Repo for the search and displace ingest module that takes odf, docx and pdf and transforms it into .md to be used with search and displace operations
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{
Vampyre Imaging Library
by Marek Mauder
http://imaginglib.sourceforge.net
The contents of this file are used with permission, subject to the Mozilla
Public License Version 1.1 (the "License"); you may not use this file except
in compliance with the License. You may obtain a copy of the License at
http://www.mozilla.org/MPL/MPL-1.1.html
Software distributed under the License is distributed on an "AS IS" basis,
WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License for
the specific language governing rights and limitations under the License.
Alternatively, the contents of this file may be used under the terms of the
GNU Lesser General Public License (the "LGPL License"), in which case the
provisions of the LGPL License are applicable instead of those above.
If you wish to allow use of your version of this file only under the terms
of the LGPL License and not to allow others to use your version of this file
under the MPL, indicate your decision by deleting the provisions above and
replace them with the notice and other provisions required by the LGPL
License. If you do not delete the provisions above, a recipient may use
your version of this file under either the MPL or the LGPL License.
For more information about the LGPL: http://www.gnu.org/copyleft/lesser.html
}
{ This unit is heart of Imaging library. It contains basic functions for
manipulating image data as well as various image file format support.}
unit Imaging;
{$I ImagingOptions.inc}
interface
uses
SysUtils, Classes, Types, ImagingTypes;
type
{ Default Imaging excepton class }
EImagingError = class(Exception);
{ Raised when function receives bad image (not passed TestImage).}
EImagingBadImage = class(Exception)
public
constructor Create;
end;
{ Dynamic array of TImageData records }
TDynImageDataArray = array of TImageData;
{ ------------------------------------------------------------------------
Low Level Interface Functions
------------------------------------------------------------------------}
{ General Functions }
{ Initializes image (all is set to zeroes). Call this for each image
before using it (before calling every other function) to be sure there
are no random-filled bytes (which would cause errors later).}
procedure InitImage(var Image: TImageData);
{ Creates empty image of given dimensions and format. Image is filled with
transparent black color (A=0, R=0, G=0, B=0).}
function NewImage(Width, Height: LongInt; Format: TImageFormat;
var Image: TImageData): Boolean;
{ Returns True if given TImageData record is valid.}
function TestImage(const Image: TImageData): Boolean;
{ Frees given image data. Ater this call image is in the same state
as after calling InitImage. If image is not valid (dost not pass TestImage
test) it is only zeroed by calling InitImage.}
procedure FreeImage(var Image: TImageData);
{ Call FreeImage() on all images in given dynamic array and sets its
length to zero.}
procedure FreeImagesInArray(var Images: TDynImageDataArray);
{ Returns True if all TImageData records in given array are valid. Returns False
if at least one is invalid or if array is empty.}
function TestImagesInArray(const Images: TDynImageDataArray): Boolean;
{ Checks given file for every supported image file format and if
the file is in one of them returns its string identifier
(which can be used in LoadFromStream/LoadFromMem type functions).
If file is not in any of the supported formats empty string is returned.}
function DetermineFileFormat(const FileName: string): string;
{ Checks given stream for every supported image file format and if
the stream is in one of them returns its string identifier
(which can be used in LoadFromStream/LoadFromMem type functions).
If stream is not in any of the supported formats empty string is returned.}
function DetermineStreamFormat(Stream: TStream): string;
{ Checks given memory for every supported image file format and if
the memory is in one of them returns its string identifier
(which can be used in LoadFromStream/LoadFromMem type functions).
If memory is not in any of the supported formats empty string is returned.}
function DetermineMemoryFormat(Data: Pointer; Size: LongInt): string;
{ Checks that an apropriate file format is supported purely from inspecting
the given file name's extension (not contents of the file itself).
The file need not exist.}
function IsFileFormatSupported(const FileName: string): Boolean;
{ Enumerates all registered image file formats. Descriptive name,
default extension, masks (like '*.jpg,*.jfif') and some capabilities
of each format are returned. To enumerate all formats start with Index at 0 and
call EnumFileFormats with given Index in loop until it returns False (Index is
automatically increased by 1 in function's body on successful call).}
function EnumFileFormats(var Index: LongInt; var Name, DefaultExt, Masks: string;
var CanSaveImages, IsMultiImageFormat: Boolean): Boolean;
{ Loading Functions }
{ Loads single image from given file.}
function LoadImageFromFile(const FileName: string; var Image: TImageData): Boolean;
{ Loads single image from given stream. If function fails stream position
is not changed.}
function LoadImageFromStream(Stream: TStream; var Image: TImageData): Boolean;
{ Loads single image from given memory location.}
function LoadImageFromMemory(Data: Pointer; Size: LongInt; var Image: TImageData): Boolean;
{ Loads multiple images from given file.}
function LoadMultiImageFromFile(const FileName: string;
var Images: TDynImageDataArray): Boolean;
{ Loads multiple images from given stream. If function fails stream position
is not changed.}
function LoadMultiImageFromStream(Stream: TStream;
var Images: TDynImageDataArray): Boolean;
{ Loads multiple images from given memory location.}
function LoadMultiImageFromMemory(Data: Pointer; Size: LongInt;
var Images: TDynImageDataArray): Boolean;
{ Saving Functions }
{ Saves single image to given file.}
function SaveImageToFile(const FileName: string; const Image: TImageData): Boolean;
{ Saves single image to given stream. If function fails stream position
is not changed. Ext identifies desired image file format (jpg, png, dds, ...).}
function SaveImageToStream(const Ext: string; Stream: TStream;
const Image: TImageData): Boolean;
{ Saves single image to given memory location. Memory must be allocated and its
size is passed in Size parameter in which number of written bytes is returned.
Ext identifies desired image file format (jpg, png, dds, ...).}
function SaveImageToMemory(const Ext: string; Data: Pointer; var Size: LongInt;
const Image: TImageData): Boolean;
{ Saves multiple images to given file. If format supports
only single level images and there are multiple images to be saved,
they are saved as sequence of files img000.jpg, img001.jpg ....).}
function SaveMultiImageToFile(const FileName: string;
const Images: TDynImageDataArray): Boolean;
{ Saves multiple images to given stream. If format supports
only single level images and there are multiple images to be saved,
they are saved one after another to the stream. If function fails stream
position is not changed. Ext identifies desired image file format (jpg, png, dds, ...).}
function SaveMultiImageToStream(const Ext: string; Stream: TStream;
const Images: TDynImageDataArray): Boolean;
{ Saves multiple images to given memory location. If format supports
only single level images and there are multiple images to be saved,
they are saved one after another to the memory. Memory must be allocated and
its size is passed in Size parameter in which number of written bytes is returned.
