path: root/NW4RTools/BrresWriter.cs

using System;
using System.Collections;
using System.Collections.Generic;

using NW4RTools.Models;

namespace NW4RTools {
	public class BrresWriter {
		public static byte[] WriteFile(ResFile file) {
			return new BrresWriter().Save(file);
		}



		private ResFile File;
		private ILogger Debug;
		private SortedDictionary<int, string> OffsetMap;
		private OutputStream Output;

		private BrresWriter() {
			Debug = new ConsoleLogger();
			OffsetMap = new SortedDictionary<int, string>();
		}

		private byte[] Save(ResFile file) {
			Output = new OutputStream(ByteEndian.BigEndian);
			File = file;

			using (var c = Debug.Push("Offset Calculation"))
				CalculateRoot();

			using (var c = Debug.Push("Data"))
				WriteRoot();

			using (var c = Debug.Push("Offset Map")) {
				foreach (var e in OffsetMap) {
					// Commented for easier output reading atm
					Debug.Send("0x{0:X} : {1}", e.Key, e.Value);
				}
			}

			return Output.GetBuffer();
		}


		private void LogPosition(string text) {
			Debug.Send("0x{0:X} : {1}", CurrentPos, text);
			OffsetMap.Add(CurrentPos, text);
		}

		// OK, here's how I'm going to code this: kinda like how BrawlLib works, first I'll calculate the size of
		// each written element, and use that to build up a list of offsets. Then, I'll actually write out the data.
		// This code will also handle building the string table.

		#region Offset Data Storage
		private Dictionary<Model, int> ModelOffsets;
		private Dictionary<ByteCode, int> BytecodeOffsets;
		private Dictionary<Node, int> NodeOffsets;
		private Dictionary<VertexPosData, int> VtxPosOffsets;
		private Dictionary<VertexNrmData, int> VtxNrmOffsets;
		private Dictionary<VertexClrData, int> VtxClrOffsets;
		private Dictionary<VertexTexCoordData, int> VtxTexCoordOffsets;
		private Dictionary<Material, int> MaterialOffsets;
		private Dictionary<Material, int> MaterialDLOffsets;
		private Dictionary<Shader, int> ShaderOffsets;
		private Dictionary<Shape, int> ShapeOffsets;
		private Dictionary<Shape, int> ShapeDL1Offsets;
		private Dictionary<Shape, int> ShapeDL2Offsets;
		private Dictionary<Shape, int> ShapeSizes;
		private Dictionary<List<TexMatPairing>, int> PairingOffsets;
		private Dictionary<TextureInfo, int> TextureInfoOffsets;

		// Models have lots of extra offset data attached
		private class ModelCalcInfo {
			public int MatrixIDtoNodeID, Bytecode, Nodes;
			public int VtxPosData, VtxNrmData, VtxClrData, VtxTexCoordData;
			public int Materials, Shaders, Shapes;
			public int PairingLookupByTexture;
			public int BlockSize;
			// Duplicate shader structs are removed from the model, so they require special tracking
			public List<Shader> UniqueShaders;
		}
		private Dictionary<Model, ModelCalcInfo> ModelCalcInfos;

		private Dictionary<Texture, int> TextureOffsets;
		private Dictionary<Texture, int> TextureDataOffsets;

		private Dictionary<object, int> RootDictOffsets;

		private int CurrentPos;
		private int BlockCount;
		private int RootBlockSize;
		#endregion

		#region Offset/String Table Calculation
		private void CalculateRoot() {
			// Where it all starts!
			InitialiseStringTable();

			// First up: BRRES header
			CurrentPos = 0x10;

			// First block, and ResDict
			CurrentPos += 8;
			CurrentPos += GetSizeForResDict(File.Count);
			RootBlockSize = 8 + GetSizeForResDict(File.Count);

			// "root" block counts
			BlockCount = 1;

			RootDictOffsets = new Dictionary<object, int>();

			// Now do each ResDict in the File
			foreach (var kv in File) {
				LogPosition("ResDict: " + kv.Key);
				RootDictOffsets[kv.Value] = CurrentPos;

				CurrentPos += GetSizeForResDict((kv.Value as ICollection).Count);
				RootBlockSize += GetSizeForResDict((kv.Value as ICollection).Count);
				BlockCount += (kv.Value as ICollection).Count;
			}

			// OK, so that's done. Process each type
			foreach (var name in File.Keys) {
				AddString(name);
				switch (name) {
				case "3DModels(NW4R)":
					CalculateModels();
					break;
				case "Textures(NW4R)":
					CalculateTextures();
					break;
				default:
					Debug.Send("[[ UNIMPLEMENTED {0} ]]", name);
					break;
				}
			}

			// ... and done with that. Build the string table and go!
			AlignCalcPos(4);
			LogPosition("String Table");
			CalculateStringTable();
		}

		#region Model Calculation

		private void CalculateModels() {
			ModelOffsets = new Dictionary<Model, int>();
			ModelCalcInfos = new Dictionary<Model, ModelCalcInfo>();

			BytecodeOffsets = new Dictionary<ByteCode, int>();
			NodeOffsets = new Dictionary<Node, int>();
			VtxPosOffsets = new Dictionary<VertexPosData, int>();
			VtxNrmOffsets = new Dictionary<VertexNrmData, int>();
			VtxClrOffsets = new Dictionary<VertexClrData, int>();
			VtxTexCoordOffsets = new Dictionary<VertexTexCoordData, int>();
			MaterialOffsets = new Dictionary<Material, int>();
			MaterialDLOffsets = new Dictionary<Material, int>();
			ShaderOffsets = new Dictionary<Shader, int>();
			ShapeOffsets = new Dictionary<Shape, int>();
			ShapeDL1Offsets = new Dictionary<Shape, int>();
			ShapeDL2Offsets = new Dictionary<Shape, int>();
			ShapeSizes = new Dictionary<Shape, int>();
			PairingOffsets = new Dictionary<List<TexMatPairing>, int>();
			TextureInfoOffsets = new Dictionary<TextureInfo, int>();

			foreach (var kv in File.GetGroup<Model>("3DModels(NW4R)")) {
				AddString(kv.Key);
				AlignCalcPos(0x20);
				// 0x40? dunno
				Model model = kv.Value;

				var calcInfo = ModelCalcInfos[model] = new BrresWriter.ModelCalcInfo();

				// This is used later to calculate the MDL0 block size easily
				int startPos = CurrentPos;

