/// <summary>
/// Creates a byte array from this JMP.
/// </summary>
/// <returns>The JMP as a byte array.</returns>
public byte[] Write()
{
MemoryStream stream = new MemoryStream();
DhBinaryWriter bw = new DhBinaryWriter(stream, DhEndian.Big);
uint entryOffset = CalculateEntryOffset();
uint entrySize = CalculateEntrySize();
bw.WriteU32((uint)Entries.Count);
bw.WriteU32((uint)Fields.Count);
bw.WriteU32(entryOffset);
bw.WriteU32(entrySize);
for (int i = 0; i < Fields.Count; i++)
{
Fields[i].Write(bw);
}
for (int i = 0; i < Entries.Count; i++)
{
bw.Goto(entryOffset + (i * entrySize));
Entries[i].Write(bw, Fields);
}
bw.Back(0);
bw.WritePadding32('@');
return(stream.ToArray());
}
/// <summary>
/// Creates a byte array from this TMB.
/// </summary>
/// <returns>The TMB as a byte array.</returns>
public byte[] Write()
{
// Define a stream to hold our TMB data.
MemoryStream stream = new MemoryStream();
// Define a binary writer to write with.
DhBinaryWriter bw = new DhBinaryWriter(stream, DhEndian.Big);
// Write the amount of sequences.
bw.WriteU16((ushort)Sequences.Count);
// Find the largest duration value in each keyframe in each sequence.
float longestDuration = Sequences.Max(s => s.KeyFrames.Max(k => k.Time));
// Write the largest duration. (This is the duration of the timing)
bw.WriteU16((ushort)longestDuration);
// Write placeholder for sequence data offset.
bw.WriteU32(0);
// Loop through sequences within this bank.
foreach (TMBSequence sequence in Sequences)
{
// Loop through keyframe's within this sequence.
foreach (TIMKeyFrame keyframe in sequence.KeyFrames)
{
// Write this keyframe.
keyframe.Write(bw);
}
}
// Save the sequence data offset.
uint sequenceDataOffset = (uint)bw.Position();
// Goto sequence data offset value.
bw.Goto(4);
// Write sequence data offset.
bw.WriteU32(sequenceDataOffset);
// Go back to end of stream.
bw.Back(0);
// Loop through sequences within this bank.
foreach (TMBSequence sequence in Sequences)
{
// Write this sequence.
sequence.Write(bw);
}
// Pad to nearest whole 32.
bw.WritePadding32();
// Return the TMB as byte array.
return(stream.ToArray());
}
/// <summary>
/// Creates a stream from this JMP.
/// </summary>
/// <returns>The JMP as a stream.</returns>
public Stream Write()
{
// Define a stream to hold our GEB data.
Stream stream = new MemoryStream();
// Define a binary writer to write with.
DhBinaryWriter bw = new DhBinaryWriter(stream, DhEndian.Big);
// Write JMP's Header
bw.WriteU32((uint)Entries.Count);
bw.WriteU32((uint)Fields.Count);
bw.WriteU32(EntryOffset);
bw.WriteU32(EntrySize);
// Write JMP's Fields
for (int i = 0; i < Fields.Count; i++)
{
Fields[i].Write(bw);
}
// Seek to beginning of file.
bw.Goto(0);
// Write JMP's Entries
for (int i = 0; i < Entries.Count; i++)
{
bw.Goto(EntryOffset + (i * EntrySize));
Entries[i].Write(bw, Fields);
}
// Back up from the end of the file.
bw.Back(0);
// Pad file with @'s to nearest whole 32 bytes.
bw.WritePadding32('@');
// Returns the JMP as a stream.
return(stream);
}
/// <summary>
/// Creates a byte array from this BIN.
/// </summary>
/// <returns>The BIN as a byte array.</returns>
public byte[] Write()
{
// Define a stream to hold our BIN data.
MemoryStream stream = new MemoryStream();
// Define a binary writer to write with.
