/// <summary>
/// Calculates the code for overlapping multiple brightness gradients.
/// <para>The final code will use the channel of the first BrightnessHDMA object passed.</para>
/// </summary>
/// <param name="hdma">An array of BrightnessHDMA object that will be overlapped for the final code.</param>
/// <returns>The final code.</returns>
public static string MultiCode(params BrightnessHDMA[] hdma)
{
if (hdma == null || hdma.Length == 0)
{
return(null);
}
int channel = hdma[0].Channel;
EffectClasses.HDMATable table = new HDMATable(".BrightTable");
using (Bitmap b = BitmapEffects.OverlapImages(hdma.Select(h => h.EffectImage).ToArray()))
{
byte scanlines = 1;
int now = 0;
int compare = 0x0F - (b.GetPixel(0, 0).A / 17);
for (int y = 1; y < b.Height; y++, scanlines++)
{
now = 0x0F - (b.GetPixel(0, y).A / 17);
if (compare != now || scanlines >= 0x80)
{
table.Add(new HDMATableEntry(TableValueType.db, scanlines, (byte)compare));
compare = now;
scanlines = 0;
}
}
if (table.TotalScanlines != Scanlines)
{
table.Add(new HDMATableEntry(TableValueType.db, scanlines, (byte)now));
}
table.Add(HDMATableEntry.End);
DMAMode mode = (table[0].Values.Length == 1 ? DMAMode.P : DMAMode.PP);
ASMCodeBuilder code = new ASMCodeBuilder();
int channelAdd = 16 * channel;
table.Name = ".BrightTable";
code.AppendLabel(INITLabel, "Code to be inserted INIT");
code.OpenNewBlock();
code.AppendCode("\tREP #$20", "16 bit mode");
code.AppendCode("\tLDA #$" + (((Registers.Brightness & 0xFF) << 8) + (int)mode).ToString("X4"));
code.AppendCode("\tSTA $" + (Registers.DMAMode + channelAdd).ToString("X4"));
code.AppendCode("\tLDA #" + table.Name, "load high and low byte of table address");
code.AppendCode("\tSTA $" + (Registers.DMALowByte + channelAdd).ToString("X4"));
code.AppendCode("\tSEP #$20", "back to 8 bit mode");
code.AppendCode("\tLDA.b #" + table.Name + ">>16", "load bank byte of table address");
code.AppendCode("\tSTA $" + (Registers.DMABankByte + channelAdd).ToString("X4"));
code.AppendCode("\tLDA #$" + (1 << channel).ToString("X2"));
code.AppendCode("\tTSB $" + RAM.HDMAEnable[RAM.SA1].ToString("X4"), "enable HDMA channel " + channel);
code.AppendCode("\tRTS");
code.CloseBlock();
code.AppendEmptyLine();
code.AppendTable(table);
return(code.ToString());
}
}
/// <summary>
/// Sets up the color math and calculates the values for the HDMA table based on the entries of Values
/// </summary>
private void Setup()
{
Table.Clear();
byte totalScanlines = 0;
Bitmap bg1 = OriginalImages.BG1;
Bitmap bg2 = OriginalImages.BG2;
Bitmap bg3 = OriginalImages.BG3;
Bitmap bg4 = OriginalImages.BG4;
foreach (PixelScanline pix in Values)
{
if (pix.Scanline > 0x80)
{
Table.Add(new HDMATableEntry(TableValueType.db, 0x80, (byte)((pix.Pixelation << 4) + (byte)pix.BGs)));
Table.Add(new HDMATableEntry(TableValueType.db, (byte)(pix.Scanline - 0x80), (byte)((pix.Pixelation << 4) + (byte)pix.BGs)));
}
else
{
Table.Add(new HDMATableEntry(TableValueType.db, pix.Scanline, (byte)((pix.Pixelation << 4) + (byte)pix.BGs)));
}
if (pix.BGs.HasFlag(PixelationBGs.BG1))
{
bg1 = BitmapEffects.PixelLine(pix.Scanline, pix.Pixelation, totalScanlines, bg1);
}
if (pix.BGs.HasFlag(PixelationBGs.BG2))
{
bg2 = BitmapEffects.PixelLine(pix.Scanline, pix.Pixelation, totalScanlines, bg2);
}
if (pix.BGs.HasFlag(PixelationBGs.BG3))
{
bg3 = BitmapEffects.PixelLine(pix.Scanline, pix.Pixelation, totalScanlines, bg3);
}
if (pix.BGs.HasFlag(PixelationBGs.BG4))
{
bg4 = BitmapEffects.PixelLine(pix.Scanline, pix.Pixelation, totalScanlines, bg4);
}
totalScanlines += pix.Scanline;
if (totalScanlines >= Scanlines)
{
break;
}
}
if (totalScanlines < Scanlines)
{
Table.Add(new HDMATableEntry(TableValueType.db, 1, 0));
}
ColorMath.BG1 = bg1;
ColorMath.BG2 = bg2;
ColorMath.BG3 = bg3;
ColorMath.BG4 = bg4;
ColorMath.OBJ = OriginalImages.OBJ;
Table.Add(HDMATableEntry.End);
}
public ColorMath(BitmapCollection Collection) : this()
{
BG1 = Collection.BG1;
BG2 = Collection.BG2;
BG3 = Collection.BG3;
BG4 = Collection.BG4;
OBJ = Collection.OBJ;
FixedColor = BitmapEffects.FromColor(Collection.FixedColor, LayerSizes);
}
/// <summary>
/// Creates a base image with the preset setting of Amplitede and Width
/// </summary>
/// <param name="basePic">The base for the disordered image</param>
/// <returns>The according to the settings disordered image</returns>
public override Bitmap StaticPic(Bitmap basePic)
{
Reset();
Bitmap NewOne = new Bitmap(basePic);
//NewOne gets overwritten with the disordered image.
