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Diffstat (limited to '')
-rw-r--r-- | Game/Code/lib/PngImage/pngimage.~pas | 5205 |
1 files changed, 0 insertions, 5205 deletions
diff --git a/Game/Code/lib/PngImage/pngimage.~pas b/Game/Code/lib/PngImage/pngimage.~pas deleted file mode 100644 index ec712737..00000000 --- a/Game/Code/lib/PngImage/pngimage.~pas +++ /dev/null @@ -1,5205 +0,0 @@ -{Portable Network Graphics Delphi 1.4361 (8 March 2003) }
-
-{This is the latest implementation for TPngImage component }
-{It's meant to be a full replacement for the previous one. }
-{There are lots of new improvements, including cleaner code, }
-{full partial transparency support, speed improvements, }
-{saving using ADAM 7 interlacing, better error handling, also }
-{the best compression for the final image ever. And now it's }
-{truly able to read about any png image. }
-
-{
- Version 1.4361
- 2003-03-04 - Fixed important bug for simple transparency when using
- RGB, Grayscale color modes
-
- Version 1.436
- 2003-03-04 - * NEW * Property Pixels for direct access to pixels
- * IMPROVED * Palette property (TPngObject) (read only)
- Slovenian traslation for the component (Miha Petelin)
- Help file update (scanline article/png->jpg example)
-
- Version 1.435
- 2003-11-03 - * NEW * New chunk implementation zTXt (method AddzTXt)
- * NEW * New compiler flags to store the extra 8 bits
- from 16 bits samples (when saving it is ignored), the
- extra data may be acessed using ExtraScanline property
- * Fixed * a bug on tIMe chunk
- French translation included (Thanks to IBE Software)
- Bugs fixed
-
- Version 1.432
- 2002-08-24 - * NEW * A new method, CreateAlpha will transform the
- current image into partial transparency.
- Help file updated with a new article on how to handle
- partial transparency.
-
- Version 1.431
- 2002-08-14 - Fixed and tested to work on:
- C++ Builder 3
- C++ Builder 5
- Delphi 3
- There was an error when setting TransparentColor, fixed
- New method, RemoveTransparency to remove image
- BIT TRANSPARENCY
-
- Version 1.43
- 2002-08-01 - * NEW * Support for Delphi 3 and C++ Builder 3
- Implements mostly some things that were missing,
- a few tweaks and fixes.
-
- Version 1.428
- 2002-07-24 - More minor fixes (thanks to Ian Boyd)
- Bit transparency fixes
- * NEW * Finally support to bit transparency
- (palette / rgb / grayscale -> all)
-
- Version 1.427
- 2002-07-19 - Lots of bugs and leaks fixed
- * NEW * method to easy adding text comments, AddtEXt
- * NEW * property for setting bit transparency,
- TransparentColor
-
- Version 1.426
- 2002-07-18 - Clipboard finally fixed (hope)
- Changed UseDelphi trigger to UseDelphi
- * NEW * Support for bit transparency bitmaps
- when assigning from/to TBitmap objects
- Altough it does not support drawing transparent
- parts of bit transparency pngs (only partial)
- it is closer than ever
-
- Version 1.425
- 2002-07-01 - Clipboard methods implemented
- Lots of bugs fixed
-
- Version 1.424
- 2002-05-16 - Scanline and AlphaScanline are now working correctly.
- New methods for handling the clipboard
-
- Version 1.423
- 2002-05-16 - * NEW * Partial transparency for 1, 2, 4 and 8 bits is
- also supported using the tRNS chunk (for palette and
- grayscaling).
- New bug fixes (Peter Haas).
-
- Version 1.422
- 2002-05-14 - Fixed some critical leaks, thanks to Peter Haas tips.
- New translation for German (Peter Haas).
-
- Version 1.421
- 2002-05-06 - Now uses new ZLIB version, 1.1.4 with some security
- fixes.
- LoadFromResourceID and LoadFromResourceName added and
- help file updated for that.
- The resources strings are now located in pnglang.pas.
- New translation for Brazilian Portuguese.
- Bugs fixed.
-
- IMPORTANT: I'm currently looking for bugs on the library. If
- anyone has found one, please send me an email and
- I will fix right away. Thanks for all the help and
- ideias I'm receiving so far.}
-
-{My new email is: gubadaud@terra.com.br}
-{Website link : pngdelphi.sourceforge.net}
-{Gustavo Huffenbacher Daud}
-
-unit pngimage;
-
-interface
-
-{Triggers avaliable (edit the fields bellow)}
-{$DEFINE UseDelphi} //Disable fat vcl units (perfect to small apps)
-{$DEFINE ErrorOnUnknownCritical} //Error when finds an unknown critical chunk
-{$DEFINE CheckCRC} //Enables CRC checking
-{$DEFINE RegisterGraphic} //Registers TPNGObject to use with TPicture
-{$DEFINE PartialTransparentDraw} //Draws partial transparent images
-{.$DEFINE Store16bits} //Stores the extra 8 bits from 16bits/sample
-{.$DEFINE Debug} //For programming purposes
-{$RANGECHECKS OFF} {$J+}
-
-
-
-uses
- Windows {$IFDEF UseDelphi}, Classes, Graphics, SysUtils{$ENDIF} {$IFDEF Debug},
- dialogs{$ENDIF}, pngzlib, pnglang;
-
-{$IFNDEF UseDelphi}
- const
- soFromBeginning = 0;
- soFromCurrent = 1;
- soFromEnd = 2;
-{$ENDIF}
-
-const
- {ZLIB constants}
- ZLIBErrors: Array[-6..2] of string = ('incompatible version (-6)',
- 'buffer error (-5)', 'insufficient memory (-4)', 'data error (-3)',
- 'stream error (-2)', 'file error (-1)', '(0)', 'stream end (1)',
- 'need dictionary (2)');
- Z_NO_FLUSH = 0;
- Z_FINISH = 4;
- Z_STREAM_END = 1;
-
- {Avaliable PNG filters for mode 0}
- FILTER_NONE = 0;
- FILTER_SUB = 1;
- FILTER_UP = 2;
- FILTER_AVERAGE = 3;
- FILTER_PAETH = 4;
-
- {Avaliable color modes for PNG}
- COLOR_GRAYSCALE = 0;
- COLOR_RGB = 2;
- COLOR_PALETTE = 3;
- COLOR_GRAYSCALEALPHA = 4;
- COLOR_RGBALPHA = 6;
-
-
-type
- {$IFNDEF UseDelphi}
- {Custom exception handler}
- Exception = class(TObject)
- constructor Create(Msg: String);
- end;
- ExceptClass = class of Exception;
- TColor = ColorRef;
- {$ENDIF}
-
- {Error types}
- EPNGOutMemory = class(Exception);
- EPngError = class(Exception);
- EPngUnexpectedEnd = class(Exception);
- EPngInvalidCRC = class(Exception);
- EPngInvalidIHDR = class(Exception);
- EPNGMissingMultipleIDAT = class(Exception);
- EPNGZLIBError = class(Exception);
- EPNGInvalidPalette = class(Exception);
- EPNGInvalidFileHeader = class(Exception);
- EPNGIHDRNotFirst = class(Exception);
- EPNGNotExists = class(Exception);
- EPNGSizeExceeds = class(Exception);
- EPNGMissingPalette = class(Exception);
- EPNGUnknownCriticalChunk = class(Exception);
- EPNGUnknownCompression = class(Exception);
- EPNGUnknownInterlace = class(Exception);
- EPNGNoImageData = class(Exception);
- EPNGCouldNotLoadResource = class(Exception);
- EPNGCannotChangeTransparent = class(Exception);
- EPNGHeaderNotPresent = class(Exception);
-
-type
- {Direct access to pixels using R,G,B}
- TRGBLine = array[word] of TRGBTriple;
- pRGBLine = ^TRGBLine;
-
- {Same as TBitmapInfo but with allocated space for}
- {palette entries}
- TMAXBITMAPINFO = packed record
- bmiHeader: TBitmapInfoHeader;
- bmiColors: packed array[0..255] of TRGBQuad;
- end;
-
- {Transparency mode for pngs}
- TPNGTransparencyMode = (ptmNone, ptmBit, ptmPartial);
- {Pointer to a cardinal type}
- pCardinal = ^Cardinal;
- {Access to a rgb pixel}
- pRGBPixel = ^TRGBPixel;
- TRGBPixel = packed record
- B, G, R: Byte;
- end;
-
- {Pointer to an array of bytes type}
- TByteArray = Array[Word] of Byte;
- pByteArray = ^TByteArray;
-
- {Forward}
- TPNGObject = class;
- pPointerArray = ^TPointerArray;
- TPointerArray = Array[Word] of Pointer;
-
- {Contains a list of objects}
- TPNGPointerList = class
- private
- fOwner: TPNGObject;
- fCount : Cardinal;
- fMemory: pPointerArray;
- function GetItem(Index: Cardinal): Pointer;
- procedure SetItem(Index: Cardinal; const Value: Pointer);
- protected
- {Removes an item}
- function Remove(Value: Pointer): Pointer; virtual;
- {Inserts an item}
- procedure Insert(Value: Pointer; Position: Cardinal);
- {Add a new item}
- procedure Add(Value: Pointer);
- {Returns an item}
- property Item[Index: Cardinal]: Pointer read GetItem write SetItem;
- {Set the size of the list}
- procedure SetSize(const Size: Cardinal);
- {Returns owner}
- property Owner: TPNGObject read fOwner;
- public
- {Returns number of items}
- property Count: Cardinal read fCount write SetSize;
- {Object being either created or destroyed}
- constructor Create(AOwner: TPNGObject);
- destructor Destroy; override;
- end;
-
- {Forward declaration}
- TChunk = class;
- TChunkClass = class of TChunk;
-
- {Same as TPNGPointerList but providing typecasted values}
- TPNGList = class(TPNGPointerList)
- private
- {Used with property Item}
- function GetItem(Index: Cardinal): TChunk;
- public
- {Removes an item}
- procedure RemoveChunk(Chunk: TChunk); overload;
- {Add a new chunk using the class from the parameter}
- function Add(ChunkClass: TChunkClass): TChunk;
- {Returns pointer to the first chunk of class}
- function ItemFromClass(ChunkClass: TChunkClass): TChunk;
- {Returns a chunk item from the list}
- property Item[Index: Cardinal]: TChunk read GetItem;
- end;
-
- {$IFNDEF UseDelphi}
- {The STREAMs bellow are only needed in case delphi provided ones is not}
- {avaliable (UseDelphi trigger not set)}
- {Object becomes handles}
- TCanvas = THandle;
- TBitmap = HBitmap;
- {Trick to work}
- TPersistent = TObject;
-
- {Base class for all streams}
- TStream = class
- protected
- {Returning/setting size}
- function GetSize: Longint; virtual;
- procedure SetSize(const Value: Longint); virtual; abstract;
- {Returns/set position}
- function GetPosition: Longint; virtual;
- procedure SetPosition(const Value: Longint); virtual;
- public
- {Returns/sets current position}
- property Position: Longint read GetPosition write SetPosition;
- {Property returns/sets size}
- property Size: Longint read GetSize write SetSize;
- {Allows reading/writing data}
- function Read(var Buffer; Count: Longint): Cardinal; virtual; abstract;
- function Write(const Buffer; Count: Longint): Cardinal; virtual; abstract;
- {Copies from another Stream}
- function CopyFrom(Source: TStream;
- Count: Cardinal): Cardinal; virtual;
- {Seeks a stream position}
- function Seek(Offset: Longint; Origin: Word): Longint; virtual; abstract;
- end;
-
- {File stream modes}
- TFileStreamMode = (fsmRead, fsmWrite, fsmCreate);
- TFileStreamModeSet = set of TFileStreamMode;
-
- {File stream for reading from files}
- TFileStream = class(TStream)
- private
- {Opened mode}
- Filemode: TFileStreamModeSet;
- {Handle}
- fHandle: THandle;
- protected
- {Set the size of the file}
- procedure SetSize(const Value: Longint); override;
- public
- {Seeks a file position}
- function Seek(Offset: Longint; Origin: Word): Longint; override;
- {Reads/writes data from/to the file}
- function Read(var Buffer; Count: Longint): Cardinal; override;
- function Write(const Buffer; Count: Longint): Cardinal; override;
- {Stream being created and destroy}
- constructor Create(Filename: String; Mode: TFileStreamModeSet);
- destructor Destroy; override;
- end;
-
- {Stream for reading from resources}
- TResourceStream = class(TStream)
- constructor Create(Instance: HInst; const ResName: String; ResType:PChar);
- private
- {Variables for reading}
- Size: Integer;
- Memory: Pointer;
- Position: Integer;
- protected
- {Set the size of the file}
- procedure SetSize(const Value: Longint); override;
- public
- {Stream processing}
- function Read(var Buffer; Count: Integer): Cardinal; override;
- function Seek(Offset: Integer; Origin: Word): Longint; override;
- function Write(const Buffer; Count: Longint): Cardinal; override;
- end;
- {$ENDIF}
-
- {Forward}
- TChunkIHDR = class;
- {Interlace method}
- TInterlaceMethod = (imNone, imAdam7);
- {Compression level type}
- TCompressionLevel = 0..9;
- {Filters type}
- TFilter = (pfNone, pfSub, pfUp, pfAverage, pfPaeth);
- TFilters = set of TFilter;
-
- {Png implementation object}
- TPngObject = class{$IFDEF UseDelphi}(TGraphic){$ENDIF}
- protected
- {Gamma table values}
- GammaTable, InverseGamma: Array[Byte] of Byte;
- procedure InitializeGamma;
- private
- {Temporary palette}
- TempPalette: HPalette;
- {Filters to test to encode}
- fFilters: TFilters;
- {Compression level for ZLIB}
- fCompressionLevel: TCompressionLevel;
- {Maximum size for IDAT chunks}
- fMaxIdatSize: Cardinal;
- {Returns if image is interlaced}
- fInterlaceMethod: TInterlaceMethod;
- {Chunks object}
- fChunkList: TPngList;
- {Clear all chunks in the list}
- procedure ClearChunks;
- {Returns if header is present}
- function HeaderPresent: Boolean;
- {Returns linesize and byte offset for pixels}
- procedure GetPixelInfo(var LineSize, Offset: Cardinal);
- procedure SetMaxIdatSize(const Value: Cardinal);
- function GetAlphaScanline(const LineIndex: Integer): pByteArray;
- function GetScanline(const LineIndex: Integer): Pointer;
- {$IFDEF Store16bits}
- function GetExtraScanline(const LineIndex: Integer): Pointer;
- {$ENDIF}
- function GetTransparencyMode: TPNGTransparencyMode;
- function GetTransparentColor: TColor;
- procedure SetTransparentColor(const Value: TColor);
- protected
- {Returns the image palette}
- function GetPalette: HPALETTE; {$IFDEF UseDelphi}override;{$ENDIF}
- {Returns/sets image width and height}
- function GetWidth: Integer; {$IFDEF UseDelphi}override;{$ENDIF}
- function GetHeight: Integer; {$IFDEF UseDelphi}override; {$ENDIF}
- procedure SetWidth(Value: Integer); {$IFDEF UseDelphi}override; {$ENDIF}
- procedure SetHeight(Value: Integer); {$IFDEF UseDelphi}override;{$ENDIF}
- {Assigns from another TPNGObject}
- procedure AssignPNG(Source: TPNGObject);
- {Returns if the image is empty}
- function GetEmpty: Boolean; {$IFDEF UseDelphi}override; {$ENDIF}
- {Used with property Header}
- function GetHeader: TChunkIHDR;
- {Draws using partial transparency}
- procedure DrawPartialTrans(DC: HDC; Rect: TRect);
- {$IFDEF UseDelphi}
- {Returns if the image is transparent}
- function GetTransparent: Boolean; override;
- {$ENDIF}
- {Returns a pixel}
- function GetPixels(const X, Y: Integer): TColor; virtual;
- procedure SetPixels(const X, Y: Integer; const Value: TColor); virtual;
- public
- {Generates alpha information}
- procedure CreateAlpha;
- {Removes the image transparency}
- procedure RemoveTransparency;
- {Transparent color}
- property TransparentColor: TColor read GetTransparentColor write
- SetTransparentColor;
- {Add text chunk, TChunkTEXT, TChunkzTXT}
- procedure AddtEXt(const Keyword, Text: String);
- procedure AddzTXt(const Keyword, Text: String);
- {$IFDEF UseDelphi}
- {Saves to clipboard format (thanks to Antoine Pottern)}
- procedure SaveToClipboardFormat(var AFormat: Word; var AData: THandle;
- var APalette: HPalette); override;
- procedure LoadFromClipboardFormat(AFormat: Word; AData: THandle;
- APalette: HPalette); override;
- {$ENDIF}
- {Calling errors}
- procedure RaiseError(ExceptionClass: ExceptClass; Text: String);
- {Returns a scanline from png}
- property Scanline[const Index: Integer]: Pointer read GetScanline;
- {$IFDEF Store16bits}
- property ExtraScanline[const Index: Integer]: Pointer read GetExtraScanline;
- {$ENDIF}
- property AlphaScanline[const Index: Integer]: pByteArray read GetAlphaScanline;
- {Returns pointer to the header}
- property Header: TChunkIHDR read GetHeader;
- {Returns the transparency mode used by this png}
- property TransparencyMode: TPNGTransparencyMode read GetTransparencyMode;
- {Assigns from another object}
- procedure Assign(Source: TPersistent);{$IFDEF UseDelphi}override;{$ENDIF}
- {Assigns to another object}
- procedure AssignTo(Dest: TPersistent);{$IFDEF UseDelphi}override;{$ENDIF}
- {Assigns from a windows bitmap handle}
- procedure AssignHandle(Handle: HBitmap; Transparent: Boolean;
- TransparentColor: ColorRef);
- {Draws the image into a canvas}
- procedure Draw(ACanvas: TCanvas; const Rect: TRect);
- {$IFDEF UseDelphi}override;{$ENDIF}
- {Width and height properties}
- property Width: Integer read GetWidth;
- property Height: Integer read GetHeight;
- {Returns if the image is interlaced}
- property InterlaceMethod: TInterlaceMethod read fInterlaceMethod
- write fInterlaceMethod;
- {Filters to test to encode}
- property Filters: TFilters read fFilters write fFilters;
- {Maximum size for IDAT chunks, default and minimum is 65536}
- property MaxIdatSize: Cardinal read fMaxIdatSize write SetMaxIdatSize;
- {Property to return if the image is empty or not}
- property Empty: Boolean read GetEmpty;
- {Compression level}
- property CompressionLevel: TCompressionLevel read fCompressionLevel
- write fCompressionLevel;
- {Access to the chunk list}
- property Chunks: TPngList read fChunkList;
- {Object being created and destroyed}
- constructor Create; {$IFDEF UseDelphi}override;{$ENDIF}
- destructor Destroy; override;
- {$IFNDEF UseDelphi}procedure LoadFromFile(const Filename: String);{$ENDIF}
- {$IFNDEF UseDelphi}procedure SaveToFile(const Filename: String);{$ENDIF}
- procedure LoadFromStream(Stream: TStream); {$IFDEF UseDelphi}override;{$ENDIF}
- procedure SaveToStream(Stream: TStream); {$IFDEF UseDelphi}override;{$ENDIF}
- {Loading the image from resources}
- procedure LoadFromResourceName(Instance: HInst; const Name: String);
- procedure LoadFromResourceID(Instance: HInst; ResID: Integer);
- {Access to the png pixels}
- property Pixels[const X, Y: Integer]: TColor read GetPixels write SetPixels;
- {Palette property}
- {$IFNDEF UseDelphi}property Palette: HPalette read GetPalette;{$ENDIF}
- end;
-
- {Chunk name object}
- TChunkName = Array[0..3] of Char;
-
- {Global chunk object}
- TChunk = class
- private
- {Contains data}
- fData: Pointer;
- fDataSize: Cardinal;
- {Stores owner}
- fOwner: TPngObject;
- {Stores the chunk name}
- fName: TChunkName;
- {Returns pointer to the TChunkIHDR}
- function GetHeader: TChunkIHDR;
- {Used with property index}
- function GetIndex: Integer;
- {Should return chunk class/name}
- class function GetName: String; virtual;
- {Returns the chunk name}
- function GetChunkName: String;
- public
- {Returns index from list}
- property Index: Integer read GetIndex;
- {Returns pointer to the TChunkIHDR}
- property Header: TChunkIHDR read GetHeader;
- {Resize the data}
- procedure ResizeData(const NewSize: Cardinal);
- {Returns data and size}
- property Data: Pointer read fData;
- property DataSize: Cardinal read fDataSize;
- {Assigns from another TChunk}
- procedure Assign(Source: TChunk); virtual;
- {Returns owner}
- property Owner: TPngObject read fOwner;
- {Being destroyed/created}
- constructor Create(Owner: TPngObject); virtual;
- destructor Destroy; override;
- {Returns chunk class/name}
- property Name: String read GetChunkName;
- {Loads the chunk from a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; virtual;
- {Saves the chunk to a stream}
- function SaveData(Stream: TStream): Boolean;
- function SaveToStream(Stream: TStream): Boolean; virtual;
- end;
-
- {Chunk classes}
- TChunkIEND = class(TChunk); {End chunk}
-
- {IHDR data}
- pIHDRData = ^TIHDRData;
- TIHDRData = packed record
- Width, Height: Cardinal;
- BitDepth,
- ColorType,
- CompressionMethod,
- FilterMethod,
- InterlaceMethod: Byte;