DhBinaryWriter bw = new DhBinaryWriter(stream, DhEndian.Big);
// Define a buffer to store our offsets.
uint[] offsets = new uint[21];
// Write version.
bw.Write(Version);
// Write model Name.
bw.WriteFixedStr(ModelName, 11);
// Write offsets.
bw.WriteU32s(Offsets);
// Make sure bin has textures.
if (Textures.Count > 0)
{
// Set textures offset.
offsets[0] = (uint)bw.Position();
// Define a array to temporarily
uint[] textureDataOffsets = new uint[Textures.Count];
// Write texture headers. (CALCULATED)
bw.Write(new byte[Textures.Count * 0x0C]);
// Pad to nearest whole 32.
bw.WritePadding32();
// Loop through textures to write texture data.
for (int i = 0; i < textureDataOffsets.Length; i++)
{
// Get actual offset of texture data.
textureDataOffsets[i] = (uint)bw.Position() - offsets[0];
// Write texture data.
bw.Write(Textures[i].Data);
}
// Store this so we can resume after writing the texture headers.
long currentOffset = (uint)bw.Position();
// Pad to nearest whole 32.
bw.WritePadding32();
// Goto textures offset.
bw.Goto(offsets[0]);
// Loop through textures to write texture headers.
for (int i = 0; i < Textures.Count; i++)
{
// Write texture width.
bw.WriteU16(Textures[i].Width);
// Write texture height.
bw.WriteU16(Textures[i].Height);
// Write texture format.
bw.Write((byte)Textures[i].Format);
// Write texture alpha flag.
bw.Write(Textures[i].AlphaFlag);
// Write padding.
bw.WriteU16(0);
// Write texture dataoffset.
bw.WriteU32(textureDataOffsets[i]);
}
// Goto resume point.
bw.Goto(currentOffset);
// Pad to nearest whole 32.
bw.WritePadding32();
}
// Make sure bin has materials.
if (Materials.Count > 0)
{
// Set materials offset.
offsets[1] = (uint)bw.Position();
// Loop through materials.
for (int i = 0; i < Materials.Count; i++)
{
// Write material.
Materials[i].Write(bw);
}
// Pad to nearest whole 32.
bw.WritePadding32();
}
// Make sure bin has positions.
if (Positions.Count > 0)
{
// Set positions offset.
offsets[2] = (uint)bw.Position();
// Loop through positions.
for (int i = 0; i < Positions.Count; i++)
{
// Write position.
bw.WriteS16s(new short[] { (short)(Positions[i].X * 256.0f), (short)(Positions[i].Y * 256.0f), (short)(Positions[i].Z * 256.0f) });
}
// Pad to nearest whole 32.
bw.WritePadding32();
}
// Make sure bin has normals.
if (Normals.Count > 0)
{
// Set normals offset.
offsets[3] = (uint)bw.Position();
// Loop through normals.
for (int i = 0; i < Normals.Count; i++)
{
// Write normal.
bw.WriteVec3(Normals[i]);
}
// Pad to nearest whole 32.
bw.WritePadding32();
}
// SKIP COLOR0
offsets[4] = (uint)0;
// SKIP COLOR1
offsets[5] = (uint)0;
// Make sure bin has texture coordinates 0.
if (TextureCoordinates0.Count > 0)
{
// Set texture coordinates 0 offset.
offsets[6] = (uint)bw.Position();
// Loop through texture coordinates 0.
for (int i = 0; i < TextureCoordinates0.Count; i++)
{
// Write texture coordinate 0.
bw.WriteVec2(TextureCoordinates0[i]);
}
// Pad to nearest whole 32.
bw.WritePadding32();
}
// SKIP TEXTURE COORDINATES 1
offsets[7] = (uint)0;
// SKIP TEXTURE COORDINATES 2 (?)
offsets[8] = (uint)0;
// SKIP TEXTURE COORDINATES 3 (?)
offsets[9] = (uint)0;
// Make sure bin has shaders.
if (Shaders.Count > 0)
{
// Set shaders offset.
offsets[10] = (uint)bw.Position();
// Loop through shaders.
for (int i = 0; i < Shaders.Count; i++)
{
// Write shader.
Shaders[i].Write(bw);
}
// Pad to nearest whole 32.
bw.WritePadding32();
}
// Make sure bin has batches.
if (Batches.Count > 0)
{
// Set batches offset.
offsets[11] = (uint)bw.Position();
// Loop through batches.
for (int i = 0; i < Batches.Count; i++)
{
// Write batch headers.
Batches[i].Write(bw);
}
// Pad to nearest whole 32.
bw.WritePadding32();
// We need to store this stuff somewhere
long[] listStarts = new long[Batches.Count];
long[] listEnds = new long[Batches.Count];
// Loop through batches. (Write primitives)
for (int i = 0; i < Batches.Count; i++)
{
// We'll store this offset for later.
listStarts[i] = bw.Position();
// Loop through primitives.
for (int y = 0; y < Batches[i].Primitives.Count; y++)
{
// Write primitive.