				LogPosition("Model: " + kv.Key);
				ModelOffsets.Add(model, CurrentPos);
				CurrentPos += 0x4C;
				LogPosition("Model Info Struct for: " + kv.Key);
				CurrentPos += 0x40;

				LogPosition("Matrix ID to Node ID Data for: " + kv.Key);
				calcInfo.MatrixIDtoNodeID = CurrentPos;
				CurrentPos += 4 + (model.MatrixIDtoNodeID.Length * 4);

			
				LogPosition("ResDict: ByteCode");
				calcInfo.Bytecode = CurrentPos;
				CurrentPos += GetSizeForResDict(model.Bytecode.Count);

				LogPosition("ResDict: Nodes");
				calcInfo.Nodes = CurrentPos;
				CurrentPos += GetSizeForResDict(model.Nodes.Count);

				LogPosition("ResDict: VertexPosData");
				calcInfo.VtxPosData = CurrentPos;
				CurrentPos += GetSizeForResDict(model.VtxPosData.Count);

				if (model.VtxNrmData.Count > 0) {
					LogPosition("ResDict: VertexNrmData");
					calcInfo.VtxNrmData = CurrentPos;
					CurrentPos += GetSizeForResDict(model.VtxNrmData.Count);
				}

				if (model.VtxClrData.Count > 0) {
					LogPosition("ResDict: VertexClrData");
					calcInfo.VtxClrData = CurrentPos;
					CurrentPos += GetSizeForResDict(model.VtxClrData.Count);
				}

				if (model.VtxTexCoordData.Count > 0) {
					LogPosition("ResDict: VertexTexCoordData");
					calcInfo.VtxTexCoordData = CurrentPos;
					CurrentPos += GetSizeForResDict(model.VtxTexCoordData.Count);
				}

				LogPosition("ResDict: Materials");
				calcInfo.Materials = CurrentPos;
				CurrentPos += GetSizeForResDict(model.Materials.Count);

				LogPosition("ResDict: Shaders");
				calcInfo.Shaders = CurrentPos;
				CurrentPos += GetSizeForResDict(model.Shaders.Count);

				LogPosition("ResDict: Shapes");
				calcInfo.Shapes = CurrentPos;
				CurrentPos += GetSizeForResDict(model.Shapes.Count);

				if (model.PairingLookupByTexture.Count > 0) {
					LogPosition("ResDict: Texture Lookup");
					calcInfo.PairingLookupByTexture = CurrentPos;
					CurrentPos += GetSizeForResDict(model.PairingLookupByTexture.Count);
				}

				// todo: palette lookup, checking if dicts are empty or do not exist
				// todo: can dicts even NOT exist? must find this out

				CalculatePairings(model, model.PairingLookupByTexture);
				CalculateBytecode(model);
				CalculateNodes(model);
				CalculateMaterials(model);
				calcInfo.UniqueShaders = new List<Shader>();
				CalculateShaders(model);
				CalculateShapes(model);
				CalculateVtxPosData(model);
				CalculateVtxNrmData(model);
				CalculateVtxClrData(model);
				CalculateVtxTexCoordData(model);

				// Here we go!
				calcInfo.BlockSize = CurrentPos - startPos;
			}
		}

		private void CalculatePairings(Model m, ResDict<List<TexMatPairing>> dict) {
			foreach (var kv in dict) {
				LogPosition("Texture/Material Pairing List for: " + kv.Key);
				PairingOffsets.Add(kv.Value, CurrentPos);

				CurrentPos += 4 + (kv.Value.Count * 8);
			}
		}

		private void CalculateBytecode(Model m) {
			foreach (var kv in m.Bytecode) {
				AddString(kv.Key);
				ByteCode bc = kv.Value;

				LogPosition("ByteCode: " + kv.Key);
				BytecodeOffsets.Add(kv.Value, CurrentPos);

				foreach (var insn in bc.Instructions) {
					switch (insn.GetOp()) {
					case ByteCode.OpType.None:
						CurrentPos += 1;
						break;
					case ByteCode.OpType.Done:
						CurrentPos += 1;
						break;
					case ByteCode.OpType.AssignNodeToParentMtx:
						CurrentPos += 5;
						break;
					case ByteCode.OpType.BlendMatrices:
						CurrentPos += 4 + (6 * (insn as ByteCode.BlendMatricesInstruction).BlendedMatrices.Length);
						break;
					case ByteCode.OpType.DrawShape:
						CurrentPos += 8;
						break;
					case ByteCode.OpType.AssignMtxToNode:
						CurrentPos += 5;
						break;
					}
				}
			}

			AlignCalcPos(4); // should be per-bytecode maybe?
		}

		private void CalculateNodes(Model m) {
			foreach (var kv in m.Nodes) {
				AddString(kv.Key);

				LogPosition("Node: " + kv.Key);
				NodeOffsets.Add(kv.Value, CurrentPos);

				CurrentPos += 0xD0;
			}
		}

		private void CalculateMaterials(Model m) {
			foreach (var kv in m.Materials) {
				AddString(kv.Key);

				LogPosition("Material: " + kv.Key);
				MaterialOffsets.Add(kv.Value, CurrentPos);

				// Base material struct
				CurrentPos += 0x14;

				// ResGenMode
				CurrentPos += 8;

				// ResMatMode
				CurrentPos += 0xC;

				// other stuff
				CurrentPos += 0x18;

				// ResTexObj
				CurrentPos += 0x104;

				// ResTlutObj
				CurrentPos += 0x64;

				// ResTexSrt
				CurrentPos += 8 + (0x14 * 8) + (0x34 * 8);

				// ResMatChan
				CurrentPos += 0x28;

				// Texture Infos
				if (kv.Value.TextureInfos.Count > 0)
					LogPosition("Material Texture Infos: " + kv.Key);

				for (int i = 0; i < kv.Value.TextureInfos.Count; i++) {
					TextureInfoOffsets[kv.Value.TextureInfos[i]] = CurrentPos;
					CurrentPos += 0x34;
				}

				// Display Lists
				AlignCalcPos(0x20);
				LogPosition("Material Display Lists: " + kv.Key);
				MaterialDLOffsets[kv.Value] = CurrentPos;
				CurrentPos += 0x20 + 0x80 + 0x40 + 0xA0;
			}
		}

		private void CalculateShaders(Model m) {
			// Oh great, now I need to optimise this by removing duplicate shaders.
			// I'm doing it like this: I'll loop through every shader in the ResDict.
			// I'll check each one against the UniqueShaders list.
			// If it's not in the list, I'll add it there and add it to the resource data.