- end;
-
- {Information header chunk}
- TChunkIHDR = class(TChunk)
- private
- {Current image}
- ImageHandle: HBitmap;
- ImageDC: HDC;
-
- {Output windows bitmap}
- HasPalette: Boolean;
- BitmapInfo: TMaxBitmapInfo;
- BytesPerRow: Integer;
- {Stores the image bytes}
- {$IFDEF Store16bits}ExtraImageData: Pointer;{$ENDIF}
- ImageData: pointer;
- ImageAlpha: Pointer;
-
- {Contains all the ihdr data}
- IHDRData: TIHDRData;
- protected
- {Resizes the image data to fill the color type, bit depth, }
- {width and height parameters}
- procedure PrepareImageData;
- {Release allocated ImageData memory}
- procedure FreeImageData;
- public
- {Properties}
- property Width: Cardinal read IHDRData.Width write IHDRData.Width;
- property Height: Cardinal read IHDRData.Height write IHDRData.Height;
- property BitDepth: Byte read IHDRData.BitDepth write IHDRData.BitDepth;
- property ColorType: Byte read IHDRData.ColorType write IHDRData.ColorType;
- property CompressionMethod: Byte read IHDRData.CompressionMethod
- write IHDRData.CompressionMethod;
- property FilterMethod: Byte read IHDRData.FilterMethod
- write IHDRData.FilterMethod;
- property InterlaceMethod: Byte read IHDRData.InterlaceMethod
- write IHDRData.InterlaceMethod;
- {Loads the chunk from a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; override;
- {Saves the chunk to a stream}
- function SaveToStream(Stream: TStream): Boolean; override;
- {Destructor/constructor}
- constructor Create(Owner: TPngObject); override;
- destructor Destroy; override;
- {Assigns from another TChunk}
- procedure Assign(Source: TChunk); override;
- end;
-
- {Gamma chunk}
- TChunkgAMA = class(TChunk)
- private
- {Returns/sets the value for the gamma chunk}
- function GetValue: Cardinal;
- procedure SetValue(const Value: Cardinal);
- public
- {Returns/sets gamma value}
- property Gamma: Cardinal read GetValue write SetValue;
- {Loading the chunk from a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; override;
- {Being created}
- constructor Create(Owner: TPngObject); override;
- {Assigns from another TChunk}
- procedure Assign(Source: TChunk); override;
- end;
-
- {ZLIB Decompression extra information}
- TZStreamRec2 = packed record
- {From ZLIB}
- ZLIB: TZStreamRec;
- {Additional info}
- Data: Pointer;
- fStream : TStream;
- end;
-
- {Palette chunk}
- TChunkPLTE = class(TChunk)
- private
- {Number of items in the palette}
- fCount: Integer;
- {Contains the palette handle}
- function GetPaletteItem(Index: Byte): TRGBQuad;
- public
- {Returns the color for each item in the palette}
- property Item[Index: Byte]: TRGBQuad read GetPaletteItem;
- {Returns the number of items in the palette}
- property Count: Integer read fCount;
- {Loads the chunk from a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; override;
- {Saves the chunk to a stream}
- function SaveToStream(Stream: TStream): Boolean; override;
- {Assigns from another TChunk}
- procedure Assign(Source: TChunk); override;
- end;
-
- {Transparency information}
- TChunktRNS = class(TChunk)
- private
- fBitTransparency: Boolean;
- function GetTransparentColor: ColorRef;
- {Returns the transparent color}
- procedure SetTransparentColor(const Value: ColorRef);
- public
- {Palette values for transparency}
- PaletteValues: Array[Byte] of Byte;
- {Returns if it uses bit transparency}
- property BitTransparency: Boolean read fBitTransparency;
- {Returns the transparent color}
- property TransparentColor: ColorRef read GetTransparentColor write
- SetTransparentColor;
- {Loads/saves the chunk from/to a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; override;
- function SaveToStream(Stream: TStream): Boolean; override;
- {Assigns from another TChunk}
- procedure Assign(Source: TChunk); override;
- end;
-
- {Actual image information}
- TChunkIDAT = class(TChunk)
- private
- {Holds another pointer to the TChunkIHDR}
- Header: TChunkIHDR;
- {Stores temporary image width and height}
- ImageWidth, ImageHeight: Integer;
- {Size in bytes of each line and offset}
- Row_Bytes, Offset : Cardinal;
- {Contains data for the lines}
- Encode_Buffer: Array[0..5] of pByteArray;
- Row_Buffer: Array[Boolean] of pByteArray;
- {Variable to invert the Row_Buffer used}
- RowUsed: Boolean;
- {Ending position for the current IDAT chunk}
- EndPos: Integer;
- {Filter the current line}
- procedure FilterRow;
- {Filter to encode and returns the best filter}
- function FilterToEncode: Byte;
- {Reads ZLIB compressed data}
- function IDATZlibRead(var ZLIBStream: TZStreamRec2; Buffer: Pointer;
- Count: Integer; var EndPos: Integer; var crcfile: Cardinal): Integer;
- {Compress and writes IDAT data}
- procedure IDATZlibWrite(var ZLIBStream: TZStreamRec2; Buffer: Pointer;
- const Length: Cardinal);
- procedure FinishIDATZlib(var ZLIBStream: TZStreamRec2);
- {Prepares the palette}
- procedure PreparePalette;
- protected
- {Decode interlaced image}
- procedure DecodeInterlacedAdam7(Stream: TStream;
- var ZLIBStream: TZStreamRec2; const Size: Integer; var crcfile: Cardinal);
- {Decode non interlaced imaged}
- procedure DecodeNonInterlaced(Stream: TStream;
- var ZLIBStream: TZStreamRec2; const Size: Integer;
- var crcfile: Cardinal);
- protected
- {Encode non interlaced images}
- procedure EncodeNonInterlaced(Stream: TStream;
- var ZLIBStream: TZStreamRec2);
- {Encode interlaced images}
- procedure EncodeInterlacedAdam7(Stream: TStream;
- var ZLIBStream: TZStreamRec2);
- protected
- {Memory copy methods to decode}
- procedure CopyNonInterlacedRGB8(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedRGB16(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedPalette148(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedPalette2(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedGray2(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedGrayscale16(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedRGBAlpha8(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedRGBAlpha16(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedGrayscaleAlpha8(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyNonInterlacedGrayscaleAlpha16(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedRGB8(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedRGB16(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedPalette148(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedPalette2(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedGray2(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedGrayscale16(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedRGBAlpha8(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedRGBAlpha16(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedGrayscaleAlpha8(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- procedure CopyInterlacedGrayscaleAlpha16(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
- protected
- {Memory copy methods to encode}
- procedure EncodeNonInterlacedRGB8(Src, Dest, Trans: pChar);
- procedure EncodeNonInterlacedRGB16(Src, Dest, Trans: pChar);
- procedure EncodeNonInterlacedGrayscale16(Src, Dest, Trans: pChar);
- procedure EncodeNonInterlacedPalette148(Src, Dest, Trans: pChar);
- procedure EncodeNonInterlacedRGBAlpha8(Src, Dest, Trans: pChar);
- procedure EncodeNonInterlacedRGBAlpha16(Src, Dest, Trans: pChar);
- procedure EncodeNonInterlacedGrayscaleAlpha8(Src, Dest, Trans: pChar);
- procedure EncodeNonInterlacedGrayscaleAlpha16(Src, Dest, Trans: pChar);
- procedure EncodeInterlacedRGB8(const Pass: Byte; Src, Dest, Trans: pChar);
- procedure EncodeInterlacedRGB16(const Pass: Byte; Src, Dest, Trans: pChar);
- procedure EncodeInterlacedPalette148(const Pass: Byte;
- Src, Dest, Trans: pChar);
- procedure EncodeInterlacedGrayscale16(const Pass: Byte;
- Src, Dest, Trans: pChar);
- procedure EncodeInterlacedRGBAlpha8(const Pass: Byte;
- Src, Dest, Trans: pChar);
- procedure EncodeInterlacedRGBAlpha16(const Pass: Byte;
- Src, Dest, Trans: pChar);
- procedure EncodeInterlacedGrayscaleAlpha8(const Pass: Byte;
- Src, Dest, Trans: pChar);
- procedure EncodeInterlacedGrayscaleAlpha16(const Pass: Byte;
- Src, Dest, Trans: pChar);
- public
- {Loads the chunk from a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; override;
- {Saves the chunk to a stream}
- function SaveToStream(Stream: TStream): Boolean; override;
- end;
-
- {Image last modification chunk}
- TChunktIME = class(TChunk)
- private
- {Holds the variables}
- fYear: Word;
- fMonth, fDay, fHour, fMinute, fSecond: Byte;
- public
- {Returns/sets variables}
- property Year: Word read fYear write fYear;
- property Month: Byte read fMonth write fMonth;
- property Day: Byte read fDay write fDay;
- property Hour: Byte read fHour write fHour;
- property Minute: Byte read fMinute write fMinute;
- property Second: Byte read fSecond write fSecond;
- {Loads the chunk from a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; override;
- {Saves the chunk to a stream}
- function SaveToStream(Stream: TStream): Boolean; override;
- end;
-
- {Textual data}
- TChunktEXt = class(TChunk)
- private
- fKeyword, fText: String;
- public
- {Keyword and text}
- property Keyword: String read fKeyword write fKeyword;
- property Text: String read fText write fText;
- {Loads the chunk from a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; override;
- {Saves the chunk to a stream}
- function SaveToStream(Stream: TStream): Boolean; override;
- {Assigns from another TChunk}
- procedure Assign(Source: TChunk); override;
- end;
-
- {zTXT chunk}
- TChunkzTXt = class(TChunktEXt)
- {Loads the chunk from a stream}
- function LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean; override;
- {Saves the chunk to a stream}
- function SaveToStream(Stream: TStream): Boolean; override;
- end;
-
-{Here we test if it's c++ builder or delphi version 3 or less}
-{$IFDEF VER110}{$DEFINE DelphiBuilder3Less}{$ENDIF}
-{$IFDEF VER100}{$DEFINE DelphiBuilder3Less}{$ENDIF}
-{$IFDEF VER93}{$DEFINE DelphiBuilder3Less}{$ENDIF}
-{$IFDEF VER90}{$DEFINE DelphiBuilder3Less}{$ENDIF}
-{$IFDEF VER80}{$DEFINE DelphiBuilder3Less}{$ENDIF}
-
-
-{Registers a new chunk class}
-procedure RegisterChunk(ChunkClass: TChunkClass);
-{Calculates crc}
-function update_crc(crc: {$IFNDEF DelphiBuilder3Less}Cardinal{$ELSE}Integer
- {$ENDIF}; buf: pByteArray; len: Integer): Cardinal;
-{Invert bytes using assembly}
-function ByteSwap(const a: integer): integer;
-
-implementation
-
-var
- ChunkClasses: TPngPointerList;
- {Table of CRCs of all 8-bit messages}
- crc_table: Array[0..255] of Cardinal;
- {Flag: has the table been computed? Initially false}
- crc_table_computed: Boolean;
-
-{Draw transparent image using transparent color}
-procedure DrawTransparentBitmap(dc: HDC; srcBits: Pointer;
- var srcHeader: TBitmapInfoHeader;
- srcBitmapInfo: pBitmapInfo; Rect: TRect; cTransparentColor: COLORREF);
-var
- cColor: COLORREF;
- bmAndBack, bmAndObject, bmAndMem: HBITMAP;
- bmBackOld, bmObjectOld, bmMemOld: HBITMAP;
- hdcMem, hdcBack, hdcObject, hdcTemp: HDC;
- ptSize, orgSize: TPOINT;
- OldBitmap, DrawBitmap: HBITMAP;
-begin
- hdcTemp := CreateCompatibleDC(dc);
- // Select the bitmap
- DrawBitmap := CreateDIBitmap(dc, srcHeader, CBM_INIT, srcBits, srcBitmapInfo^,
- DIB_RGB_COLORS);
- OldBitmap := SelectObject(hdcTemp, DrawBitmap);
-
- // Sizes
- OrgSize.x := abs(srcHeader.biWidth);
- OrgSize.y := abs(srcHeader.biHeight);
- ptSize.x := Rect.Right - Rect.Left; // Get width of bitmap
- ptSize.y := Rect.Bottom - Rect.Top; // Get height of bitmap
-
- // Create some DCs to hold temporary data.
- hdcBack := CreateCompatibleDC(dc);
- hdcObject := CreateCompatibleDC(dc);
- hdcMem := CreateCompatibleDC(dc);
-
- // Create a bitmap for each DC. DCs are required for a number of
- // GDI functions.
-
- // Monochrome DCs
- bmAndBack := CreateBitmap(ptSize.x, ptSize.y, 1, 1, nil);
- bmAndObject := CreateBitmap(ptSize.x, ptSize.y, 1, 1, nil);
-
- bmAndMem := CreateCompatibleBitmap(dc, ptSize.x, ptSize.y);
-
- // Each DC must select a bitmap object to store pixel data.
- bmBackOld := SelectObject(hdcBack, bmAndBack);
- bmObjectOld := SelectObject(hdcObject, bmAndObject);
- bmMemOld := SelectObject(hdcMem, bmAndMem);
-
- // Set the background color of the source DC to the color.
- // contained in the parts of the bitmap that should be transparent
- cColor := SetBkColor(hdcTemp, cTransparentColor);
-
- // Create the object mask for the bitmap by performing a BitBlt
- // from the source bitmap to a monochrome bitmap.
- StretchBlt(hdcObject, 0, 0, ptSize.x, ptSize.y, hdcTemp, 0, 0,
- orgSize.x, orgSize.y, SRCCOPY);
-
- // Set the background color of the source DC back to the original
- // color.
- SetBkColor(hdcTemp, cColor);
-
- // Create the inverse of the object mask.
- BitBlt(hdcBack, 0, 0, ptSize.x, ptSize.y, hdcObject, 0, 0,
- NOTSRCCOPY);
-
- // Copy the background of the main DC to the destination.
- BitBlt(hdcMem, 0, 0, ptSize.x, ptSize.y, dc, Rect.Left, Rect.Top,
- SRCCOPY);
-
- // Mask out the places where the bitmap will be placed.
- BitBlt(hdcMem, 0, 0, ptSize.x, ptSize.y, hdcObject, 0, 0, SRCAND);
-
- // Mask out the transparent colored pixels on the bitmap.
-// BitBlt(hdcTemp, 0, 0, ptSize.x, ptSize.y, hdcBack, 0, 0, SRCAND);
- StretchBlt(hdcTemp, 0, 0, OrgSize.x, OrgSize.y, hdcBack, 0, 0,
- PtSize.x, PtSize.y, SRCAND);
-
- // XOR the bitmap with the background on the destination DC.
- StretchBlt(hdcMem, 0, 0, ptSize.x, ptSize.y, hdcTemp, 0, 0,
- OrgSize.x, OrgSize.y, SRCPAINT);
-
- // Copy the destination to the screen.
- BitBlt(dc, Rect.Left, Rect.Top, ptSize.x, ptSize.y, hdcMem, 0, 0,
- SRCCOPY);
-
- // Delete the memory bitmaps.
- DeleteObject(SelectObject(hdcBack, bmBackOld));
- DeleteObject(SelectObject(hdcObject, bmObjectOld));
- DeleteObject(SelectObject(hdcMem, bmMemOld));
- DeleteObject(SelectObject(hdcTemp, OldBitmap));
-
- // Delete the memory DCs.
- DeleteDC(hdcMem);
- DeleteDC(hdcBack);
- DeleteDC(hdcObject);
- DeleteDC(hdcTemp);
-end;
-
-{Make the table for a fast CRC.}
-procedure make_crc_table;
-var
- c: Cardinal;
- n, k: Integer;
-begin
-
- {fill the crc table}
- for n := 0 to 255 do
- begin
- c := Cardinal(n);
- for k := 0 to 7 do
- begin
- if Boolean(c and 1) then
- c := $edb88320 xor (c shr 1)
- else
- c := c shr 1;
- end;
- crc_table[n] := c;
- end;
-
- {The table has already being computated}
- crc_table_computed := true;
-end;
-
-{Update a running CRC with the bytes buf[0..len-1]--the CRC
- should be initialized to all 1's, and the transmitted value
- is the 1's complement of the final running CRC (see the
- crc() routine below)).}
-function update_crc(crc: {$IFNDEF DelphiBuilder3Less}Cardinal{$ELSE}Integer
- {$ENDIF}; buf: pByteArray; len: Integer): Cardinal;
-var
- c: Cardinal;
- n: Integer;
-begin
- c := crc;
-
- {Create the crc table in case it has not being computed yet}
- if not crc_table_computed then make_crc_table;
-
- {Update}
- for n := 0 to len - 1 do
- c := crc_table[(c XOR buf^[n]) and $FF] XOR (c shr 8);
-
- {Returns}
- Result := c;
-end;
-
-{$IFNDEF UseDelphi}
- function FileExists(Filename: String): Boolean;
- var
- FindFile: THandle;
- FindData: TWin32FindData;
- begin
- FindFile := FindFirstFile(PChar(Filename), FindData);
- Result := FindFile <> INVALID_HANDLE_VALUE;
- if Result then Windows.FindClose(FindFile);
- end;
-
-
-{$ENDIF}
-
-{$IFNDEF UseDelphi}
- {Exception implementation}
- constructor Exception.Create(Msg: String);
- begin
- end;
-{$ENDIF}
-
-{Calculates the paeth predictor}
-function PaethPredictor(a, b, c: Byte): Byte;
-var
- pa, pb, pc: Integer;
-begin
- { a = left, b = above, c = upper left }
- pa := abs(b - c); { distances to a, b, c }
- pb := abs(a - c);
- pc := abs(a + b - c * 2);
-
- { return nearest of a, b, c, breaking ties in order a, b, c }
- if (pa <= pb) and (pa <= pc) then
- Result := a
- else
- if pb <= pc then
- Result := b
- else
- Result := c;
-end;
-
-{Invert bytes using assembly}
-function ByteSwap(const a: integer): integer;
-asm
- bswap eax
-end;
-function ByteSwap16(inp:word): word;
-asm
- bswap eax
- shr eax, 16
-end;
-
-{Calculates number of bytes for the number of pixels using the}
-{color mode in the paramenter}
-function BytesForPixels(const Pixels: Integer; const ColorType,
- BitDepth: Byte): Integer;
-begin
- case ColorType of
- {Palette and grayscale contains a single value, for palette}
- {an value of size 2^bitdepth pointing to the palette index}
- {and grayscale the value from 0 to 2^bitdepth with color intesity}
- COLOR_GRAYSCALE, COLOR_PALETTE:
- Result := (Pixels * BitDepth + 7) div 8;
- {RGB contains 3 values R, G, B with size 2^bitdepth each}
- COLOR_RGB:
- Result := (Pixels * BitDepth * 3) div 8;
- {Contains one value followed by alpha value booth size 2^bitdepth}
- COLOR_GRAYSCALEALPHA:
- Result := (Pixels * BitDepth * 2) div 8;
- {Contains four values size 2^bitdepth, Red, Green, Blue and alpha}
- COLOR_RGBALPHA:
- Result := (Pixels * BitDepth * 4) div 8;
- else
- Result := 0;
- end {case ColorType}
-end;
-
-type
- pChunkClassInfo = ^TChunkClassInfo;
- TChunkClassInfo = record
- ClassName: TChunkClass;
- end;
-
-{Register a chunk type}
-procedure RegisterChunk(ChunkClass: TChunkClass);
-var
- NewClass: pChunkClassInfo;
-begin
- {In case the list object has not being created yet}
- if ChunkClasses = nil then ChunkClasses := TPngPointerList.Create(nil);
-
- {Add this new class}
- new(NewClass);
- NewClass^.ClassName := ChunkClass;
- ChunkClasses.Add(NewClass);
-end;
-
-{Free chunk class list}
-procedure FreeChunkClassList;
-var
- i: Integer;
-begin
- if (ChunkClasses <> nil) then
- begin
- FOR i := 0 TO ChunkClasses.Count - 1 do
- Dispose(pChunkClassInfo(ChunkClasses.Item[i]));
- ChunkClasses.Free;
- end;
-end;
-
-{Registering of common chunk classes}
-procedure RegisterCommonChunks;
-begin
- {Important chunks}
- RegisterChunk(TChunkIEND);
- RegisterChunk(TChunkIHDR);
- RegisterChunk(TChunkIDAT);
- RegisterChunk(TChunkPLTE);
- RegisterChunk(TChunkgAMA);
- RegisterChunk(TChunktRNS);
-
- {Not so important chunks}
- RegisterChunk(TChunktIME);
- RegisterChunk(TChunktEXt);
- RegisterChunk(TChunkzTXt);
-end;
-
-{Creates a new chunk of this class}
-function CreateClassChunk(Owner: TPngObject; Name: TChunkName): TChunk;
-var
- i : Integer;
- NewChunk: TChunkClass;
-begin
- {Looks for this chunk}
- NewChunk := TChunk; {In case there is no registered class for this}
-
- {Looks for this class in all registered chunks}
- if Assigned(ChunkClasses) then
- FOR i := 0 TO ChunkClasses.Count - 1 DO
- begin
- if pChunkClassInfo(ChunkClasses.Item[i])^.ClassName.GetName = Name then
- begin
- NewChunk := pChunkClassInfo(ChunkClasses.Item[i])^.ClassName;
- break;
- end;
- end;
-
- {Returns chunk class}
- Result := NewChunk.Create(Owner);
- Result.fName := Name;
-end;
-
-{ZLIB support}
-
-const
- ZLIBAllocate = High(Word);
-
-{Initializes ZLIB for decompression}