Batches[i].Primitives[y].Write(bw, Batches[i].VertexAttributes);
}
// We'll store this offset for later.
listEnds[i] = bw.Position();
}
// This offset is where we'll continue writing from.
long currentOffset = bw.Position();
// Loop through batches. (Write offsets)
for (int i = 0; i < Batches.Count; i++)
{
// Goto current batch's offset.
bw.Goto(offsets[11] + i * 24);
// Skip 2 bytes.
bw.Sail(2);
// Write list size represented as 32 byte blocks.
bw.WriteS16((short)(Math.Ceiling((float)(listEnds[i] - listStarts[i]) / 32)));
// Skip 8 bytes.
bw.Sail(8);
// Write primitive list offset.
bw.WriteU32((uint)(listStarts[i] - offsets[11]));
}
// Goto continue point we saved earlier.
bw.Goto(currentOffset);
// Pad to nearest whole 32.
bw.WritePadding32();
}
// Make sure bin has graphobjects.
if (GraphObjects.Count > 0)
{
// Set graphObjects offset.
offsets[12] = (uint)bw.Position();
// Loop through graphObjects.
for (int i = 0; i < GraphObjects.Count; i++)
{
// Write graphObject headers.
GraphObjects[i].Write(bw);
}
// Pad to nearest whole 16.
bw.WritePadding16();
// Array to hold graphobject's parts offset.
long[] graphObjectsPartsOffsets = new long[GraphObjects.Count];
// Loop through graphObjects. (Write parts)
for (int i = 0; i < GraphObjects.Count; i++)
{
// Store this graphobject's part offset.
graphObjectsPartsOffsets[i] = bw.Position();
// Loop through graphobject's parts.
for (int y = 0; y < GraphObjects[i].Parts.Count; y++)
{
// Write graphobject's parts.
GraphObjects[i].Parts[y].Write(bw);
}
}
// This offset is where we'll continue writing from.
long currentOffset = bw.Position();
// Loop through graphObjects. (Write offsets)
for (int i = 0; i < GraphObjects.Count; i++)
{
// Goto current graphobject's part offset.
bw.Goto(offsets[12] + (i * 140));
// Skip 80 bytes.
bw.Sail(80);
// Write graphobject's part offset.
bw.WriteU32((uint)(graphObjectsPartsOffsets[i] - offsets[12]));
}
// Goto continue point we saved earlier.
bw.Goto(currentOffset);
}
// Goto offsets section.
bw.Goto(12);
// Write offsets.
bw.WriteU32s(offsets);
// Goto end of file.
bw.Back(0);
// Pad to nearest whole 16.
bw.WritePadding16();
// Return the BIN as a byte array.
return(stream.ToArray());
}
/// <summary>
/// Creates a stream from this TXP.
/// </summary>
/// <returns>The TXP as a stream.</returns>
public Stream Write()
{
// Buffer for new TXP File
Stream stream = new MemoryStream();
// Define a binary writer to write with.
DhBinaryWriter bw = new DhBinaryWriter(stream, DhEndian.Big);
// Write Unknown 1.
bw.WriteU16(Unknown1);
// Write Unknown 2.
bw.WriteU16(Unknown2);
// Write Entry Count.
bw.WriteU16((ushort)Entries.Count);
// Check if Entry Count is greater than 0.
if (Entries.Count > 0)
{
// Write Keyframe Count.
bw.WriteU16((ushort)Entries[0].Indices.Count);
}
else
{
// Write 0.
bw.WriteU16(0);
}
// Write Keyframe Offset.
bw.WriteU32((uint)(12 + (Entries.Count * 12)));
// Loop through entries.
for (int i = 0; i < Entries.Count; i++)
{
// Write entry header.
Entries[i].WriteHeader(bw);
}
// Define a list to hold the offsets for each keyframe offsets.
List <uint> indicesOffsets = new List <uint>();
// Loop through entries.
for (int i = 0; i < Entries.Count; i++)
{
// Save the current offset
indicesOffsets.Add((uint)bw.Position());
// Write entry indices.
Entries[i].WriteIndices(bw);
}
// Loop through entries.
for (int i = 0; i < Entries.Count; i++)
{
// Go to current entry's indices offset value.
bw.Goto(0x0C + (i * 12) + 8);
// Write indices offset.
bw.WriteU32(indicesOffsets[i]);
}
// Return to end of file.
bw.Back(0);
// Write padding to nearest whole 32 bytes.
bw.WritePadding32();
// Return the TXP as a stream
return(stream);
}
