static void CompressElement(Stream outtxa, Image <Rgba32> image, IndexEntry indexEntry, bool useDict)
{
int strideBytes, neededSize;
if (useDict)
{
strideBytes = (image.Width + 3) & 0x7fffc;
neededSize = 1024 + image.Height * strideBytes;
}
else
{
strideBytes = (4 * image.Width + 15) & 0x7fff0;
neededSize = image.Height * strideBytes;
}
var buffer = ArrayPool <byte> .Shared.Rent(neededSize);
try
{
if (useDict)
{
ShinTextureCompress.EncodeDict(image, 0, 0, image.Width, image.Height,
MemoryMarshal.Cast <byte, Rgba32>(buffer.AsSpan()[..1024]),
public static unsafe void EncodePicture(Stream outpic, Image <Rgba32> image,
int effectiveWidth, int effectiveHeight, uint pictureId, Origin origin, ShinTextureCompress.FragmentCompressionConfig fragmentCompressionConfig)
{
Trace.Assert(effectiveWidth > 0 && effectiveHeight > 0);
// Split image into fragments
// this algorithm does not match the one used originally __exactly__, but seems to give close results
// probably the order of checks and size transformations is different in the tool
// this is good enough for me :shrug:
int minX = int.MaxValue,
maxX = int.MinValue,
minY = int.MaxValue,
maxY = int.MinValue;
Trace.Assert(effectiveHeight <= image.Height);
Trace.Assert(effectiveWidth <= image.Width);
for (var j = 0; j < effectiveHeight; j++)
{
var row = image.GetPixelRowSpan(j);
for (var i = 0; i < effectiveWidth; i++)
{
if (row[i].A > 0)
{
minX = Math.Min(minX, i);
minY = Math.Min(minY, j);
maxX = Math.Max(maxX, i);
maxY = Math.Max(maxY, j);
}
}
}
var preliminaryFragments = new List <Rectangle>();
for (var j = minY; j <= maxY; j += MagicHeight)
{
for (var i = minX; i <= maxX; i += MagicWidth)
{
var h = Math.Min(j + MagicHeight, effectiveHeight) - j;
while (i <= maxX && IsBorderEmptyV(image, i, j, h))
{
i++;
}
if (i > maxX)
{
break;
}
var w = Math.Min(i + MagicWidth, effectiveWidth) - i;
preliminaryFragments.Add(new Rectangle(i, j, w, h));
}
}
var fragments = preliminaryFragments
.Select(frag =>
{
// make sure it's in the image bounds
var shrinkY = frag.Bottom - Math.Min(frag.Bottom, maxY + 1);
var shrinkX = frag.Right - Math.Min(frag.Right, maxX + 1);
frag.Width -= shrinkX;
frag.Height -= shrinkY;
if (frag.Width <= 0 && frag.Height <= 0)
{
return(frag);
}
// shrink the top
while (frag.Width > 0 && frag.Height > 0 && IsBorderEmptyH(image, frag.X, frag.Top, frag.Width))
{
frag.Y++;
frag.Height--;
}
// shrink the bottom
while (frag.Width > 0 && frag.Height > 0 && IsBorderEmptyH(image, frag.X, frag.Bottom - 1, frag.Width))
{
frag.Height--;
}
// shrink the left
while (frag.Width > 0 && frag.Height > 0 && IsBorderEmptyV(image, frag.Left, frag.Y, frag.Height))
{
frag.X++;
frag.Width--;
}
// shrink the right
while (frag.Width > 0 && frag.Height > 0 && IsBorderEmptyV(image, frag.Right - 1, frag.Y, frag.Height))
{
frag.Width--;
}
return(frag);
})
.Where(frag => frag.Width > 0 && frag.Height > 0)
.ToImmutableArray();
// we have one more padding to add: in case if fragment does not have directly adjacent fragments to the right or bottom,
// it's width or height (respectively) needs to be incremented
// unfortunately linear, which makes the algorithm O(n^2)
// but hey, nobody will pass huge pictures here, right?..
bool CheckAdj(bool isBottom, Rectangle rect)
{
var rectButt = isBottom
? new Rectangle(rect.X, rect.Bottom - 1, rect.Width, 1)
: new Rectangle(rect.Right - 1, rect.Y, 1, rect.Height);
//? new Rectangle(rect.X + 1, rect.Bottom - 1, rect.Width - 2, 1)
//: new Rectangle(rect.Right - 1, rect.Y + 1, 1, rect.Height - 2);
Trace.Assert(rectButt.Width > 0 && rectButt.Height > 0);
for (var i = 0; i < fragments.Length; i++)
{
if (fragments[i] != rect && fragments[i].IntersectsWith(rectButt))
{
return(true);
}
}
return(false);
}
fragments = fragments
.Select(frag =>
{
// add another bit of padding to match the original encoder results
frag.X -= 1;
frag.Width += 2;
frag.Y -= 1;
frag.Height += 2;
if (frag.X < 0)
{
frag.X = 0;
}
if (frag.Y <= 0)
{
frag.Y = 0;
}
return(frag);
})
.Select(frag =>
{
// hello, O(n^2), my old friend...
