,"_____________________________________________________________"); LPRINT(5,"\nLight_Trace " + itos (iLightID)); LMAN->m_Trace.Trace_Light(*LMAN, l, LTrace::LR_CONVERT); // now save the data from the trace LRoomManager::LLightRender &lr = LMAN->m_LightRender; // visible rooms for (int n=0; nGetRoom(room_id); room.AddLocalLight(iLightID); // store the affected room on the light l.AddAffectedRoom(room_id); } // sobs for (int n=0; nm_LightCasters_SOB.size(); LMAN->m_LightCasters_SOB.push_back(sob_id); l.m_NumCasters++; } LPRINT(5, itos(lr.m_Temp_Visible_Rooms.size()) + " visible rooms, " + itos (lr.m_Temp_Visible_SOBs.size()) + " visible SOBs.\n"); /* // blank this each time as it is used to create the list of casters LMAN->m_BF_caster_SOBs.Blank(); // reset the planes pool for each render out from the source room LMAN->m_Pool.Reset(); // the first set of planes are blank unsigned int pool_member = LMAN->m_Pool.Request(); assert (pool_member != -1); LVector &planes = LMAN->m_Pool.Get(pool_member); planes.clear(); Lawn::LDebug::m_iTabDepth = 0; Light_TraceRecursive(0, LMAN->m_Rooms[l.m_Source.m_RoomID], l, iLightID, planes); */ } /* void LRoomConverter::Light_TraceRecursive(int depth, LRoom &lroom, LLight &light, int iLightID, const LVector &planes) { // prevent too much depth if (depth > 8) { LPRINT_RUN(2, "\t\t\tLight_TraceRecursive DEPTH LIMIT REACHED"); return; } Lawn::LDebug::m_iTabDepth = depth; LPRINT_RUN(2, "ROOM " + lroom.get_name() + " affected by local light"); // add to the local lights affecting this room // already in list? bool bAlreadyInList = false; for (int n=0; nm_SOBs[n]; //LPRINT_RUN(2, "sob " + itos(n) + " " + sob.GetSpatial()->get_name()); // already determined to be visible through another portal // if (LMAN->m_BF_caster_SOBs.GetBit(n)) // { // //LPRINT_RUN(2, "\talready visible"); // continue; // } bool bShow = true; // estimate the radius .. for now const AABB &bb = sob.m_aabb; // print("\t\t\tculling object " + pObj->get_name()); for (int p=0; p 0.0f) { bShow = false; break; } } if (bShow) { Light_AddCaster_SOB(light, n); } } // for through sobs // look through every portal out for (int n=0; nm_Portals[portalID]; LPRINT_RUN(2, "\tPORTAL " + itos (n) + " (" + itos(portalID) + ") " + port.get_name() + " normal " + port.m_Plane.normal); float dot = port.m_Plane.normal.dot(light.m_Source.m_ptDir); if (dot <= 0.0f) { LPRINT_RUN(2, "\t\tCULLED (wrong direction)"); continue; } // is it culled by the planes? LPortal::eClipResult overall_res = LPortal::eClipResult::CLIP_INSIDE; // cull portal with planes for (int l=0; lPortal_GetLinkedRoom(port); // recurse into that portal unsigned int uiPoolMem = LMAN->m_Pool.Request(); if (uiPoolMem != -1) { // get a vector of planes from the pool LVector &new_planes = LMAN->m_Pool.Get(uiPoolMem); // copy the existing planes new_planes.copy_from(planes); // add the planes for the portal port.AddLightPlanes(*LMAN, light, new_planes, false); Light_TraceRecursive(depth + 1, linked_room, light, iLightID, new_planes); // for debugging need to reset tab depth Lawn::LDebug::m_iTabDepth = depth; // we no longer need these planes LMAN->m_Pool.Free(uiPoolMem); } else { // planes pool is empty! // This will happen if the view goes through shedloads of portals // The solution is either to increase the plane pool size, or build levels // with views through multiple portals. Looking through multiple portals is likely to be // slow anyway because of the number of planes to test. WARN_PRINT_ONCE("LRoom_FindShadowCasters_Recursive : Planes pool is empty"); } } } */ void LRoomConverter::Convert_ShadowCasters() { int nLights = LMAN->m_Lights.size(); LPRINT(5,"\nConvert_ShadowCasters ... numlights " + itos (nLights)); for (int l=0; lm_Lights[l]; String sz = "Light " + itos (l); if (light.m_Source.IsGlobal()) sz += " GLOBAL"; else sz += " LOCAL from room " + itos(light.m_Source.m_RoomID); LPRINT(5, sz + " direction " + light.m_Source.m_ptDir); for (int