			var calcInfo = ModelCalcInfos[m];

			foreach (var kv in m.Shaders) {
				AddString(kv.Key);

				// Check to see if it's in the UniqueShaders list already
				// This is made slightly difficult -- shaders can be different object instances
				// yet still match, so simple reference comparison isn't good enough.
				// So, I added a "DataMatches" method to the Shader class that checks the
				// data in two Shaders and sees if they match.

				bool wasFound = false;
				Shader match = null;

				foreach (var checkAgainst in calcInfo.UniqueShaders) {
					if (checkAgainst.DataMatches(kv.Value)) {
						wasFound = true;
						match = checkAgainst;
						break;
					}
				}

				if (wasFound) {
					// It's already in there.
					int positionOfMatch = ShaderOffsets[match];
					OffsetMap[positionOfMatch] = OffsetMap[positionOfMatch] + ", " + kv.Key;

					// Add it to ShaderOffsets so we can link it up to the shader ResDict
					ShaderOffsets.Add(kv.Value, positionOfMatch);

				} else {
					// This is a new shader, add it!
					calcInfo.UniqueShaders.Add(kv.Value);

					LogPosition("Shader: " + kv.Key);
					ShaderOffsets.Add(kv.Value, CurrentPos);

					CurrentPos += 0x200;
				}
			}
		}

		private void CalculateShapes(Model m) {
			foreach (var kv in m.Shapes) {
				AddString(kv.Key);

				LogPosition("Shape: " + kv.Key);
				ShapeOffsets.Add(kv.Value, CurrentPos);

				CurrentPos += 0x68;

				// extra data
				CurrentPos += 4;
				CurrentPos += (kv.Value.ExtraData.Length * 2);

				// display lists
				AlignCalcPos(0x20);

				ShapeDL1Offsets.Add(kv.Value, CurrentPos);
				LogPosition("Shape DL 1: " + kv.Key);
				CurrentPos += (int)kv.Value.DLBufferSize1;
				AlignCalcPos(0x20);

				ShapeDL2Offsets.Add(kv.Value, CurrentPos);
				LogPosition("Shape DL 2: " + kv.Key);
				CurrentPos += (int)kv.Value.DLBufferSize2;

				// Should this line be after the final alignment?
				// Does it even matter? I'd assume DL sizes will be aligned to 0x20...
				ShapeSizes[kv.Value] = CurrentPos - ShapeOffsets[kv.Value];

				AlignCalcPos(0x20);
			}
		}

		private void CalculateVtxPosData(Model m) {
			foreach (var kv in m.VtxPosData) {
				AddString(kv.Key);

				LogPosition("VertexPosData: " + kv.Key);
				VtxPosOffsets.Add(kv.Value, CurrentPos);

				// Main data
				CurrentPos += 0x20;

				// Minimum/maximum VEC3 (specific to VtxPosData)
				CurrentPos += 0x18;

				AlignCalcPos(0x20);
				LogPosition("Data: " + kv.Key);
				CurrentPos += kv.Value.EntryCount * kv.Value.EntrySize;
				AlignCalcPos(0x20);
			}
		}

		private void CalculateVtxNrmData(Model m) {
			foreach (var kv in m.VtxNrmData) {
				AddString(kv.Key);

				LogPosition("VertexNrmData: " + kv.Key);
				VtxNrmOffsets.Add(kv.Value, CurrentPos);

				// Main data
				CurrentPos += 0x20;

				AlignCalcPos(0x20);
				LogPosition("Data: " + kv.Key);
				CurrentPos += kv.Value.EntryCount * kv.Value.EntrySize;
				AlignCalcPos(0x20);
			}
		}

		private void CalculateVtxClrData(Model m) {
			foreach (var kv in m.VtxClrData) {
				AddString(kv.Key);

				LogPosition("VertexClrData: " + kv.Key);
				VtxClrOffsets.Add(kv.Value, CurrentPos);

				// Main data
				CurrentPos += 0x20;

				AlignCalcPos(0x20);
				LogPosition("Data: " + kv.Key);
				CurrentPos += kv.Value.EntryCount * kv.Value.EntrySize;
				AlignCalcPos(0x20);
			}
		}

		private void CalculateVtxTexCoordData(Model m) {
			foreach (var kv in m.VtxTexCoordData) {
				AddString(kv.Key);

				LogPosition("VertexTexCoordData: " + kv.Key);
				VtxTexCoordOffsets.Add(kv.Value, CurrentPos);

				// Main data
				CurrentPos += 0x20;

				// Minimum/maximum VEC2 (specific to VtxTexCoordData)
				CurrentPos += 0x10;
				
				AlignCalcPos(0x20);
				LogPosition("Data: " + kv.Key);
				CurrentPos += kv.Value.EntryCount * kv.Value.EntrySize;
				AlignCalcPos(0x20);
			}
		}
		#endregion

		#region Texture Calculation
		private void CalculateTextures() {
			TextureOffsets = new Dictionary<Texture, int>();
			TextureDataOffsets = new Dictionary<Texture, int>();


			var textureDict = File.GetGroup<Texture>("Textures(NW4R)");

			foreach (var kv in textureDict) {
				AddString(kv.Key);
				AlignCalcPos(0x20);
				Texture texture = kv.Value;

				Debug.Send("Current: {0}", kv.Key);


				LogPosition("Texture: " + kv.Key);
				TextureOffsets.Add(kv.Value, CurrentPos);

				CurrentPos += 0x30;
				AlignCalcPos(0x20);


				LogPosition("Texture Data for: " + kv.Key);
				TextureDataOffsets.Add(kv.Value, CurrentPos);

				CurrentPos += texture.GetDataSize();
				AlignCalcPos(0x20);
			}
		}
		#endregion



		private void AlignCalcPos(int alignTo) {
			if ((CurrentPos & (alignTo - 1)) == 0)
				return;

			CurrentPos += (alignTo - (CurrentPos & (alignTo - 1)));
		}

		private int GetSizeForResDict(int entryCount) {
			return 8 + ((entryCount + 1) * 0x10);
		}