-function ZLIBInitInflate(Stream: TStream): TZStreamRec2;
-begin
- {Fill record}
- Fillchar(Result, SIZEOF(TZStreamRec2), #0);
-
- {Set internal record information}
- with Result do
- begin
- GetMem(Data, ZLIBAllocate);
- fStream := Stream;
- end;
-
- {Init decompression}
- InflateInit_(Result.zlib, zlib_version, SIZEOF(TZStreamRec));
-end;
-
-{Initializes ZLIB for compression}
-function ZLIBInitDeflate(Stream: TStream;
- Level: TCompressionlevel; Size: Cardinal): TZStreamRec2;
-begin
- {Fill record}
- Fillchar(Result, SIZEOF(TZStreamRec2), #0);
-
- {Set internal record information}
- with Result, ZLIB do
- begin
- GetMem(Data, Size);
- fStream := Stream;
- next_out := Data;
- avail_out := Size;
- end;
-
- {Inits compression}
- deflateInit_(Result.zlib, Level, zlib_version, sizeof(TZStreamRec));
-end;
-
-{Terminates ZLIB for compression}
-procedure ZLIBTerminateDeflate(var ZLIBStream: TZStreamRec2);
-begin
- {Terminates decompression}
- DeflateEnd(ZLIBStream.zlib);
- {Free internal record}
- FreeMem(ZLIBStream.Data, ZLIBAllocate);
-end;
-
-{Terminates ZLIB for decompression}
-procedure ZLIBTerminateInflate(var ZLIBStream: TZStreamRec2);
-begin
- {Terminates decompression}
- InflateEnd(ZLIBStream.zlib);
- {Free internal record}
- FreeMem(ZLIBStream.Data, ZLIBAllocate);
-end;
-
-{Decompresses ZLIB into a memory address}
-function DecompressZLIB(const Input: Pointer; InputSize: Integer;
- var Output: Pointer; var OutputSize: Integer;
- var ErrorOutput: String): Boolean;
-var
- StreamRec : TZStreamRec;
- Buffer : Array[Byte] of Byte;
- InflateRet: Integer;
-begin
- with StreamRec do
- begin
- {Initializes}
- Result := True;
- OutputSize := 0;
-
- {Prepares the data to decompress}
- FillChar(StreamRec, SizeOf(TZStreamRec), #0);
- InflateInit_(StreamRec, zlib_version, SIZEOF(TZStreamRec));
- next_in := Input;
- avail_in := InputSize;
-
- {Decodes data}
- repeat
- {In case it needs an output buffer}
- if (avail_out = 0) then
- begin
- next_out := @Buffer;
- avail_out := SizeOf(Buffer);
- end {if (avail_out = 0)};
-
- {Decompress and put in output}
- InflateRet := inflate(StreamRec, 0);
- if (InflateRet = Z_STREAM_END) or (InflateRet = 0) then
- begin
- {Reallocates output buffer}
- inc(OutputSize, total_out);
- if Output = nil then
- GetMem(Output, OutputSize) else ReallocMem(Output, OutputSize);
- {Copies the new data}
- CopyMemory(Ptr(Longint(Output) + OutputSize - total_out),
- @Buffer, total_out);
- end {if (InflateRet = Z_STREAM_END) or (InflateRet = 0)}
- {Now tests for errors}
- else if InflateRet < 0 then
- begin
- Result := False;
- ErrorOutput := StreamRec.msg;
- InflateEnd(StreamRec);
- Exit;
- end {if InflateRet < 0}
- until InflateRet = Z_STREAM_END;
-
- {Terminates decompression}
- InflateEnd(StreamRec);
- end {with StreamRec}
-
-end;
-
-{Compresses ZLIB into a memory address}
-function CompressZLIB(Input: Pointer; InputSize, CompressionLevel: Integer;
- var Output: Pointer; var OutputSize: Integer;
- var ErrorOutput: String): Boolean;
-var
- StreamRec : TZStreamRec;
- Buffer : Array[Byte] of Byte;
- DeflateRet: Integer;
-begin
- with StreamRec do
- begin
- Result := True; {By default returns TRUE as everything might have gone ok}
- OutputSize := 0; {Initialize}
- {Prepares the data to compress}
- FillChar(StreamRec, SizeOf(TZStreamRec), #0);
- DeflateInit_(StreamRec, CompressionLevel,zlib_version, SIZEOF(TZStreamRec));
-
- next_in := Input;
- avail_in := InputSize;
-
- while avail_in > 0 do
- begin
- {When it needs new buffer to stores the compressed data}
- if avail_out = 0 then
- begin
- {Restore buffer}
- next_out := @Buffer;
- avail_out := SizeOf(Buffer);
- end {if avail_out = 0};
-
- {Compresses}
- DeflateRet := deflate(StreamRec, Z_FINISH);
-
- if (DeflateRet = Z_STREAM_END) or (DeflateRet = 0) then
- begin
- {Updates the output memory}
- inc(OutputSize, total_out);
- if Output = nil then
- GetMem(Output, OutputSize) else ReallocMem(Output, OutputSize);
-
- {Copies the new data}
- CopyMemory(Ptr(Longint(Output) + OutputSize - total_out),
- @Buffer, total_out);
- end {if (InflateRet = Z_STREAM_END) or (InflateRet = 0)}
- {Now tests for errors}
- else if DeflateRet < 0 then
- begin
- Result := False;
- ErrorOutput := StreamRec.msg;
- DeflateEnd(StreamRec);
- Exit;
- end {if InflateRet < 0}
-
- end {while avail_in > 0};
-
- {Finishes compressing}
- DeflateEnd(StreamRec);
- end {with StreamRec}
-
-end;
-
-{TPngPointerList implementation}
-
-{Object being created}
-constructor TPngPointerList.Create(AOwner: TPNGObject);
-begin
- inherited Create; {Let ancestor work}
- {Holds owner}
- fOwner := AOwner;
- {Memory pointer not being used yet}
- fMemory := nil;
- {No items yet}
- fCount := 0;
-end;
-
-{Removes value from the list}
-function TPngPointerList.Remove(Value: Pointer): Pointer;
-var
- I, Position: Integer;
-begin
- {Gets item position}
- Position := -1;
- FOR I := 0 TO Count - 1 DO
- if Value = Item[I] then Position := I;
- {In case a match was found}
- if Position >= 0 then
- begin
- Result := Item[Position]; {Returns pointer}
- {Remove item and move memory}
- Dec(fCount);
- if Position < Integer(FCount) then
- System.Move(fMemory^[Position + 1], fMemory^[Position],
- (Integer(fCount) - Position) * SizeOf(Pointer));
- end {if Position >= 0} else Result := nil
-end;
-
-{Add a new value in the list}
-procedure TPngPointerList.Add(Value: Pointer);
-begin
- Count := Count + 1;
- Item[Count - 1] := Value;
-end;
-
-
-{Object being destroyed}
-destructor TPngPointerList.Destroy;
-begin
- {Release memory if needed}
- if fMemory <> nil then
- FreeMem(fMemory, fCount * sizeof(Pointer));
-
- {Free things}
- inherited Destroy;
-end;
-
-{Returns one item from the list}
-function TPngPointerList.GetItem(Index: Cardinal): Pointer;
-begin
- if (Index <= Count - 1) then
- Result := fMemory[Index]
- else
- {In case it's out of bounds}
- Result := nil;
-end;
-
-{Inserts a new item in the list}
-procedure TPngPointerList.Insert(Value: Pointer; Position: Cardinal);
-begin
- if (Position < Count) then
- begin
- {Increase item count}
- SetSize(Count + 1);
- {Move other pointers}
- if Position < Count then
- System.Move(fMemory^[Position], fMemory^[Position + 1],
- (Count - Position - 1) * SizeOf(Pointer));
- {Sets item}
- Item[Position] := Value;
- end;
-end;
-
-{Sets one item from the list}
-procedure TPngPointerList.SetItem(Index: Cardinal; const Value: Pointer);
-begin
- {If index is in bounds, set value}
- if (Index <= Count - 1) then
- fMemory[Index] := Value
-end;
-
-{This method resizes the list}
-procedure TPngPointerList.SetSize(const Size: Cardinal);
-begin
- {Sets the size}
- if (fMemory = nil) and (Size > 0) then
- GetMem(fMemory, Size * SIZEOF(Pointer))
- else
- if Size > 0 then {Only realloc if the new size is greater than 0}
- ReallocMem(fMemory, Size * SIZEOF(Pointer))
- else
- {In case user is resize to 0 items}
- begin
- FreeMem(fMemory);
- fMemory := nil;
- end;
- {Update count}
- fCount := Size;
-end;
-
-{TPNGList implementation}
-
-{Removes an item}
-procedure TPNGList.RemoveChunk(Chunk: TChunk);
-begin
- Remove(Chunk);
- Chunk.Free
-end;
-
-{Add a new item}
-function TPNGList.Add(ChunkClass: TChunkClass): TChunk;
-var
- IHDR: TChunkIHDR;
- IEND: TChunkIEND;
-
- IDAT: TChunkIDAT;
- PLTE: TChunkPLTE;
-begin
- Result := nil; {Default result}
- {Adding these is not allowed}
- if (ChunkClass = TChunkIHDR) or (ChunkClass = TChunkIDAT) or
- (ChunkClass = TChunkPLTE) or (ChunkClass = TChunkIEND) then
- fOwner.RaiseError(EPngError, EPNGCannotAddChunkText)
- {Two of these is not allowed}
- else if ((ChunkClass = TChunkgAMA) and (ItemFromClass(TChunkgAMA) <> nil)) or
- ((ChunkClass = TChunktRNS) and (ItemFromClass(TChunktRNS) <> nil)) then
- fOwner.RaiseError(EPngError, EPNGCannotAddChunkText)
- {There must have an IEND and IHDR chunk}
- else if (ItemFromClass(TChunkIEND) = nil) or
- (ItemFromClass(TChunkIHDR) = nil) then
- fOwner.RaiseError(EPngError, EPNGCannotAddInvalidImageText)
- else
- begin
- {Get common chunks}
- IHDR := ItemFromClass(TChunkIHDR) as TChunkIHDR;
- IEND := ItemFromClass(TChunkIEND) as TChunkIEND;
- {Create new chunk}
- Result := ChunkClass.Create(Owner);
- {Add to the list}
- if (ChunkClass = TChunkgAMA) then
- Insert(Result, IHDR.Index + 1)
- {Transparency chunk (fix by Ian Boyd)}
- else if (ChunkClass = TChunktRNS) then
- begin
- {Transparecy chunk must be after PLTE; before IDAT}
- IDAT := ItemFromClass(TChunkIDAT) as TChunkIDAT;
- PLTE := ItemFromClass(TChunkPLTE) as TChunkPLTE;
-
- if Assigned(PLTE) then
- Insert(Result, PLTE.Index + 1)
- else if Assigned(IDAT) then
- Insert(Result, IDAT.Index)
- else
- Insert(Result, IHDR.Index + 1)
- end
- else {All other chunks}
- Insert(Result, IEND.Index);
- end {if}
-end;
-
-{Returns item from the list}
-function TPNGList.GetItem(Index: Cardinal): TChunk;
-begin
- Result := inherited GetItem(Index);
-end;
-
-{Returns first item from the list using the class from parameter}
-function TPNGList.ItemFromClass(ChunkClass: TChunkClass): TChunk;
-var
- i: Integer;
-begin
- Result := nil; {Initial result}
- FOR i := 0 TO Count - 1 DO
- {Test if this item has the same class}
- if Item[i] is ChunkClass then
- begin
- {Returns this item and exit}
- Result := Item[i];
- break;
- end {if}
-end;
-
-{$IFNDEF UseDelphi}
-
- {TStream implementation}
-
- {Copies all from another stream}
- function TStream.CopyFrom(Source: TStream; Count: Cardinal): Cardinal;
- const
- MaxBytes = $f000;
- var
- Buffer: PChar;
- BufSize, N: Cardinal;
- begin
- {If count is zero, copy everything from Source}
- if Count = 0 then
- begin
- Source.Seek(0, soFromBeginning);
- Count := Source.Size;
- end;
-
- Result := Count; {Returns the number of bytes readed}
- {Allocates memory}
- if Count > MaxBytes then BufSize := MaxBytes else BufSize := Count;
- GetMem(Buffer, BufSize);
-
- {Copy memory}
- while Count > 0 do
- begin
- if Count > BufSize then N := BufSize else N := Count;
- Source.Read(Buffer^, N);
- Write(Buffer^, N);
- dec(Count, N);
- end;
-
- {Deallocates memory}
- FreeMem(Buffer, BufSize);
- end;
-
-{Set current stream position}
-procedure TStream.SetPosition(const Value: Longint);
-begin
- Seek(Value, soFromBeginning);
-end;
-
-{Returns position}
-function TStream.GetPosition: Longint;
-begin
- Result := Seek(0, soFromCurrent);
-end;
-
- {Returns stream size}
-function TStream.GetSize: Longint;
- var
- Pos: Cardinal;
- begin
- Pos := Seek(0, soFromCurrent);
- Result := Seek(0, soFromEnd);
- Seek(Pos, soFromCurrent);
- end;
-
- {TFileStream implementation}
-
- {Filestream object being created}
- constructor TFileStream.Create(Filename: String; Mode: TFileStreamModeSet);
- {Makes file mode}
- function OpenMode: DWORD;
- begin
- Result := 0;
- if fsmRead in Mode then Result := GENERIC_READ;
- if (fsmWrite in Mode) or (fsmCreate in Mode) then
- Result := Result OR GENERIC_WRITE;
- end;
- const
- IsCreate: Array[Boolean] of Integer = (OPEN_ALWAYS, CREATE_ALWAYS);
- begin
- {Call ancestor}
- inherited Create;
-
- {Create handle}
- fHandle := CreateFile(PChar(Filename), OpenMode, FILE_SHARE_READ or
- FILE_SHARE_WRITE, nil, IsCreate[fsmCreate in Mode], 0, 0);
- {Store mode}
- FileMode := Mode;
- end;
-
- {Filestream object being destroyed}
- destructor TFileStream.Destroy;
- begin
- {Terminates file and close}
- if FileMode = [fsmWrite] then
- SetEndOfFile(fHandle);
- CloseHandle(fHandle);
-
- {Call ancestor}
- inherited Destroy;
- end;
-
- {Writes data to the file}
- function TFileStream.Write(const Buffer; Count: Longint): Cardinal;
- begin
- if not WriteFile(fHandle, Buffer, Count, Result, nil) then
- Result := 0;
- end;
-
- {Reads data from the file}
- function TFileStream.Read(var Buffer; Count: Longint): Cardinal;
- begin
- if not ReadFile(fHandle, Buffer, Count, Result, nil) then
- Result := 0;
- end;
-
- {Seeks the file position}
- function TFileStream.Seek(Offset: Integer; Origin: Word): Longint;
- begin
- Result := SetFilePointer(fHandle, Offset, nil, Origin);
- end;
-
- {Sets the size of the file}
- procedure TFileStream.SetSize(const Value: Longint);
- begin
- Seek(Value, soFromBeginning);
- SetEndOfFile(fHandle);
- end;
-
- {TResourceStream implementation}
-
- {Creates the resource stream}
- constructor TResourceStream.Create(Instance: HInst; const ResName: String;
- ResType: PChar);
- var
- ResID: HRSRC;
- ResGlobal: HGlobal;
- begin
- {Obtains the resource ID}
- ResID := FindResource(hInstance, PChar(ResName), RT_RCDATA);
- if ResID = 0 then raise EPNGError.Create('');
- {Obtains memory and size}
- ResGlobal := LoadResource(hInstance, ResID);
- Size := SizeOfResource(hInstance, ResID);
- Memory := LockResource(ResGlobal);
- if (ResGlobal = 0) or (Memory = nil) then EPNGError.Create('');
- end;
-
-
- {Setting resource stream size is not supported}
- procedure TResourceStream.SetSize(const Value: Integer);
- begin
- end;
-
- {Writing into a resource stream is not supported}
- function TResourceStream.Write(const Buffer; Count: Integer): Cardinal;
- begin
- Result := 0;
- end;
-
- {Reads data from the stream}
- function TResourceStream.Read(var Buffer; Count: Integer): Cardinal;
- begin
- //Returns data
- CopyMemory(@Buffer, Ptr(Longint(Memory) + Position), Count);
- //Update position
- inc(Position, Count);
- //Returns
- Result := Count;
- end;
-
- {Seeks data}
- function TResourceStream.Seek(Offset: Integer; Origin: Word): Longint;
- begin
- {Move depending on the origin}
- case Origin of
- soFromBeginning: Position := Offset;
- soFromCurrent: inc(Position, Offset);
- soFromEnd: Position := Size + Offset;
- end;
-
- {Returns the current position}
- Result := Position;
- end;
-
-{$ENDIF}
-
-{TChunk implementation}
-
-{Resizes the data}
-procedure TChunk.ResizeData(const NewSize: Cardinal);
-begin
- fDataSize := NewSize;
- ReallocMem(fData, NewSize + 1);
-end;
-
-{Returns index from list}
-function TChunk.GetIndex: Integer;
-var
- i: Integer;
-begin
- Result := -1; {Avoiding warnings}
- {Searches in the list}
- FOR i := 0 TO Owner.Chunks.Count - 1 DO
- if Owner.Chunks.Item[i] = Self then
- begin
- {Found match}
- Result := i;
- exit;
- end {for i}
-end;
-
-{Returns pointer to the TChunkIHDR}
-function TChunk.GetHeader: TChunkIHDR;
-begin
- Result := Owner.Chunks.Item[0] as TChunkIHDR;
-end;
-
-{Assigns from another TChunk}
-procedure TChunk.Assign(Source: TChunk);
-begin
- {Copy properties}
- fName := Source.fName;
- {Set data size and realloc}
- ResizeData(Source.fDataSize);
-
- {Copy data (if there's any)}
- if fDataSize > 0 then CopyMemory(fData, Source.fData, fDataSize);
-end;
-
-{Chunk being created}
-constructor TChunk.Create(Owner: TPngObject);
-var
- ChunkName: String;
-begin
- {Ancestor create}
- inherited Create;
-
- {If it's a registered class, set the chunk name based on the class}
- {name. For instance, if the class name is TChunkgAMA, the GAMA part}
- {will become the chunk name}
- ChunkName := Copy(ClassName, Length('TChunk') + 1, Length(ClassName));
- if Length(ChunkName) = 4 then CopyMemory(@fName[0], @ChunkName[1], 4);
-
- {Initialize data holder}
- GetMem(fData, 1);
- fDataSize := 0;
- {Record owner}
- fOwner := Owner;
-end;
-
-{Chunk being destroyed}
-destructor TChunk.Destroy;
-begin
- {Free data holder}
- FreeMem(fData, fDataSize + 1);
- {Let ancestor destroy}
- inherited Destroy;
-end;
-
-{Returns the chunk name 1}
-function TChunk.GetChunkName: String;
-begin
- Result := fName
-end;
-
-{Returns the chunk name 2}
-class function TChunk.GetName: String;
-begin
- {For avoid writing GetName for each TChunk descendent, by default for}
- {classes which don't declare GetName, it will look for the class name}
- {to extract the chunk kind. Example, if the class name is TChunkIEND }
- {this method extracts and returns IEND}
- Result := Copy(ClassName, Length('TChunk') + 1, Length(ClassName));
-end;
-
-{Saves the data to the stream}
-function TChunk.SaveData(Stream: TStream): Boolean;
-var
- ChunkSize, ChunkCRC: Cardinal;
-begin
- {First, write the size for the following data in the chunk}
- ChunkSize := ByteSwap(DataSize);
- Stream.Write(ChunkSize, 4);
- {The chunk name}
- Stream.Write(fName, 4);
- {If there is data for the chunk, write it}
- if DataSize > 0 then Stream.Write(Data^, DataSize);
- {Calculates and write CRC}
- ChunkCRC := update_crc($ffffffff, @fName[0], 4);
- ChunkCRC := Byteswap(update_crc(ChunkCRC, Data, DataSize) xor $ffffffff);
- Stream.Write(ChunkCRC, 4);
-
- {Returns that everything went ok}
- Result := TRUE;
-end;
-
-{Saves the chunk to the stream}
-function TChunk.SaveToStream(Stream: TStream): Boolean;
-begin
- Result := SaveData(Stream)
-end;
-
-
-{Loads the chunk from a stream}
-function TChunk.LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean;
-var
- CheckCRC: Cardinal;
- {$IFDEF CheckCRC}RightCRC: Cardinal;{$ENDIF}
-begin
- {Copies data from source}
- ResizeData(Size);
- if Size > 0 then Stream.Read(fData^, Size);
- {Reads CRC}
- Stream.Read(CheckCRC, 4);
- CheckCrc := ByteSwap(CheckCRC);
-
- {Check if crc readed is valid}
- {$IFDEF CheckCRC}
- RightCRC := update_crc($ffffffff, @ChunkName[0], 4);
- RightCRC := update_crc(RightCRC, fData, Size) xor $ffffffff;
- Result := RightCRC = CheckCrc;
-
- {Handle CRC error}
- if not Result then
- begin
- {In case it coult not load chunk}
- Owner.RaiseError(EPngInvalidCRC, EPngInvalidCRCText);
- exit;
- end
- {$ELSE}Result := TRUE; {$ENDIF}
-
-end;
-
-{TChunktIME implementation}
-
-{Chunk being loaded from a stream}
-function TChunktIME.LoadFromStream(Stream: TStream;
- const ChunkName: TChunkName; Size: Integer): Boolean;
-begin
- {Let ancestor load the data}
- Result := inherited LoadFromStream(Stream, ChunkName, Size);
- if not Result or (Size <> 7) then exit; {Size must be 7}
-
- {Reads data}
- fYear := ((pByte(Longint(Data) )^) * 256)+ (pByte(Longint(Data) + 1)^);
- fMonth := pByte(Longint(Data) + 2)^;
- fDay := pByte(Longint(Data) + 3)^;
- fHour := pByte(Longint(Data) + 4)^;
- fMinute := pByte(Longint(Data) + 5)^;
- fSecond := pByte(Longint(Data) + 6)^;
-end;
-
-{Saving the chunk to a stream}
-function TChunktIME.SaveToStream(Stream: TStream): Boolean;
-begin
- {Update data}
- ResizeData(7); {Make sure the size is 7}
- pWord(Data)^ := Year;
- pByte(Longint(Data) + 2)^ := Month;
- pByte(Longint(Data) + 3)^ := Day;
- pByte(Longint(Data) + 4)^ := Hour;
- pByte(Longint(Data) + 5)^ := Minute;
- pByte(Longint(Data) + 6)^ := Second;
-
- {Let inherited save data}
- Result := inherited SaveToStream(Stream);
-end;
-
-{TChunkztXt implementation}
-
-{Loading the chunk from a stream}
-function TChunkzTXt.LoadFromStream(Stream: TStream;
- const ChunkName: TChunkName; Size: Integer): Boolean;
-var
- ErrorOutput: String;
- CompressionMethod: Byte;
- Output: Pointer;
- OutputSize: Integer;
-begin
- {Load data from stream and validate}
- Result := inherited LoadFromStream(Stream, ChunkName, Size);
- if not Result or (Size < 4) then exit;