Ext identifies desired image file format (jpg, png, dds, ...).}
function SaveMultiImageToMemory(const Ext: string; Data: Pointer;
var Size: LongInt; const Images: TDynImageDataArray): Boolean;
{ Manipulation Functions }
{ Creates identical copy of image data. Clone should be initialized
by InitImage or it should be vaild image which will be freed by CloneImage.}
function CloneImage(const Image: TImageData; var Clone: TImageData): Boolean;
{ Converts image to the given format.}
function ConvertImage(var Image: TImageData; DestFormat: TImageFormat): Boolean;
{ Flips given image. Reverses the image along its horizontal axis - the top
becomes the bottom and vice versa.}
function FlipImage(var Image: TImageData): Boolean;
{ Mirrors given image. Reverses the image along its vertical axis — the left
side becomes the right and vice versa.}
function MirrorImage(var Image: TImageData): Boolean;
{ Resizes given image to new dimensions. Nearest, bilinear, or bicubic filtering
can be used. Input Image must already be created - use NewImage to create new images.}
function ResizeImage(var Image: TImageData; NewWidth, NewHeight: LongInt;
Filter: TResizeFilter): Boolean;
{ Swaps SrcChannel and DstChannel color or alpha channels of image.
Use ChannelRed, ChannelBlue, ChannelGreen, ChannelAlpha constants to
identify channels.}
function SwapChannels(var Image: TImageData; SrcChannel, DstChannel: LongInt): Boolean;
{ Reduces the number of colors of the Image. Currently MaxColors must be in
range <2, 4096>. Color reduction works also for alpha channel. Note that for
large images and big number of colors it can be very slow.
Output format of the image is the same as input format.}
function ReduceColors(var Image: TImageData; MaxColors: LongInt): Boolean;
{ Generates mipmaps for image. Levels is the number of desired mipmaps levels
with zero (or some invalid number) meaning all possible levels.}
function GenerateMipMaps(const Image: TImageData; Levels: LongInt;
var MipMaps: TDynImageDataArray): Boolean;
{ Maps image to existing palette producing image in ifIndex8 format.
Pal must be allocated to at least Entries * SizeOf(TColor32Rec) bytes.
As resulting image is in 8bit indexed format Entries must be lower or
equal to 256.}
function MapImageToPalette(var Image: TImageData; Pal: PPalette32;
Entries: LongInt): Boolean;
{ Splits image into XChunks x YChunks subimages. Default size of each chunk is
ChunkWidth x ChunkHeight. If PreserveSize si True chunks at the edges of
the image are also ChunkWidth x ChunkHeight sized and empty space is filled
with optional Fill pixels. After calling this function XChunks contains number of
chunks along x axis and YChunks along y axis. To access chunk [X, Y] use this
index: Chunks[Y * XChunks + X].}
function SplitImage(var Image: TImageData; var Chunks: TDynImageDataArray;
ChunkWidth, ChunkHeight: LongInt; var XChunks, YChunks: LongInt;
PreserveSize: Boolean; Fill: Pointer = nil): Boolean;
{ Creates palette with MaxColors based on the colors of images in Images array.
Use it when you want to convert several images to indexed format using
single palette for all of them. If ConvertImages is True images in array
are converted to indexed format using resulting palette. if it is False
images are left intact and only resulting palatte is returned in Pal.
Pal must be allocated to have at least MaxColors entries.}
function MakePaletteForImages(var Images: TDynImageDataArray; Pal: PPalette32;
MaxColors: LongInt; ConvertImages: Boolean): Boolean;
{ Rotates image by Angle degrees counterclockwise. All angles are allowed.}
procedure RotateImage(var Image: TImageData; Angle: Single);
{ Drawing/Pixel functions }
{ Copies rectangular part of SrcImage to DstImage. No blending is performed -
alpha is simply copied to destination image. Operates also with
negative X and Y coordinates.
Note that copying is fastest for images in the same data format
(and slowest for images in special formats).}
function CopyRect(const SrcImage: TImageData; SrcX, SrcY, Width, Height: LongInt;
var DstImage: TImageData; DstX, DstY: LongInt): Boolean;
{ Fills given rectangle of image with given pixel fill data. Fill should point
to the pixel in the same format as the given image is in.}
function FillRect(var Image: TImageData; X, Y, Width, Height: LongInt; FillColor: Pointer): Boolean;
{ Replaces pixels with OldPixel in the given rectangle by NewPixel.
OldPixel and NewPixel should point to the pixels in the same format
as the given image is in.}
function ReplaceColor(var Image: TImageData; X, Y, Width, Height: LongInt;
OldColor, NewColor: Pointer): Boolean;
{ Stretches the contents of the source rectangle to the destination rectangle
with optional resampling. No blending is performed - alpha is
simply copied/resampled to destination image. Note that stretching is
fastest for images in the same data format (and slowest for
images in special formats).}
function StretchRect(const SrcImage: TImageData; SrcX, SrcY, SrcWidth,
SrcHeight: LongInt; var DstImage: TImageData; DstX, DstY, DstWidth,
DstHeight: LongInt; Filter: TResizeFilter): Boolean;
{ Copies pixel of Image at [X, Y] to memory pointed at by Pixel. Doesn't
work with special formats.}
procedure GetPixelDirect(const Image: TImageData; X, Y: LongInt; Pixel: Pointer);
{ Copies pixel from memory pointed at by Pixel to Image at position [X, Y].
Doesn't work with special formats.}
procedure SetPixelDirect(const Image: TImageData; X, Y: LongInt; Pixel: Pointer);
{ Function for getting pixel colors. Native pixel is read from Image and
then translated to 32 bit ARGB. Works for all image formats (except special)
so it is not very fast.}
function GetPixel32(const Image: TImageData; X, Y: LongInt): TColor32Rec;
{ Procedure for setting pixel colors. Input 32 bit ARGB color is translated to
native format and then written to Image. Works for all image formats (except special)
so it is not very fast.}
procedure SetPixel32(const Image: TImageData; X, Y: LongInt; const Color: TColor32Rec);
{ Function for getting pixel colors. Native pixel is read from Image and
then translated to FP ARGB. Works for all image formats (except special)
so it is not very fast.}
function GetPixelFP(const Image: TImageData; X, Y: LongInt): TColorFPRec;
{ Procedure for setting pixel colors. Input FP ARGB color is translated to
native format and then written to Image. Works for all image formats (except special)
so it is not very fast.}
procedure SetPixelFP(const Image: TImageData; X, Y: LongInt; const Color: TColorFPRec);
{ Palette Functions }
{ Allocates new palette with Entries ARGB color entries.}
procedure NewPalette(Entries: LongInt; var Pal: PPalette32);
{ Frees given palette.}
procedure FreePalette(var Pal: PPalette32);
{ Copies Count palette entries from SrcPal starting at index SrcIdx to
DstPal at index DstPal.}
procedure CopyPalette(SrcPal, DstPal: PPalette32; SrcIdx, DstIdx, Count: LongInt);
{ Returns index of color in palette or index of nearest color if exact match
is not found. Pal must have at least Entries color entries.}
function FindColor(Pal: PPalette32; Entries: LongInt; Color: TColor32): LongInt;
{ Creates grayscale palette where each color channel has the same value.
Pal must have at least Entries color entries.}
procedure FillGrayscalePalette(Pal: PPalette32; Entries: LongInt);
{ Creates palette with given bitcount for each channel.
2^(RBits + GBits + BBits) should be equl to Entries. Examples:
(3, 3, 2) will create palette with all possible colors of R3G3B2 format
and (8, 0, 0) will create palette with 256 shades of red.
Pal must be allocated to at least Entries * SizeOf(TColor32Rec) bytes.}
procedure FillCustomPalette(Pal: PPalette32; Entries: LongInt; RBits, GBits,
BBits: Byte; Alpha: Byte = $FF);
{ Swaps SrcChannel and DstChannel color or alpha channels of palette.