if (!CheckAdj(false, frag))
{
frag.Width++;
}
if (!CheckAdj(true, frag))
{
frag.Height++;
}
return(frag);
}).ToImmutableArray();
//Console.WriteLine(JsonConvert.SerializeObject(fragments.Select(f => new
// {f.X, f.Y, f.Width, f.Height}), Formatting.Indented));
// now we need to do the dedup
// notice: dedup works before the quantization, so it might not catch all cases
// nah, should be fine
uint HashFragment(Rectangle rect)
{
rect.Deconstruct(out var dx, out var dy, out var width, out var height);
if (dx + width > image.Width)
{
width -= dx + width - image.Width;
}
if (dy + height > image.Height)
{
height -= dy + height - image.Height;
}
HashSet <Rgba32> values = new();
uint hash = 5381;
for (var j = dy; j < dy + height; j++)
{
for (var i = dx; i < dx + width; i++)
{
var v = image[i, j];
if (v.A == 0)
{
v = Rgba32.Transparent;
}
hash = ((hash << 5) + hash) + v.PackedValue;
}
}
return(hash);
}
bool CompareFragments(Rectangle a, Rectangle b)
{
a.Intersect(image.Bounds());
b.Intersect(image.Bounds());
if (a.Size != b.Size)
{
return(false);
}
for (var j = 0; j < a.Height; j++)
{
var rowA = image.GetPixelRowSpan(a.Y + j).Slice(a.X, a.Width);
var rowB = image.GetPixelRowSpan(b.Y + j).Slice(b.X, b.Width);
if (!rowA.SequenceEqual(rowB))
{
return(false);
}
}
return(true);
}
var hashToIndex = new Dictionary <uint, List <int> >();
for (var i = 0; i < fragments.Length; i++)
{
var frag = fragments[i];
var hashValue = HashFragment(frag);
if (!hashToIndex.TryGetValue(hashValue, out var list))
{
hashToIndex[hashValue] = list = new List <int>();
}
list.Add(i);
}
var physicalFragments = new List <Rectangle>();
//var virtualFragmentsToPhysical = new Dictionary<int, int>();
var physicalFragmentsToVirtual = new Dictionary <int, List <int> >();
foreach (var(_, v) in hashToIndex)
{
var hs = v.ToHashSet();
while (hs.Count > 0)
{
var index = hs.First();
var sameValues = new List <int> {
index
};
sameValues.AddRange(hs
.Where(i => i != index && CompareFragments(fragments[i], fragments[index])));
foreach (var i in sameValues)
{
hs.Remove(i);
}
var physicalIndex = physicalFragments.Count;
physicalFragments.Add(fragments[index]);
physicalFragmentsToVirtual[physicalIndex] = sameValues;
//foreach (var i in sameValues)
// virtualFragmentsToPhysical.Add(i, physicalIndex);
}
}
var(originX, originY) = origin switch
{
Origin.TopLeft => (0, 0),
Origin.Top => (effectiveWidth / 2, 0),
Origin.TopRight => (effectiveWidth, 0),
Origin.Left => (0, effectiveHeight / 2),
Origin.Center => (effectiveWidth / 2, effectiveHeight / 2),
Origin.Right => (effectiveWidth, effectiveHeight / 2),
Origin.BottomLeft => (0, effectiveHeight),
Origin.Bottom => (effectiveWidth / 2, effectiveHeight),
Origin.BottomRight => (effectiveWidth, effectiveHeight),
_ => throw new ArgumentOutOfRangeException(nameof(origin), origin, null)
};
var header = new PicHeader
{
magic = 0x34434950,
version = 2,
// fileSize!
effectiveHeight = checked ((ushort)effectiveHeight),
effectiveWidth = checked ((ushort)effectiveWidth),
entryCount = checked ((ushort)fragments.Length),
originX = checked ((ushort)originX),
originY = checked ((ushort)originY),
field20 = 1, // this value is set in __most__ pictures, excluding __some__ from /picture/e/ directory
pictureId = pictureId
};
var dataOffset = sizeof(PicHeader) + fragments.Length * sizeof(PicHeaderFragmentEntry);
var currentOffset = dataOffset;
outpic.Seek(dataOffset, SeekOrigin.Begin);
var fragmentEntries = new PicHeaderFragmentEntry[fragments.Length];
foreach (var(i, frag) in physicalFragments.Select((x, i) => (i, x)))
{
var p1 = outpic.Position;
var sz = ShinTextureCompress.EncodeImageFragment(outpic, image, frag.X, frag.Y,
0, 0, frag.Width, frag.Height, fragmentCompressionConfig);
var p2 = outpic.Position;
Debug.Assert(p2 - p1 == sz);
foreach (var virtualIndex in physicalFragmentsToVirtual[i])
{
var virtualRect = fragments[virtualIndex];
fragmentEntries[virtualIndex] = new PicHeaderFragmentEntry
{
x = checked ((ushort)virtualRect.X),
y = checked ((ushort)virtualRect.Y),
offset = checked ((uint)currentOffset),
size = checked ((uint)sz),
};
}
currentOffset += sz;
}
Trace.Assert(currentOffset == outpic.Length);
var fragmentEntriesArray = fragmentEntries.ToImmutableArray();
outpic.Seek(0, SeekOrigin.Begin);
header.fileSize = checked ((uint)currentOffset);
outpic.Write(SpanUtil.AsBytes(ref header));
outpic.Write(MemoryMarshal.Cast <PicHeaderFragmentEntry, byte>(fragmentEntriesArray.AsSpan()));
Trace.Assert(dataOffset == outpic.Position);
}