- fKeyword := PChar(Data); {Get keyword and compression method bellow}
- CompressionMethod := pByte(Longint(fKeyword) + Length(fKeyword))^;
- fText := '';
-
- {In case the compression is 0 (only one accepted by specs), reads it}
- if CompressionMethod = 0 then
- begin
- Output := nil;
- if DecompressZLIB(PChar(Longint(Data) + Length(fKeyword) + 2),
- Size - Length(fKeyword) - 2, Output, OutputSize, ErrorOutput) then
- begin
- SetLength(fText, OutputSize);
- CopyMemory(@fText[1], Output, OutputSize);
- end {if DecompressZLIB(...};
- FreeMem(Output);
- end {if CompressionMethod = 0}
-
-end;
-
-{Saving the chunk to a stream}
-function TChunkztXt.SaveToStream(Stream: TStream): Boolean;
-var
- Output: Pointer;
- OutputSize: Integer;
- ErrorOutput: String;
-begin
- Output := nil; {Initializes output}
- if fText = '' then fText := ' ';
-
- {Compresses the data}
- if CompressZLIB(@fText[1], Length(fText), Owner.CompressionLevel, Output,
- OutputSize, ErrorOutput) then
- begin
- {Size is length from keyword, plus a null character to divide}
- {plus the compression method, plus the length of the text (zlib compressed)}
- ResizeData(Length(fKeyword) + 2 + OutputSize);
-
- Fillchar(Data^, DataSize, #0);
- {Copies the keyword data}
- if Keyword <> '' then
- CopyMemory(Data, @fKeyword[1], Length(Keyword));
- {Compression method 0 (inflate/deflate)}
- pByte(Ptr(Longint(Data) + Length(Keyword) + 1))^ := 0;
- if OutputSize > 0 then
- CopyMemory(Ptr(Longint(Data) + Length(Keyword) + 2), Output, OutputSize);
-
- {Let ancestor calculate crc and save}
- Result := SaveData(Stream);
- end {if CompressZLIB(...} else Result := False;
-
- {Frees output}
- if Output <> nil then FreeMem(Output)
-end;
-
-{TChunktEXt implementation}
-
-{Assigns from another text chunk}
-procedure TChunktEXt.Assign(Source: TChunk);
-begin
- fKeyword := TChunktEXt(Source).fKeyword;
- fText := TChunktEXt(Source).fText;
-end;
-
-{Loading the chunk from a stream}
-function TChunktEXt.LoadFromStream(Stream: TStream;
- const ChunkName: TChunkName; Size: Integer): Boolean;
-begin
- {Load data from stream and validate}
- Result := inherited LoadFromStream(Stream, ChunkName, Size);
- if not Result or (Size < 3) then exit;
- {Get text}
- fKeyword := PChar(Data);
- SetLength(fText, Size - Length(fKeyword) - 1);
- CopyMemory(@fText[1], Ptr(Longint(Data) + Length(fKeyword) + 1),
- Length(fText));
-end;
-
-{Saving the chunk to a stream}
-function TChunktEXt.SaveToStream(Stream: TStream): Boolean;
-begin
- {Size is length from keyword, plus a null character to divide}
- {plus the length of the text}
- ResizeData(Length(fKeyword) + 1 + Length(fText));
- Fillchar(Data^, DataSize, #0);
- {Copy data}
- if Keyword <> '' then
- CopyMemory(Data, @fKeyword[1], Length(Keyword));
- if Text <> '' then
- CopyMemory(Ptr(Longint(Data) + Length(Keyword) + 1), @fText[1],
- Length(Text));
- {Let ancestor calculate crc and save}
- Result := inherited SaveToStream(Stream);
-end;
-
-
-{TChunkIHDR implementation}
-
-{Chunk being created}
-constructor TChunkIHDR.Create(Owner: TPngObject);
-begin
- {Call inherited}
- inherited Create(Owner);
- {Prepare pointers}
- ImageHandle := 0;
- ImageDC := 0;
-end;
-
-{Chunk being destroyed}
-destructor TChunkIHDR.Destroy;
-begin
- {Free memory}
- FreeImageData();
-
- {Calls TChunk destroy}
- inherited Destroy;
-end;
-
-{Assigns from another IHDR chunk}
-procedure TChunkIHDR.Assign(Source: TChunk);
-begin
- {Copy the IHDR data}
- if Source is TChunkIHDR then
- begin
- {Copy IHDR values}
- IHDRData := TChunkIHDR(Source).IHDRData;
-
- {Prepare to hold data by filling BitmapInfo structure and}
- {resizing ImageData and ImageAlpha memory allocations}
- PrepareImageData();
-
- {Copy image data}
- CopyMemory(ImageData, TChunkIHDR(Source).ImageData,
- BytesPerRow * Integer(Height));
- CopyMemory(ImageAlpha, TChunkIHDR(Source).ImageAlpha,
- Integer(Width) * Integer(Height));
-
- {Copy palette colors}
- BitmapInfo.bmiColors := TChunkIHDR(Source).BitmapInfo.bmiColors;
- end
- else
- Owner.RaiseError(EPNGError, EPNGCannotAssignChunkText);
-end;
-
-{Release allocated image data}
-procedure TChunkIHDR.FreeImageData;
-begin
- {Free old image data}
- if ImageHandle <> 0 then DeleteObject(ImageHandle);
- if ImageDC <> 0 then DeleteDC(ImageDC);
- if ImageAlpha <> nil then FreeMem(ImageAlpha);
- {$IFDEF Store16bits}
- if ExtraImageData <> nil then FreeMem(ExtraImageData);
- {$ENDIF}
- ImageHandle := 0; ImageDC := 0; ImageAlpha := nil; ImageData := nil;
-end;
-
-{Chunk being loaded from a stream}
-function TChunkIHDR.LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean;
-begin
- {Let TChunk load it}
- Result := inherited LoadFromStream(Stream, ChunkName, Size);
- if not Result then Exit;
-
- {Now check values}
- {Note: It's recommended by png specification to make sure that the size}
- {must be 13 bytes to be valid, but some images with 14 bytes were found}
- {which could be loaded by internet explorer and other tools}
- if (fDataSize < SIZEOF(TIHdrData)) then
- begin
- {Ihdr must always have at least 13 bytes}
- Result := False;
- Owner.RaiseError(EPNGInvalidIHDR, EPNGInvalidIHDRText);
- exit;
- end;
-
- {Everything ok, reads IHDR}
- IHDRData := pIHDRData(fData)^;
- IHDRData.Width := ByteSwap(IHDRData.Width);
- IHDRData.Height := ByteSwap(IHDRData.Height);
-
- {The width and height must not be larger than 65535 pixels}
- if (IHDRData.Width > High(Word)) or (IHDRData.Height > High(Word)) then
- begin
- Result := False;
- Owner.RaiseError(EPNGSizeExceeds, EPNGSizeExceedsText);
- exit;
- end {if IHDRData.Width > High(Word)};
- {Compression method must be 0 (inflate/deflate)}
- if (IHDRData.CompressionMethod <> 0) then
- begin
- Result := False;
- Owner.RaiseError(EPNGUnknownCompression, EPNGUnknownCompressionText);
- exit;
- end;
- {Interlace must be either 0 (none) or 7 (adam7)}
- if (IHDRData.InterlaceMethod <> 0) and (IHDRData.InterlaceMethod <> 1) then
- begin
- Result := False;
- Owner.RaiseError(EPNGUnknownInterlace, EPNGUnknownInterlaceText);
- exit;
- end;
-
- {Updates owner properties}
- Owner.InterlaceMethod := TInterlaceMethod(IHDRData.InterlaceMethod);
-
- {Prepares data to hold image}
- PrepareImageData();
-end;
-
-{Saving the IHDR chunk to a stream}
-function TChunkIHDR.SaveToStream(Stream: TStream): Boolean;
-begin
- {Ignore 2 bits images}
- if BitDepth = 2 then BitDepth := 4;
-
- {It needs to do is update the data with the IHDR data}
- {structure containing the write values}
- ResizeData(SizeOf(TIHDRData));
- pIHDRData(fData)^ := IHDRData;
- {..byteswap 4 byte types}
- pIHDRData(fData)^.Width := ByteSwap(pIHDRData(fData)^.Width);
- pIHDRData(fData)^.Height := ByteSwap(pIHDRData(fData)^.Height);
- {..update interlace method}
- pIHDRData(fData)^.InterlaceMethod := Byte(Owner.InterlaceMethod);
- {..and then let the ancestor SaveToStream do the hard work}
- Result := inherited SaveToStream(Stream);
-end;
-
-{Resizes the image data to fill the color type, bit depth, }
-{width and height parameters}
-procedure TChunkIHDR.PrepareImageData();
-
- {Set the bitmap info}
- procedure SetInfo(const Bitdepth: Integer; const Palette: Boolean);
- begin
-
- {Copy if the bitmap contain palette entries}
- HasPalette := Palette;
- {Initialize the structure with zeros}
- fillchar(BitmapInfo, sizeof(BitmapInfo), #0);
- {Fill the strucutre}
- with BitmapInfo.bmiHeader do
- begin
- biSize := sizeof(TBitmapInfoHeader);
- biHeight := Height;
- biWidth := Width;
- biPlanes := 1;
- biBitCount := BitDepth;
- biCompression := BI_RGB;
- end {with BitmapInfo.bmiHeader}
- end;
-begin
- {Prepare bitmap info header}
- Fillchar(BitmapInfo, sizeof(TMaxBitmapInfo), #0);
- {Release old image data}
- FreeImageData();
-
- {Obtain number of bits for each pixel}
- case ColorType of
- COLOR_GRAYSCALE, COLOR_PALETTE, COLOR_GRAYSCALEALPHA:
- case BitDepth of
- {These are supported by windows}
- 1, 4, 8: SetInfo(BitDepth, TRUE);
- {2 bits for each pixel is not supported by windows bitmap}
- 2 : SetInfo(4, TRUE);
- {Also 16 bits (2 bytes) for each pixel is not supported}
- {and should be transormed into a 8 bit grayscale}
- 16 : SetInfo(8, TRUE);
- end;
- {Only 1 byte (8 bits) is supported}
- COLOR_RGB, COLOR_RGBALPHA: SetInfo(24, FALSE);
- end {case ColorType};
- {Number of bytes for each scanline}
- BytesPerRow := (((BitmapInfo.bmiHeader.biBitCount * Width) + 31)
- and not 31) div 8;
-
- {Build array for alpha information, if necessary}
- if (ColorType = COLOR_RGBALPHA) or (ColorType = COLOR_GRAYSCALEALPHA) then
- begin
- GetMem(ImageAlpha, Integer(Width) * Integer(Height));
- FillChar(ImageAlpha^, Integer(Width) * Integer(Height), #0);
- end;
-
- {Build array for extra byte information}
- {$IFDEF Store16bits}
- if (BitDepth = 16) then
- begin
- GetMem(ExtraImageData, BytesPerRow * Integer(Height));
- FillChar(ExtraImageData^, BytesPerRow * Integer(Height), #0);
- end;
- {$ENDIF}
-
- {Creates the image to hold the data, CreateDIBSection does a better}
- {work in allocating necessary memory}
- ImageDC := CreateCompatibleDC(0);
- ImageHandle := CreateDIBSection(ImageDC, pBitmapInfo(@BitmapInfo)^,
- DIB_RGB_COLORS, ImageData, 0, 0);
-
- {Clears the old palette (if any)}
- with Owner do
- if TempPalette <> 0 then
- begin
- DeleteObject(TempPalette);
- TempPalette := 0;
- end {with Owner, if TempPalette <> 0};
-
- {Build array and allocate bytes for each row}
- zeromemory(ImageData, BytesPerRow * Integer(Height));
-end;
-
-{TChunktRNS implementation}
-
-{$IFNDEF UseDelphi}
-function CompareMem(P1, P2: pByte; const Size: Integer): Boolean;
-var i: Integer;
-begin
- Result := True;
- for i := 1 to Size do
- begin
- if P1^ <> P2^ then Result := False;
- inc(P1); inc(P2);
- end {for i}
-end;
-{$ENDIF}
-
-{Sets the transpararent color}
-procedure TChunktRNS.SetTransparentColor(const Value: ColorRef);
-var
- i: Byte;
- LookColor: TRGBQuad;
-begin
- {Clears the palette values}
- Fillchar(PaletteValues, SizeOf(PaletteValues), #0);
- {Sets that it uses bit transparency}
- fBitTransparency := True;
-
-
- {Depends on the color type}
- with Header do
- case ColorType of
- COLOR_GRAYSCALE:
- begin
- Self.ResizeData(2);
- pWord(@PaletteValues[0])^ := ByteSwap16(GetRValue(Value));
- end;
- COLOR_RGB:
- begin
- Self.ResizeData(6);
- pWord(@PaletteValues[0])^ := ByteSwap16(GetRValue(Value));
- pWord(@PaletteValues[2])^ := ByteSwap16(GetGValue(Value));
- pWord(@PaletteValues[4])^ := ByteSwap16(GetBValue(Value));
- end;
- COLOR_PALETTE:
- begin
- {Creates a RGBQuad to search for the color}
- LookColor.rgbRed := GetRValue(Value);
- LookColor.rgbGreen := GetGValue(Value);
- LookColor.rgbBlue := GetBValue(Value);
- {Look in the table for the entry}
- for i := 0 to 255 do
- if CompareMem(@BitmapInfo.bmiColors[i], @LookColor, 3) then
- Break;
- {Fill the transparency table}
- Fillchar(PaletteValues, i, 255);
- Self.ResizeData(i + 1)
-
- end
- end {case / with};
-
-end;
-
-{Returns the transparent color for the image}
-function TChunktRNS.GetTransparentColor: ColorRef;
-var
- PaletteChunk: TChunkPLTE;
- i: Integer;
-begin
- Result := 0; {Default: Unknown transparent color}
-
- {Depends on the color type}
- with Header do
- case ColorType of
- COLOR_GRAYSCALE:
- Result := RGB(PaletteValues[0], PaletteValues[0],
- PaletteValues[0]);
- COLOR_RGB:
- Result := RGB(PaletteValues[1], PaletteValues[3], PaletteValues[5]);
- COLOR_PALETTE:
- begin
- {Obtains the palette chunk}
- PaletteChunk := Owner.Chunks.ItemFromClass(TChunkPLTE) as TChunkPLTE;
-
- {Looks for an entry with 0 transparency meaning that it is the}
- {full transparent entry}
- for i := 0 to Self.DataSize - 1 do
- if PaletteValues[i] = 0 then
- with PaletteChunk.GetPaletteItem(i) do
- begin
- Result := RGB(rgbRed, rgbGreen, rgbBlue);
- break
- end
- end {COLOR_PALETTE}
- end {case Header.ColorType};
-end;
-
-{Saving the chunk to a stream}
-function TChunktRNS.SaveToStream(Stream: TStream): Boolean;
-begin
- {Copy palette into data buffer}
- if DataSize <= 256 then
- CopyMemory(fData, @PaletteValues[0], DataSize);
-
- Result := inherited SaveToStream(Stream);
-end;
-
-{Assigns from another chunk}
-procedure TChunktRNS.Assign(Source: TChunk);
-begin
- CopyMemory(@PaletteValues[0], @TChunkTrns(Source).PaletteValues[0], 256);
- fBitTransparency := TChunkTrns(Source).fBitTransparency;
- inherited Assign(Source);
-end;
-
-{Loads the chunk from a stream}
-function TChunktRNS.LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean;
-var
- i, Differ255: Integer;
-begin
- {Let inherited load}
- Result := inherited LoadFromStream(Stream, ChunkName, Size);
-
- if not Result then Exit;
-
- {Make sure size is correct}
- if Size > 256 then Owner.RaiseError(EPNGInvalidPalette,
- EPNGInvalidPaletteText);
-
- {The unset items should have value 255}
- Fillchar(PaletteValues[0], 256, 255);
- {Copy the other values}
- CopyMemory(@PaletteValues[0], fData, Size);
-
- {Create the mask if needed}
- case Header.ColorType of
- {Mask for grayscale and RGB}
- COLOR_RGB, COLOR_GRAYSCALE: fBitTransparency := True;
- COLOR_PALETTE:
- begin
- Differ255 := 0; {Count the entries with a value different from 255}
- {Tests if it uses bit transparency}
- for i := 0 to Size - 1 do
- if PaletteValues[i] <> 255 then inc(Differ255);
-
- {If it has one value different from 255 it is a bit transparency}
- fBitTransparency := (Differ255 = 1);
- end {COLOR_PALETTE}
- end {case Header.ColorType};
-
-end;
-
-{Prepares the image palette}
-procedure TChunkIDAT.PreparePalette;
-var
- Entries: Word;
- j : Integer;
-begin
- {In case the image uses grayscale, build a grayscale palette}
- with Header do
- if (ColorType = COLOR_GRAYSCALE) or (ColorType = COLOR_GRAYSCALEALPHA) then
- begin
- {Calculate total number of palette entries}
- Entries := (1 shl Byte(BitmapInfo.bmiHeader.biBitCount));
-
- FOR j := 0 TO Entries - 1 DO
- with BitmapInfo.bmiColors[j] do
- begin
-
- {Calculate each palette entry}
- rgbRed := fOwner.GammaTable[MulDiv(j, 255, Entries - 1)];
- rgbGreen := rgbRed;
- rgbBlue := rgbRed;
- end {with BitmapInfo.bmiColors[j]}
- end {if ColorType = COLOR_GRAYSCALE..., with Header}
-end;
-
-{Reads from ZLIB}
-function TChunkIDAT.IDATZlibRead(var ZLIBStream: TZStreamRec2;
- Buffer: Pointer; Count: Integer; var EndPos: Integer;
- var crcfile: Cardinal): Integer;
-var
- ProcResult : Integer;
- IDATHeader : Array[0..3] of char;
- IDATCRC : Cardinal;
-begin
- {Uses internal record pointed by ZLIBStream to gather information}
- with ZLIBStream, ZLIBStream.zlib do
- begin
- {Set the buffer the zlib will read into}
- next_out := Buffer;
- avail_out := Count;
-
- {Decode until it reach the Count variable}
- while avail_out > 0 do
- begin
- {In case it needs more data and it's in the end of a IDAT chunk,}
- {it means that there are more IDAT chunks}
- if (fStream.Position = EndPos) and (avail_out > 0) and
- (avail_in = 0) then
- begin
- {End this chunk by reading and testing the crc value}
- fStream.Read(IDATCRC, 4);
-
- {$IFDEF CheckCRC}
- if crcfile xor $ffffffff <> Cardinal(ByteSwap(IDATCRC)) then
- begin
- Result := -1;
- Owner.RaiseError(EPNGInvalidCRC, EPNGInvalidCRCText);
- exit;
- end;
- {$ENDIF}
-
- {Start reading the next chunk}
- fStream.Read(EndPos, 4); {Reads next chunk size}
- fStream.Read(IDATHeader[0], 4); {Next chunk header}
- {It must be a IDAT chunk since image data is required and PNG}
- {specification says that multiple IDAT chunks must be consecutive}
- if IDATHeader <> 'IDAT' then
- begin
- Owner.RaiseError(EPNGMissingMultipleIDAT, EPNGMissingMultipleIDATText);
- result := -1;
- exit;
- end;
-
- {Calculate chunk name part of the crc}
- {$IFDEF CheckCRC}
- crcfile := update_crc($ffffffff, @IDATHeader[0], 4);
- {$ENDIF}
- EndPos := fStream.Position + ByteSwap(EndPos);
- end;
-
-
- {In case it needs compressed data to read from}
- if avail_in = 0 then
- begin
- {In case it's trying to read more than it is avaliable}
- if fStream.Position + ZLIBAllocate > EndPos then
- avail_in := fStream.Read(Data^, EndPos - fStream.Position)
- else
- avail_in := fStream.Read(Data^, ZLIBAllocate);
- {Update crc}
- {$IFDEF CheckCRC}
- crcfile := update_crc(crcfile, Data, avail_in);
- {$ENDIF}
-
- {In case there is no more compressed data to read from}
- if avail_in = 0 then
- begin
- Result := Count - avail_out;
- Exit;
- end;
-
- {Set next buffer to read and record current position}
- next_in := Data;
-
- end {if avail_in = 0};
-
- ProcResult := inflate(zlib, 0);
-
- {In case the result was not sucessfull}
- if (ProcResult < 0) then
- begin
- Result := -1;
- Owner.RaiseError(EPNGZLIBError,
- EPNGZLIBErrorText + zliberrors[procresult]);
- exit;
- end;
-
- end {while avail_out > 0};
-
- end {with};
-
- {If everything gone ok, it returns the count bytes}
- Result := Count;
-end;
-
-{TChunkIDAT implementation}
-
-const
- {Adam 7 interlacing values}
- RowStart: array[0..6] of Integer = (0, 0, 4, 0, 2, 0, 1);
- ColumnStart: array[0..6] of Integer = (0, 4, 0, 2, 0, 1, 0);
- RowIncrement: array[0..6] of Integer = (8, 8, 8, 4, 4, 2, 2);
- ColumnIncrement: array[0..6] of Integer = (8, 8, 4, 4, 2, 2, 1);
-
-{Copy interlaced images with 1 byte for R, G, B}
-procedure TChunkIDAT.CopyInterlacedRGB8(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Dest := pChar(Longint(Dest) + Col * 3);
- repeat
- {Copy this row}
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 1)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) )^]; inc(Dest);
-
- {Move to next column}
- inc(Src, 3);
- inc(Dest, ColumnIncrement[Pass] * 3 - 3);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Copy interlaced images with 2 bytes for R, G, B}
-procedure TChunkIDAT.CopyInterlacedRGB16(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Dest := pChar(Longint(Dest) + Col * 3);
- repeat
- {Copy this row}
- Byte(Dest^) := Owner.GammaTable[pByte(Longint(Src) + 4)^]; inc(Dest);
- Byte(Dest^) := Owner.GammaTable[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := Owner.GammaTable[pByte(Longint(Src) )^]; inc(Dest);
- {$IFDEF Store16bits}
- {Copy extra pixel values}
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 5)^]; inc(Extra);
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 3)^]; inc(Extra);
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 1)^]; inc(Extra);
- {$ENDIF}
-
- {Move to next column}
- inc(Src, 6);
- inc(Dest, ColumnIncrement[Pass] * 3 - 3);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Copy ímages with palette using bit depths 1, 4 or 8}
-procedure TChunkIDAT.CopyInterlacedPalette148(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-const
- BitTable: Array[1..8] of Integer = ($1, $3, 0, $F, 0, 0, 0, $FF);
- StartBit: Array[1..8] of Integer = (7 , 0 , 0, 4, 0, 0, 0, 0);
-var
- CurBit, Col: Integer;
- Dest2: PChar;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- repeat
- {Copy data}
- CurBit := StartBit[Header.BitDepth];
- repeat