Use ChannelRed, ChannelBlue, ChannelGreen, ChannelAlpha constants to
identify channels. Pal must be allocated to at least
Entries * SizeOf(TColor32Rec) bytes.}
procedure SwapChannelsOfPalette(Pal: PPalette32; Entries, SrcChannel,
DstChannel: LongInt);
{ Options Functions }
{ Sets value of integer option specified by OptionId parameter.
Option Ids are constans starting ImagingXXX.}
function SetOption(OptionId, Value: LongInt): Boolean;
{ Returns value of integer option specified by OptionId parameter. If OptionId is
invalid, InvalidOption is returned. Option Ids are constans
starting ImagingXXX.}
function GetOption(OptionId: LongInt): LongInt;
{ Pushes current values of all options on the stack. Returns True
if successfull (max stack depth is 8 now). }
function PushOptions: Boolean;
{ Pops back values of all options from the top of the stack. Returns True
if successfull (max stack depth is 8 now). }
function PopOptions: Boolean;
{ Image Format Functions }
{ Returns short information about given image format.}
function GetImageFormatInfo(Format: TImageFormat; out Info: TImageFormatInfo): Boolean;
{ Returns size in bytes of Width x Height area of pixels. Works for all formats.}
function GetPixelsSize(Format: TImageFormat; Width, Height: LongInt): LongInt;
{ IO Functions }
{ User can set his own file IO functions used when loading from/saving to
files by this function.}
procedure SetUserFileIO(OpenProc: TOpenProc; CloseProc: TCloseProc; EofProc: TEofProc; SeekProc:
TSeekProc; TellProc: TTellProc; ReadProc: TReadProc; WriteProc: TWriteProc);
{ Sets file IO functions to Imaging default.}
procedure ResetFileIO;
{ Raw Image IO Functions }
procedure ReadRawImageFromFile(const FileName: string; Width, Height: Integer;
Format: TImageFormat; var Image: TImageData; Offset: Integer = 0; RowLength: Integer = 0);
procedure ReadRawImageFromStream(Stream: TStream; Width, Height: Integer;
Format: TImageFormat; var Image: TImageData; Offset: Integer = 0; RowLength: Integer = 0);
procedure ReadRawImageFromMemory(Data: Pointer; DataSize: Integer; Width, Height: Integer;
Format: TImageFormat; var Image: TImageData; Offset: Integer = 0; RowLength: Integer = 0);
procedure ReadRawImageRect(Data: Pointer; Left, Top, Width, Height: Integer;
var Image: TImageData; Offset: Integer = 0; RowLength: Integer = 0);
procedure WriteRawImageToFile(const FileName: string; const Image: TImageData;
Offset: Integer = 0; RowLength: Integer = 0);
procedure WriteRawImageToStream(Stream: TStream; const Image: TImageData;
Offset: Integer = 0; RowLength: Integer = 0);
procedure WriteRawImageToMemory(Data: Pointer; DataSize: Integer; const Image: TImageData;
Offset: Integer = 0; RowLength: Integer = 0);
procedure WriteRawImageRect(Data: Pointer; Left, Top, Width, Height: Integer;
const Image: TImageData; Offset: Integer = 0; RowLength: Integer = 0);
{ Convenience/helper Functions }
procedure ResizeImageToFit(const SrcImage: TImageData; FitWidth, FitHeight: Integer;
Filter: TResizeFilter; var DestImage: TImageData);
{ Color functions }
{ Constructs TColor24Rec color.}
function Color24(R, G, B: Byte): TColor24Rec; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Constructs TColor32Rec color.}
function Color32(A, R, G, B: Byte): TColor32Rec; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Constructs TColor48Rec color.}
function Color48(R, G, B: Word): TColor48Rec; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Constructs TColor64Rec color.}
function Color64(A, R, G, B: Word): TColor64Rec; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Constructs TColorFPRec color.}
function ColorFP(A, R, G, B: Single): TColorFPRec; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Constructs TColorHFRec color.}
function ColorHF(A, R, G, B: THalfFloat): TColorHFRec; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Convenience function for getting alpha component of TColor32.}
function GetAlphaValue(Color32: TColor32): Byte; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Convenience function for getting red component of TColor32.}
function GetRedValue(Color32: TColor32): Byte; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Convenience function for getting green component of TColor32.}
function GetGreenValue(Color32: TColor32): Byte; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ Convenience function for getting blue component of TColor32.}
function GetBlueValue(Color32: TColor32): Byte; {$IFDEF USE_INLINE}inline;{$ENDIF}
{ ------------------------------------------------------------------------
Other Imaging Stuff
------------------------------------------------------------------------}
type
{ Set of TImageFormat enum.}
TImageFormats = set of TImageFormat;
{ Record containg set of IO functions internaly used by image loaders/savers.}
TIOFunctions = record
Open: TOpenProc;
Close: TCloseProc;
Eof: TEofProc;
Seek: TSeekProc;
Tell: TTellProc;
Read: TReadProc;
Write: TWriteProc;
end;
PIOFunctions = ^TIOFunctions;
type
TFileFormatFeature = (
ffLoad,
ffSave,
ffMultiImage,
ffReadOnSave,
ffProgress,
ffReadScanlines);
TFileFormatFeatures = set of TFileFormatFeature;
TMetadata = class;
{ Base class for various image file format loaders/savers which
descend from this class. If you want to add support for new image file
format the best way is probably to look at TImageFileFormat descendants'
implementations that are already part of Imaging.}
{$TYPEINFO ON}
TImageFileFormat = class
private
FExtensions: TStringList;
FMasks: TStringList;
function GetCanLoad: Boolean;
function GetCanSave: Boolean;
function GetIsMultiImageFormat: Boolean;
{ Does various checks and actions before LoadData method is called.}
function PrepareLoad(Handle: TImagingHandle; var Images: TDynImageDataArray;
OnlyFirstFrame: Boolean): Boolean;
{ Processes some actions according to result of LoadData.}
function PostLoadCheck(var Images: TDynImageDataArray; LoadResult: Boolean): Boolean;
{ Helper function to be called in SaveData methods of descendants (ensures proper
index and sets FFirstIdx and FLastIdx for multi-images).}
function PrepareSave(Handle: TImagingHandle; const Images: TDynImageDataArray;
var Index: LongInt): Boolean;
{ Returns file open mode used for saving images. Depends on defined Features.}
function GetSaveOpenMode: TOpenMode;
protected
FName: string;
FFeatures: TFileFormatFeatures;
FSupportedFormats: TImageFormats;
FFirstIdx, FLastIdx: LongInt;
FMetadata: TMetadata;
{ Descendants must override this method and define file format name and
capabilities.}
procedure Define; virtual;
{ Defines filename masks for this image file format. AMasks should be
in format '*.ext1,*.ext2,umajo.*'.}
procedure AddMasks(const AMasks: string);
function GetFormatInfo(Format: TImageFormat): TImageFormatInfo;
{ Returns set of TImageData formats that can be saved in this file format
without need for conversion.}
function GetSupportedFormats: TImageFormats; virtual;
{ Method which must be overrided in descendants if they' are be capable
of loading images. Images are already freed and length is set to zero
whenever this method gets called. Also Handle is assured to be valid
and contains data that passed TestFormat method's check.}
function LoadData(Handle: TImagingHandle; var Images: TDynImageDataArray;
OnlyFirstFrame: Boolean): Boolean; virtual;
{ Method which must be overriden in descendants if they are be capable
of saving images. Images are checked to have length >0 and
that they contain valid images. For single-image file formats
Index contain valid index to Images array (to image which should be saved).