//_Breite * i sets the start of the to move setction.
//_Breite sets how thick the to move section is.
//_IArr[i % 16] says how many pixel to move the image to the right.
for (int i = 0; i *_width < NewOne.Height; i++)
{
NewOne = BitmapEffects.MoveLine((_width * i), _width, _IArr[i % 16] / 2, NewOne, Direction);
}
if (!EnableTable)
{
return(NewOne);
}
using (Graphics g = Graphics.FromImage(NewOne))
{
int totalCount = 0;
foreach (var entry in EnabledWaveCollection)
{
int height = entry.LineCount;
if (!entry.Value)
{
if (NewOne.Height <= totalCount + height)
{
height = NewOne.Height - totalCount;
}
var rec = Original.Clone(new Rectangle(0, totalCount, NewOne.Width, height), NewOne.PixelFormat);
g.DrawImage(rec, 0, totalCount);
}
totalCount += height;
if (totalCount >= NewOne.Height)
{
break;
}
}
/*
* if (totalCount < bm.Height)
* g.DrawImage(
* _yEffect.Original.Clone(new Rectangle(0, totalCount, bm.Width, (bm.Height - totalCount)),
* bm.PixelFormat), 0, totalCount);*/
}
return(NewOne);
}
internal void UpdateImage()
{
if (Table == null)
{
return;
}
Bitmap bm = BitmapEffects.FromColor(Color.Transparent, 1, Scanlines);
int counter = 0;
foreach (HDMATableEntry entry in Table)
{
if (entry.ValueType == TableValueType.End)
{
break;
}
if (entry.ValueType == TableValueType.Single)
{
for (int y = counter; y < counter + entry.Scanlines - 0x80 && y < Scanlines; y++)
{
for (int x = 0; x < bm.Width; x++)
{
bm.SetPixel(x, y, Color.FromArgb(255 - (entry.Values[y] & 0x0F) * 17, 0, 0, 0));
}
}
counter += entry.Scanlines - 0x80;
}
else if (entry.ValueType == TableValueType.db)
{
for (int y = counter; y < counter + entry.Scanlines && y < Scanlines; y++)
{
for (int x = 0; x < bm.Width; x++)
{
bm.SetPixel(x, y, Color.FromArgb(255 - (entry.Values[0] & 0x0F) * 17, 0, 0, 0));
}
}
counter += entry.Scanlines;
}
else
{
//fixme exception
throw new HDMAException();
}
}
Bitmap retImg = new Bitmap(256, Scanlines);
using (TextureBrush brush = new TextureBrush(bm, WrapMode.Tile))
using (Graphics gr = Graphics.FromImage(retImg))
gr.FillRectangle(brush, 0, 0, retImg.Width, retImg.Height);
EffectImage = retImg;
}
/// <summary>
/// Combines two black/white masks in a new bitmap
/// </summary>
/// <param name="mask1">The first mask for the merge</param>
/// <param name="mask2">The second mask for the merge</param>
/// <param name="logic">How to merge the masks</param>
/// <returns>The merged masks</returns>
private Bitmap MergeMasks(Bitmap mask1, Bitmap mask2, WindowMaskLogic logic)
{
Bitmap[] windowLogicMasks = new Bitmap[4];
Rectangle maskRec = new Rectangle(new Point(0, 0), mask2.Size);
//needs to run if there is any OR, XOR, XNOR => baiscally if there is any that is not And
if (logic != WindowMaskLogic.And)
{
Bitmap mask = new Bitmap(mask1);
ImageAttributes attr = new ImageAttributes();
attr.SetColorKey(Color.White, Color.White);
using (Graphics g = Graphics.FromImage(mask))
{
g.DrawImage(mask2, maskRec, maskRec.X, maskRec.Y,
maskRec.Width, maskRec.Height, GraphicsUnit.Pixel, attr);
}
windowLogicMasks[(int)WindowMaskLogic.Or] = mask;
}
//needs to run if there is any AND, XOR, XNOR => baiscally if there is any that is not Or
if (logic != WindowMaskLogic.Or)
{
Bitmap mask = new Bitmap(mask1);
ImageAttributes attr = new ImageAttributes();
attr.SetColorKey(Color.Black, Color.Black);
using (Graphics g = Graphics.FromImage(mask))
{
g.DrawImage(mask2, maskRec, maskRec.X, maskRec.Y,