- {Adjust pointer to pixel byte bounds}
- Dest2 := pChar(Longint(Dest) + (Header.BitDepth * Col) div 8);
- {Copy data}
- Byte(Dest2^) := Byte(Dest2^) or
- ( ((Byte(Src^) shr CurBit) and BitTable[Header.BitDepth])
- shl (StartBit[Header.BitDepth] - (Col * Header.BitDepth mod 8)));
-
- {Move to next column}
- inc(Col, ColumnIncrement[Pass]);
- {Will read next bits}
- dec(CurBit, Header.BitDepth);
- until CurBit < 0;
-
- {Move to next byte in source}
- inc(Src);
- until Col >= ImageWidth;
-end;
-
-{Copy ímages with palette using bit depth 2}
-procedure TChunkIDAT.CopyInterlacedPalette2(const Pass: Byte; Src, Dest,
- Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- CurBit, Col: Integer;
- Dest2: PChar;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- repeat
- {Copy data}
- CurBit := 6;
- repeat
- {Adjust pointer to pixel byte bounds}
- Dest2 := pChar(Longint(Dest) + Col div 2);
- {Copy data}
- Byte(Dest2^) := Byte(Dest2^) or (((Byte(Src^) shr CurBit) and $3)
- shl (4 - (4 * Col) mod 8));
- {Move to next column}
- inc(Col, ColumnIncrement[Pass]);
- {Will read next bits}
- dec(CurBit, 2);
- until CurBit < 0;
-
- {Move to next byte in source}
- inc(Src);
- until Col >= ImageWidth;
-end;
-
-{Copy ímages with grayscale using bit depth 2}
-procedure TChunkIDAT.CopyInterlacedGray2(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- CurBit, Col: Integer;
- Dest2: PChar;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- repeat
- {Copy data}
- CurBit := 6;
- repeat
- {Adjust pointer to pixel byte bounds}
- Dest2 := pChar(Longint(Dest) + Col div 2);
- {Copy data}
- Byte(Dest2^) := Byte(Dest2^) or ((((Byte(Src^) shr CurBit) shl 2) and $F)
- shl (4 - (Col*4) mod 8));
- {Move to next column}
- inc(Col, ColumnIncrement[Pass]);
- {Will read next bits}
- dec(CurBit, 2);
- until CurBit < 0;
-
- {Move to next byte in source}
- inc(Src);
- until Col >= ImageWidth;
-end;
-
-{Copy ímages with palette using 2 bytes for each pixel}
-procedure TChunkIDAT.CopyInterlacedGrayscale16(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Dest := pChar(Longint(Dest) + Col);
- repeat
- {Copy this row}
- Dest^ := Src^; inc(Dest);
- {$IFDEF Store16bits}
- Extra^ := pChar(Longint(Src) + 1)^; inc(Extra);
- {$ENDIF}
-
- {Move to next column}
- inc(Src, 2);
- inc(Dest, ColumnIncrement[Pass] - 1);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Decodes interlaced RGB alpha with 1 byte for each sample}
-procedure TChunkIDAT.CopyInterlacedRGBAlpha8(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Dest := pChar(Longint(Dest) + Col * 3);
- Trans := pChar(Longint(Trans) + Col);
- repeat
- {Copy this row and alpha value}
- Trans^ := pChar(Longint(Src) + 3)^;
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 1)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) )^]; inc(Dest);
-
- {Move to next column}
- inc(Src, 4);
- inc(Dest, ColumnIncrement[Pass] * 3 - 3);
- inc(Trans, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Decodes interlaced RGB alpha with 2 bytes for each sample}
-procedure TChunkIDAT.CopyInterlacedRGBAlpha16(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Dest := pChar(Longint(Dest) + Col * 3);
- Trans := pChar(Longint(Trans) + Col);
- repeat
- {Copy this row and alpha value}
- Trans^ := pChar(Longint(Src) + 6)^;
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 4)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) )^]; inc(Dest);
- {$IFDEF Store16bits}
- {Copy extra pixel values}
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 5)^]; inc(Extra);
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 3)^]; inc(Extra);
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 1)^]; inc(Extra);
- {$ENDIF}
-
- {Move to next column}
- inc(Src, 8);
- inc(Dest, ColumnIncrement[Pass] * 3 - 3);
- inc(Trans, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Decodes 8 bit grayscale image followed by an alpha sample}
-procedure TChunkIDAT.CopyInterlacedGrayscaleAlpha8(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- Col: Integer;
-begin
- {Get first column, pointers to the data and enter in loop}
- Col := ColumnStart[Pass];
- Dest := pChar(Longint(Dest) + Col);
- Trans := pChar(Longint(Trans) + Col);
- repeat
- {Copy this grayscale value and alpha}
- Dest^ := Src^; inc(Src);
- Trans^ := Src^; inc(Src);
-
- {Move to next column}
- inc(Dest, ColumnIncrement[Pass]);
- inc(Trans, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Decodes 16 bit grayscale image followed by an alpha sample}
-procedure TChunkIDAT.CopyInterlacedGrayscaleAlpha16(const Pass: Byte;
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- Col: Integer;
-begin
- {Get first column, pointers to the data and enter in loop}
- Col := ColumnStart[Pass];
- Dest := pChar(Longint(Dest) + Col);
- Trans := pChar(Longint(Trans) + Col);
- repeat
- {$IFDEF Store16bits}
- Extra^ := pChar(Longint(Src) + 1)^; inc(Extra);
- {$ENDIF}
- {Copy this grayscale value and alpha, transforming 16 bits into 8}
- Dest^ := Src^; inc(Src, 2);
- Trans^ := Src^; inc(Src, 2);
-
- {Move to next column}
- inc(Dest, ColumnIncrement[Pass]);
- inc(Trans, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Decodes an interlaced image}
-procedure TChunkIDAT.DecodeInterlacedAdam7(Stream: TStream;
- var ZLIBStream: TZStreamRec2; const Size: Integer; var crcfile: Cardinal);
-var
- CurrentPass: Byte;
- PixelsThisRow: Integer;
- CurrentRow: Integer;
- Trans, Data{$IFDEF Store16bits}, Extra{$ENDIF}: pChar;
- CopyProc: procedure(const Pass: Byte; Src, Dest,
- Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar) of object;
-begin
-
- CopyProc := nil; {Initialize}
- {Determine method to copy the image data}
- case Header.ColorType of
- {R, G, B values for each pixel}
- COLOR_RGB:
- case Header.BitDepth of
- 8: CopyProc := CopyInterlacedRGB8;
- 16: CopyProc := CopyInterlacedRGB16;
- end {case Header.BitDepth};
- {Palette}
- COLOR_PALETTE, COLOR_GRAYSCALE:
- case Header.BitDepth of
- 1, 4, 8: CopyProc := CopyInterlacedPalette148;
- 2 : if Header.ColorType = COLOR_PALETTE then
- CopyProc := CopyInterlacedPalette2
- else
- CopyProc := CopyInterlacedGray2;
- 16 : CopyProc := CopyInterlacedGrayscale16;
- end;
- {RGB followed by alpha}
- COLOR_RGBALPHA:
- case Header.BitDepth of
- 8: CopyProc := CopyInterlacedRGBAlpha8;
- 16: CopyProc := CopyInterlacedRGBAlpha16;
- end;
- {Grayscale followed by alpha}
- COLOR_GRAYSCALEALPHA:
- case Header.BitDepth of
- 8: CopyProc := CopyInterlacedGrayscaleAlpha8;
- 16: CopyProc := CopyInterlacedGrayscaleAlpha16;
- end;
- end {case Header.ColorType};
-
- {Adam7 method has 7 passes to make the final image}
- FOR CurrentPass := 0 TO 6 DO
- begin
- {Calculates the number of pixels and bytes for this pass row}
- PixelsThisRow := (ImageWidth - ColumnStart[CurrentPass] +
- ColumnIncrement[CurrentPass] - 1) div ColumnIncrement[CurrentPass];
- Row_Bytes := BytesForPixels(PixelsThisRow, Header.ColorType,
- Header.BitDepth);
- {Clear buffer for this pass}
- ZeroMemory(Row_Buffer[not RowUsed], Row_Bytes);
-
- {Get current row index}
- CurrentRow := RowStart[CurrentPass];
- {Get a pointer to the current row image data}
- Data := Ptr(Longint(Header.ImageData) + Header.BytesPerRow *
- (ImageHeight - 1 - CurrentRow));
- Trans := Ptr(Longint(Header.ImageAlpha) + ImageWidth * CurrentRow);
- {$IFDEF Store16bits}
- Extra := Ptr(Longint(Header.ExtraImageData) + Header.BytesPerRow *
- (ImageHeight - 1 - CurrentRow));
- {$ENDIF}
-
- if Row_Bytes > 0 then {There must have bytes for this interlaced pass}
- while CurrentRow < ImageHeight do
- begin
- {Reads this line and filter}
- if IDATZlibRead(ZLIBStream, @Row_Buffer[RowUsed][0], Row_Bytes + 1,
- EndPos, CRCFile) = 0 then break;
-
- FilterRow;
- {Copy image data}
-
- CopyProc(CurrentPass, @Row_Buffer[RowUsed][1], Data, Trans
- {$IFDEF Store16bits}, Extra{$ENDIF});
-
- {Use the other RowBuffer item}
- RowUsed := not RowUsed;
-
- {Move to the next row}
- inc(CurrentRow, RowIncrement[CurrentPass]);
- {Move pointer to the next line}
- dec(Data, RowIncrement[CurrentPass] * Header.BytesPerRow);
- inc(Trans, RowIncrement[CurrentPass] * ImageWidth);
- {$IFDEF Store16bits}
- dec(Extra, RowIncrement[CurrentPass] * Header.BytesPerRow);
- {$ENDIF}
- end {while CurrentRow < ImageHeight};
-
- end {FOR CurrentPass};
-
-end;
-
-{Copy 8 bits RGB image}
-procedure TChunkIDAT.CopyNonInterlacedRGB8(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- {Copy pixel values}
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 1)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) )^]; inc(Dest);
- {Move to next pixel}
- inc(Src, 3);
- end {for I}
-end;
-
-{Copy 16 bits RGB image}
-procedure TChunkIDAT.CopyNonInterlacedRGB16(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- //Since windows does not supports 2 bytes for
- //each R, G, B value, the method will read only 1 byte from it
- {Copy pixel values}
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 4)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) )^]; inc(Dest);
- {$IFDEF Store16bits}
- {Copy extra pixel values}
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 5)^]; inc(Extra);
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 3)^]; inc(Extra);
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 1)^]; inc(Extra);
- {$ENDIF}
-
- {Move to next pixel}
- inc(Src, 6);
- end {for I}
-end;
-
-{Copy types using palettes (1, 4 or 8 bits per pixel)}
-procedure TChunkIDAT.CopyNonInterlacedPalette148(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-begin
- {It's simple as copying the data}
- CopyMemory(Dest, Src, Row_Bytes);
-end;
-
-{Copy grayscale types using 2 bits for each pixel}
-procedure TChunkIDAT.CopyNonInterlacedGray2(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- i: Integer;
-begin
- {2 bits is not supported, this routine will converted into 4 bits}
- FOR i := 1 TO Row_Bytes do
- begin
- Byte(Dest^) := ((Byte(Src^) shr 2) and $F) or ((Byte(Src^)) and $F0); inc(Dest);
- Byte(Dest^) := ((Byte(Src^) shl 2) and $F) or ((Byte(Src^) shl 4) and $F0); inc(Dest);
- inc(Src);
- end {FOR i}
-end;
-
-{Copy types using palette with 2 bits for each pixel}
-procedure TChunkIDAT.CopyNonInterlacedPalette2(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- i: Integer;
-begin
- {2 bits is not supported, this routine will converted into 4 bits}
- FOR i := 1 TO Row_Bytes do
- begin
- Byte(Dest^) := ((Byte(Src^) shr 4) and $3) or ((Byte(Src^) shr 2) and $30); inc(Dest);
- Byte(Dest^) := (Byte(Src^) and $3) or ((Byte(Src^) shl 2) and $30); inc(Dest);
- inc(Src);
- end {FOR i}
-end;
-
-{Copy grayscale images with 16 bits}
-procedure TChunkIDAT.CopyNonInterlacedGrayscale16(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- {Windows does not supports 16 bits for each pixel in grayscale}
- {mode, so reduce to 8}
- Dest^ := Src^; inc(Dest);
- {$IFDEF Store16bits}
- Extra^ := pChar(Longint(Src) + 1)^; inc(Extra);
- {$ENDIF}
-
- {Move to next pixel}
- inc(Src, 2);
- end {for I}
-end;
-
-{Copy 8 bits per sample RGB images followed by an alpha byte}
-procedure TChunkIDAT.CopyNonInterlacedRGBAlpha8(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- i: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- {Copy pixel values and transparency}
- Trans^ := pChar(Longint(Src) + 3)^;
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 1)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) )^]; inc(Dest);
- {Move to next pixel}
- inc(Src, 4); inc(Trans);
- end {for I}
-end;
-
-{Copy 16 bits RGB image with alpha using 2 bytes for each sample}
-procedure TChunkIDAT.CopyNonInterlacedRGBAlpha16(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- //Copy rgb and alpha values (transforming from 16 bits to 8 bits)
- {Copy pixel values}
- Trans^ := pChar(Longint(Src) + 6)^;
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 4)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.GammaTable[pByte(Longint(Src) )^]; inc(Dest);
- {$IFDEF Store16bits}
- {Copy extra pixel values}
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 5)^]; inc(Extra);
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 3)^]; inc(Extra);
- Byte(Extra^) := fOwner.GammaTable[pByte(Longint(Src) + 1)^]; inc(Extra);
- {$ENDIF}
- {Move to next pixel}
- inc(Src, 8); inc(Trans);
- end {for I}
-end;
-
-{Copy 8 bits per sample grayscale followed by alpha}
-procedure TChunkIDAT.CopyNonInterlacedGrayscaleAlpha8(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- {Copy alpha value and then gray value}
- Dest^ := Src^; inc(Src);
- Trans^ := Src^; inc(Src);
- inc(Dest); inc(Trans);
- end;
-end;
-
-{Copy 16 bits per sample grayscale followed by alpha}
-procedure TChunkIDAT.CopyNonInterlacedGrayscaleAlpha16(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- {Copy alpha value and then gray value}
- {$IFDEF Store16bits}
- Extra^ := pChar(Longint(Src) + 1)^; inc(Extra);
- {$ENDIF}
- Dest^ := Src^; inc(Src, 2);
- Trans^ := Src^; inc(Src, 2);
- inc(Dest); inc(Trans);
- end;
-end;
-
-{Decode non interlaced image}
-procedure TChunkIDAT.DecodeNonInterlaced(Stream: TStream;
- var ZLIBStream: TZStreamRec2; const Size: Integer; var crcfile: Cardinal);
-var
- j: Cardinal;
- Trans, Data{$IFDEF Store16bits}, Extra{$ENDIF}: pChar;
- CopyProc: procedure(
- Src, Dest, Trans{$IFDEF Store16bits}, Extra{$ENDIF}: pChar) of object;
-begin
- CopyProc := nil; {Initialize}
- {Determines the method to copy the image data}
- case Header.ColorType of
- {R, G, B values}
- COLOR_RGB:
- case Header.BitDepth of
- 8: CopyProc := CopyNonInterlacedRGB8;
- 16: CopyProc := CopyNonInterlacedRGB16;
- end;
- {Types using palettes}
- COLOR_PALETTE, COLOR_GRAYSCALE:
- case Header.BitDepth of
- 1, 4, 8: CopyProc := CopyNonInterlacedPalette148;
- 2 : if Header.ColorType = COLOR_PALETTE then
- CopyProc := CopyNonInterlacedPalette2
- else
- CopyProc := CopyNonInterlacedGray2;
- 16 : CopyProc := CopyNonInterlacedGrayscale16;
- end;
- {R, G, B followed by alpha}
- COLOR_RGBALPHA:
- case Header.BitDepth of
- 8 : CopyProc := CopyNonInterlacedRGBAlpha8;
- 16 : CopyProc := CopyNonInterlacedRGBAlpha16;
- end;
- {Grayscale followed by alpha}
- COLOR_GRAYSCALEALPHA:
- case Header.BitDepth of
- 8 : CopyProc := CopyNonInterlacedGrayscaleAlpha8;
- 16 : CopyProc := CopyNonInterlacedGrayscaleAlpha16;
- end;
- end;
-
- {Get the image data pointer}
- Longint(Data) := Longint(Header.ImageData) +
- Header.BytesPerRow * (ImageHeight - 1);
- Trans := Header.ImageAlpha;
- {$IFDEF Store16bits}
- Longint(Extra) := Longint(Header.ExtraImageData) +
- Header.BytesPerRow * (ImageHeight - 1);
- {$ENDIF}
- {Reads each line}
- FOR j := 0 to ImageHeight - 1 do
- begin
- {Read this line Row_Buffer[RowUsed][0] if the filter type for this line}
- if IDATZlibRead(ZLIBStream, @Row_Buffer[RowUsed][0], Row_Bytes + 1, EndPos,
- CRCFile) = 0 then break;
-
- {Filter the current row}
- FilterRow;
- {Copies non interlaced row to image}
- CopyProc(@Row_Buffer[RowUsed][1], Data, Trans{$IFDEF Store16bits}, Extra
- {$ENDIF});
-
- {Invert line used}
- RowUsed := not RowUsed;
- dec(Data, Header.BytesPerRow);
- {$IFDEF Store16bits}dec(Extra, Header.BytesPerRow);{$ENDIF}
- inc(Trans, ImageWidth);
- end {for I};
-
-
-end;
-
-{Filter the current line}
-procedure TChunkIDAT.FilterRow;
-var
- pp: Byte;
- vv, left, above, aboveleft: Integer;
- Col: Cardinal;
-begin
- {Test the filter}
- case Row_Buffer[RowUsed]^[0] of
- {No filtering for this line}
- FILTER_NONE: begin end;
- {AND 255 serves only to never let the result be larger than one byte}
- {Sub filter}
- FILTER_SUB:
- FOR Col := Offset + 1 to Row_Bytes DO
- Row_Buffer[RowUsed][Col] := (Row_Buffer[RowUsed][Col] +
- Row_Buffer[RowUsed][Col - Offset]) and 255;
- {Up filter}
- FILTER_UP:
- FOR Col := 1 to Row_Bytes DO
- Row_Buffer[RowUsed][Col] := (Row_Buffer[RowUsed][Col] +
- Row_Buffer[not RowUsed][Col]) and 255;
- {Average filter}
- FILTER_AVERAGE:
- FOR Col := 1 to Row_Bytes DO
- begin
- {Obtains up and left pixels}
- above := Row_Buffer[not RowUsed][Col];
- if col - 1 < Offset then
- left := 0
- else
- Left := Row_Buffer[RowUsed][Col - Offset];
-
- {Calculates}
- Row_Buffer[RowUsed][Col] := (Row_Buffer[RowUsed][Col] +
- (left + above) div 2) and 255;
- end;
- {Paeth filter}
- FILTER_PAETH:
- begin
- {Initialize}
- left := 0;
- aboveleft := 0;
- {Test each byte}
- FOR Col := 1 to Row_Bytes DO
- begin
- {Obtains above pixel}
- above := Row_Buffer[not RowUsed][Col];
- {Obtains left and top-left pixels}
- if (col - 1 >= offset) Then
- begin
- left := row_buffer[RowUsed][col - offset];
- aboveleft := row_buffer[not RowUsed][col - offset];
- end;
-
- {Obtains current pixel and paeth predictor}
- vv := row_buffer[RowUsed][Col];
- pp := PaethPredictor(left, above, aboveleft);
-
- {Calculates}
- Row_Buffer[RowUsed][Col] := (pp + vv) and $FF;
- end {for};
- end;
-
- end {case};
-end;
-
-{Reads the image data from the stream}
-function TChunkIDAT.LoadFromStream(Stream: TStream; const ChunkName: TChunkName;
- Size: Integer): Boolean;
-var
- ZLIBStream: TZStreamRec2;
- CRCCheck,
- CRCFile : Cardinal;
-begin
- {Get pointer to the header chunk}
- Header := Owner.Chunks.Item[0] as TChunkIHDR;
- {Build palette if necessary}
- if Header.HasPalette then PreparePalette();
-
- {Copy image width and height}
- ImageWidth := Header.Width;
- ImageHeight := Header.Height;
-
- {Initialize to calculate CRC}
- {$IFDEF CheckCRC}
- CRCFile := update_crc($ffffffff, @ChunkName[0], 4);
- {$ENDIF}
-
- Owner.GetPixelInfo(Row_Bytes, Offset); {Obtain line information}
- ZLIBStream := ZLIBInitInflate(Stream); {Initializes decompression}
-
- {Calculate ending position for the current IDAT chunk}
- EndPos := Stream.Position + Size;
-
- {Allocate memory}
- GetMem(Row_Buffer[false], Row_Bytes + 1);
- GetMem(Row_Buffer[true], Row_Bytes + 1);
- ZeroMemory(Row_Buffer[false], Row_bytes + 1);
- {Set the variable to alternate the Row_Buffer item to use}
- RowUsed := TRUE;
-
- {Call special methods for the different interlace methods}
- case Owner.InterlaceMethod of
- imNone: DecodeNonInterlaced(stream, ZLIBStream, Size, crcfile);
- imAdam7: DecodeInterlacedAdam7(stream, ZLIBStream, size, crcfile);
- end;
-
- {Free memory}
- ZLIBTerminateInflate(ZLIBStream); {Terminates decompression}
- FreeMem(Row_Buffer[False], Row_Bytes + 1);
- FreeMem(Row_Buffer[True], Row_Bytes + 1);
-
- {Now checks CRC}
- Stream.Read(CRCCheck, 4);
- {$IFDEF CheckCRC}
- CRCFile := CRCFile xor $ffffffff;
- CRCCheck := ByteSwap(CRCCheck);
- Result := CRCCheck = CRCFile;
-
- {Handle CRC error}
- if not Result then
- begin
- {In case it coult not load chunk}
- Owner.RaiseError(EPngInvalidCRC, EPngInvalidCRCText);
- exit;
- end;
- {$ELSE}Result := TRUE; {$ENDIF}
-end;
-
-const
- IDATHeader: Array[0..3] of char = ('I', 'D', 'A', 'T');
- BUFFER = 5;
-
-{Saves the IDAT chunk to a stream}
-function TChunkIDAT.SaveToStream(Stream: TStream): Boolean;
-var