		#endregion

		#region Writing Data
		private void WriteRoot() {
			// magic "bres", endian, version, file size
			Output.WriteUInt32(0x62726573);
			Output.WriteUInt16(0xFEFF);
			Output.WriteUInt16(File.Version);
			Output.WriteUInt32((uint)(((CurrentPos + StringTableData.Position) + 0x3F) & ~0x3F));

			// header size, block count
			Output.WriteUInt16(0x10);
			Output.WriteUInt16((ushort)BlockCount);

			// first block: magic "root", block size
			Output.WriteUInt32(0x726F6F74);
			Output.WriteUInt32((uint)RootBlockSize);

			// root dictionaries
			WriteResDict<object>(File, RootDictOffsets);

			using (var c = Debug.Push("Root Dictionaries")) {
				foreach (var kv in File) {
					Debug.Send(kv.Key);

					switch (kv.Key) {
					case "3DModels(NW4R)":
						WriteResDict<Model>(kv.Value as ResDict<Model>, ModelOffsets);
						break;
					case "Textures(NW4R)":
						WriteResDict<Texture>(kv.Value as ResDict<Texture>, TextureOffsets);
						break;
					default:
						// for testing, boo
						Output.AddPadding(GetSizeForResDict((kv.Value as ICollection).Count));
						Debug.Send("UNHANDLED RESOURCE TYPE: {0}", kv.Key);
						break;
					}
				}
			}

			// now write the actual data
			using (var c = Debug.Push("Root Data")) {
				foreach (var kv in File) {
					switch (kv.Key) {
					case "3DModels(NW4R)":
						WriteModels();
						break;
					case "Textures(NW4R)":
						WriteTextures();
						break;
					default:
						Debug.Send("UNHANDLED RESOURCE TYPE: {0}", kv.Key);
						break;
					}
				}
			}

			Output.AlignTo(4);
			Output.WriteBytes(StringTableData.GetBuffer());

			// before we finish. pad the file
			Output.AlignTo(0x40);
		}

		#region Model Writing
		private void WriteModels() {
			foreach (var kv in File.GetGroup<Model>("3DModels(NW4R)")) {
				using (var c = Debug.Push("Model: {0}", kv.Key)) {
					Output.AlignTo(0x20);

					int startPos = Output.Position;
					Model model = kv.Value;
					var calcInfo = ModelCalcInfos[model];

					// Base struct: magic 'MDL0', block size, version [currently 11], resfile offset
					Output.WriteUInt32(0x4D444C30);
					Output.WriteUInt32((uint)calcInfo.BlockSize);
					Output.WriteUInt32(11);

					// Note: "0 - startPos" *DOESN'T* work when compiling under Mono!
					// Details: https://bugzilla.novell.com/show_bug.cgi?id=675777
					// So just use "-startPos".
					Output.WriteInt32(-startPos);

					// More offsets for a ton of crap
					Output.WriteInt32(calcInfo.Bytecode - startPos);
					Output.WriteInt32(calcInfo.Nodes - startPos);
					Output.WriteInt32(calcInfo.VtxPosData - startPos);
					Output.WriteInt32((calcInfo.VtxNrmData == 0) ? 0 : (calcInfo.VtxNrmData - startPos));
					Output.WriteInt32((calcInfo.VtxClrData == 0) ? 0 : (calcInfo.VtxClrData - startPos));
					Output.WriteInt32((calcInfo.VtxTexCoordData == 0) ? 0 : (calcInfo.VtxTexCoordData - startPos));
					// VtxFurVec, VtxFurPos (not handled)
					Output.WriteInt32(0);
					Output.WriteInt32(0);
					Output.WriteInt32(calcInfo.Materials - startPos);
					Output.WriteInt32(calcInfo.Shaders - startPos);
					Output.WriteInt32(calcInfo.Shapes - startPos);
					Output.WriteInt32((calcInfo.PairingLookupByTexture == 0) ? 0 : (calcInfo.PairingLookupByTexture - startPos));
					// Pairing lookup by palette, unhandled atm
					Output.WriteInt32(0);
					// Unknown extra data
					Output.WriteInt32(0);

					// Name offset
					Output.WriteInt32(StringPositions[kv.Key] - startPos);

					// Model Info struct: struct size, model offset, some other stuff
					int infoStructPos = Output.Position;

					Output.WriteUInt32(0x40);
					Output.WriteInt32(startPos - infoStructPos);

					Output.WriteUInt32((uint)model.ScaleMode);
					Output.WriteUInt32((uint)model.TexMatrixMode);
					Output.WriteUInt32((uint)model.VertexCount);
					Output.WriteUInt32((uint)model.TriangleCount);
					Output.WriteUInt32(0);
					Output.WriteUInt32((uint)model.MatrixIDtoNodeID.Length);
					Output.WriteByte(model.UsesNrmMtxArray ? (byte)1 : (byte)0);
					Output.WriteByte(model.UsesTexMtxArray ? (byte)1 : (byte)0);
					Output.AddPadding(2);
					Output.WriteInt32(calcInfo.MatrixIDtoNodeID - infoStructPos);
					Output.WriteVec3(model.Minimum);
					Output.WriteVec3(model.Maximum);

					// Matrix ID to Node ID data
					Output.WriteUInt32((uint)model.MatrixIDtoNodeID.Length);

					for (int i = 0; i < model.MatrixIDtoNodeID.Length; i++) {
						Output.WriteInt32(model.MatrixIDtoNodeID[i]);
					}


					// ResDicts
					WriteResDict<ByteCode>(model.Bytecode, BytecodeOffsets);
					WriteResDict<Node>(model.Nodes, NodeOffsets);
					WriteResDict<VertexPosData>(model.VtxPosData, VtxPosOffsets);
					if (model.VtxNrmData.Count > 0)
						WriteResDict<VertexNrmData>(model.VtxNrmData, VtxNrmOffsets);
					if (model.VtxClrData.Count > 0)
						WriteResDict<VertexClrData>(model.VtxClrData, VtxClrOffsets);
					if (model.VtxTexCoordData.Count > 0)
						WriteResDict<VertexTexCoordData>(model.VtxTexCoordData, VtxTexCoordOffsets);
					WriteResDict<Material>(model.Materials, MaterialOffsets);
					WriteResDict<Shader>(model.Shaders, ShaderOffsets);
					WriteResDict<Shape>(model.Shapes, ShapeOffsets);
					if (model.PairingLookupByTexture.Count > 0)
						WriteResDict<List<TexMatPairing>>(model.PairingLookupByTexture, PairingOffsets);