maskRec.Width, maskRec.Height, GraphicsUnit.Pixel, attr);
}
windowLogicMasks[(int)WindowMaskLogic.And] = mask;
}
if (logic == WindowMaskLogic.Xor || logic == WindowMaskLogic.XNor)
{
Bitmap mask = new Bitmap(windowLogicMasks[(int)WindowMaskLogic.Or]);
ImageAttributes attr = new ImageAttributes();
attr.SetColorKey(Color.Black, Color.Black);
using (Graphics g = Graphics.FromImage(mask))
{
g.DrawImage(BitmapEffects.Invert(windowLogicMasks[(int)WindowMaskLogic.And]),
maskRec, maskRec.X, maskRec.Y, maskRec.Width, maskRec.Height, GraphicsUnit.Pixel, attr);
}
mask.Save("XOR.png");
windowLogicMasks[(int)WindowMaskLogic.Xor] = mask;
windowLogicMasks[(int)WindowMaskLogic.XNor] = BitmapEffects.Invert(mask);
}
return(windowLogicMasks[(int)logic]);
}
public override Bitmap NextAnimateFrame(Bitmap basePic)
{
Bitmap newBM = new Bitmap(basePic);
int offset = 0;
foreach (var bar in Bars)
{
Bitmap single;
int index = (int)(bar.Multiplier * Frame) % _frames.Length;
if (_frames[index] == null)
{
single = BitmapEffects.MoveLine(0, basePic.Height, index, basePic, Orientation.Left);
_frames[index] = single;
}
else
{
single = _frames[index];
}
using (Graphics g = Graphics.FromImage(newBM))
{
int scanlines = 0;
if (offset + bar.Scanline >= basePic.Height)
{
scanlines = basePic.Height - offset;
}
else
{
scanlines = bar.Scanline;
}
Rectangle rect = new Rectangle(0, offset, basePic.Width, scanlines);
g.SetClip(rect);
g.Clear(Color.Transparent); //delete the part to be moved before drawing over it.
g.ResetClip();
g.DrawImageUnscaled(single.Clone(rect, basePic.PixelFormat), rect);
}
offset += bar.Scanline;
if (offset >= basePic.Height)
{
break;
}
}
Frame++;
return(newBM);
}
/*
* =============================================================================================================
* Constructors
* =============================================================================================================
*/
public ColorMath()
{
MainScreenDesignation = ScreenDesignation.BG1 | ScreenDesignation.OBJ;
SubScreenDesignation = ScreenDesignation.BG2 | ScreenDesignation.BG4 | ScreenDesignation.BG3;
ColorMathDesignation = ColorMathMode.Backdrop;
LayerSizes = new Size(256, HDMA.Scanlines);
BG1 = new Bitmap(LayerSizes.Width, LayerSizes.Height);
BG2 = new Bitmap(LayerSizes.Width, LayerSizes.Height);
BG3 = new Bitmap(LayerSizes.Width, LayerSizes.Height);
BG4 = new Bitmap(LayerSizes.Width, LayerSizes.Height);
OBJ = new Bitmap(LayerSizes.Width, LayerSizes.Height);
FixedColor = new Bitmap(LayerSizes.Width, LayerSizes.Height);
Backdrop = BitmapEffects.FromColor(Color.Black, LayerSizes);
//default: White = hide nothing
WindowingMask1 = BitmapEffects.FromColor(Color.White, LayerSizes);
WindowingMask2 = BitmapEffects.FromColor(Color.White, LayerSizes);
}
/// <summary>
/// Creates a Bitmap depending on the settings and the internal counter, which also get's increased at the end.
/// </summary>
/// <param name="basePic">The still (unchanged) image.</param>
/// <returns>Depending on the settings moved image.</returns>
public override Bitmap NextAnimateFrame(Bitmap basePic)
{
Bitmap NewOne;
try
{
int index = (int)(Frame * _speed) % _animationFrames.Length;
//only calculate new frame if we don't have one yet.
if (_animationFrames[index] == null)
{
NewOne = new Bitmap(basePic);
for (int i = 0; i *_width < NewOne.Height; i++)
{
//NewOne gets overwritten with the disordered image.