- ZLIBStream : TZStreamRec2;
-begin
- {Get pointer to the header chunk}
- Header := Owner.Chunks.Item[0] as TChunkIHDR;
- {Copy image width and height}
- ImageWidth := Header.Width;
- ImageHeight := Header.Height;
- Owner.GetPixelInfo(Row_Bytes, Offset); {Obtain line information}
-
- {Allocate memory}
- GetMem(Encode_Buffer[BUFFER], Row_Bytes);
- ZeroMemory(Encode_Buffer[BUFFER], Row_Bytes);
- {Allocate buffers for the filters selected}
- {Filter none will always be calculated to the other filters to work}
- GetMem(Encode_Buffer[FILTER_NONE], Row_Bytes);
- ZeroMemory(Encode_Buffer[FILTER_NONE], Row_Bytes);
- if pfSub in Owner.Filters then
- GetMem(Encode_Buffer[FILTER_SUB], Row_Bytes);
- if pfUp in Owner.Filters then
- GetMem(Encode_Buffer[FILTER_UP], Row_Bytes);
- if pfAverage in Owner.Filters then
- GetMem(Encode_Buffer[FILTER_AVERAGE], Row_Bytes);
- if pfPaeth in Owner.Filters then
- GetMem(Encode_Buffer[FILTER_PAETH], Row_Bytes);
-
- {Initialize ZLIB}
- ZLIBStream := ZLIBInitDeflate(Stream, Owner.fCompressionLevel,
- Owner.MaxIdatSize);
- {Write data depending on the interlace method}
- case Owner.InterlaceMethod of
- imNone: EncodeNonInterlaced(stream, ZLIBStream);
- imAdam7: EncodeInterlacedAdam7(stream, ZLIBStream);
- end;
- {Terminates ZLIB}
- ZLIBTerminateDeflate(ZLIBStream);
-
- {Release allocated memory}
- FreeMem(Encode_Buffer[BUFFER], Row_Bytes);
- FreeMem(Encode_Buffer[FILTER_NONE], Row_Bytes);
- if pfSub in Owner.Filters then
- FreeMem(Encode_Buffer[FILTER_SUB], Row_Bytes);
- if pfUp in Owner.Filters then
- FreeMem(Encode_Buffer[FILTER_UP], Row_Bytes);
- if pfAverage in Owner.Filters then
- FreeMem(Encode_Buffer[FILTER_AVERAGE], Row_Bytes);
- if pfPaeth in Owner.Filters then
- FreeMem(Encode_Buffer[FILTER_PAETH], Row_Bytes);
-
- {Everything went ok}
- Result := True;
-end;
-
-{Writes the IDAT using the settings}
-procedure WriteIDAT(Stream: TStream; Data: Pointer; const Length: Cardinal);
-var
- ChunkLen, CRC: Cardinal;
-begin
- {Writes IDAT header}
- ChunkLen := ByteSwap(Length);
- Stream.Write(ChunkLen, 4); {Chunk length}
- Stream.Write(IDATHeader[0], 4); {Idat header}
- CRC := update_crc($ffffffff, @IDATHeader[0], 4); {Crc part for header}
-
- {Writes IDAT data and calculates CRC for data}
- Stream.Write(Data^, Length);
- CRC := Byteswap(update_crc(CRC, Data, Length) xor $ffffffff);
- {Writes final CRC}
- Stream.Write(CRC, 4);
-end;
-
-{Compress and writes IDAT chunk data}
-procedure TChunkIDAT.IDATZlibWrite(var ZLIBStream: TZStreamRec2;
- Buffer: Pointer; const Length: Cardinal);
-begin
- with ZLIBStream, ZLIBStream.ZLIB do
- begin
- {Set data to be compressed}
- next_in := Buffer;
- avail_in := Length;
-
- {Compress all the data avaliable to compress}
- while avail_in > 0 do
- begin
- deflate(ZLIB, Z_NO_FLUSH);
-
- {The whole buffer was used, save data to stream and restore buffer}
- if avail_out = 0 then
- begin
- {Writes this IDAT chunk}
- WriteIDAT(fStream, Data, ZLIBAllocate);
-
- {Restore buffer}
- next_out := Data;
- avail_out := ZLIBAllocate;
- end {if avail_out = 0};
-
- end {while avail_in};
-
- end {with ZLIBStream, ZLIBStream.ZLIB}
-end;
-
-{Finishes compressing data to write IDAT chunk}
-procedure TChunkIDAT.FinishIDATZlib(var ZLIBStream: TZStreamRec2);
-begin
- with ZLIBStream, ZLIBStream.ZLIB do
- begin
- {Set data to be compressed}
- next_in := nil;
- avail_in := 0;
-
- while deflate(ZLIB,Z_FINISH) <> Z_STREAM_END do
- begin
- {Writes this IDAT chunk}
- WriteIDAT(fStream, Data, ZLIBAllocate - avail_out);
- {Re-update buffer}
- next_out := Data;
- avail_out := ZLIBAllocate;
- end;
-
- if avail_out < ZLIBAllocate then
- {Writes final IDAT}
- WriteIDAT(fStream, Data, ZLIBAllocate - avail_out);
-
- end {with ZLIBStream, ZLIBStream.ZLIB};
-end;
-
-{Copy memory to encode RGB image with 1 byte for each color sample}
-procedure TChunkIDAT.EncodeNonInterlacedRGB8(Src, Dest, Trans: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- {Copy pixel values}
- Byte(Dest^) := fOwner.InverseGamma[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.InverseGamma[pByte(Longint(Src) + 1)^]; inc(Dest);
- Byte(Dest^) := fOwner.InverseGamma[pByte(Longint(Src) )^]; inc(Dest);
- {Move to next pixel}
- inc(Src, 3);
- end {for I}
-end;
-
-{Copy memory to encode RGB images with 16 bits for each color sample}
-procedure TChunkIDAT.EncodeNonInterlacedRGB16(Src, Dest, Trans: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- //Now we copy from 1 byte for each sample stored to a 2 bytes (or 1 word)
- //for sample
- {Copy pixel values}
- pWORD(Dest)^ := fOwner.InverseGamma[pByte(Longint(Src) + 2)^]; inc(Dest, 2);
- pWORD(Dest)^ := fOwner.InverseGamma[pByte(Longint(Src) + 1)^]; inc(Dest, 2);
- pWORD(Dest)^ := fOwner.InverseGamma[pByte(Longint(Src) )^]; inc(Dest, 2);
- {Move to next pixel}
- inc(Src, 3);
- end {for I}
-
-end;
-
-{Copy memory to encode types using palettes (1, 4 or 8 bits per pixel)}
-procedure TChunkIDAT.EncodeNonInterlacedPalette148(Src, Dest, Trans: pChar);
-begin
- {It's simple as copying the data}
- CopyMemory(Dest, Src, Row_Bytes);
-end;
-
-{Copy memory to encode grayscale images with 2 bytes for each sample}
-procedure TChunkIDAT.EncodeNonInterlacedGrayscale16(Src, Dest, Trans: pChar);
-var
- I: Integer;
-begin
- FOR I := 1 TO ImageWidth DO
- begin
- //Now we copy from 1 byte for each sample stored to a 2 bytes (or 1 word)
- //for sample
- pWORD(Dest)^ := pByte(Longint(Src))^; inc(Dest, 2);
- {Move to next pixel}
- inc(Src);
- end {for I}
-end;
-
-{Encode images using RGB followed by an alpha value using 1 byte for each}
-procedure TChunkIDAT.EncodeNonInterlacedRGBAlpha8(Src, Dest, Trans: pChar);
-var
- i: Integer;
-begin
- {Copy the data to the destination, including data from Trans pointer}
- FOR i := 1 TO ImageWidth do
- begin
- Byte(Dest^) := Owner.InverseGamma[PByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := Owner.InverseGamma[PByte(Longint(Src) + 1)^]; inc(Dest);
- Byte(Dest^) := Owner.InverseGamma[PByte(Longint(Src) )^]; inc(Dest);
- Dest^ := Trans^; inc(Dest);
- inc(Src, 3); inc(Trans);
- end {for i};
-end;
-
-{Encode images using RGB followed by an alpha value using 2 byte for each}
-procedure TChunkIDAT.EncodeNonInterlacedRGBAlpha16(Src, Dest, Trans: pChar);
-var
- i: Integer;
-begin
- {Copy the data to the destination, including data from Trans pointer}
- FOR i := 1 TO ImageWidth do
- begin
- pWord(Dest)^ := Owner.InverseGamma[PByte(Longint(Src) + 2)^]; inc(Dest, 2);
- pWord(Dest)^ := Owner.InverseGamma[PByte(Longint(Src) + 1)^]; inc(Dest, 2);
- pWord(Dest)^ := Owner.InverseGamma[PByte(Longint(Src) )^]; inc(Dest, 2);
- pWord(Dest)^ := PByte(Longint(Trans) )^; inc(Dest, 2);
- inc(Src, 3); inc(Trans);
- end {for i};
-end;
-
-{Encode grayscale images followed by an alpha value using 1 byte for each}
-procedure TChunkIDAT.EncodeNonInterlacedGrayscaleAlpha8(
- Src, Dest, Trans: pChar);
-var
- i: Integer;
-begin
- {Copy the data to the destination, including data from Trans pointer}
- FOR i := 1 TO ImageWidth do
- begin
- Dest^ := Src^; inc(Dest);
- Dest^ := Trans^; inc(Dest);
- inc(Src); inc(Trans);
- end {for i};
-end;
-
-{Encode grayscale images followed by an alpha value using 2 byte for each}
-procedure TChunkIDAT.EncodeNonInterlacedGrayscaleAlpha16(
- Src, Dest, Trans: pChar);
-var
- i: Integer;
-begin
- {Copy the data to the destination, including data from Trans pointer}
- FOR i := 1 TO ImageWidth do
- begin
- pWord(Dest)^ := pByte(Src)^; inc(Dest, 2);
- pWord(Dest)^ := pByte(Trans)^; inc(Dest, 2);
- inc(Src); inc(Trans);
- end {for i};
-end;
-
-{Encode non interlaced images}
-procedure TChunkIDAT.EncodeNonInterlaced(Stream: TStream;
- var ZLIBStream: TZStreamRec2);
-var
- {Current line}
- j: Cardinal;
- {Pointers to image data}
- Data, Trans: PChar;
- {Filter used for this line}
- Filter: Byte;
- {Method which will copy the data into the buffer}
- CopyProc: procedure(Src, Dest, Trans: pChar) of object;
-begin
- CopyProc := nil; {Initialize to avoid warnings}
- {Defines the method to copy the data to the buffer depending on}
- {the image parameters}
- case Header.ColorType of
- {R, G, B values}
- COLOR_RGB:
- case Header.BitDepth of
- 8: CopyProc := EncodeNonInterlacedRGB8;
- 16: CopyProc := EncodeNonInterlacedRGB16;
- end;
- {Palette and grayscale values}
- COLOR_GRAYSCALE, COLOR_PALETTE:
- case Header.BitDepth of
- 1, 4, 8: CopyProc := EncodeNonInterlacedPalette148;
- 16: CopyProc := EncodeNonInterlacedGrayscale16;
- end;
- {RGB with a following alpha value}
- COLOR_RGBALPHA:
- case Header.BitDepth of
- 8: CopyProc := EncodeNonInterlacedRGBAlpha8;
- 16: CopyProc := EncodeNonInterlacedRGBAlpha16;
- end;
- {Grayscale images followed by an alpha}
- COLOR_GRAYSCALEALPHA:
- case Header.BitDepth of
- 8: CopyProc := EncodeNonInterlacedGrayscaleAlpha8;
- 16: CopyProc := EncodeNonInterlacedGrayscaleAlpha16;
- end;
- end {case Header.ColorType};
-
- {Get the image data pointer}
- Longint(Data) := Longint(Header.ImageData) +
- Header.BytesPerRow * (ImageHeight - 1);
- Trans := Header.ImageAlpha;
-
- {Writes each line}
- FOR j := 0 to ImageHeight - 1 do
- begin
- {Copy data into buffer}
- CopyProc(Data, @Encode_Buffer[BUFFER][0], Trans);
- {Filter data}
- Filter := FilterToEncode;
-
- {Compress data}
- IDATZlibWrite(ZLIBStream, @Filter, 1);
- IDATZlibWrite(ZLIBStream, @Encode_Buffer[Filter][0], Row_Bytes);
-
- {Adjust pointers to the actual image data}
- dec(Data, Header.BytesPerRow);
- inc(Trans, ImageWidth);
- end;
-
- {Compress and finishes copying the remaining data}
- FinishIDATZlib(ZLIBStream);
-end;
-
-{Copy memory to encode interlaced images using RGB value with 1 byte for}
-{each color sample}
-procedure TChunkIDAT.EncodeInterlacedRGB8(const Pass: Byte;
- Src, Dest, Trans: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Src := pChar(Longint(Src) + Col * 3);
- repeat
- {Copy this row}
- Byte(Dest^) := fOwner.InverseGamma[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := fOwner.InverseGamma[pByte(Longint(Src) + 1)^]; inc(Dest);
- Byte(Dest^) := fOwner.InverseGamma[pByte(Longint(Src) )^]; inc(Dest);
-
- {Move to next column}
- inc(Src, ColumnIncrement[Pass] * 3);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Copy memory to encode interlaced RGB images with 2 bytes each color sample}
-procedure TChunkIDAT.EncodeInterlacedRGB16(const Pass: Byte;
- Src, Dest, Trans: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Src := pChar(Longint(Src) + Col * 3);
- repeat
- {Copy this row}
- pWord(Dest)^ := Owner.InverseGamma[pByte(Longint(Src) + 2)^]; inc(Dest, 2);
- pWord(Dest)^ := Owner.InverseGamma[pByte(Longint(Src) + 1)^]; inc(Dest, 2);
- pWord(Dest)^ := Owner.InverseGamma[pByte(Longint(Src) )^]; inc(Dest, 2);
-
- {Move to next column}
- inc(Src, ColumnIncrement[Pass] * 3);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Copy memory to encode interlaced images using palettes using bit depths}
-{1, 4, 8 (each pixel in the image)}
-procedure TChunkIDAT.EncodeInterlacedPalette148(const Pass: Byte;
- Src, Dest, Trans: pChar);
-const
- BitTable: Array[1..8] of Integer = ($1, $3, 0, $F, 0, 0, 0, $FF);
- StartBit: Array[1..8] of Integer = (7 , 0 , 0, 4, 0, 0, 0, 0);
-var
- CurBit, Col: Integer;
- Src2: PChar;
-begin
- {Clean the line}
- fillchar(Dest^, Row_Bytes, #0);
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- with Header.BitmapInfo.bmiHeader do
- repeat
- {Copy data}
- CurBit := StartBit[biBitCount];
- repeat
- {Adjust pointer to pixel byte bounds}
- Src2 := pChar(Longint(Src) + (biBitCount * Col) div 8);
- {Copy data}
- Byte(Dest^) := Byte(Dest^) or
- (((Byte(Src2^) shr (StartBit[Header.BitDepth] - (biBitCount * Col)
- mod 8))) and (BitTable[biBitCount])) shl CurBit;
-
- {Move to next column}
- inc(Col, ColumnIncrement[Pass]);
- {Will read next bits}
- dec(CurBit, biBitCount);
- until CurBit < 0;
-
- {Move to next byte in source}
- inc(Dest);
- until Col >= ImageWidth;
-end;
-
-{Copy to encode interlaced grayscale images using 16 bits for each sample}
-procedure TChunkIDAT.EncodeInterlacedGrayscale16(const Pass: Byte;
- Src, Dest, Trans: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Src := pChar(Longint(Src) + Col);
- repeat
- {Copy this row}
- pWord(Dest)^ := Byte(Src^); inc(Dest, 2);
-
- {Move to next column}
- inc(Src, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Copy to encode interlaced rgb images followed by an alpha value, all using}
-{one byte for each sample}
-procedure TChunkIDAT.EncodeInterlacedRGBAlpha8(const Pass: Byte;
- Src, Dest, Trans: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Src := pChar(Longint(Src) + Col * 3);
- Trans := pChar(Longint(Trans) + Col);
- repeat
- {Copy this row}
- Byte(Dest^) := Owner.InverseGamma[pByte(Longint(Src) + 2)^]; inc(Dest);
- Byte(Dest^) := Owner.InverseGamma[pByte(Longint(Src) + 1)^]; inc(Dest);
- Byte(Dest^) := Owner.InverseGamma[pByte(Longint(Src) )^]; inc(Dest);
- Dest^ := Trans^; inc(Dest);
-
- {Move to next column}
- inc(Src, ColumnIncrement[Pass] * 3);
- inc(Trans, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Copy to encode interlaced rgb images followed by an alpha value, all using}
-{two byte for each sample}
-procedure TChunkIDAT.EncodeInterlacedRGBAlpha16(const Pass: Byte;
- Src, Dest, Trans: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Src := pChar(Longint(Src) + Col * 3);
- Trans := pChar(Longint(Trans) + Col);
- repeat
- {Copy this row}
- pWord(Dest)^ := pByte(Longint(Src) + 2)^; inc(Dest, 2);
- pWord(Dest)^ := pByte(Longint(Src) + 1)^; inc(Dest, 2);
- pWord(Dest)^ := pByte(Longint(Src) )^; inc(Dest, 2);
- pWord(Dest)^ := pByte(Trans)^; inc(Dest, 2);
-
- {Move to next column}
- inc(Src, ColumnIncrement[Pass] * 3);
- inc(Trans, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Copy to encode grayscale interlaced images followed by an alpha value, all}
-{using 1 byte for each sample}
-procedure TChunkIDAT.EncodeInterlacedGrayscaleAlpha8(const Pass: Byte;
- Src, Dest, Trans: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Src := pChar(Longint(Src) + Col);
- Trans := pChar(Longint(Trans) + Col);
- repeat
- {Copy this row}
- Dest^ := Src^; inc(Dest);
- Dest^ := Trans^; inc(Dest);
-
- {Move to next column}
- inc(Src, ColumnIncrement[Pass]);
- inc(Trans, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Copy to encode grayscale interlaced images followed by an alpha value, all}
-{using 2 bytes for each sample}
-procedure TChunkIDAT.EncodeInterlacedGrayscaleAlpha16(const Pass: Byte;
- Src, Dest, Trans: pChar);
-var
- Col: Integer;
-begin
- {Get first column and enter in loop}
- Col := ColumnStart[Pass];
- Src := pChar(Longint(Src) + Col);
- Trans := pChar(Longint(Trans) + Col);
- repeat
- {Copy this row}
- pWord(Dest)^ := pByte(Src)^; inc(Dest, 2);
- pWord(Dest)^ := pByte(Trans)^; inc(Dest, 2);
-
- {Move to next column}
- inc(Src, ColumnIncrement[Pass]);
- inc(Trans, ColumnIncrement[Pass]);
- inc(Col, ColumnIncrement[Pass]);
- until Col >= ImageWidth;
-end;
-
-{Encode interlaced images}
-procedure TChunkIDAT.EncodeInterlacedAdam7(Stream: TStream;
- var ZLIBStream: TZStreamRec2);
-var
- CurrentPass, Filter: Byte;
- PixelsThisRow: Integer;
- CurrentRow : Integer;
- Trans, Data: pChar;
- CopyProc: procedure(const Pass: Byte;
- Src, Dest, Trans: pChar) of object;
-begin
- CopyProc := nil; {Initialize to avoid warnings}
- {Defines the method to copy the data to the buffer depending on}
- {the image parameters}
- case Header.ColorType of
- {R, G, B values}
- COLOR_RGB:
- case Header.BitDepth of
- 8: CopyProc := EncodeInterlacedRGB8;
- 16: CopyProc := EncodeInterlacedRGB16;
- end;
- {Grayscale and palette}
- COLOR_PALETTE, COLOR_GRAYSCALE:
- case Header.BitDepth of
- 1, 4, 8: CopyProc := EncodeInterlacedPalette148;
- 16: CopyProc := EncodeInterlacedGrayscale16;
- end;
- {RGB followed by alpha}
- COLOR_RGBALPHA:
- case Header.BitDepth of
- 8: CopyProc := EncodeInterlacedRGBAlpha8;
- 16: CopyProc := EncodeInterlacedRGBAlpha16;
- end;
- COLOR_GRAYSCALEALPHA:
- {Grayscale followed by alpha}
- case Header.BitDepth of
- 8: CopyProc := EncodeInterlacedGrayscaleAlpha8;
- 16: CopyProc := EncodeInterlacedGrayscaleAlpha16;
- end;
- end {case Header.ColorType};
-
- {Compress the image using the seven passes for ADAM 7}
- FOR CurrentPass := 0 TO 6 DO
- begin
- {Calculates the number of pixels and bytes for this pass row}
- PixelsThisRow := (ImageWidth - ColumnStart[CurrentPass] +
- ColumnIncrement[CurrentPass] - 1) div ColumnIncrement[CurrentPass];
- Row_Bytes := BytesForPixels(PixelsThisRow, Header.ColorType,
- Header.BitDepth);
- ZeroMemory(Encode_Buffer[FILTER_NONE], Row_Bytes);
-
- {Get current row index}
- CurrentRow := RowStart[CurrentPass];
- {Get a pointer to the current row image data}
- Data := Ptr(Longint(Header.ImageData) + Header.BytesPerRow *
- (ImageHeight - 1 - CurrentRow));
- Trans := Ptr(Longint(Header.ImageAlpha) + ImageWidth * CurrentRow);
-
- {Process all the image rows}
- if Row_Bytes > 0 then
- while CurrentRow < ImageHeight do
- begin
- {Copy data into buffer}
- CopyProc(CurrentPass, Data, @Encode_Buffer[BUFFER][0], Trans);
- {Filter data}
- Filter := FilterToEncode;
-
- {Compress data}
- IDATZlibWrite(ZLIBStream, @Filter, 1);
- IDATZlibWrite(ZLIBStream, @Encode_Buffer[Filter][0], Row_Bytes);
-
- {Move to the next row}
- inc(CurrentRow, RowIncrement[CurrentPass]);
- {Move pointer to the next line}
- dec(Data, RowIncrement[CurrentPass] * Header.BytesPerRow);
- inc(Trans, RowIncrement[CurrentPass] * ImageWidth);
- end {while CurrentRow < ImageHeight}
-
- end {CurrentPass};
-
- {Compress and finishes copying the remaining data}
- FinishIDATZlib(ZLIBStream);
-end;
-
-{Filters the row to be encoded and returns the best filter}
-function TChunkIDAT.FilterToEncode: Byte;
-var
- Run, LongestRun, ii, jj: Cardinal;
- Last, Above, LastAbove: Byte;
-begin
- {Selecting more filters using the Filters property from TPngObject}
- {increases the chances to the file be much smaller, but decreases}
- {the performace}
-
- {This method will creates the same line data using the different}
- {filter methods and select the best}
-
- {Sub-filter}
- if pfSub in Owner.Filters then
- for ii := 0 to Row_Bytes - 1 do
- begin
- {There is no previous pixel when it's on the first pixel, so}
- {set last as zero when in the first}
- if (ii >= Offset) then
- last := Encode_Buffer[BUFFER]^[ii - Offset]
- else
- last := 0;
- Encode_Buffer[FILTER_SUB]^[ii] := Encode_Buffer[BUFFER]^[ii] - last;
- end;
-
- {Up filter}
- if pfUp in Owner.Filters then
- for ii := 0 to Row_Bytes - 1 do
- Encode_Buffer[FILTER_UP]^[ii] := Encode_Buffer[BUFFER]^[ii] -
- Encode_Buffer[FILTER_NONE]^[ii];
-
- {Average filter}
- if pfAverage in Owner.Filters then
- for ii := 0 to Row_Bytes - 1 do
- begin
- {Get the previous pixel, if the current pixel is the first, the}
- {previous is considered to be 0}
- if (ii >= Offset) then