Multi-image formats should use FFirstIdx and FLastIdx fields to
to get all images that are to be saved.}
function SaveData(Handle: TImagingHandle; const Images: TDynImageDataArray;
Index: LongInt): Boolean; virtual;
{ This method is called internaly by MakeCompatible when input image
is in format not supported by this file format. Image is clone of
MakeCompatible's input and Info is its extended format info.}
procedure ConvertToSupported(var Image: TImageData;
const Info: TImageFormatInfo); virtual;
{ Returns True if given image is supported for saving by this file format.
Most file formats don't need to override this method. It checks
(in this base class) if Image's format is in SupportedFromats set.
But you may override it if you want further checks
(proper widht and height for example).}
function IsSupported(const Image: TImageData): Boolean; virtual;
public
constructor Create(AMetadata: TMetadata = nil); virtual;
destructor Destroy; override;
{ Loads images from file source.}
function LoadFromFile(const FileName: string; var Images: TDynImageDataArray;
OnlyFirstLevel: Boolean = False): Boolean;
{ Loads images from stream source.}
function LoadFromStream(Stream: TStream; var Images: TDynImageDataArray;
OnlyFirstLevel: Boolean = False): Boolean;
{ Loads images from memory source.}
function LoadFromMemory(Data: Pointer; Size: LongInt;
var Images: TDynImageDataArray; OnlyFirstLevel: Boolean = False): Boolean;
{ Saves images to file. If format supports only single level images and
there are multiple images to be saved, they are saved as sequence of
independent images (for example SaveToFile saves sequence of
files img000.jpg, img001.jpg ....).}
function SaveToFile(const FileName: string; const Images: TDynImageDataArray;
OnlyFirstLevel: Boolean = False): Boolean;
{ Saves images to stream. If format supports only single level images and
there are multiple images to be saved, they are saved as sequence of
independent images.}
function SaveToStream(Stream: TStream; const Images: TDynImageDataArray;
OnlyFirstLevel: Boolean = False): Boolean;
{ Saves images to memory. If format supports only single level images and
there are multiple images to be saved, they are saved as sequence of
independent images. Data must be already allocated and their size passed
as Size parameter, number of written bytes is then returned in the same
parameter.}
function SaveToMemory(Data: Pointer; var Size: LongInt;
const Images: TDynImageDataArray; OnlyFirstLevel: Boolean = False): Boolean;
{ Makes Image compatible with this file format (that means it is in one
of data formats in Supported formats set). If input is already
in supported format then Compatible just use value from input
(Compatible := Image) so must not free it after you are done with it
(image bits pointer points to input image's bits).
If input is not in supported format then it is cloned to Compatible
and concerted to one of supported formats (which one dependeds on
this file format). If image is cloned MustBeFreed is set to True
to indicated that you must free Compatible after you are done with it.}
function MakeCompatible(const Image: TImageData; var Compatible: TImageData;
out MustBeFreed: Boolean): Boolean;
{ Returns True if data located in source identified by Handle
represent valid image in current format.}
function TestFormat(Handle: TImagingHandle): Boolean; virtual;
{ Resturns True if the given FileName matches filter for this file format.
For most formats it just checks filename extensions.
It uses filename masks in from Masks property so it can recognize
filenames like this 'umajoXXXumajo.j0j' if one of themasks is
'umajo*umajo.j?j'.}
function TestFileName(const FileName: string): Boolean;
{ Descendants use this method to check if their options (registered with
constant Ids for SetOption/GetOption interface or accessible as properties
of descendants) have valid values and make necessary changes.}
procedure CheckOptionsValidity; virtual;
{ Description of this format.}
property Name: string read FName;
{ Indicates whether images in this format can be loaded.}
property CanLoad: Boolean read GetCanLoad;
{ Indicates whether images in this format can be saved.}
property CanSave: Boolean read GetCanSave;
{ Indicates whether images in this format can contain multiple image levels.}
property IsMultiImageFormat: Boolean read GetIsMultiImageFormat;
{ List of filename extensions for this format.}
property Extensions: TStringList read FExtensions;
{ List of filename masks that are used to associate filenames
with TImageFileFormat descendants. Typical mask looks like
'*.bmp' or 'texture.*' (supports file formats which use filename instead
of extension to identify image files).}
property Masks: TStringList read FMasks;
{ Set of TImageFormats supported by saving functions of this format. Images
can be saved only in one those formats.}
property SupportedFormats: TImageFormats read GetSupportedFormats;
end;
{$TYPEINFO OFF}
{ Class reference for TImageFileFormat class}
TImageFileFormatClass = class of TImageFileFormat;
{ Physical resolution unit.}
TResolutionUnit = (
ruSizeInMicroMeters, // value is pixel size in micrometers
ruDpi, // value is pixels/dots per inch
ruDpm, // value is pixels/dots per meter
ruDpcm // value is pixels/dots per centimeter
);
{ Class for storage of single metadata item.}
TMetadataItem = class
public
Id: string;
ImageIndex: Integer;
Value: Variant;
end;
{ Metadata manager class.}
TMetadata = class
private
FLoadMetaItems: TStringList;
FSaveMetaItems: TStringList;
procedure AddMetaToList(List: TStringList; const Id: string; const Value: Variant; ImageIndex: Integer);
procedure ClearMetaList(List: TStringList);
function GetMetaById(const Id: string): Variant;
function GetMetaByIdMulti(const Id: string; ImageIndex: Integer): Variant;
function GetMetaCount: Integer;
function GetMetaByIdx(Index: Integer): TMetadataItem;
function GetSaveMetaById(const Id: string): Variant;
function GetSaveMetaByIdMulti(const Id: string; ImageIndex: Integer): Variant;
procedure TranslateUnits(ResolutionUnit: TResolutionUnit; var XRes, YRes: Single);
public
constructor Create;
destructor Destroy; override;
procedure SetMetaItem(const Id: string; const Value: Variant; ImageIndex: Integer = 0);
procedure SetMetaItemForSaving(const Id: string; const Value: Variant; ImageIndex: Integer = 0);
function HasMetaItem(const Id: string; ImageIndex: Integer = 0): Boolean;
function HasMetaItemForSaving(const Id: string; ImageIndex: Integer = 0): Boolean;
procedure ClearMetaItems;
procedure ClearMetaItemsForSaving;
function GetMetaItemName(const Id: string; ImageIndex: Integer): string;
{ Copies loaded meta items to items-for-save stack. Use this when you want to
save metadata that have been just loaded (e.g. resaving image in
different file format but keeping the metadata).}
procedure CopyLoadedMetaItemsForSaving;
function GetPhysicalPixelSize(ResUnit: TResolutionUnit; var XSize,
YSize: Single; MetaForSave: Boolean = False; ImageIndex: Integer = 0): Boolean;
procedure SetPhysicalPixelSize(ResUnit: TResolutionUnit; XSize, YSize: Single;
MetaForSave: Boolean = False; ImageIndex: Integer = 0);
property MetaItems[const Id: string]: Variant read GetMetaById;
property MetaItemsMulti[const Id: string; ImageIndex: Integer]: Variant read GetMetaByIdMulti;
{ Number of loaded metadata items.}
property MetaItemCount: Integer read GetMetaCount;
property MetaItemsByIdx[Index: Integer]: TMetadataItem read GetMetaByIdx;
property MetaItemsForSaving[const Id: string]: Variant read GetSaveMetaById;
property MetaItemsForSavingMulti[const Id: string; ImageIndex: Integer]: Variant read GetSaveMetaByIdMulti;
end;
const
{ Metadata item id constants }
{ Physical size of one pixel in micrometers. Type of value is Float.}
SMetaPhysicalPixelSizeX = 'PhysicalPixelSizeX';
SMetaPhysicalPixelSizeY = 'PhysicalPixelSizeY';
{ Delay for frame of animation (how long it should stay visible) in milliseconds.