n=0; nm_Rooms.size(); n++) { LRoom &lroom = LMAN->m_Rooms[n]; // global lights affect every room bool bAffectsRoom = false; // true // if the light is local, does it affect this room? if (!light.m_Source.IsGlobal()) { // a local light .. does it affect this room? bAffectsRoom = false; for (int i=0; im_Rooms.size(); n++) { LRoom &lroom = LMAN->m_Rooms[n]; //print("DetectBounds from room " + lroom.get_name()); Spatial * pGRoom = lroom.GetGodotRoom(); assert (pGRoom); for (int n=0; nget_child_count(); n++) { Node * pChild = pGRoom->get_child(n); if (Node_IsBound(pChild)) { MeshInstance * pMesh = Object::cast_to(pChild); assert (pMesh); Convert_Bound(lroom, pMesh); // delete the mesh pGRoom->remove_child(pChild); pChild->queue_delete(); break; } } } } void LRoomConverter::Convert_Portals() { for (int pass=0; pass<3; pass++) { LPRINT(2, "Convert_Portals pass " + itos(pass)); LPRINT(2, ""); for (int n=0; nm_Rooms.size(); n++) { LRoom &lroom = LMAN->m_Rooms[n]; LTempRoom &troom = m_TempRooms[n]; switch (pass) { case 0: LRoom_DetectPortalMeshes(lroom, troom); break; case 1: LRoom_MakePortalsTwoWay(lroom, troom, n); break; case 2: LRoom_MakePortalFinalList(lroom, troom); break; } } } } int LRoomConverter::CountRooms() { if (m_bSingleRoomMode) return 1; // hard coded int nChildren = LROOMLIST->get_child_count(); int count = 0; for (int n=0; nget_child(n); if (Node_IsRoom(pChild)) count++; else { // also check the children if this is an area if (Node_IsArea(pChild)) { for (int c=0; cget_child_count(); c++) { Node * pChild2 = pChild->get_child(c); if (Node_IsRoom(pChild2)) count++; } } } } return count; } // find all objects that cast shadows onto the objects in this room //void LRoomConverter::LRoom_FindShadowCasters(LRoom &lroom, int lightID, const LLight &light) //{ // // each global light, and each light affecting this room // for (int n=0; nm_Lights.size(); n++) // { // // if the light is not a global light, we are only interested if it emits from this room // const LLight &l = LMAN->m_Lights[n]; // bool bAffectsRoom = true; // if (l.m_RoomID != -1) // { // // a local light .. does it affect this room? // bAffectsRoom = false; // for (int i=0; im_BF_caster_SOBs.GetBit(sobID)) return; LPRINT_RUN(2, "\t\t\tLightCaster " + itos(sobID)); LMAN->m_BF_caster_SOBs.SetBit(sobID, true); // first? if (!light.m_NumCasters) light.m_FirstCaster = LMAN->m_LightCasters_SOB.size(); LMAN->m_LightCasters_SOB.push_back(sobID); light.m_NumCasters++; } */ void LRoomConverter::LRoom_AddShadowCaster_SOB(LRoom &lroom, int sobID) { // we will reuse the rendering bitflags for shadow casters for this ... to check for double entries (fnaa fnaa) if (LMAN->m_BF_caster_SOBs.GetBit(sobID)) return; LMAN->m_BF_caster_SOBs.SetBit(sobID, true); // first? if (!lroom.m_iNumShadowCasters_SOB) lroom.m_iFirstShadowCaster_SOB = LMAN->m_ShadowCasters_SOB.size(); LMAN->m_ShadowCasters_SOB.push_back(sobID); lroom.m_iNumShadowCasters_SOB++; } void LRoomConverter::LRoom_FindShadowCasters_FromLight(LRoom &lroom, const LLight &light) { // blank this each time as it is used to create the list of casters LMAN->m_BF_caster_SOBs.Blank(); // first add all objects in this room as casters // int last_sob = lroom.m_iFirstSOB + lroom.m_iNumSOBs; // for (int n=lroom.m_iFirstSOB; nm_Pool.Reset(); // the first set of planes are blank unsigned int pool_member = LMAN->m_Pool.Request(); assert (pool_member != -1); LVector &planes = LMAN->m_Pool.Get(pool_member); planes.clear(); Lawn::LDebug::m_iTabDepth = 0; LRoom_FindShadowCasters_Recursive(lroom, 1, lroom, light, planes); } void LRoomConverter::LRoom_FindShadowCasters_Recursive(LRoom &source_lroom, int depth, LRoom &lroom, const LLight &light, const LVector &planes) { // prevent too much depth if (depth > 8) { LPRINT_RUN(2, "\t\t\tLRoom_FindShadowCasters_Recursive DEPTH LIMIT REACHED"); // WARN_PRINT_ONCE("LPortal Depth Limit reached (seeing through > 8 portals)"); return; } Lawn::LDebug::m_iTabDepth = depth; LPRINT_RUN(2, "ROOM " + lroom.get_name()); // every object in this room is added that is within the planes int last_sob = lroom.m_iFirstSOB + lroom.m_iNumSOBs; for (int n=lroom.m_iFirstSOB; nm_SOBs[n]; // not a shadow caster? don't add to the list if (!sob.IsShadowCaster()) continue; bool bShow = true; const AABB &bb = sob.m_aabb; // print("\t\t\tculling object " + pObj->get_name()); for (int p=0; p 0.0f) // if (r_max < 0.0f) { //LPRINT_RUN(2, "\tR_MIN is " + String(Variant(r_min)) + " R_MAX is " + String(Variant(r_max))+ ", for plane " + itos(p)); bShow = false; break; } } if (bShow) { LPRINT_RUN(2, "\tcaster " + itos(n) + ", " + sob.GetSpatial()->get_name()); LRoom_AddShadowCaster_SOB(source_lroom, n); } else { //LPRINT_RUN(2, "\tculled " + itos(n) + ", " + sob.GetSpatial()->get_name()); } } // look through every portal out for (int n=0; nm_Portals[portalID]; LPRINT_RUN(2, "\tPORTAL " + itos (n) + " (" + itos(portalID) + ") " + port.get_name() + " normal " + port.m_Plane.normal); // cull with light direction float dot; if (light.m_Source.m_eType == LSource::ST_DIRECTIONAL) { dot = port.m_Plane.normal.dot(light.m_Source.m_ptDir); } else { // cull with light direction to portal Vector3 ptLightToPort = port.m_ptCentre - light.m_Source.m_ptPos; dot = port.m_Plane.normal.dot(ptLightToPort); } // float dot = port.m_Plane.normal.dot(light.m_ptDir); if (dot >= 0.0f) { LPRINT_RUN(2, "\t\tCULLED (wrong direction)"); continue; } // is it culled by the planes? LPortal::eClipResult overall_res = LPortal::eClipResult::CLIP_INSIDE; // cull portal with planes for (int l=0; lPortal_GetLinkedRoom(port); // recurse into that portal unsigned int uiPoolMem = LMAN->m_Pool.Request(); if (uiPoolMem != -1) { // get a vector of planes from the pool LVector &new_planes = LMAN->m_Pool.Get(uiPoolMem); // copy the existing planes new_planes.copy_from(planes); // add the planes for the portal port.AddLightPlanes(*LMAN, light, new_planes, true); LRoom_FindShadowCasters_Recursive(source_lroom, depth + 1, linked_room, light, new_planes); // for debugging need to reset tab depth Lawn::LDebug::m_iTabDepth = depth; // we no longer need these planes LMAN->m_Pool.Free(uiPoolMem); } else { // planes pool is empty! // This will happen if the view goes through shedloads of portals // The solution is either to increase the plane pool size, or build levels // with views through multiple portals. Looking through multiple portals is likely to be // slow anyway because of the number of planes to test. WARN_PRINT_ONCE("LRoom_FindShadowCasters_Recursive : Planes pool is empty"); } } } // go through the nodes hanging off the room looking for those that are meshes to mark portal locations void LRoomConverter::LRoom_DetectPortalMeshes(LRoom &lroom, LTempRoom &troom) { LPRINT(2, "DETECT_PORTALS from room " + lroom.get_name()); Spatial * pGRoom = lroom.GetGodotRoom(); assert (pGRoom); for (int n=0; nget_child_count(); n++) { Node * pChild = pGRoom->get_child(n); if (Node_IsPortal(pChild)) { MeshInstance * pMesh = Object::cast_to(pChild); assert (pMesh); // name must start with 'portal_' // and ends with the name of the room we want to link to (without the 'room_') String szLinkRoom = LPortal::FindNameAfter(pMesh, "portal_"); LRoom_DetectedPortalMesh(lroom, troom, pMesh, szLinkRoom); } } // delete portal meshes if (m_bFinalRun) // if (true) { // we need an enclosing while loop because we might be deleting children and mucking up the iterator bool bDetectedOne = true; while (bDetectedOne) { bDetectedOne = false; for (int n=0; nget_child_count(); n++) { Node * pChild = pGRoom->get_child(n); if (Node_IsPortal(pChild)) { // delete the original child, as it is no longer needed at runtime (except maybe for debugging .. NYI?) // pMeshInstance->hide(); pChild->get_parent()->remove_child(pChild); pChild->queue_delete(); bDetectedOne = true; } if (bDetectedOne) break; } // for loop } // while } // if we want to delete portal meshes } void