- last := Encode_Buffer[BUFFER]^[ii - Offset]
- else
- last := 0;
- {Get the pixel above}
- above := Encode_Buffer[FILTER_NONE]^[ii];
-
- {Calculates formula to the average pixel}
- Encode_Buffer[FILTER_AVERAGE]^[ii] := Encode_Buffer[BUFFER]^[ii] -
- (above + last) div 2 ;
- end;
-
- {Paeth filter (the slower)}
- if pfPaeth in Owner.Filters then
- begin
- {Initialize}
- last := 0;
- lastabove := 0;
- for ii := 0 to Row_Bytes - 1 do
- begin
- {In case this pixel is not the first in the line obtains the}
- {previous one and the one above the previous}
- if (ii >= Offset) then
- begin
- last := Encode_Buffer[BUFFER]^[ii - Offset];
- lastabove := Encode_Buffer[FILTER_NONE]^[ii - Offset];
- end;
- {Obtains the pixel above}
- above := Encode_Buffer[FILTER_NONE]^[ii];
- {Calculate paeth filter for this byte}
- Encode_Buffer[FILTER_PAETH]^[ii] := Encode_Buffer[BUFFER]^[ii] -
- PaethPredictor(last, above, lastabove);
- end;
- end;
-
- {Now calculates the same line using no filter, which is necessary}
- {in order to have data to the filters when the next line comes}
- CopyMemory(@Encode_Buffer[FILTER_NONE]^[0],
- @Encode_Buffer[BUFFER]^[0], Row_Bytes);
-
- {If only filter none is selected in the filter list, we don't need}
- {to proceed and further}
- if (Owner.Filters = [pfNone]) or (Owner.Filters = []) then
- begin
- Result := FILTER_NONE;
- exit;
- end {if (Owner.Filters = [pfNone...};
-
- {Check which filter is the best by checking which has the larger}
- {sequence of the same byte, since they are best compressed}
- LongestRun := 0; Result := FILTER_NONE;
- for ii := FILTER_NONE TO FILTER_PAETH do
- {Check if this filter was selected}
- if TFilter(ii) in Owner.Filters then
- begin
- Run := 0;
- {Check if it's the only filter}
- if Owner.Filters = [TFilter(ii)] then
- begin
- Result := ii;
- exit;
- end;
-
- {Check using a sequence of four bytes}
- for jj := 2 to Row_Bytes - 1 do
- if (Encode_Buffer[ii]^[jj] = Encode_Buffer [ii]^[jj-1]) or
- (Encode_Buffer[ii]^[jj] = Encode_Buffer [ii]^[jj-2]) then
- inc(Run); {Count the number of sequences}
-
- {Check if this one is the best so far}
- if (Run > LongestRun) then
- begin
- Result := ii;
- LongestRun := Run;
- end {if (Run > LongestRun)};
-
- end {if TFilter(ii) in Owner.Filters};
-end;
-
-{TChunkPLTE implementation}
-
-{Returns an item in the palette}
-function TChunkPLTE.GetPaletteItem(Index: Byte): TRGBQuad;
-begin
- {Test if item is valid, if not raise error}
- if Index > Count - 1 then
- Owner.RaiseError(EPNGError, EPNGUnknownPalEntryText)
- else
- {Returns the item}
- Result := Header.BitmapInfo.bmiColors[Index];
-end;
-
-{Loads the palette chunk from a stream}
-function TChunkPLTE.LoadFromStream(Stream: TStream;
- const ChunkName: TChunkName; Size: Integer): Boolean;
-type
- pPalEntry = ^PalEntry;
- PalEntry = record r, g, b: Byte end;
-var
- j : Integer; {For the FOR}
- PalColor : pPalEntry;
-begin
- {Let ancestor load data and check CRC}
- Result := inherited LoadFromStream(Stream, ChunkName, Size);
- if not Result then exit;
-
- {This chunk must be divisible by 3 in order to be valid}
- if (Size mod 3 <> 0) or (Size div 3 > 256) then
- begin
- {Raise error}
- Result := FALSE;
- Owner.RaiseError(EPNGInvalidPalette, EPNGInvalidPaletteText);
- exit;
- end {if Size mod 3 <> 0};
-
- {Fill array with the palette entries}
- fCount := Size div 3;
- PalColor := Data;
- FOR j := 0 TO fCount - 1 DO
- with Header.BitmapInfo.bmiColors[j] do
- begin
- rgbRed := Owner.GammaTable[PalColor.r];
- rgbGreen := Owner.GammaTable[PalColor.g];
- rgbBlue := Owner.GammaTable[PalColor.b];
- rgbReserved := 0;
- inc(PalColor); {Move to next palette entry}
- end;
-end;
-
-{Saves the PLTE chunk to a stream}
-function TChunkPLTE.SaveToStream(Stream: TStream): Boolean;
-var
- J: Integer;
- DataPtr: pByte;
-begin
- {Adjust size to hold all the palette items}
- ResizeData(fCount * 3);
- {Copy pointer to data}
- DataPtr := fData;
-
- {Copy palette items}
- with Header do
- FOR j := 0 TO fCount - 1 DO
- with BitmapInfo.bmiColors[j] do
- begin
- DataPtr^ := Owner.InverseGamma[rgbRed]; inc(DataPtr);
- DataPtr^ := Owner.InverseGamma[rgbGreen]; inc(DataPtr);
- DataPtr^ := Owner.InverseGamma[rgbBlue]; inc(DataPtr);
- end {with BitmapInfo};
-
- {Let ancestor do the rest of the work}
- Result := inherited SaveToStream(Stream);
-end;
-
-{Assigns from another PLTE chunk}
-procedure TChunkPLTE.Assign(Source: TChunk);
-begin
- {Copy the number of palette items}
- if Source is TChunkPLTE then
- fCount := TChunkPLTE(Source).fCount
- else
- Owner.RaiseError(EPNGError, EPNGCannotAssignChunkText);
-end;
-
-{TChunkgAMA implementation}
-
-{Assigns from another chunk}
-procedure TChunkgAMA.Assign(Source: TChunk);
-begin
- {Copy the gamma value}
- if Source is TChunkgAMA then
- Gamma := TChunkgAMA(Source).Gamma
- else
- Owner.RaiseError(EPNGError, EPNGCannotAssignChunkText);
-end;
-
-{Gamma chunk being created}
-constructor TChunkgAMA.Create(Owner: TPngObject);
-begin
- {Call ancestor}
- inherited Create(Owner);
- Gamma := 1; {Initial value}
-end;
-
-{Returns gamma value}
-function TChunkgAMA.GetValue: Cardinal;
-begin
- {Make sure that the size is four bytes}
- if DataSize <> 4 then
- begin
- {Adjust size and returns 1}
- ResizeData(4);
- Result := 1;
- end
- {If it's right, read the value}
- else Result := Cardinal(ByteSwap(pCardinal(Data)^))
-end;
-
-function Power(Base, Exponent: Extended): Extended;
-begin
- if Exponent = 0.0 then
- Result := 1.0 {Math rule}
- else if (Base = 0) or (Exponent = 0) then Result := 0
- else
- Result := Exp(Exponent * Ln(Base));
-end;
-
-
-{Loading the chunk from a stream}
-function TChunkgAMA.LoadFromStream(Stream: TStream;
- const ChunkName: TChunkName; Size: Integer): Boolean;
-var
- i: Integer;
- Value: Cardinal;
-begin
- {Call ancestor and test if it went ok}
- Result := inherited LoadFromStream(Stream, ChunkName, Size);
- if not Result then exit;
- Value := Gamma;
- {Build gamma table and inverse table for saving}
- if Value <> 0 then
- with Owner do
- FOR i := 0 TO 255 DO
- begin
- GammaTable[I] := Round(Power((I / 255), 1 /
- (Value / 100000 * 2.2)) * 255);
- InverseGamma[Round(Power((I / 255), 1 /
- (Value / 100000 * 2.2)) * 255)] := I;
- end
-end;
-
-{Sets the gamma value}
-procedure TChunkgAMA.SetValue(const Value: Cardinal);
-begin
- {Make sure that the size is four bytes}
- if DataSize <> 4 then ResizeData(4);
- {If it's right, set the value}
- pCardinal(Data)^ := ByteSwap(Value);
-end;
-
-{TPngObject implementation}
-
-{Assigns from another object}
-procedure TPngObject.Assign(Source: TPersistent);
-begin
- {Assigns contents from another TPNGObject}
- if Source is TPNGObject then
- AssignPNG(Source as TPNGObject)
- {Copy contents from a TBitmap}
- {$IFDEF UseDelphi}else if Source is TBitmap then
- with Source as TBitmap do
- AssignHandle(Handle, Transparent,
- ColorToRGB(TransparentColor)){$ENDIF}
- {Unknown source, let ancestor deal with it}
- else
- inherited;
-end;
-
-{Clear all the chunks in the list}
-procedure TPngObject.ClearChunks;
-var
- i: Integer;
-begin
- {Initialize gamma}
- InitializeGamma();
- {Free all the objects and memory (0 chunks Bug fixed by Noel Sharpe)}
- for i := 0 TO Integer(Chunks.Count) - 1 do
- TChunk(Chunks.Item[i]).Free;
- Chunks.Count := 0;
-end;
-
-{Portable Network Graphics object being created}
-constructor TPngObject.Create;
-begin
- {Let it be created}
- inherited Create;
-
- {Initial properties}
- TempPalette := 0;
- fFilters := [pfSub];
- fCompressionLevel := 7;
- fInterlaceMethod := imNone;
- fMaxIdatSize := High(Word);
- {Create chunklist object}
- fChunkList := TPngList.Create(Self);
-end;
-
-{Portable Network Graphics object being destroyed}
-destructor TPngObject.Destroy;
-begin
- {Free object list}
- ClearChunks;
- fChunkList.Free;
- {Free the temporary palette}
- if TempPalette <> 0 then DeleteObject(TempPalette);
-
- {Call ancestor destroy}
- inherited Destroy;
-end;
-
-{Returns linesize and byte offset for pixels}
-procedure TPngObject.GetPixelInfo(var LineSize, Offset: Cardinal);
-begin
- {There must be an Header chunk to calculate size}
- if HeaderPresent then
- begin
- {Calculate number of bytes for each line}
- LineSize := BytesForPixels(Header.Width, Header.ColorType, Header.BitDepth);
-
- {Calculates byte offset}
- Case Header.ColorType of
- {Grayscale}
- COLOR_GRAYSCALE:
- If Header.BitDepth = 16 Then
- Offset := 2
- Else
- Offset := 1 ;
- {It always smaller or equal one byte, so it occupes one byte}
- COLOR_PALETTE:
- offset := 1;
- {It might be 3 or 6 bytes}
- COLOR_RGB:
- offset := 3 * Header.BitDepth Div 8;
- {It might be 2 or 4 bytes}
- COLOR_GRAYSCALEALPHA:
- offset := 2 * Header.BitDepth Div 8;
- {4 or 8 bytes}
- COLOR_RGBALPHA:
- offset := 4 * Header.BitDepth Div 8;
- else
- Offset := 0;
- End ;
-
- end
- else
- begin
- {In case if there isn't any Header chunk}
- Offset := 0;
- LineSize := 0;
- end;
-
-end;
-
-{Returns image height}
-function TPngObject.GetHeight: Integer;
-begin
- {There must be a Header chunk to get the size, otherwise returns 0}
- if HeaderPresent then
- Result := TChunkIHDR(Chunks.Item[0]).Height
- else Result := 0;
-end;
-
-{Returns image width}
-function TPngObject.GetWidth: Integer;
-begin
- {There must be a Header chunk to get the size, otherwise returns 0}
- if HeaderPresent then
- Result := Header.Width
- else Result := 0;
-end;
-
-{Returns if the image is empty}
-function TPngObject.GetEmpty: Boolean;
-begin
- Result := (Chunks.Count = 0);
-end;
-
-{Raises an error}
-procedure TPngObject.RaiseError(ExceptionClass: ExceptClass; Text: String);
-begin
- raise ExceptionClass.Create(Text);
-end;
-
-{Set the maximum size for IDAT chunk}
-procedure TPngObject.SetMaxIdatSize(const Value: Cardinal);
-begin
- {Make sure the size is at least 65535}
- if Value < High(Word) then
- fMaxIdatSize := High(Word) else fMaxIdatSize := Value;
-end;
-
-{$IFNDEF UseDelphi}
- {Creates a file stream reading from the filename in the parameter and load}
- procedure TPngObject.LoadFromFile(const Filename: String);
- var
- FileStream: TFileStream;
- begin
- {Test if the file exists}
- if not FileExists(Filename) then
- begin
- {In case it does not exists, raise error}
- RaiseError(EPNGNotExists, EPNGNotExistsText);
- exit;
- end;
-
- {Creates the file stream to read}
- FileStream := TFileStream.Create(Filename, [fsmRead]);
- LoadFromStream(FileStream); {Loads the data}
- FileStream.Free; {Free file stream}
- end;
-
- {Saves the current png image to a file}
- procedure TPngObject.SaveToFile(const Filename: String);
- var
- FileStream: TFileStream;
- begin
- {Creates the file stream to write}
- FileStream := TFileStream.Create(Filename, [fsmWrite]);
- SaveToStream(FileStream); {Saves the data}
- FileStream.Free; {Free file stream}
- end;
-
-{$ENDIF}
-
-{Returns pointer to the chunk TChunkIHDR which should be the first}
-function TPngObject.GetHeader: TChunkIHDR;
-begin
- {If there is a TChunkIHDR returns it, otherwise returns nil}
- if (Chunks.Count <> 0) and (Chunks.Item[0] is TChunkIHDR) then
- Result := Chunks.Item[0] as TChunkIHDR
- else
- begin
- {No header, throw error message}
- RaiseError(EPNGHeaderNotPresent, EPNGHeaderNotPresentText);
- Result := nil
- end
-end;
-
-{Draws using partial transparency}
-procedure TPngObject.DrawPartialTrans(DC: HDC; Rect: TRect);
-type
- {Access to pixels}
- TPixelLine = Array[Word] of TRGBQuad;
- pPixelLine = ^TPixelLine;
-const
- {Structure used to create the bitmap}
- BitmapInfoHeader: TBitmapInfoHeader =
- (biSize: sizeof(TBitmapInfoHeader);
- biWidth: 100;
- biHeight: 100;
- biPlanes: 1;
- biBitCount: 32;
- biCompression: BI_RGB;
- biSizeImage: 0;
- biXPelsPerMeter: 0;
- biYPelsPerMeter: 0;
- biClrUsed: 0;
- biClrImportant: 0);
-var
- {Buffer bitmap creation}
- BitmapInfo : TBitmapInfo;
- BufferDC : HDC;
- BufferBits : Pointer;
- OldBitmap,
- BufferBitmap: HBitmap;
-
- {Transparency/palette chunks}
- TransparencyChunk: TChunktRNS;
- PaletteChunk: TChunkPLTE;
- TransValue, PaletteIndex: Byte;
- CurBit: Integer;
- Data: PByte;
-
- {Buffer bitmap modification}
- BytesPerRowDest,
- BytesPerRowSrc,
- BytesPerRowAlpha: Integer;
- ImageSource,
- AlphaSource : pByteArray;
- ImageData : pPixelLine;
- i, j : Integer;
-begin
- {Prepare to create the bitmap}
- Fillchar(BitmapInfo, sizeof(BitmapInfo), #0);
- BitmapInfoHeader.biWidth := Header.Width;
- BitmapInfoHeader.biHeight := -1 * Header.Height;
- BitmapInfo.bmiHeader := BitmapInfoHeader;
-
- {Create the bitmap which will receive the background, the applied}
- {alpha blending and then will be painted on the background}
- BufferDC := CreateCompatibleDC(0);
- {In case BufferDC could not be created}
- if (BufferDC = 0) then RaiseError(EPNGOutMemory, EPNGOutMemoryText);
- BufferBitmap := CreateDIBSection(BufferDC, BitmapInfo, DIB_RGB_COLORS,
- BufferBits, 0, 0);
- {In case buffer bitmap could not be created}
- if (BufferBitmap = 0) or (BufferBits = Nil) then
- begin
- if BufferBitmap <> 0 then DeleteObject(BufferBitmap);
- DeleteDC(BufferDC);
- RaiseError(EPNGOutMemory, EPNGOutMemoryText);
- end;
-
- {Selects new bitmap and release old bitmap}
- OldBitmap := SelectObject(BufferDC, BufferBitmap);
-
- {Draws the background on the buffer image}
- StretchBlt(BufferDC, 0, 0, Header.Width, Header.height, DC, Rect.Left,
- Rect.Top, Header.Width, Header.Height, SRCCOPY);
-
- {Obtain number of bytes for each row}
- BytesPerRowAlpha := Header.Width;
- BytesPerRowDest := (((BitmapInfo.bmiHeader.biBitCount * Width) + 31)
- and not 31) div 8; {Number of bytes for each image row in destination}
- BytesPerRowSrc := (((Header.BitmapInfo.bmiHeader.biBitCount * Header.Width) +
- 31) and not 31) div 8; {Number of bytes for each image row in source}
-
- {Obtains image pointers}
- ImageData := BufferBits;
- AlphaSource := Header.ImageAlpha;
- Longint(ImageSource) := Longint(Header.ImageData) +
- Header.BytesPerRow * Longint(Header.Height - 1);
-
- case Header.BitmapInfo.bmiHeader.biBitCount of
- {R, G, B images}
- 24:
- FOR j := 1 TO Header.Height DO
- begin
- {Process all the pixels in this line}
- FOR i := 0 TO Header.Width - 1 DO
- with ImageData[i] do
- begin
- rgbRed := (255+ImageSource[2+i*3] * AlphaSource[i] + rgbRed * (255 -
- AlphaSource[i])) shr 8;
- rgbGreen := (255+ImageSource[1+i*3] * AlphaSource[i] + rgbGreen *
- (255 - AlphaSource[i])) shr 8;
- rgbBlue := (255+ImageSource[i*3] * AlphaSource[i] + rgbBlue *
- (255 - AlphaSource[i])) shr 8;
- end;
-
- {Move pointers}
- Longint(ImageData) := Longint(ImageData) + BytesPerRowDest;
- Longint(ImageSource) := Longint(ImageSource) - BytesPerRowSrc;
- Longint(AlphaSource) := Longint(AlphaSource) + BytesPerRowAlpha;
- end;
- {Palette images with 1 byte for each pixel}
- 1,4,8: if Header.ColorType = COLOR_GRAYSCALEALPHA then
- FOR j := 1 TO Header.Height DO
- begin
- {Process all the pixels in this line}
- FOR i := 0 TO Header.Width - 1 DO
- with ImageData[i], Header.BitmapInfo do begin
- rgbRed := (255 + ImageSource[i] * AlphaSource[i] +
- rgbRed * (255 - AlphaSource[i])) shr 8;
- rgbGreen := (255 + ImageSource[i] * AlphaSource[i] +
- rgbGreen * (255 - AlphaSource[i])) shr 8;
- rgbBlue := (255 + ImageSource[i] * AlphaSource[i] +
- rgbBlue * (255 - AlphaSource[i])) shr 8;
- end;
-
- {Move pointers}
- Longint(ImageData) := Longint(ImageData) + BytesPerRowDest;
- Longint(ImageSource) := Longint(ImageSource) - BytesPerRowSrc;
- Longint(AlphaSource) := Longint(AlphaSource) + BytesPerRowAlpha;
- end
- else {Palette images}
- begin
- {Obtain pointer to the transparency chunk}
- TransparencyChunk := TChunktRNS(Chunks.ItemFromClass(TChunktRNS));
- PaletteChunk := TChunkPLTE(Chunks.ItemFromClass(TChunkPLTE));
-
- FOR j := 1 TO Header.Height DO
- begin
- {Process all the pixels in this line}
- i := 0; Data := @ImageSource[0];
- repeat
- CurBit := 0;
-
- repeat
- {Obtains the palette index}
- case Header.BitDepth of
- 1: PaletteIndex := (Data^ shr (7-(I Mod 8))) and 1;
- 2,4: PaletteIndex := (Data^ shr ((1-(I Mod 2))*4)) and $0F;
- else PaletteIndex := Data^;
- end;
-
- {Updates the image with the new pixel}
- with ImageData[i] do
- begin
- TransValue := TransparencyChunk.PaletteValues[PaletteIndex];
- rgbRed := (255 + PaletteChunk.Item[PaletteIndex].rgbRed *
- TransValue + rgbRed * (255 - TransValue)) shr 8;
- rgbGreen := (255 + PaletteChunk.Item[PaletteIndex].rgbGreen *
- TransValue + rgbGreen * (255 - TransValue)) shr 8;
- rgbBlue := (255 + PaletteChunk.Item[PaletteIndex].rgbBlue *
- TransValue + rgbBlue * (255 - TransValue)) shr 8;
- end;
-
- {Move to next data}
- inc(i); inc(CurBit, Header.BitmapInfo.bmiHeader.biBitCount);
- until CurBit >= 8;
- {Move to next source data}
- inc(Data);
- until i >= Integer(Header.Width);
-
- {Move pointers}
- Longint(ImageData) := Longint(ImageData) + BytesPerRowDest;
- Longint(ImageSource) := Longint(ImageSource) - BytesPerRowSrc;
- end
- end {Palette images}
- end {case Header.BitmapInfo.bmiHeader.biBitCount};
-
- {Draws the new bitmap on the foreground}
- StretchBlt(DC, Rect.Left, Rect.Top, Header.Width, Header.Height, BufferDC,
- 0, 0, Header.Width, Header.Height, SRCCOPY);
-
- {Free bitmap}
- SelectObject(BufferDC, OldBitmap);
- DeleteObject(BufferBitmap);
- DeleteDC(BufferDC);
-end;
-
-{Draws the image into a canvas}
-procedure TPngObject.Draw(ACanvas: TCanvas; const Rect: TRect);
-var
- Header: TChunkIHDR;
-begin
- {Quit in case there is no header, otherwise obtain it}
- if (Chunks.Count = 0) or not (Chunks.GetItem(0) is TChunkIHDR) then Exit;
- Header := Chunks.GetItem(0) as TChunkIHDR;
-
- {Copy the data to the canvas}
- case Self.TransparencyMode of
- {$IFDEF PartialTransparentDraw}
- ptmPartial:
- DrawPartialTrans(ACanvas{$IFDEF UseDelphi}.Handle{$ENDIF}, Rect);
- {$ENDIF}
- ptmBit: DrawTransparentBitmap(ACanvas{$IFDEF UseDelphi}.Handle{$ENDIF},
- Header.ImageData, Header.BitmapInfo.bmiHeader,
- pBitmapInfo(@Header.BitmapInfo), Rect,
- {$IFDEF UseDelphi}ColorToRGB({$ENDIF}TransparentColor)
- {$IFDEF UseDelphi}){$ENDIF}
- else
- StretchDiBits(ACanvas{$IFDEF UseDelphi}.Handle{$ENDIF}, Rect.Left,
- Rect.Top, Rect.Right - Rect.Left, Rect.Bottom - Rect.Top, 0, 0,
- Header.Width, Header.Height, Header.ImageData,
- pBitmapInfo(@Header.BitmapInfo)^, DIB_RGB_COLORS, SRCCOPY)
- end {case}
-end;
-
-{Characters for the header}
-const
- PngHeader: Array[0..7] of Char = (#137, #80, #78, #71, #13, #10, #26, #10);
-
-{Loads the image from a stream of data}
-procedure TPngObject.LoadFromStream(Stream: TStream);
-var
- Header : Array[0..7] of Char;
- HasIDAT : Boolean;
-
- {Chunks reading}
- ChunkCount : Cardinal;
- ChunkLength: Cardinal;
- ChunkName : TChunkName;
-begin
- {Initialize before start loading chunks}
- ChunkCount := 0;
- ClearChunks();
- {Reads the header}
- Stream.Read(Header[0], 8);
-
- {Test if the header matches}
- if Header <> PngHeader then
- begin
- RaiseError(EPNGInvalidFileHeader, EPNGInvalidFileHeaderText);