Type of value is Integer.}
SMetaFrameDelay = 'FrameDelay';
{ Number of times animation should be looped (0 = infinite looping). Type is Int. }
SMetaAnimationLoops = 'AnimationLoops';
{ Gamma correction value. Type is Float.}
SMetaGamma = 'Gamma';
{ Exposure value for HDR etc. Type is Float.}
SMetaExposure = 'Exposure';
{ EXIF image metadata raw blob.}
SMetaExifBlob = 'ExifBlob';
{ XMP image metadata raw blob.}
SMetaXmpBlob = 'XmpBlob';
{ IPTC image metadata raw blob.}
SMetaIptcBlob = 'IptcBlob';
var
GlobalMetadata: TMetadata;
{ Returns symbolic name of given format.}
function GetFormatName(Format: TImageFormat): string;
{ Returns string with information about given Image.}
function ImageToStr(const Image: TImageData): string;
{ Returns Imaging version string in format 'Major.Minor'.}
function GetVersionStr: string;
{ If Condition is True then TruePart is retured, otherwise FalsePart is returned.}
function IffFormat(Condition: Boolean; const TruePart, FalsePart: TImageFormat): TImageFormat;
{ Registers new option so it can be used by SetOption and GetOption functions.
Returns True if registration was succesful - that is Id is valid and is
not already taken by another option.}
function RegisterOption(OptionId: LongInt; Variable: PLongInt): Boolean;
{ Registers new image loader/saver so it can be used by LoadFrom/SaveTo
functions.}
procedure RegisterImageFileFormat(AClass: TImageFileFormatClass);
{ Returns image format loader/saver according to given extension
or nil if not found.}
function FindImageFileFormatByExt(const Ext: string): TImageFileFormat;
{ Returns image format loader/saver according to given filename
or nil if not found.}
function FindImageFileFormatByName(const FileName: string): TImageFileFormat;
{ Returns image format loader/saver based on its class
or nil if not found or not registered.}
function FindImageFileFormatByClass(AClass: TImageFileFormatClass): TImageFileFormat;
{ Returns number of registered image file format loaders/saver.}
function GetFileFormatCount: LongInt;
{ Returns image file format loader/saver at given index. Index must be
in range [0..GetFileFormatCount - 1] otherwise nil is returned.}
function GetFileFormatAtIndex(Index: LongInt): TImageFileFormat;
{ Returns filter string for usage with open and save picture dialogs
which contains all registered image file formats.
Set OpenFileFilter to True if you want filter for open dialog
and to False if you want save dialog filter (formats that cannot save to files
are not added then).
For open dialog filter for all known graphic files
(like All(*.jpg;*.png;....) is added too at the first index.}
function GetImageFileFormatsFilter(OpenFileFilter: Boolean): string;
{ Returns file extension (without dot) of image format selected
by given filter index. Used filter string is defined by GetImageFileFormatsFilter
function. This function can be used with save dialogs (with filters created
by GetImageFileFormatsFilter) to get the extension of file format selected
in dialog quickly. Index is in range 1..N (as FilterIndex property
of TOpenDialog/TSaveDialog)}
function GetFilterIndexExtension(Index: LongInt; OpenFileFilter: Boolean): string;
{ Returns filter index of image file format of file specified by FileName. Used filter
string is defined by GetImageFileFormatsFilter function.
Returned index is in range 1..N (as FilterIndex property of TOpenDialog/TSaveDialog)}
function GetFileNameFilterIndex(const FileName: string; OpenFileFilter: Boolean): LongInt;
{ Returns current IO functions.}
function GetIO: TIOFunctions;
{ Raises EImagingError with given message.}
procedure RaiseImaging(const Msg: string; const Args: array of const); overload;
procedure RaiseImaging(const Msg: string); overload; {$IFDEF USE_INLINE}inline;{$ENDIF}
const
SImagingLibTitle = 'Vampyre Imaging Library';
implementation
uses
{$IFNDEF DONT_LINK_FILE_FORMATS}
{$IFNDEF DONT_LINK_BITMAP}
ImagingBitmap,
{$ENDIF}
{$IFNDEF DONT_LINK_JPEG}
ImagingJpeg,
{$ENDIF}
{$IF not Defined(DONT_LINK_PNG) or not Defined(DONT_LINK_MNG) or not Defined(DONT_LINK_JNG)}
ImagingNetworkGraphics,
{$IFEND}
{$IFNDEF DONT_LINK_GIF}
ImagingGif,
{$ENDIF}
{$IFNDEF DONT_LINK_DDS}
ImagingDds,
{$ENDIF}
{$IFNDEF DONT_LINK_TARGA}
ImagingTarga,
{$ENDIF}
{$IFNDEF DONT_LINK_PNM}
ImagingPortableMaps,
{$ENDIF}
{$IFNDEF DONT_LINK_RADHDR}
ImagingRadiance,
{$ENDIF}
{$IFNDEF DONT_LINK_EXTRAS}
ImagingExtras,
{$ENDIF}
{$ENDIF}
//ImagingDebug,
ImagingFormats, ImagingUtility, ImagingIO, Variants;
resourcestring
SExceptMsg = 'Exception Message';
SAllFilter = 'All Images';
SUnknownFormat = 'Unknown and unsupported format';
SErrorFreeImage = 'Error while freeing image. %s';
SErrorCloneImage = 'Error while cloning image. %s';
SErrorFlipImage = 'Error while flipping image. %s';
SErrorMirrorImage = 'Error while mirroring image. %s';
SErrorResizeImage = 'Error while resizing image. %s';
SErrorSwapImage = 'Error while swapping channels of image. %s';
SFileFormatCanNotLoad = 'Image Format "%s" does not support loading images.';
SFileFormatCanNotSave = 'Image Format "%s" does not support saving images.';
SErrorNewImage = 'Error while creating image data with params: Width=%d ' +
'Height=%d Format=%s.';
SErrorConvertImage = 'Error while converting image to format "%s". %s';
SImageInfo = 'Image @%p info: Width = %dpx, Height = %dpx, ' +
'Format = %s, Size = %.0n %s, Bits @%p, Palette @%p.';
SImageInfoInvalid = 'Access violation encountered when getting info on ' +
'image at address %p.';
SFileNotValid = 'File "%s" is not valid image in "%s" format.';
SStreamNotValid = 'Stream %p does not contain valid image in "%s" format.';
SMemoryNotValid = 'Memory %p (%d Bytes) does not contain valid image ' +
'in "%s" format.';
SErrorLoadingFile = 'Error while loading images from file "%s" (file format: %s).';
SErrorLoadingStream = 'Error while loading images from stream %p (file format: %s).';
SErrorLoadingMemory = 'Error while loading images from memory %p (%d Bytes) (file format: %s).';