LRoomConverter::LRoom_PushBackSOB(LRoom &lroom, const LSob &sob) { // first added for this room? if (lroom.m_iNumSOBs == 0) lroom.m_iFirstSOB = LMAN->m_SOBs.size(); LMAN->m_SOBs.push_back(sob); lroom.m_iNumSOBs++; } // handles the slight faff involved in getting a new portal in the manager contiguous list of portals LPortal * LRoomConverter::LRoom_RequestNewPortal(LRoom &lroom) { // is this the first portal? if (lroom.m_iNumPortals == 0) lroom.m_iFirstPortal = LMAN->m_Portals.size(); lroom.m_iNumPortals++; return LMAN->m_Portals.request(); } // convert the list on each room to a single contiguous list in the manager void LRoomConverter::LRoom_MakePortalFinalList(LRoom &lroom, LTempRoom &troom) { for (int n=0; n(pNode); assert (pLight); if (m_bDeleteLights) { LPRINT(2, "Deleting Light : " + pLight->get_name()); // delete light now we are using lightmaps for test pLight->queue_delete(); } else { LPRINT(2, "Detected Light : " + pLight->get_name()); LMAN->LightCreate(pLight, lroom.m_RoomID); } } // found a portal mesh! create a matching LPortal void LRoomConverter::LRoom_DetectedPortalMesh(LRoom &lroom, LTempRoom &troom, MeshInstance * pMeshInstance, String szLinkRoom) { LPRINT(2, "\tdetected to " + szLinkRoom); // which room does this portal want to link to? int iLinkRoom = FindRoom_ByName(szLinkRoom); if (iLinkRoom == -1) { LWARN(5, "portal to room " + szLinkRoom + ", room not found"); //WARN_PRINTS("portal to room " + szLinkRoom + ", room not found"); return; } // some godot jiggery pokery to get the mesh verts in local space Ref rmesh = pMeshInstance->get_mesh(); Array arrays = rmesh->surface_get_arrays(0); PoolVector p_vertices = arrays[VS::ARRAY_VERTEX]; // create a new LPortal to fill with this wonderful info LPortal &lport = *troom.m_Portals.request(); lport.m_szName = szLinkRoom; lport.m_iRoomNum = iLinkRoom; // create the portal geometry lport.CreateGeometry(p_vertices, pMeshInstance->get_global_transform()); // LPRINT(2, "\t\t\tnum portals now " + itos(troom.m_Portals.size())); } // This aims to make life easier for level designers. They only need to make a portal facing one way and LPortal // will automatically create a mirror portal the other way. void LRoomConverter::LRoom_MakePortalsTwoWay(LRoom &lroom, LTempRoom &troom, int iRoomNum) { LPRINT(2, "MAKE_PORTALS_TWOWAY from room " + lroom.get_name()); LPRINT(2, "\tcontains " + itos (troom.m_Portals.size()) + " portals"); for (int n=0; nm_Rooms[iRoomOrig]; // the new portal should have the name of the room the original came from LPortal &new_port = *nroom.m_Portals.request(); new_port.m_szName = orig_lroom.m_szName; new_port.m_iRoomNum = iRoomOrig; new_port.m_bMirror = true; // the portal vertices should be the same but reversed (to flip the normal) new_port.CopyReversedGeometry(port); } /////////////////////////////////////////////////// // helper bool LRoomConverter::Node_IsLight(Node * pNode) const { Light * pLight = Object::cast_to(pNode); if (!pLight) return false; return true; } bool LRoomConverter::Node_IsArea(Node * pNode) const { Spatial * pSpat = Object::cast_to(pNode); if (!pSpat) return false; if (LPortal::NameStartsWith(pSpat, "area_")) return true; return false; } bool LRoomConverter::Node_IsRoom(Node * pNode) const { Spatial * pSpat = Object::cast_to(pNode); if (!pSpat) return false; if (LPortal::NameStartsWith(pSpat, "room_")) return true; return false; } bool LRoomConverter::Node_IsIgnore(Node * pNode) const { if (LPortal::NameStartsWith(pNode, "ignore_")) return true; return false; } bool LRoomConverter::Node_IsBound(Node * pNode) const { MeshInstance * pMI = Object::cast_to(pNode); if (!pMI) return false; if (LPortal::NameStartsWith(pMI, "bound_")) return true; return false; } bool LRoomConverter::Node_IsPortal(Node * pNode) const { MeshInstance * pMI = Object::cast_to(pNode); if (!pMI) return false; if (LPortal::NameStartsWith(pMI, "portal_")) return true; return false; } // keep the global namespace clean #undef LMAN