					// TODO: Palette pairing lookups

					WritePairings(model, model.PairingLookupByTexture);
					WriteBytecode(model);
					WriteNodes(model);
					WriteMaterials(model);
					WriteShaders(model);
					WriteShapes(model);
					WriteVertexData(model, model.VtxPosData);
					WriteVertexData(model, model.VtxNrmData);
					WriteVertexData(model, model.VtxClrData);
					WriteVertexData(model, model.VtxTexCoordData);
				}
			}
		}

		private void WritePairings(Model m, ResDict<List<TexMatPairing>> dict) {
			foreach (var kv in dict) {
				int startPos = Output.Position;
				Output.WriteUInt32((uint)kv.Value.Count);

				foreach (var pairing in kv.Value) {
					// Material offset
					Output.WriteInt32(MaterialOffsets[pairing.Material] - startPos);

					// Texture info offset, points to the TextureInfo struct in the Material data
					Output.WriteInt32(TextureInfoOffsets[pairing.Texture] - startPos);
				}
			}
		}

		private void WriteBytecode(Model m) {
			foreach (var kv in m.Bytecode) {
				Debug.Send("Writing bytecode {0} @ offset {1:X}", kv.Key, Output.Position);
				ByteCode bc = kv.Value;

				foreach (var insn in bc.Instructions) {
					Output.WriteByte((byte)insn.GetOp());

					switch (insn.GetOp()) {
					case ByteCode.OpType.None:
						break;
					case ByteCode.OpType.Done:
						break;

					case ByteCode.OpType.AssignNodeToParentMtx:
						var op2 = insn as ByteCode.AssignNodeToParentMtxInstruction;
						Output.WriteUInt16(op2.NodeID);
						Output.WriteUInt16(op2.ParentMatrixID);
						break;

					case ByteCode.OpType.BlendMatrices:
						var op3 = insn as ByteCode.BlendMatricesInstruction;
						Output.WriteUInt16(op3.MatrixID);
						Output.WriteByte((byte)op3.BlendedMatrices.Length);

						foreach (var bm in op3.BlendedMatrices) {
							Output.WriteUInt16(bm.MatrixID);
							Output.WriteFloat(bm.Ratio);
						}
						break;

					case ByteCode.OpType.DrawShape:
						var op4 = insn as ByteCode.DrawShapeInstruction;
						Output.WriteUInt16(op4.MaterialID);
						Output.WriteUInt16(op4.ShapeID);
						Output.WriteUInt16(op4.NodeID);
						Output.WriteByte(0);
						break;

					case ByteCode.OpType.AssignMtxToNode:
						var op5 = insn as ByteCode.AssignMtxToNodeInstruction;
						Output.WriteUInt16(op5.MatrixID);
						Output.WriteUInt16(op5.NodeID);
						break;
					}
				}
			}
			
			Output.AlignTo(4);
		}

		private void WriteNodes(Model m) {
			int currentIndex = 0;

			foreach (var kv in m.Nodes) {
				Debug.Send("Writing node {0} @ offset {1:X}", kv.Key, Output.Position);
				Node node = kv.Value;
				int startPos = Output.Position;

				// Size, model offset, name offset, index
				// Reminds me... TODO: remove "Index" from the Node/Material/... classes
				Output.WriteUInt32(0xD0);
				Output.WriteInt32(ModelOffsets[m] - startPos);
				Output.WriteInt32(StringPositions[kv.Key] - startPos);
				Output.WriteUInt32((uint)currentIndex);

				Output.WriteUInt32(node.MatrixID);
				Output.WriteUInt32(node.Flags);
				Output.WriteUInt32((uint)node.BillboardMode);
				Output.WriteUInt32(0);
				// TODO: might be swapped with bbmode, check asm to confirm

				Output.WriteVec3(node.Scale);
				Output.WriteVec3(node.Rotation);
				Output.WriteVec3(node.Translation);
				Output.WriteVec3(node.BoxMin);
				Output.WriteVec3(node.BoxMax);

				// node offsets: parent, child, next, previous
				Output.WriteInt32((node.Parent == null) ? 0 : (NodeOffsets[node.Parent] - startPos));
				Output.WriteInt32((node.FirstChild == null) ? 0 : (NodeOffsets[node.FirstChild] - startPos));
				Output.WriteInt32((node.Next == null) ? 0 : (NodeOffsets[node.Next] - startPos));
				Output.WriteInt32((node.Previous == null) ? 0 : (NodeOffsets[node.Previous] - startPos));

				// extra data offset (currently unhandled)
				Output.WriteInt32(0);

				// matrices
				Output.WriteMatrix(node.NodeMatrix);
				Output.WriteMatrix(node.NodeInvMatrix);

				// done
				currentIndex++;
			}
		}

		private void WriteMaterials(Model m) {
			int currentIndex = 0;

			foreach (var kv in m.Materials) {
				Debug.Send("Writing material {0} @ offset {1:X}", kv.Key, Output.Position);
				Material mat = kv.Value;
				int startPos = Output.Position;

				// size, model offset, name offset, index
				// is size static, or does it change? must verify
				Output.WriteUInt32(0x5E8);
				Output.WriteInt32(ModelOffsets[m] - startPos);
				Output.WriteInt32(StringPositions[kv.Key] - startPos);
				Output.WriteUInt32((uint)currentIndex);

				Output.WriteUInt32(mat.Flags);

				// ResGenMode
				Output.WriteByte(mat.TexCoordGenCount);
				Output.WriteByte(mat.ChanCount);
				Output.WriteByte(mat.TevStageCount);
				Output.WriteByte(mat.IndStageCount);
				Output.WriteUInt32(mat.CullMode);

				// ResMatMisc
				Output.WriteByte(mat.ZCompLoc);
				Output.WriteByte(mat.LightSetID);
				Output.WriteByte(mat.FogID);

				// are these even correct? maybe not
				Output.WriteBytes(mat.IndirectTexMtxCalcMethod1);
				Output.WriteBytes(mat.IndirectTexMtxCalcMethod2);

				// padding -- this is weird, the previous two might be incorrect
				Output.WriteByte(0xFF);

				// more stuff: shader offset, texinfo count, texinfo offset, fur offset, unk offset, DL offset
				Output.WriteInt32(ShaderOffsets[mat.ShaderRef] - startPos);
				Output.WriteInt32(mat.TextureInfos.Count);
				if (mat.TextureInfos.Count > 0)
					Output.WriteInt32(TextureInfoOffsets[mat.TextureInfos[0]] - startPos);
				else
					Output.WriteInt32(0);
				Output.WriteInt32(0);
				Output.WriteInt32(0);
				Output.WriteInt32(MaterialDLOffsets[mat] - startPos);