//_Breite * i sets the start of the to move setction.
//_Breite sets how thick the to move section is.
//_IArr[(i + _rounds) % 16] says how many pixel to move the image to the right.
NewOne = BitmapEffects.MoveLine((_width * i), _width, _IArr[(i + index) % 16] / 2, NewOne, Direction);
}
_animationFrames[index] = NewOne;
}
else
{
//load frame from memory
NewOne = _animationFrames[index];
}
//SPEED_FACTOR multiplication because _speed < 1. So it would get reeeaaally slow.
//_dRounds = (_dRounds + (_speed * SPEED_FACTOR)) % 16;
//actual _rounds only increases ever so often due to cast.
//_rounds = (int)_dRounds;
Frame++;
if (!EnableTable)
{
return(NewOne);
}
Bitmap img = new Bitmap(NewOne.Width, NewOne.Height);
using (Graphics g = Graphics.FromImage(img))
{
int totalCount = 0;
foreach (var entry in EnabledWaveCollection)
{
int height = entry.LineCount;
Bitmap toUse = entry.Value ? NewOne : basePic;
if (img.Height <= totalCount + height)
{
height = img.Height - totalCount;
}
var rec = toUse.Clone(new Rectangle(0, totalCount, img.Width, height), toUse.PixelFormat);
g.DrawImage(rec, 0, totalCount);
totalCount += height;
if (totalCount >= img.Height)
{
break;
}
}
if (totalCount < img.Height)
{
g.DrawImage(
basePic.Clone(new Rectangle(0, totalCount, img.Width, (img.Height - totalCount)),
img.PixelFormat), 0, totalCount);
}
}
return(img);
}
catch (Exception ex)
{
ThrowExceptionEvent(ex);
return(StaticPic(basePic));
}
}
public BrightnessHDMA()
{
EffectImage = BitmapEffects.FromColor(Color.Transparent, 256, Scanlines);
}
public bool CheckAndSplitMask(Bitmap mask, ColorMath math)
{
//array of with array for each line.
//each line has entrys with the color and the start position of that color in that line
ColPos[][] C_Arr = new ColPos[Scanlines][];
BitmapData data = mask.LockBits(new Rectangle(new Point(0, 0), mask.Size), ImageLockMode.ReadWrite, mask.PixelFormat);
byte[] bytes = new byte[data.Height * data.Stride];
System.Runtime.InteropServices.Marshal.Copy(data.Scan0, bytes, 0, bytes.Length);
for (int y = 0; y < mask.Height; y++)
{
Color ColorToCheck = BitmapEffects.GetPixel(data, bytes, 0, y); //mask.GetPixel(0, y);
List <ColPos> CList = new List <ColPos>();
CList.Add(new ColPos(ColorToCheck, 0));
for (int x = 1; x < mask.Width; x++)
{
Color c = BitmapEffects.GetPixel(data, bytes, x, y);
if (ColorToCheck == c) //mask.GetPixel(x, y))
{
continue;
}
ColorToCheck = c; //mask.GetPixel(x, y);
CList.Add(new ColPos(ColorToCheck, x));
}
C_Arr[y] = CList.ToArray();
}
mask.UnlockBits(data);
//if more then two black/white transitions appear in (any) line
bool black3 = C_Arr.Any((CA => CA.Count(c => c.Color.Name == "ff000000") > 2));
bool white3 = C_Arr.Any((CA => CA.Count(c => c.Color.Name == "ffffffff") > 2));
//3 transitions in both won't work eg. black-white-black-white-black-white
if (black3 && white3)
{
return(false);
}
int[] BlackLines;
int[] WhiteLines;
//get all the lines with 3 black transitions.
//can't be more then 3 because that would result in more then 3 white trans. in the same line.
IEnumerable <ColPos[]> Puff = C_Arr.Where((CA => CA.Count(c => c.Color.Name == "ff000000") > 2));
//an array of indeces to those lines.
BlackLines = new int[Puff.Count()];
int i = 0;
foreach (ColPos[] cp in Puff)
{
BlackLines[i] = Array.IndexOf(C_Arr, cp);
i++;
}
//same for white.