SErrorSavingFile = 'Error while saving images to file "%s" (file format: %s).';
SErrorSavingStream = 'Error while saving images to stream %p (file format: %s).';
SErrorSavingMemory = 'Error while saving images to memory %p (%d Bytes) (file format: %s).';
SErrorFindColor = 'Error while finding color in palette @%p with %d entries.';
SErrorGrayscalePalette = 'Error while filling grayscale palette @%p with %d entries.';
SErrorCustomPalette = 'Error while filling custom palette @%p with %d entries.';
SErrorSwapPalette = 'Error while swapping channels of palette @%p with %d entries.';
SErrorReduceColors = 'Error while reducing number of colors of image to %d. %s';
SErrorGenerateMipMaps = 'Error while generating %d mipmap levels for image %s';
SImagesNotValid = 'One or more images are not valid.';
SErrorCopyRect = 'Error while copying rect from image %s to image %s.';
SErrorMapImage = 'Error while mapping image %s to palette.';
SErrorFillRect = 'Error while filling rectangle X:%d Y:%d W:%d H:%d in image %s';
SErrorSplitImage = 'Error while splitting image %s to %dx%d sized chunks.';
SErrorMakePaletteForImages = 'Error while making %d color palette for %d images.';
SErrorNewPalette = 'Error while creating new palette with %d entries';
SErrorFreePalette = 'Error while freeing palette @%p';
SErrorCopyPalette = 'Error while copying %d entries from palette @%p to @%p';
SErrorReplaceColor = 'Error while replacing colors in rectangle X:%d Y:%d W:%d H:%d of image %s';
SErrorRotateImage = 'Error while rotating image %s by %.2n degrees';
SErrorStretchRect = 'Error while stretching rect from image %s to image %s.';
SErrorEmptyStream = 'Input stream has no data. Check Position property.';
SErrorInvalidInputImage = 'Invalid input image.';
SErrorBadImage = 'Bad image detected.';
const
// Initial size of array with options information
InitialOptions = 256;
// Max depth of the option stack
OptionStackDepth = 8;
// Do not change the default format now, its too late
DefaultImageFormat: TImageFormat = ifA8R8G8B8;
// Format used to create metadata IDs for frames loaded form multiimages.
SMetaIdForSubImage = '%s/%d';
type
TOptionArray = array of PLongInt;
TOptionValueArray = array of LongInt;
TOptionStack = class(TObject)
private
FStack: array[0..OptionStackDepth - 1] of TOptionValueArray;
FPosition: LongInt;
public
constructor Create;
destructor Destroy; override;
function Push: Boolean;
function Pop: Boolean;
end;
var
// Currently set IO functions
IO: TIOFunctions;
// List with all registered TImageFileFormat classes
ImageFileFormats: TList = nil;
// Aarray with registered options (pointers to their values)
Options: TOptionArray = nil;
// Array containing addional infomation about every image format
ImageFormatInfos: TImageFormatInfoArray;
// Stack used by PushOptions/PopOtions functions
OptionStack: TOptionStack = nil;
var
// Variable for ImagingColorReduction option
ColorReductionMask: LongInt = $FF;
// Variable for ImagingLoadOverrideFormat option
LoadOverrideFormat: TImageFormat = ifUnknown;
// Variable for ImagingSaveOverrideFormat option
SaveOverrideFormat: TImageFormat = ifUnknown;
// Variable for ImagingSaveOverrideFormat option
MipMapFilter: TSamplingFilter = sfLinear;
// Variable for ImagingBinaryTreshold option
BinaryTreshold: Integer = 128;
{ Exceptions }
constructor EImagingBadImage.Create;
begin
inherited Create(SErrorBadImage);
end;
{ Internal unit functions }
{ Modifies option value to be in the allowed range. Works only
for options registered in this unit.}
function CheckOptionValue(OptionId, Value: LongInt): LongInt; forward;
{ Sets IO functions to file IO.}
procedure SetFileIO; forward;
{ Sets IO functions to stream IO.}
procedure SetStreamIO; forward;
{ Sets IO functions to memory IO.}
procedure SetMemoryIO; forward;
{ Inits image format infos array.}
procedure InitImageFormats; forward;
{ Freew image format infos array.}
procedure FreeImageFileFormats; forward;
{ Creates options array and stack.}
procedure InitOptions; forward;
{ Frees options array and stack.}
procedure FreeOptions; forward;
function UpdateExceptMessage(E: Exception; const MsgToPrepend: string; const Args: array of const): Exception;
begin
Result := E;
E.Message := Format(MsgToPrepend, Args) + ' ' + SExceptMsg + ': ' + E.Message
end;
{ ------------------------------------------------------------------------
Low Level Interface Functions
------------------------------------------------------------------------}
{ General Functions }
procedure InitImage(var Image: TImageData);
begin
FillChar(Image, SizeOf(Image), 0);
end;
function NewImage(Width, Height: LongInt; Format: TImageFormat; var Image:
TImageData): Boolean;
var
FInfo: PImageFormatInfo;
begin
Assert((Width > 0) and (Height >0));
Assert(IsImageFormatValid(Format));
Result := False;
FreeImage(Image);
try
Image.Width := Width;
Image.Height := Height;
// Select default data format if selected
if (Format = ifDefault) then
Image.Format := DefaultImageFormat
else
Image.Format := Format;
// Get extended format info
FInfo := ImageFormatInfos[Image.Format];
if FInfo = nil then
begin
InitImage(Image);
Exit;
end;
// Check image dimensions and calculate its size in bytes
FInfo.CheckDimensions(FInfo.Format, Image.Width, Image.Height);
Image.Size := FInfo.GetPixelsSize(FInfo.Format, Image.Width, Image.Height);
if Image.Size = 0 then
begin
InitImage(Image);
Exit;
end;
// Image bits are allocated and set to zeroes
GetMem(Image.Bits, Image.Size);
FillChar(Image.Bits^, Image.Size, 0);
// Palette is allocated and set to zeroes
if FInfo.PaletteEntries > 0 then
begin
GetMem(Image.Palette, FInfo.PaletteEntries * SizeOf(TColor32Rec));
FillChar(Image.Palette^, FInfo.PaletteEntries * SizeOf(TColor32Rec), 0);
end;
Result := TestImage(Image);
except
on E: Exception do
begin
FreeMem(Image.Bits);
FreeMem(Image.Palette);
InitImage(Image);
raise UpdateExceptMessage(E, SErrorNewImage, [Width, Height, GetFormatName(Format)]);
end;
end;
end;
function TestImage(const Image: TImageData): Boolean;
begin
try