				// ResTexObj
				UInt32 textureFlag = 0;
				int texObjPadding = 0x100;

				// first calculate the flag
				for (int i = 0; i < 8; i++) {
					if (mat.TexObj[i] != null) {
						textureFlag |= (uint)(1 << i);
						texObjPadding -= 0x20;
					}
				}

				// now write it
				Output.WriteUInt32(textureFlag);
				for (int i = 0; i < 8; i++) {
					if (mat.TexObj[i] != null) {
						Output.WriteBytes(mat.TexObj[i]);
					}
				}

				Output.AddPadding(texObjPadding);

				// ResTlutObj
				Output.WriteUInt32(mat.TlutFlag);

				if (mat.TlutObj == null) {
					Output.AddPadding(0x60);
				} else {
					Output.WriteBytes(mat.TlutObj);
					Output.AddPadding(0x60 - mat.TlutObj.Length);
				}

				// ResTexSrt
				// this one is a bit of a pain
				UInt32 srtFlag = 0;
				int unusedSlots = 8;

				// first, calculate the flag
				for (int i = 0; i < 8; i++) {
					byte thisFlag = 0;

					if (mat.SRTSettings[i] != null) {
						thisFlag |= 1;

						if (mat.SRTSettings[i].ScaleX == 1.0f && mat.SRTSettings[i].ScaleY == 1.0f)
							thisFlag |= 2;

						if (mat.SRTSettings[i].Rotate == 0.0f)
							thisFlag |= 4;

						if (mat.SRTSettings[i].TranslateX == 0.0f && mat.SRTSettings[i].TranslateY == 0.0f)
							thisFlag |= 8;

						unusedSlots--;
					}

					srtFlag |= ((uint)thisFlag << (i * 4));
				}

				Output.WriteUInt32(srtFlag);
				Output.WriteUInt32(mat.TexMatrixType);

				// now write out TexSrt
				for (int i = 0; i < 8; i++) {
					if (mat.SRTSettings[i] != null) {
						Output.WriteFloat(mat.SRTSettings[i].ScaleX);
						Output.WriteFloat(mat.SRTSettings[i].ScaleY);
						Output.WriteFloat(mat.SRTSettings[i].Rotate);
						Output.WriteFloat(mat.SRTSettings[i].TranslateX);
						Output.WriteFloat(mat.SRTSettings[i].TranslateY);
					}
				}

				// frustratingly, the padding here is NOT a section of zeroes, but instead
				// a blank section (scale=1.0 rotate=0.0 translate=0.0).
				for (int i = 0; i < unusedSlots; i++) {
					Output.WriteFloat(1.0f);
					Output.WriteFloat(1.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(0.0f);
				}

				// then write out TexSet
				for (int i = 0; i < 8; i++) {
					if (mat.SRTSettings[i] != null) {
						Output.WriteByte(mat.SRTSettings[i].CameraID);
						Output.WriteByte(mat.SRTSettings[i].LightID);
						Output.WriteByte(mat.SRTSettings[i].MapType);
						Output.WriteByte(mat.SRTSettings[i].Flags);
						Output.WriteMatrix(mat.SRTSettings[i].TexMatrix);
					}
				}

				// and TexSet does the same thing for padding -_-
				for (int i = 0; i < unusedSlots; i++) {
					Output.WriteByte(0xFF);
					Output.WriteByte(0xFF);
					Output.WriteByte(0x00);
					Output.WriteByte(0x01);
					Output.WriteFloat(1.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(1.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(0.0f);
					Output.WriteFloat(1.0f);
					Output.WriteFloat(0.0f);
				}

				// ResMatChan
				for (int i = 0; i < 2; i++) {
					Output.WriteUInt32(mat.ChanCtrls[i].Flags);
					Output.WriteColor(mat.ChanCtrls[i].MatColor);
					Output.WriteColor(mat.ChanCtrls[i].AmbColor);
					Output.WriteUInt32(mat.ChanCtrls[i].FlagC);
					Output.WriteUInt32(mat.ChanCtrls[i].FlagA);
				}

				// Texture Infos
				foreach (var texInfo in mat.TextureInfos) {
					int texInfoPos = Output.Position;

					Output.WriteInt32(texInfo.TextureName == null ? 0 : (StringPositions[texInfo.TextureName] - texInfoPos));
					Output.WriteInt32(texInfo.PaletteName == null ? 0 : (StringPositions[texInfo.PaletteName] - texInfoPos));

					// placeholder pointers
					Output.WriteUInt32(0);
					Output.WriteUInt32(0);

					Output.WriteUInt32(texInfo.TexMapID);
					Output.WriteUInt32(texInfo.TlutID);
					Output.WriteUInt32((uint)texInfo.WrapS);
					Output.WriteUInt32((uint)texInfo.WrapT);
					Output.WriteUInt32(texInfo.MinFilt);
					Output.WriteUInt32(texInfo.MagFilt);
					Output.WriteFloat(texInfo.LODBias);
					Output.WriteUInt32(texInfo.MaxAniso);
					Output.WriteBool(texInfo.BiasClamp);
					Output.WriteBool(texInfo.DoEdgeLOD);
					Output.AddPadding(2);
				}

				// Display Lists
				Output.AlignTo(0x20);

				Output.WriteBytes(mat.PixDL);
				Output.WriteBytes(mat.TevColorDL);
				Output.WriteBytes(mat.IndMtxAndScaleDL);
				Output.WriteBytes(mat.TexCoordGenDL);

				// I can't believe this is done
				currentIndex++;
			}
		}

		private void WriteShaders(Model m) {
			int currentIndex = 0;

			foreach (var shader in ModelCalcInfos[m].UniqueShaders) {
				Debug.Send("Writing shader @ offset {0:X}", Output.Position);
				int startPos = Output.Position;

				// Size, model offset, index
				Output.WriteUInt32((uint)(0x20 + shader.DisplayList.Length));
				Output.WriteInt32(ModelOffsets[m] - startPos);
				// What do I write here...?
				Output.WriteUInt32((uint)currentIndex);

				Output.WriteByte(shader.TevStageCount);
				Output.AddPadding(3);