Puff = C_Arr.Where((CA => CA.Count(c => c.Color.Name == "ffffffff") > 2));
WhiteLines = new int[Puff.Count()];
i = 0;
foreach (ColPos[] cp in Puff)
{
WhiteLines[i] = Array.IndexOf(C_Arr, cp);
i++;
}
Bitmap w1 = BitmapEffects.FromColor(Color.White, 256, 224);
Bitmap w2 = BitmapEffects.FromColor(Color.White, 256, 224);
BitmapData w1Data = w1.LockBits(new Rectangle(0, 0, w1.Width, w1.Height), ImageLockMode.ReadWrite, w1.PixelFormat);
BitmapData w2Data = w2.LockBits(new Rectangle(0, 0, w2.Width, w2.Height), ImageLockMode.ReadWrite, w2.PixelFormat);
byte[] w1Bytes = new byte[w1Data.Height * w1Data.Stride];
byte[] w2Bytes = new byte[w2Data.Height * w2Data.Stride];
System.Runtime.InteropServices.Marshal.Copy(w1Data.Scan0, w1Bytes, 0, w1Bytes.Length);
System.Runtime.InteropServices.Marshal.Copy(w2Data.Scan0, w2Bytes, 0, w2Bytes.Length);
Table = new HDMATable(".windowTable");
HDMATableEntry entry = null;
HDMATableEntry lastEntry = null;
//if any line in this image requires 3 black and 2 white, one window (bm1) has to be inverted.
bool WindowInverted = C_Arr.Any(cp => (cp.Count(c => c.Color.Name == "ff000000") == 3 &&
cp.Count(c => c.Color.Name == "ffffffff") == 2));
for (int y = 0; y < Scanlines; y++)
{
entry = new HDMATableEntry(TableValueType.db, (byte)(1 + y - Table.TotalScanlines),
0xFF, 0x00, 0xFF, 0x00);
int countBlack = C_Arr[y].Count(cp => cp.Color.Name == "ff000000");
int countWhite = C_Arr[y].Count(cp => cp.Color.Name == "ffffffff");
Func <int, int, int, bool> BlackFromTill = (window, from, till) =>
{
if (till == 0x100)
{
till = 0xFF;
}
if (window == 1)
{
for (int x = from; x < till; x++)
{
BitmapEffects.SetPixel(w1Data, ref w1Bytes, x, y, Color.Black);
}
entry.Values[0] = (byte)from;
entry.Values[1] = (byte)till;
return(true);
}
else if (window == 2)
{
for (int x = from; x < till; x++)
{
BitmapEffects.SetPixel(w2Data, ref w2Bytes, x, y, Color.Black);
}
entry.Values[2] = (byte)from;
entry.Values[3] = (byte)till;
return(true);
}
return(false);
};
if (countBlack == 1 && countWhite == 0)
{
// whole line black.
// if window get's inverted, line can be left unchanged.
if (!WindowInverted)
{
BlackFromTill(1, 0, w1.Width); // if not, whole line black
}
}
else if (countBlack == 2 && countWhite == 1)
{
//outer black, inner white (black-white-black)
if (WindowInverted) //if window 1 is inverted it can be done using one window.
{
BlackFromTill(1, C_Arr[y][1].Position, C_Arr[y][2].Position); //The part white in the mask will be black in w1
}
else //window 1 not inveted:
{
BlackFromTill(1, C_Arr[y][0].Position, C_Arr[y][1].Position); // first black part of mask in window 1,
BlackFromTill(2, C_Arr[y][2].Position, w2.Width); // and the second in window 2.
}
}
else if (countBlack == 3 && countWhite == 2)
{
//black-white-black-white-black
//1 window inverted, the other not (not possible otherwise).
//meaning window 1 will be inverted.
BlackFromTill(1, C_Arr[y][1].Position, C_Arr[y][4].Position); // windows 1 will be black from the beginning of the first white
BlackFromTill(2, C_Arr[y][2].Position, C_Arr[y][3].Position); // till the end of the second. Windows 2 is the middle black part.
}
//else if (countBlack == 3 && countWhite == 3)
//... IMPOSSIBRU <.<
else if (countBlack == 2 && countWhite == 3)
{
//white-black-white-black-white
//both windows have to be uninverted. (or playing with XOR setting)
BlackFromTill(1, C_Arr[y][1].Position, C_Arr[y][2].Position); // window 1 black for first black part of mask
BlackFromTill(2, C_Arr[y][3].Position, C_Arr[y][4].Position); // windows 2 black for second part.
}
else if (countBlack == 1 && countWhite == 2)
{
//outer white inner black (white-black-white)
if (WindowInverted) //if windows 1 is inverted, we have to use window 2 and set window 1 black on the whole line
{
BlackFromTill(1, 0, w1.Width); // window 1 completly black
BlackFromTill(2, C_Arr[y][1].Position, C_Arr[y][2].Position); // window 2 black where mask is black.
}
else
{
BlackFromTill(1, C_Arr[y][1].Position, C_Arr[y][2].Position); // if not inverted, simply use window 1.