Result := (LongInt(Image.Format) >= LongInt(Low(TImageFormat))) and
(LongInt(Image.Format) <= LongInt(High(TImageFormat))) and
(ImageFormatInfos[Image.Format] <> nil) and
(Assigned(ImageFormatInfos[Image.Format].GetPixelsSize) and
(ImageFormatInfos[Image.Format].GetPixelsSize(Image.Format,
Image.Width, Image.Height) = Image.Size));
except
// Possible int overflows or other errors
Result := False;
end;
end;
procedure FreeImage(var Image: TImageData);
begin
try
if TestImage(Image) then
begin
FreeMemNil(Image.Bits);
FreeMemNil(Image.Palette);
end;
InitImage(Image);
except
raise UpdateExceptMessage(GetExceptObject, SErrorFreeImage, [ImageToStr(Image)]);
end;
end;
procedure FreeImagesInArray(var Images: TDynImageDataArray);
var
I: LongInt;
begin
if Length(Images) > 0 then
begin
for I := 0 to Length(Images) - 1 do
FreeImage(Images[I]);
SetLength(Images, 0);
end;
end;
function TestImagesInArray(const Images: TDynImageDataArray): Boolean;
var
I: LongInt;
begin
if Length(Images) > 0 then
begin
Result := True;
for I := 0 to Length(Images) - 1 do
begin
Result := Result and TestImage(Images[I]);
if not Result then
Break;
end;
end
else
Result := False;
end;
function DetermineFileFormat(const FileName: string): string;
var
I: LongInt;
Fmt: TImageFileFormat;
Handle: TImagingHandle;
begin
Assert(FileName <> '');
Result := '';
SetFileIO;
Handle := IO.Open(PChar(FileName), omReadOnly);
try
// First file format according to FileName and test if the data in
// file is really in that format
for I := 0 to ImageFileFormats.Count - 1 do
begin
Fmt := TImageFileFormat(ImageFileFormats[I]);
if Fmt.TestFileName(FileName) and Fmt.TestFormat(Handle) then
begin
Result := Fmt.Extensions[0];
Exit;
end;
end;
// No file format was found with filename search so try data-based search
for I := 0 to ImageFileFormats.Count - 1 do
begin
Fmt := TImageFileFormat(ImageFileFormats[I]);
if Fmt.TestFormat(Handle) then
begin
Result := Fmt.Extensions[0];
Exit;
end;
end;
finally
IO.Close(Handle);
end;
end;
function DetermineStreamFormat(Stream: TStream): string;
var
I: LongInt;
Fmt: TImageFileFormat;
Handle: TImagingHandle;
begin
Assert(Stream <> nil);
Result := '';
SetStreamIO;
Handle := IO.Open(Pointer(Stream), omReadOnly);
try
for I := 0 to ImageFileFormats.Count - 1 do
begin
Fmt := TImageFileFormat(ImageFileFormats[I]);
if Fmt.TestFormat(Handle) then
begin
Result := Fmt.Extensions[0];
Exit;
end;
end;
finally
IO.Close(Handle);
end;
end;
function DetermineMemoryFormat(Data: Pointer; Size: LongInt): string;
var
I: LongInt;
Fmt: TImageFileFormat;
Handle: TImagingHandle;
IORec: TMemoryIORec;
begin
Assert((Data <> nil) and (Size > 0));
Result := '';
SetMemoryIO;
IORec.Data := Data;
IORec.Position := 0;
IORec.Size := Size;
Handle := IO.Open(@IORec, omReadOnly);
try
for I := 0 to ImageFileFormats.Count - 1 do
begin
Fmt := TImageFileFormat(ImageFileFormats[I]);
if Fmt.TestFormat(Handle) then
begin
Result := Fmt.Extensions[0];
Exit;
end;
end;
finally
IO.Close(Handle);
end;
end;
function IsFileFormatSupported(const FileName: string): Boolean;
begin
Result := FindImageFileFormatByName(FileName) <> nil;
end;
function EnumFileFormats(var Index: LongInt; var Name, DefaultExt, Masks: string;
var CanSaveImages, IsMultiImageFormat: Boolean): Boolean;
var
FileFmt: TImageFileFormat;
begin
FileFmt := GetFileFormatAtIndex(Index);
Result := FileFmt <> nil;
if Result then
begin
Name := FileFmt.Name;
DefaultExt := FileFmt.Extensions[0];
Masks := FileFmt.Masks.DelimitedText;
CanSaveImages := FileFmt.CanSave;
IsMultiImageFormat := FileFmt.IsMultiImageFormat;
Inc(Index);
end
else
begin
Name := '';
DefaultExt := '';
Masks := '';
CanSaveImages := False;
IsMultiImageFormat := False;
end;
end;
{ Loading Functions }
function LoadImageFromFile(const FileName: string; var Image: TImageData):
Boolean;
var
Format: TImageFileFormat;
IArray: TDynImageDataArray;
I: LongInt;
begin
Assert(FileName <> '');
Result := False;
Format := FindImageFileFormatByExt(DetermineFileFormat(FileName));
if Format <> nil then
begin
FreeImage(Image);
Result := Format.LoadFromFile(FileName, IArray, True);
if Result and (Length(IArray) > 0) then
begin
Image := IArray[0];
for I := 1 to Length(IArray) - 1 do
FreeImage(IArray[I]);
end
else
Result := False;
end;
end;
function LoadImageFromStream(Stream: TStream; var Image: TImageData): Boolean;
var
Format: TImageFileFormat;
IArray: TDynImageDataArray;
I: LongInt;
begin
Assert(Stream <> nil);
if Stream.Size - Stream.Position = 0 then
RaiseImaging(SErrorEmptyStream, []);
Result := False;
Format := FindImageFileFormatByExt(DetermineStreamFormat(Stream));
if Format <> nil then
begin
FreeImage(Image);
Result := Format.LoadFromStream(Stream, IArray, True);
if Result and (Length(IArray) > 0) then
begin
Image := IArray[0];
for I := 1 to Length(IArray) - 1 do
FreeImage(IArray[I]);
end
else
Result := False;
end;
end;
function LoadImageFromMemory(Data: Pointer; Size: LongInt; var Image: TImageData): Boolean;
var
Format: TImageFileFormat;
IArray: TDynImageDataArray;
I: LongInt;
begin
Assert((Data <> nil) and (Size > 0));
Result := False;
Format := FindImageFileFormatByExt(DetermineMemoryFormat(Data, Size));
if Format <> nil then
begin
FreeImage(Image);
Result := Format.LoadFromMemory(Data, Size, IArray, True);
if Result and (Length(IArray) > 0) then
begin
Image := IArray[0];
for I := 1 to Length(IArray) - 1 do
FreeImage(IArray[I]);
end
else
Result := False;
end;
end;
function LoadMultiImageFromFile(const FileName: string; var Images:
TDynImageDataArray): Boolean;
var
Format: TImageFileFormat;
begin
Assert(FileName <> '');
Result := False;
Format := FindImageFileFormatByExt(DetermineFileFormat(FileName));
if Format <> nil then
begin
FreeImagesInArray(Images);
Result := Format.LoadFromFile(FileName, Images);
end;
end;
function LoadMultiImageFromStream(Stream: TStream; var Images: TDynImageDataArray): Boolean;
var
Format: TImageFileFormat;
begin
Assert(Stream <> nil);
if Stream.Size - Stream.Position = 0 then
RaiseImaging(SErrorEmptyStream, []);
Result := False;