				Output.WriteUInt32(shader.Unk1);
				Output.WriteUInt32(shader.Unk2);
				Output.AddPadding(8);

				Output.WriteBytes(shader.DisplayList);

				// done
				currentIndex++;
			}
		}

		private void WriteShapes(Model m) {
			int currentIndex = 0;

			foreach (var kv in m.Shapes) {
				Debug.Send("Writing shape {0} @ offset {1:X}", kv.Key, Output.Position);
				Shape shape = kv.Value;

				int startPos = Output.Position;

				// Size, model offset, matrix ID, unknown data
				Output.WriteUInt32((uint)ShapeSizes[shape]);
				Output.WriteInt32(ModelOffsets[m] - startPos);
				Output.WriteInt32(shape.MatrixID);

				Output.WriteBytes(shape.Unk);

				// Display Lists
				int dlBase1 = Output.Position;
				Output.WriteUInt32(shape.DLBufferSize1);
				Output.WriteUInt32((uint)shape.DisplayList1.Length);
				Output.WriteInt32(ShapeDL1Offsets[shape] - dlBase1);

				int dlBase2 = Output.Position;
				Output.WriteUInt32(shape.DLBufferSize2);
				Output.WriteUInt32((uint)shape.DisplayList2.Length);
				Output.WriteInt32(ShapeDL2Offsets[shape] - dlBase2);

				// Indexes and flags and other stuff
				Output.WriteUInt32(shape.DataFlags);
				Output.WriteUInt32(shape.Flags);

				Output.WriteInt32(StringPositions[kv.Key] - startPos);
				Output.WriteUInt32((uint)currentIndex);

				Output.WriteUInt32(shape.VertexCount);
				Output.WriteUInt32(shape.PolygonCount);

				Output.WriteInt16((short)m.VtxPosData.GetIndexForValue(shape.PosData));

				if (shape.NrmData != null)
					Output.WriteInt16((short)m.VtxNrmData.GetIndexForValue(shape.NrmData));
				else
					Output.WriteInt16(-1);

				for (int i = 0; i < 2; i++) {
					if (shape.ClrData[i] != null)
						Output.WriteInt16((short)m.VtxClrData.GetIndexForValue(shape.ClrData[i]));
					else
						Output.WriteInt16(-1);
				}

				for (int i = 0; i < 8; i++) {
					if (shape.TexCoordData[i] != null)
						Output.WriteInt16((short)m.VtxTexCoordData.GetIndexForValue(shape.TexCoordData[i]));
					else
						Output.WriteInt16(-1);
				}

				// Indexes for VtxFurVec and VtxFurPos, not used here
				Output.WriteInt16(-1);
				Output.WriteInt16(-1);

				// Extra data offset (fixed)
				Output.WriteInt32(0x68);

				// Extra data
				Output.WriteInt32(shape.ExtraData.Length);
				for (int i = 0; i < shape.ExtraData.Length; i++)
					Output.WriteUInt16(shape.ExtraData[i]);

				// Display lists
				// Padding is added to fill up the buffer (Display List data size can be smaller than the buffer size)
				Output.AlignTo(0x20);
				Output.WriteBytes(shape.DisplayList1);
				Output.AddPadding((int)(shape.DLBufferSize1 - shape.DisplayList1.Length));
				Output.AlignTo(0x20);
				Output.WriteBytes(shape.DisplayList2);
				Output.AddPadding((int)(shape.DLBufferSize2 - shape.DisplayList2.Length));
				Output.AlignTo(0x20);

				// done!
				currentIndex++;
			}
		}

		private void WriteVertexData<T>(Model m, ResDict<T> dict) where T : VertexDataBase {
			int currentIndex = 0;

			foreach (var kv in dict) {
				Debug.Send("Writing vtxdata {0} @ offset {1:X}", kv.Key, Output.Position);
				int startPos = Output.Position;

				int structSize = 0x20;
				if (kv.Value is VertexPosData || kv.Value is VertexTexCoordData) {
					// Min/max fields, plus alignment
					structSize += 0x20;
				}

				// Size, model offset, data offset, name offset, index
				// For some reason, the raw data length added to the size is aligned...
				Output.WriteUInt32((uint)(((structSize + kv.Value.RawData.Length) + 0x1F) & ~0x1F));
				Output.WriteInt32(ModelOffsets[m] - startPos);
				Output.WriteInt32(structSize);
				Output.WriteInt32(StringPositions[kv.Key] - startPos);
				Output.WriteUInt32((uint)currentIndex);

				// Parameters
				Output.WriteUInt32((uint)kv.Value.ComponentCount);
				Output.WriteUInt32((uint)kv.Value.ComponentType);

				if (kv.Value is VertexClrData) {
					Output.WriteByte(kv.Value.EntrySize);
					Output.AddPadding(1);
				} else {
					Output.WriteByte(kv.Value.Fraction);
					Output.WriteByte(kv.Value.EntrySize);
				}

				Output.WriteUInt16(kv.Value.EntryCount);

				// Type-specific stuff
				if (kv.Value is VertexPosData) {
					var posData = kv.Value as VertexPosData;
					Output.WriteVec3(posData.Minimum);
					Output.WriteVec3(posData.Maximum);

				} else if (kv.Value is VertexTexCoordData) {
					var tcData = kv.Value as VertexTexCoordData;
					Output.WriteVec2(tcData.Minimum);
					Output.WriteVec2(tcData.Maximum);
				}

				Output.AlignTo(0x20);
				Output.WriteBytes(kv.Value.RawData);
				Output.AlignTo(0x20);

				// done!
				currentIndex++;
			}
		}
		#endregion

		#region Texture Writing
		private void WriteTextures() {
			foreach (var kv in File.GetGroup<Texture>("Textures(NW4R)")) {
				using (var c = Debug.Push("Texture: {0}", kv.Key)) {
					Output.AlignTo(0x20);

					int startPos = Output.Position;
					Texture tex = kv.Value;

					// Base struct: magic 'TEX0', block size, version [currently 11], resfile offset
					Output.WriteUInt32(0x54455830);
					Output.WriteUInt32((uint)(0x40 + tex.GetDataSize()));
					Output.WriteUInt32(3);
					Output.WriteInt32(-startPos);

					// Data offset, name offset
					Output.WriteInt32(0x40);
					Output.WriteInt32(StringPositions[kv.Key] - startPos);

					// Flags -- Stores nothing interesting, just an "is CI" flag (0x1)
					// We don't handle that atm, so ignore it
					Output.WriteUInt32(0);