}
}
else if (countBlack == 0 && countWhite == 1)
{
//whole line visible
if (WindowInverted)
{
BlackFromTill(1, 0, w1.Width); // if window 1 inverted, whole line black
}
}
else if (countBlack == 2 && countWhite == 2)
{
//problem: unknown if black-white-black-white or white-black-white-black
#region 2/2
if (C_Arr[y][0].Color.Name == "ff000000") //if fisrt part black then B-W-B-W
{
if (WindowInverted) //inverted:
{
BlackFromTill(1, C_Arr[y][1].Position, w1.Width); // the -W-B-W area will be black, so inverted makes the first bar black
BlackFromTill(2, C_Arr[y][2].Position, C_Arr[y][3].Position); // window 2 simply makes second bar black
}
else //not inverted
{
BlackFromTill(1, C_Arr[y][0].Position, C_Arr[y][1].Position); // first bar in window 1
BlackFromTill(2, C_Arr[y][2].Position, C_Arr[y][3].Position); // guess what
}
}
else // first bar not black, thus W-B-W-B
{
if (WindowInverted) //inverted:
{
BlackFromTill(1, C_Arr[y][0].Position, C_Arr[y][3].Position); // the W-B-W- area will be black, inverting makes the last bar black.
BlackFromTill(2, C_Arr[y][1].Position, C_Arr[y][2].Position); // window 2 will be black where the first bar is.
}
else //not inverted
{
BlackFromTill(1, C_Arr[y][1].Position, C_Arr[y][2].Position); // first bar in window 2
BlackFromTill(2, C_Arr[y][3].Position, w2.Width); // ...
}
}
#endregion
}
else if (countBlack == 1 && countWhite == 1)
{
//problem: unknown if black-white or white-black
if (C_Arr[y][0].Color.Name == "ff000000") //first bar is black thus B-W
{
if (WindowInverted) //inverted:
{
BlackFromTill(1, C_Arr[y][1].Position, w1.Width); //set second bar (white) to black due to inverting
}
else //not inverted
{
BlackFromTill(1, C_Arr[y][0].Position, C_Arr[y][1].Position); //first bar (black) in window one to black
}
}
else //first bar not black thus W-B
{
if (WindowInverted) //inverted:
{
BlackFromTill(1, C_Arr[y][0].Position, C_Arr[y][1].Position); // set white part black;
}
else //not inverted
{
BlackFromTill(1, C_Arr[y][1].Position, w1.Width); //set second bar black.
}
}
}
if ((lastEntry != null && !entry.Values.SequenceEqual(lastEntry.Values)) || entry.Scanlines == 0x81)
{
Table.Add(lastEntry);
entry.Scanlines = 1;
}
lastEntry = (HDMATableEntry)entry.Clone();
} //end of for-loop
Table.Add(lastEntry); //the last last entry
Table.Add(HDMATableEntry.End); //the actual end.
System.Runtime.InteropServices.Marshal.Copy(w1Bytes, 0, w1Data.Scan0, w1Bytes.Length);
System.Runtime.InteropServices.Marshal.Copy(w2Bytes, 0, w2Data.Scan0, w2Bytes.Length);
w1.UnlockBits(w1Data);
w2.UnlockBits(w2Data);
math.WindowingMask1 = w1;
math.WindowingMask2 = w2;
math.Window1Inverted = WindowInverted ? (WindowingLayers)0x3F : 0;
return(true);
}
public WindowingHDMA()
{
Orignal = BitmapEffects.FromColor(Color.White, 256, Scanlines);
}
/// <summary>
/// Gets the screen as it would be displayed by the SNES.
/// </summary>
/// <returns></returns>
public Bitmap GetScreen()
{
if (BG1 == null || BG2 == null || BG3 == null || BG4 == null)
{
throw new ArgumentNullException("BGs need to be initialized");
}
if (FixedColor == null)
{
throw new ArgumentNullException("FixedColor need to be initialized");
}
if (Backdrop == null)
{
throw new ArgumentNullException("Backdrop need to be initialized");
}
Bitmap main, sub;
Bitmap statusBar = new Bitmap(LayerSizes.Width, LayerSizes.Height);
Bitmap bg3_remain = new Bitmap(LayerSizes.Width, LayerSizes.Height);
//cut layer 3 into status bar end rest.