- Exit;
- end;
-
-
- HasIDAT := FALSE;
- Chunks.Count := 10;
-
- {Load chunks}
- repeat
- inc(ChunkCount); {Increment number of chunks}
- if Chunks.Count < ChunkCount then {Resize the chunks list if needed}
- Chunks.Count := Chunks.Count + 10;
-
- {Reads chunk length and invert since it is in network order}
- {also checks the Read method return, if it returns 0, it}
- {means that no bytes was readed, probably because it reached}
- {the end of the file}
- if Stream.Read(ChunkLength, 4) = 0 then
- begin
- {In case it found the end of the file here}
- Chunks.Count := ChunkCount - 1;
- RaiseError(EPNGUnexpectedEnd, EPNGUnexpectedEndText);
- end;
-
- ChunkLength := ByteSwap(ChunkLength);
- {Reads chunk name}
- Stream.Read(Chunkname, 4);
-
- {Here we check if the first chunk is the Header which is necessary}
- {to the file in order to be a valid Portable Network Graphics image}
- if (ChunkCount = 1) and (ChunkName <> 'IHDR') then
- begin
- Chunks.Count := ChunkCount - 1;
- RaiseError(EPNGIHDRNotFirst, EPNGIHDRNotFirstText);
- exit;
- end;
-
- {Has a previous IDAT}
- if (HasIDAT and (ChunkName = 'IDAT')) or (ChunkName = 'cHRM') then
- begin
- dec(ChunkCount);
- Stream.Seek(ChunkLength + 4, soFromCurrent);
- Continue;
- end;
- {Tell it has an IDAT chunk}
- if ChunkName = 'IDAT' then HasIDAT := TRUE;
-
- {Creates object for this chunk}
- Chunks.SetItem(ChunkCount - 1, CreateClassChunk(Self, ChunkName));
-
- {Check if the chunk is critical and unknown}
- {$IFDEF ErrorOnUnknownCritical}
- if (TChunk(Chunks.Item[ChunkCount - 1]).ClassType = TChunk) and
- ((Byte(ChunkName[0]) AND $20) = 0) and (ChunkName <> '') then
- begin
- Chunks.Count := ChunkCount;
- RaiseError(EPNGUnknownCriticalChunk, EPNGUnknownCriticalChunkText);
- end;
- {$ENDIF}
-
- {Loads it}
- try if not TChunk(Chunks.Item[ChunkCount - 1]).LoadFromStream(Stream,
- ChunkName, ChunkLength) then break;
- except
- Chunks.Count := ChunkCount;
- raise;
- end;
-
- {Terminates when it reaches the IEND chunk}
- until (ChunkName = 'IEND');
-
- {Resize the list to the appropriate size}
- Chunks.Count := ChunkCount;
-
- {Check if there is data}
- if not HasIDAT then
- RaiseError(EPNGNoImageData, EPNGNoImageDataText);
-end;
-
-{Changing height is not supported}
-procedure TPngObject.SetHeight(Value: Integer);
-begin
- RaiseError(EPNGError, EPNGCannotChangeSizeText);
-end;
-
-{Changing width is not supported}
-procedure TPngObject.SetWidth(Value: Integer);
-begin
- RaiseError(EPNGError, EPNGCannotChangeSizeText);
-end;
-
-{$IFDEF UseDelphi}
-{Saves to clipboard format (thanks to Antoine Pottern)}
-procedure TPNGObject.SaveToClipboardFormat(var AFormat: Word;
- var AData: THandle; var APalette: HPalette);
-begin
- with TBitmap.Create do
- try
- Width := Self.Width;
- Height := Self.Height;
- Self.Draw(Canvas, Rect(0, 0, Width, Height));
- SaveToClipboardFormat(AFormat, AData, APalette);
- finally
- Free;
- end {try}
-end;
-
-{Loads data from clipboard}
-procedure TPngObject.LoadFromClipboardFormat(AFormat: Word;
- AData: THandle; APalette: HPalette);
-begin
- with TBitmap.Create do
- try
- LoadFromClipboardFormat(AFormat, AData, APalette);
- Self.AssignHandle(Handle, False, 0);
- finally
- Free;
- end {try}
-end;
-
-{Returns if the image is transparent}
-function TPngObject.GetTransparent: Boolean;
-begin
- Result := (TransparencyMode <> ptmNone);
-end;
-
-{$ENDIF}
-
-{Saving the PNG image to a stream of data}
-procedure TPngObject.SaveToStream(Stream: TStream);
-var
- j: Integer;
-begin
- {Reads the header}
- Stream.Write(PNGHeader[0], 8);
- {Write each chunk}
- FOR j := 0 TO Chunks.Count - 1 DO
- Chunks.Item[j].SaveToStream(Stream)
-end;
-
-{Prepares the Header chunk}
-procedure BuildHeader(Header: TChunkIHDR; Handle: HBitmap; Info: pBitmap;
- HasPalette: Boolean);
-var
- DC: HDC;
-begin
- {Set width and height}
- Header.Width := Info.bmWidth;
- Header.Height := abs(Info.bmHeight);
- {Set bit depth}
- if Info.bmBitsPixel >= 16 then
- Header.BitDepth := 8 else Header.BitDepth := Info.bmBitsPixel;
- {Set color type}
- if Info.bmBitsPixel >= 16 then
- Header.ColorType := COLOR_RGB else Header.ColorType := COLOR_PALETTE;
- {Set other info}
- Header.CompressionMethod := 0; {deflate/inflate}
- Header.InterlaceMethod := 0; {no interlace}
-
- {Prepares bitmap headers to hold data}
- Header.PrepareImageData();
- {Copy image data}
- DC := CreateCompatibleDC(0);
- GetDIBits(DC, Handle, 0, Header.Height, Header.ImageData,
- pBitmapInfo(@Header.BitmapInfo)^, DIB_RGB_COLORS);
- DeleteDC(DC);
-end;
-
-{Loads the image from a resource}
-procedure TPngObject.LoadFromResourceName(Instance: HInst;
- const Name: String);
-var
- ResStream: TResourceStream;
-begin
- {Creates an especial stream to load from the resource}
- try ResStream := TResourceStream.Create(Instance, Name, RT_RCDATA);
- except RaiseError(EPNGCouldNotLoadResource, EPNGCouldNotLoadResourceText);
- exit; end;
-
- {Loads the png image from the resource}
- try
- LoadFromStream(ResStream);
- finally
- ResStream.Free;
- end;
-end;
-
-{Loads the png from a resource ID}
-procedure TPngObject.LoadFromResourceID(Instance: HInst; ResID: Integer);
-begin
- LoadFromResourceName(Instance, String(ResID));
-end;
-
-{Assigns this tpngobject to another object}
-procedure TPngObject.AssignTo(Dest: TPersistent);
-{$IFDEF UseDelphi}
-var
- DeskDC: HDC;
- TRNS: TChunkTRNS;
-{$ENDIF}
-begin
- {If the destination is also a TPNGObject make it assign}
- {this one}
- if Dest is TPNGObject then
- TPNGObject(Dest).AssignPNG(Self)
- {$IFDEF UseDelphi}
- {In case the destination is a bitmap}
- else if (Dest is TBitmap) and HeaderPresent then
- begin
- {Device context}
- DeskDC := GetDC(0);
- {Copy the data}
- TBitmap(Dest).Handle := CreateDIBitmap(DeskDC,
- Header.BitmapInfo.bmiHeader, CBM_INIT, Header.ImageData,
- pBitmapInfo(@Header.BitmapInfo)^, DIB_RGB_COLORS);
- ReleaseDC(0, DeskDC);
- {Tests for the best pixelformat}
- case Header.BitmapInfo.bmiHeader.biBitCount of
- 1: TBitmap(Dest).PixelFormat := pf1Bit;
- 4: TBitmap(Dest).PixelFormat := pf4Bit;
- 8: TBitmap(Dest).PixelFormat := pf8Bit;
- 24: TBitmap(Dest).PixelFormat := pf24Bit;
- 32: TBitmap(Dest).PixelFormat := pf32Bit;
- end {case Header.BitmapInfo.bmiHeader.biBitCount};
-
- {Copy transparency mode}
- if (TransparencyMode = ptmBit) then
- begin
- TRNS := Chunks.ItemFromClass(TChunkTRNS) as TChunkTRNS;
- TBitmap(Dest).TransparentColor := TRNS.TransparentColor;
- TBitmap(Dest).Transparent := True
- end {if (TransparencyMode = ptmBit)}
-
- end
- else
- {Unknown destination kind, }
- inherited AssignTo(Dest);
- {$ENDIF}
-end;
-
-{Assigns from a bitmap object}
-procedure TPngObject.AssignHandle(Handle: HBitmap; Transparent: Boolean;
- TransparentColor: ColorRef);
-var
- BitmapInfo: Windows.TBitmap;
- HasPalette: Boolean;
-
- {Chunks}
- Header: TChunkIHDR;
- PLTE: TChunkPLTE;
- IDAT: TChunkIDAT;
- IEND: TChunkIEND;
- TRNS: TChunkTRNS;
-begin
- {Obtain bitmap info}
- GetObject(Handle, SizeOf(BitmapInfo), @BitmapInfo);
-
- {Only bit depths 1, 4 and 8 needs a palette}
- HasPalette := (BitmapInfo.bmBitsPixel < 16);
-
- {Clear old chunks and prepare}
- ClearChunks();
-
- {Create the chunks}
- Header := TChunkIHDR.Create(Self);
- if HasPalette then PLTE := TChunkPLTE.Create(Self) else PLTE := nil;
- if Transparent then TRNS := TChunkTRNS.Create(Self) else TRNS := nil;
- IDAT := TChunkIDAT.Create(Self);
- IEND := TChunkIEND.Create(Self);
-
- {Add chunks}
- TPNGPointerList(Chunks).Add(Header);
- if HasPalette then TPNGPointerList(Chunks).Add(PLTE);
- if Transparent then TPNGPointerList(Chunks).Add(TRNS);
- TPNGPointerList(Chunks).Add(IDAT);
- TPNGPointerList(Chunks).Add(IEND);
-
- {This method will fill the Header chunk with bitmap information}
- {and copy the image data}
- BuildHeader(Header, Handle, @BitmapInfo, HasPalette);
- {In case there is a image data, set the PLTE chunk fCount variable}
- {to the actual number of palette colors which is 2^(Bits for each pixel)}
- if HasPalette then PLTE.fCount := 1 shl BitmapInfo.bmBitsPixel;
-
- {In case it is a transparent bitmap, prepares it}
- if Transparent then TRNS.TransparentColor := TransparentColor;
-
-end;
-
-{Assigns from another PNG}
-procedure TPngObject.AssignPNG(Source: TPNGObject);
-var
- J: Integer;
-begin
- {Copy properties}
- InterlaceMethod := Source.InterlaceMethod;
- MaxIdatSize := Source.MaxIdatSize;
- CompressionLevel := Source.CompressionLevel;
- Filters := Source.Filters;
-
- {Clear old chunks and prepare}
- ClearChunks();
- Chunks.Count := Source.Chunks.Count;
- {Create chunks and makes a copy from the source}
- FOR J := 0 TO Chunks.Count - 1 DO
- with Source.Chunks do
- begin
- Chunks.SetItem(J, TChunkClass(TChunk(Item[J]).ClassType).Create(Self));
- TChunk(Chunks.Item[J]).Assign(TChunk(Item[J]));
- end {with};
-end;
-
-{Returns a alpha data scanline}
-function TPngObject.GetAlphaScanline(const LineIndex: Integer): pByteArray;
-begin
- with Header do
- if (ColorType = COLOR_RGBALPHA) or (ColorType = COLOR_GRAYSCALEALPHA) then
- Longint(Result) := Longint(ImageAlpha) + (LineIndex * Longint(Width))
- else Result := nil; {In case the image does not use alpha information}
-end;
-
-{$IFDEF Store16bits}
-{Returns a png data extra scanline}
-function TPngObject.GetExtraScanline(const LineIndex: Integer): Pointer;
-begin
- with Header do
- Longint(Result) := (Longint(ExtraImageData) + ((Longint(Height) - 1) *
- BytesPerRow)) - (LineIndex * BytesPerRow);
-end;
-{$ENDIF}
-
-{Returns a png data scanline}
-function TPngObject.GetScanline(const LineIndex: Integer): Pointer;
-begin
- with Header do
- Longint(Result) := (Longint(ImageData) + ((Longint(Height) - 1) *
- BytesPerRow)) - (LineIndex * BytesPerRow);
-end;
-
-{Initialize gamma table}
-procedure TPngObject.InitializeGamma;
-var
- i: Integer;
-begin
- {Build gamma table as if there was no gamma}
- FOR i := 0 to 255 do
- begin
- GammaTable[i] := i;
- InverseGamma[i] := i;
- end {for i}
-end;
-
-{Returns the transparency mode used by this png}
-function TPngObject.GetTransparencyMode: TPNGTransparencyMode;
-var
- TRNS: TChunkTRNS;
-begin
- with Header do
- begin
- Result := ptmNone; {Default result}
- {Gets the TRNS chunk pointer}
- TRNS := Chunks.ItemFromClass(TChunkTRNS) as TChunkTRNS;
-
- {Test depending on the color type}
- case ColorType of
- {This modes are always partial}
- COLOR_RGBALPHA, COLOR_GRAYSCALEALPHA: Result := ptmPartial;
- {This modes support bit transparency}
- COLOR_RGB, COLOR_GRAYSCALE: if TRNS <> nil then Result := ptmBit;
- {Supports booth translucid and bit}
- COLOR_PALETTE:
- {A TRNS chunk must be present, otherwise it won't support transparency}
- if TRNS <> nil then
- if TRNS.BitTransparency then
- Result := ptmBit else Result := ptmPartial
- end {case}
-
- end {with Header}
-end;
-
-{Add a text chunk}
-procedure TPngObject.AddtEXt(const Keyword, Text: String);
-var
- TextChunk: TChunkTEXT;
-begin
- TextChunk := Chunks.Add(TChunkText) as TChunkTEXT;
- TextChunk.Keyword := Keyword;
- TextChunk.Text := Text;
-end;
-
-{Add a text chunk}
-procedure TPngObject.AddzTXt(const Keyword, Text: String);
-var
- TextChunk: TChunkzTXt;
-begin
- TextChunk := Chunks.Add(TChunkText) as TChunkzTXt;
- TextChunk.Keyword := Keyword;
- TextChunk.Text := Text;
-end;
-
-{Removes the image transparency}
-procedure TPngObject.RemoveTransparency;
-var
- TRNS: TChunkTRNS;
-begin
- TRNS := Chunks.ItemFromClass(TChunkTRNS) as TChunkTRNS;
- if TRNS <> nil then Chunks.RemoveChunk(TRNS)
-end;
-
-{Generates alpha information}
-procedure TPngObject.CreateAlpha;
-var
- TRNS: TChunkTRNS;
-begin
- {Generates depending on the color type}
- with Header do
- case ColorType of
- {Png allocates different memory space to hold alpha information}
- {for these types}
- COLOR_GRAYSCALE, COLOR_RGB:
- begin
- {Transform into the appropriate color type}
- if ColorType = COLOR_GRAYSCALE then
- ColorType := COLOR_GRAYSCALEALPHA
- else ColorType := COLOR_RGBALPHA;
- {Allocates memory to hold alpha information}
- GetMem(ImageAlpha, Integer(Width) * Integer(Height));
- FillChar(ImageAlpha^, Integer(Width) * Integer(Height), #255);
- end;
- {Palette uses the TChunktRNS to store alpha}
- COLOR_PALETTE:
- begin
- {Gets/creates TRNS chunk}
- if Chunks.ItemFromClass(TChunkTRNS) = nil then
- TRNS := Chunks.Add(TChunkTRNS) as TChunkTRNS
- else
- TRNS := Chunks.ItemFromClass(TChunkTRNS) as TChunkTRNS;
-
- {Prepares the TRNS chunk}
- with TRNS do
- begin
- Fillchar(PaletteValues[0], 256, 255);
- fDataSize := 1 shl Header.BitDepth;
- fBitTransparency := False
- end {with Chunks.Add};
- end;
- end {case Header.ColorType}
-
-end;
-
-{Returns transparent color}
-function TPngObject.GetTransparentColor: TColor;
-var
- TRNS: TChunkTRNS;
-begin
- TRNS := Chunks.ItemFromClass(TChunkTRNS) as TChunkTRNS;
- {Reads the transparency chunk to get this info}
- if Assigned(TRNS) then Result := TRNS.TransparentColor
- else Result := 0
-end;
-
-{$OPTIMIZATION OFF}
-procedure TPngObject.SetTransparentColor(const Value: TColor);
-var
- TRNS: TChunkTRNS;
-begin
- if HeaderPresent then
- {Tests the ColorType}
- case Header.ColorType of
- {Not allowed for this modes}
- COLOR_RGBALPHA, COLOR_GRAYSCALEALPHA: Self.RaiseError(
- EPNGCannotChangeTransparent, EPNGCannotChangeTransparentText);
- {Allowed}
- COLOR_PALETTE, COLOR_RGB, COLOR_GRAYSCALE:
- begin
- TRNS := Chunks.ItemFromClass(TChunkTRNS) as TChunkTRNS;
- if not Assigned(TRNS) then TRNS := Chunks.Add(TChunkTRNS) as TChunkTRNS;
-
- {Sets the transparency value from TRNS chunk}
- TRNS.TransparentColor := {$IFDEF UseDelphi}ColorToRGB({$ENDIF}Value{$IFDEF UseDelphi}){$ENDIF}
- end {COLOR_PALETTE, COLOR_RGB, COLOR_GRAYSCALE)}
- end {case}
-end;
-
-{Returns if header is present}
-function TPngObject.HeaderPresent: Boolean;
-begin
- Result := ((Chunks.Count <> 0) and (Chunks.Item[0] is TChunkIHDR))
-end;
-
-{Returns pixel for png using palette and grayscale}
-function GetByteArrayPixel(const png: TPngObject; const X, Y: Integer): TColor;
-var
- ByteData: Byte;
- DataDepth: Byte;
-begin
- with png, Header do
- begin
- {Make sure the bitdepth is not greater than 8}
- DataDepth := BitDepth;
- if DataDepth > 8 then DataDepth := 8;
- {Obtains the byte containing this pixel}
- ByteData := pByteArray(png.Scanline[Y])^[X div (8 div DataDepth)];
- {Moves the bits we need to the right}
- ByteData := (ByteData shr ((8 - DataDepth) -
- (X mod (8 div DataDepth)) * DataDepth));
- {Discard the unwanted pixels}
- ByteData:= ByteData and ($FF shr (8 - DataDepth));
-
- {For palette mode map the palette entry and for grayscale convert and
- returns the intensity}
- case ColorType of
- COLOR_PALETTE:
- with TChunkPLTE(png.Chunks.ItemFromClass(TChunkPLTE)).Item[ByteData] do
- Result := rgb(GammaTable[rgbRed], GammaTable[rgbGreen],
- GammaTable[rgbBlue]);
- COLOR_GRAYSCALE:
- begin
- ByteData := GammaTable[ByteData * ((1 shl DataDepth) + 1)];
- Result := rgb(ByteData, ByteData, ByteData);
- end;
- else Result := 0;
- end {case};
- end {with}
-end;
-
-{In case vcl units are not being used}
-{$IFNDEF UseDelphi}
-function ColorToRGB(const Color: TColor): COLORREF;
-begin
- Result := Color
-end;
-{$ENDIF}
-
-{Sets a pixel for grayscale and palette pngs}
-procedure SetByteArrayPixel(const png: TPngObject; const X, Y: Integer;
- const Value: TColor);
-const
- ClearFlag: Array[1..8] of Integer = (1, 3, 0, 15, 0, 0, 0, $FF);
-var
- ByteData: pByte;
- DataDepth: Byte;
- ValEntry: Byte;
-begin
- with png.Header do
- begin
- {Map into a palette entry}
- ValEntry := GetNearestPaletteIndex(Png.Palette, ColorToRGB(Value));
-
- {16 bits grayscale extra bits are discarted}
- DataDepth := BitDepth;
- if DataDepth > 8 then DataDepth := 8;
- {Gets a pointer to the byte we intend to change}
- ByteData := @pByteArray(png.Scanline[Y])^[X div (8 div DataDepth)];
- {Clears the old pixel data}
- ByteData^ := ByteData^ and not (ClearFlag[DataDepth] shl ((8 - DataDepth) -
- (X mod (8 div DataDepth)) * DataDepth));
-
- {Setting the new pixel}
- ByteData^ := ByteData^ or (ValEntry shl ((8 - DataDepth) -
- (X mod (8 div DataDepth)) * DataDepth));
- end {with png.Header}
-end;
-
-{Returns pixel when png uses RGB}
-function GetRGBLinePixel(const png: TPngObject;
- const X, Y: Integer): TColor;
-begin
- with pRGBLine(png.Scanline[Y])^[X] do
- Result := RGB(rgbtRed, rgbtGreen, rgbtBlue)
-end;
-
-{Sets pixel when png uses RGB}
-procedure SetRGBLinePixel(const png: TPngObject;
- const X, Y: Integer; Value: TColor);
-begin
- with pRGBLine(png.Scanline[Y])^[X] do
- begin
- rgbtRed := GetRValue(Value);
- rgbtGreen := GetGValue(Value);
- rgbtBlue := GetBValue(Value)
- end
-end;
-
-{Sets a pixel}
-procedure TPngObject.SetPixels(const X, Y: Integer; const Value: TColor);
-begin
- if (X in [0..Width - 1]) and (Y in [0..Height - 1]) then
- with Header do
- begin
- if ColorType in [COLOR_GRAYSCALE, COLOR_PALETTE] then
- SetByteArrayPixel(Self, X, Y, Value)
- else
- SetRGBLinePixel(Self, X, Y, Value)
- end {with}
-end;
-
-{Returns a pixel}
-function TPngObject.GetPixels(const X, Y: Integer): TColor;
-begin
- if (X in [0..Width - 1]) and (Y in [0..Height - 1]) then
- with Header do
- begin
- if ColorType in [COLOR_GRAYSCALE, COLOR_PALETTE] then
- Result := GetByteArrayPixel(Self, X, Y)
- else
- Result := GetRGBLinePixel(Self, X, Y)
- end {with}
- else Result := 0
-end;
-
-{Returns the image palette}
-function TPngObject.GetPalette: HPALETTE;
-var
- LogPalette: TMaxLogPalette;
- i: Integer;
-begin
- {Palette is avaliable for COLOR_PALETTE and COLOR_GRAYSCALE modes}
- if (Header.ColorType in [COLOR_PALETTE, COLOR_GRAYSCALE]) then
- begin
- {In case the pal}
- if TempPalette = 0 then
- with LogPalette do
- begin
- {Prepares the new palette}
- palVersion := $300;
- palNumEntries := 256;
- {Copy entries}
- for i := 0 to LogPalette.palNumEntries - 1 do
- begin
- palPalEntry[i].peRed := Header.BitmapInfo.bmiColors[i].rgbRed;
- palPalEntry[i].peGreen := Header.BitmapInfo.bmiColors[i].rgbGreen;
- palPalEntry[i].peBlue := Header.BitmapInfo.bmiColors[i].rgbBlue;
- palPalEntry[i].peFlags := 0;
- end {for i};
- {Creates the palette}
- TempPalette := CreatePalette(pLogPalette(@LogPalette)^);
- end {with LogPalette, if Temppalette = 0}
- end {if Header.ColorType in ...};
- Result := TempPalette;
-end;
-
-initialization
- {Initialize}
- ChunkClasses := nil;
- {crc table has not being computed yet}
- crc_table_computed := FALSE;
- {Register the necessary chunks for png}
- RegisterCommonChunks;
- {Registers TPNGObject to use with TPicture}
- {$IFDEF UseDelphi}{$IFDEF RegisterGraphic}
- TPicture.RegisterFileFormat('PNG', 'Portable Network Graphics', TPNGObject);
- {$ENDIF}{$ENDIF}
-finalization
- {$IFDEF UseDelphi}{$IFDEF RegisterGraphic}
- TPicture.UnregisterGraphicClass(TPNGObject);
- {$ENDIF}{$ENDIF}
- {Free chunk classes}
- FreeChunkClassList;
-end.
-
-
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