					Output.WriteInt16((short)tex.Images[0].Width);
					Output.WriteInt16((short)tex.Images[0].Height);
					Output.WriteUInt32((uint)tex.Format);

					Output.WriteInt32(tex.Images.Length);
					Output.WriteFloat(tex.MinLOD);
					Output.WriteFloat(tex.MaxLOD);

					Output.AlignTo(0x20);
					for (int i = 0; i < tex.Images.Length; i++)
						Output.WriteBytes(tex.ExportData(i));
				}
			}
		}
		#endregion

		#region ResDicts
		private struct RawDictEntry {
			public ushort Ref;
			public ushort Unk;
			public ushort ILeft;
			public ushort IRight;
		}

		private unsafe void WriteResDict<TValue>(ResDict<TValue> dict, Dictionary<TValue, int> positions) {
			int dictPos = Output.Position;

			// First, I've got to build an in-memory representation of the raw ResDict.
			// Next, I've got to write it out. This'll be fun.
			// This is partly based off the BrawlLib code.

			RawDictEntry[] rd = new RawDictEntry[dict.Count + 1];
			byte[][] encodedNames = new byte[dict.Count + 1][];

			// Before the actual calculation, build that list

			rd[0].Ref = 0xFFFF;
			rd[0].Unk = 0;
			rd[0].ILeft = 0;
			rd[0].IRight = 0;

			encodedNames[0] = new byte[] { };

			for (int i = 1; i <= dict.Count; i++) {
				rd[i].Ref = 0;
				rd[i].Unk = 0;
				rd[i].ILeft = 0;
				rd[i].IRight = 0;

				// I wanted to store the encoded name as a member of RawDictEntry, but C# doesn't let me
				// get a pointer to the struct if I do that -- see Compiler Error CS0208 on MSDN.
				string theName = dict.GetKeyForIndex(i - 1);
				encodedNames[i] = System.Text.Encoding.GetEncoding("Shift_JIS").GetBytes(theName);
			}


			// Now calculate indexes, etc

			for (ushort i = 1; i <= dict.Count; i++) {
				// Using unsafe pointers for convenience
				fixed (RawDictEntry* entry = &rd[i]) {
					ushort prev = 0;
					ushort current = rd[prev].ILeft;

					bool isRight = false;

					int strLen = encodedNames[i].Length;
					byte[] pChar = encodedNames[i];
					byte[] sChar;

					int eIndex = strLen - 1;
					int eBits = CompareBits(pChar[eIndex], 0);
					int val;

					entry->Ref = (ushort)((eIndex << 3) | eBits);
					entry->ILeft = (ushort)i;
					entry->IRight = (ushort)i;

					while ((entry->Ref <= rd[current].Ref) && (rd[prev].Ref > rd[current].Ref)) {
						if (entry->Ref == rd[current].Ref) {
							sChar = encodedNames[current];

							for (eIndex = strLen; (--eIndex > 0) && (pChar[eIndex] == sChar[eIndex]););

							eBits = CompareBits(pChar[eIndex], sChar[eIndex]);

							entry->Ref = (ushort)((eIndex << 3) | eBits);

							if (((sChar[eIndex] >> eBits) & 1) != 0) {
								entry->ILeft = (ushort)i;
								entry->IRight = current;
							} else {
								entry->ILeft = current;
								entry->IRight = (ushort)i;
							}
						}

						isRight = ((val = rd[current].Ref >> 3) < strLen) && (((pChar[val] >> (rd[current].Ref & 7)) & 1) != 0);

						prev = current;
						current = isRight ? rd[current].IRight : rd[current].ILeft;
					}

					sChar = encodedNames[current];
					val = sChar == null ? 0 : sChar.Length;

					if ((val == strLen) && (((sChar[eIndex] >> eBits) & 1) != 0))
						entry->IRight = current;
					else
						entry->ILeft = current;

					if (isRight)
						rd[prev].IRight = i;
					else
						rd[prev].ILeft = i;
				}
			}


			// Now write it
			Output.WriteUInt32((uint)(8 + (rd.Length * 0x10)));
			Output.WriteUInt32((uint)(rd.Length - 1));

			for (int entryID = 0; entryID < rd.Length; entryID++) {
				Output.WriteUInt16(rd[entryID].Ref);
				Output.WriteUInt16(rd[entryID].Unk);
				Output.WriteUInt16(rd[entryID].ILeft);
				Output.WriteUInt16(rd[entryID].IRight);

				if (entryID == 0) {
					Output.WriteInt32(0);
					Output.WriteInt32(0);
				} else {
					// Name offset
					Output.WriteInt32(StringPositions[dict.GetKeyForIndex(entryID - 1)] - dictPos);

					// Data offset
					Output.WriteInt32(positions[dict[entryID - 1]] - dictPos);
				}
			}
		}

		private static int CompareBits(byte b1, byte b2) {
			int b = 0x80;
			for (int i = 7; i != 0; i--) {
				if ((b1 & b) != (b2 & b))
					return i;
				b >>= 1;
			}
			return 0;
		}
		#endregion

		#endregion


		#region String Table Handling
		// Contains the strings while they're being pulled from the ResFile data
		private List<string> StringTable;

		// Once every string used in the .brres is found, CalculateStringTable() is called, which
		// writes the table to an OutputStream and saves every offset
		private Dictionary<string, int> StringPositions;

		private OutputStream StringTableData;


		// Called at the start of the process
		private void InitialiseStringTable() {
			StringTable = new List<string>();
		}

		private void AddString(string str) {
			if (!StringTable.Contains(str)) {
				StringTable.Add(str);
			}
		}

		private void CalculateStringTable() {
			// Hmm... this doesn't work for whatever reason? Might be a Mono thing.
			//StringTable.Sort(StringComparer.Create(System.Globalization.CultureInfo.InvariantCulture, false));
			StringTable.Sort(StringComparer.Ordinal);

			StringPositions = new Dictionary<string, int>();
			StringTableData = new OutputStream(ByteEndian.BigEndian);

			// Note: once all calculation is done, CurrentPos stores the address of the string table

			foreach (var s in StringTable) {
				// Add 4 because the Names are referenced by the string data, and not by the ResName struct itself
				StringPositions[s] = CurrentPos + StringTableData.Position + 4;
				StringTableData.WriteName(s);
			}
		}
		#endregion
	}
}