using (Graphics g = Graphics.FromImage(statusBar))
g.DrawImageUnscaledAndClipped(BG3, new Rectangle(0, 0, statusBar.Width, StatusBarHeight));
using (Graphics g = Graphics.FromImage(bg3_remain))
{
Rectangle rec = new Rectangle(0, StatusBarHeight, bg3_remain.Width, bg3_remain.Height - StatusBarHeight);
g.DrawImageUnscaledAndClipped(BG3.Clone(rec, BG3.PixelFormat), rec);
}
Func <bool, bool, bool, bool, WindowMaskLogic, Bitmap, Bitmap> doWindowing = (enable1, enable2, invert1, invert2, logic, bg) =>
{
Bitmap mask1 = invert1 ? BitmapEffects.Invert(WindowingMask1) : WindowingMask1;
Bitmap mask2 = invert2 ? BitmapEffects.Invert(WindowingMask2) : WindowingMask2;
if (enable1 && enable2)
{
return(BitmapEffects.ApplyMask(bg, MergeMasks(mask1, mask2, logic), 0.5f));
}
else if (enable1)
{
return(BitmapEffects.ApplyMask(bg, mask1, 0.5f));
}
else if (enable2)
{
return(BitmapEffects.ApplyMask(bg, mask2, 0.5f));
}
else
{
return(bg);
}
};
Bitmap bg1Windowed = doWindowing(Window1Enabled.HasFlag(WindowingLayers.BG1), Window2Enabled.HasFlag(WindowingLayers.BG1),
Window1Inverted.HasFlag(WindowingLayers.BG1), Window2Inverted.HasFlag(WindowingLayers.BG1), Bg1MaskLogic, BG1);
Bitmap bg2Windowed = doWindowing(Window1Enabled.HasFlag(WindowingLayers.BG2), Window2Enabled.HasFlag(WindowingLayers.BG2),
Window1Inverted.HasFlag(WindowingLayers.BG2), Window2Inverted.HasFlag(WindowingLayers.BG2), Bg2MaskLogic, BG2);
Bitmap statusBarWindowed = doWindowing(Window1Enabled.HasFlag(WindowingLayers.BG3), Window2Enabled.HasFlag(WindowingLayers.BG3),
Window1Inverted.HasFlag(WindowingLayers.BG3), Window2Inverted.HasFlag(WindowingLayers.BG3), Bg3MaskLogic, statusBar);
Bitmap bg3RemainWindowed = doWindowing(Window1Enabled.HasFlag(WindowingLayers.BG3), Window2Enabled.HasFlag(WindowingLayers.BG3),
Window1Inverted.HasFlag(WindowingLayers.BG3), Window2Inverted.HasFlag(WindowingLayers.BG3), Bg3MaskLogic, bg3_remain);
Bitmap bg4Windowed = doWindowing(Window1Enabled.HasFlag(WindowingLayers.BG4), Window2Enabled.HasFlag(WindowingLayers.BG4),
Window1Inverted.HasFlag(WindowingLayers.BG4), Window2Inverted.HasFlag(WindowingLayers.BG4), Bg4MaskLogic, BG4);
Bitmap objWindowed = doWindowing(Window1Enabled.HasFlag(WindowingLayers.OBJ), Window2Enabled.HasFlag(WindowingLayers.OBJ),
Window1Inverted.HasFlag(WindowingLayers.OBJ), Window2Inverted.HasFlag(WindowingLayers.OBJ), ObjMaskLogic, OBJ);
Bitmap colorWindowed = BitmapEffects.FromColor(Color.Black, LayerSizes);
Bitmap colorWindowedHoles = doWindowing(Window1Enabled.HasFlag(WindowingLayers.Color), Window2Enabled.HasFlag(WindowingLayers.Color),
Window1Inverted.HasFlag(WindowingLayers.Color), Window2Inverted.HasFlag(WindowingLayers.Color), ColorMaskLogic,
BitmapEffects.FromColor(Color.White, LayerSizes));
//colorWindowsedHoles is white with holes where the black should be
using (Graphics g = Graphics.FromImage(colorWindowed))
g.DrawImage(colorWindowedHoles, 0, 0);
#region Sub Screen
List <Bitmap> BGs = new List <Bitmap>();
if (SubScreenDesignation.HasFlag(ScreenDesignation.OBJ) && !Hide.HasFlag(ScreenDesignation.OBJ))
{
BGs.Add(SubScreenWindowMaskDesignation.HasFlag(ScreenDesignation.OBJ) ? objWindowed : OBJ);
}
if (SubScreenDesignation.HasFlag(ScreenDesignation.BG1) && !Hide.HasFlag(ScreenDesignation.BG1))
{
BGs.Add(SubScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG1) ? bg1Windowed : BG1);
}
if (SubScreenDesignation.HasFlag(ScreenDesignation.BG2) && !Hide.HasFlag(ScreenDesignation.BG2))
{
BGs.Add(SubScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG2) ? bg2Windowed : BG2);
}
//layer 3 special (status bar split) onyl lower part
if (SubScreenDesignation.HasFlag(ScreenDesignation.BG3) && !Hide.HasFlag(ScreenDesignation.BG3))
{
BGs.Add(SubScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG3) ? bg3RemainWindowed : bg3_remain);
}
if (SubScreenDesignation.HasFlag(ScreenDesignation.BG4) && !Hide.HasFlag(ScreenDesignation.BG4))
{
BGs.Add(SubScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG4) ? bg4Windowed : BG4);
}
BGs.Add(FixedColor);
sub = BitmapEffects.OverlapImages(BGs.ToArray());
#endregion
#region Main Screen
BGs.Clear();
if (MainScreenDesignation.HasFlag(ScreenDesignation.OBJ) && !Hide.HasFlag(ScreenDesignation.OBJ))
{
Bitmap objUse = MainScreenWindowMaskDesignation.HasFlag(ScreenDesignation.OBJ) ? objWindowed : OBJ;
if (ColorMathDesignation.HasFlag(ColorMathMode.OBJ))
{
BGs.Add(ApplyColorMath(objUse, AddColor ? FixedColor : sub, ColorMathDesignation, colorWindowed, ClipToBlack, PreventColorMath));
}
else
{
BGs.Add(objUse);
}
}
if (MainScreenDesignation.HasFlag(ScreenDesignation.BG1) && !Hide.HasFlag(ScreenDesignation.BG1))
{
Bitmap bg1Use = MainScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG1) ? bg1Windowed : BG1;
if (ColorMathDesignation.HasFlag(ColorMathMode.BG1))
{
BGs.Add(ApplyColorMath(bg1Use, AddColor ? FixedColor : sub, ColorMathDesignation, colorWindowed, ClipToBlack, PreventColorMath));
}
else
{
BGs.Add(bg1Use);
}
}
if (MainScreenDesignation.HasFlag(ScreenDesignation.BG2) && !Hide.HasFlag(ScreenDesignation.BG2))
{
Bitmap bg2Use = MainScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG2) ? bg2Windowed : BG2;
if (ColorMathDesignation.HasFlag(ColorMathMode.BG2))
{
BGs.Add(ApplyColorMath(bg2Use, AddColor ? FixedColor : sub, ColorMathDesignation, colorWindowed, ClipToBlack, PreventColorMath));
}
else
{
BGs.Add(bg2Use);
}
}
if (MainScreenDesignation.HasFlag(ScreenDesignation.BG3) && !Hide.HasFlag(ScreenDesignation.BG3))
{
//layer 3 special (status bar split) onyl lower half
Bitmap bg3Use = MainScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG3) ? bg3RemainWindowed : bg3_remain;
if (ColorMathDesignation.HasFlag(ColorMathMode.BG3))
{
BGs.Add(ApplyColorMath(bg3Use, AddColor ? FixedColor : sub, ColorMathDesignation, colorWindowed, ClipToBlack, PreventColorMath));
}
else
{
BGs.Add(bg3Use);
}
}
if (MainScreenDesignation.HasFlag(ScreenDesignation.BG4) && !Hide.HasFlag(ScreenDesignation.BG4))
{
Bitmap bg4Use = MainScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG3) ? bg4Windowed : BG4;
if (ColorMathDesignation.HasFlag(ColorMathMode.BG4))
{
BGs.Add(ApplyColorMath(bg4Use, AddColor ? FixedColor : sub, ColorMathDesignation, colorWindowed, ClipToBlack, PreventColorMath));
}
else
{
BGs.Add(bg4Use);
}
}
//handle the backdrop too
if (ColorMathDesignation.HasFlag(ColorMathMode.Backdrop))
{
BGs.Add(ApplyColorMath(Backdrop, AddColor ? FixedColor : sub, ColorMathDesignation, colorWindowed, ClipToBlack, PreventColorMath));
}
else
{
BGs.Add(Backdrop);
}
main = BitmapEffects.OverlapImages(BGs.ToArray());
#endregion
BGs.Clear();
//check windowing for status bar
if (MainScreenDesignation.HasFlag(ScreenDesignation.BG3) && !Hide.HasFlag(ScreenDesignation.BG3))
{
BGs.Add(MainScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG3) ? statusBarWindowed : statusBar);
}
//if not main, check subscreen. (still put it before main for display purpose)
else if (SubScreenDesignation.HasFlag(ScreenDesignation.BG3) && !Hide.HasFlag(ScreenDesignation.BG3))
{
BGs.Add(SubScreenWindowMaskDesignation.HasFlag(ScreenDesignation.BG3) ? statusBarWindowed : statusBar);
}
BGs.Add(main);
BGs.Add(sub);
return(BitmapEffects.OverlapImages(BGs.ToArray()));
}
/// <summary>
/// Sets the FixedColor property based on a desired color.
/// </summary>
/// <param name="color">The color for the Bitmap</param>
public void SetBackdrop(Color color)
{
Backdrop = BitmapEffects.FromColor(color, LayerSizes);
}
/// <summary>
/// Sets the FixedColor property based on a desired color.
/// </summary>
/// <param name="color">The color for the Bitmap</param>
public void SetFixedColor(Color color)
{
FixedColor = BitmapEffects.FromColor(color, LayerSizes);
}