Format := FindImageFileFormatByExt(DetermineStreamFormat(Stream));
if Format <> nil then
begin
FreeImagesInArray(Images);
Result := Format.LoadFromStream(Stream, Images);
end;
end;
function LoadMultiImageFromMemory(Data: Pointer; Size: LongInt;
var Images: TDynImageDataArray): Boolean;
var
Format: TImageFileFormat;
begin
Assert((Data <> nil) and (Size > 0));
Result := False;
Format := FindImageFileFormatByExt(DetermineMemoryFormat(Data, Size));
if Format <> nil then
begin
FreeImagesInArray(Images);
Result := Format.LoadFromMemory(Data, Size, Images);
end;
end;
{ Saving Functions }
function SaveImageToFile(const FileName: string; const Image: TImageData): Boolean;
var
Format: TImageFileFormat;
IArray: TDynImageDataArray;
begin
Assert(FileName <> '');
Result := False;
Format := FindImageFileFormatByName(FileName);
if Format <> nil then
begin
SetLength(IArray, 1);
IArray[0] := Image;
Result := Format.SaveToFile(FileName, IArray, True);
end;
end;
function SaveImageToStream(const Ext: string; Stream: TStream;
const Image: TImageData): Boolean;
var
Format: TImageFileFormat;
IArray: TDynImageDataArray;
begin
Assert((Ext <> '') and (Stream <> nil));
Result := False;
Format := FindImageFileFormatByExt(Ext);
if Format <> nil then
begin
SetLength(IArray, 1);
IArray[0] := Image;
Result := Format.SaveToStream(Stream, IArray, True);
end;
end;
function SaveImageToMemory(const Ext: string; Data: Pointer; var Size: LongInt;
const Image: TImageData): Boolean;
var
Format: TImageFileFormat;
IArray: TDynImageDataArray;
begin
Assert((Ext <> '') and (Data <> nil) and (Size > 0));
Result := False;
Format := FindImageFileFormatByExt(Ext);
if Format <> nil then
begin
SetLength(IArray, 1);
IArray[0] := Image;
Result := Format.SaveToMemory(Data, Size, IArray, True);
end;
end;
function SaveMultiImageToFile(const FileName: string;
const Images: TDynImageDataArray): Boolean;
var
Format: TImageFileFormat;
begin
Assert(FileName <> '');
Result := False;
Format := FindImageFileFormatByName(FileName);
if Format <> nil then
Result := Format.SaveToFile(FileName, Images);
end;
function SaveMultiImageToStream(const Ext: string; Stream: TStream;
const Images: TDynImageDataArray): Boolean;
var
Format: TImageFileFormat;
begin
Assert((Ext <> '') and (Stream <> nil));
Result := False;
Format := FindImageFileFormatByExt(Ext);
if Format <> nil then
Result := Format.SaveToStream(Stream, Images);
end;
function SaveMultiImageToMemory(const Ext: string; Data: Pointer;
var Size: LongInt; const Images: TDynImageDataArray): Boolean;
var
Format: TImageFileFormat;
begin
Assert((Ext <> '') and (Data <> nil) and (Size > 0));
Result := False;
Format := FindImageFileFormatByExt(Ext);
if Format <> nil then
Result := Format.SaveToMemory(Data, Size, Images);
end;
{ Manipulation Functions }
function CloneImage(const Image: TImageData; var Clone: TImageData): Boolean;
var
Info: PImageFormatInfo;
begin
Result := False;
if TestImage(Image) then
try
if TestImage(Clone) and (Image.Bits <> Clone.Bits) then
FreeImage(Clone)
else
InitImage(Clone);
Info := ImageFormatInfos[Image.Format];
Clone.Width := Image.Width;
Clone.Height := Image.Height;
Clone.Format := Image.Format;
Clone.Size := Image.Size;
if Info.PaletteEntries > 0 then
begin
GetMem(Clone.Palette, Info.PaletteEntries * SizeOf(TColor32Rec));
Move(Image.Palette^, Clone.Palette^, Info.PaletteEntries *
SizeOf(TColor32Rec));
end;
GetMem(Clone.Bits, Clone.Size);
Move(Image.Bits^, Clone.Bits^, Clone.Size);
Result := True;
except
raise UpdateExceptMessage(GetExceptObject, SErrorCloneImage, [ImageToStr(Image)]);
end;
end;
function ConvertImage(var Image: TImageData; DestFormat: TImageFormat): Boolean;
var
NewData: Pointer;
NewPal: PPalette32;
NewSize, NumPixels: LongInt;
SrcInfo, DstInfo: PImageFormatInfo;
begin
Assert(IsImageFormatValid(DestFormat));
Result := False;
if TestImage(Image) then
with Image do
try
// If default format is set we use DefaultImageFormat
if DestFormat = ifDefault then
DestFormat := DefaultImageFormat;
SrcInfo := ImageFormatInfos[Format];
DstInfo := ImageFormatInfos[DestFormat];
if SrcInfo = DstInfo then
begin
// There is nothing to convert - src is alredy in dest format
Result := True;
Exit;
end;
// Exit Src or Dest format is invalid
if (SrcInfo = nil) or (DstInfo = nil) then Exit;
// If dest format is just src with swapped channels we call
// SwapChannels instead
if (SrcInfo.RBSwapFormat = DestFormat) and
(DstInfo.RBSwapFormat = SrcInfo.Format) then
begin
Result := SwapChannels(Image, ChannelRed, ChannelBlue);
Image.Format := SrcInfo.RBSwapFormat;
Exit;
end;
if (not SrcInfo.IsSpecial) and (not DstInfo.IsSpecial) then
begin
NumPixels := Width * Height;
NewSize := NumPixels * DstInfo.BytesPerPixel;
GetMem(NewData, NewSize);
FillChar(NewData^, NewSize, 0);
GetMem(NewPal, DstInfo.PaletteEntries * SizeOf(TColor32Rec));
FillChar(NewPal^, DstInfo.PaletteEntries * SizeOf(TColor32Rec), 0);
if SrcInfo.IsIndexed then
begin
// Source: indexed format
if DstInfo.IsIndexed then
IndexToIndex(NumPixels, Bits, NewData, SrcInfo, DstInfo, Palette, NewPal)
else if DstInfo.HasGrayChannel then
IndexToGray(NumPixels, Bits, NewData, SrcInfo, DstInfo, Palette)
else if DstInfo.IsFloatingPoint then
IndexToFloat(NumPixels, Bits, NewData, SrcInfo, DstInfo, Palette)
else
IndexToChannel(NumPixels, Bits, NewData, SrcInfo, DstInfo, Palette);
end
else if SrcInfo.HasGrayChannel then
begin
// Source: grayscale format
if DstInfo.IsIndexed then
GrayToIndex(NumPixels, Bits, NewData, SrcInfo, DstInfo, NewPal)
else if DstInfo.HasGrayChannel then
GrayToGray(NumPixels, Bits, NewData, SrcInfo, DstInfo)
else if DstInfo.IsFloatingPoint then
GrayToFloat(NumPixels, Bits, NewData, SrcInfo, DstInfo)
else
GrayToChannel(NumPixels, Bits, NewData, SrcInfo, DstInfo);
end
else if SrcInfo.IsFloatingPoint then
begin
// Source: floating point format
if DstInfo.IsIndexed then
FloatToIndex(NumPixels, Bits, NewData, SrcInfo, DstInfo, NewPal)
else if DstInfo.HasGrayChannel then
FloatToGray(NumPixels, Bits, NewData, SrcInfo, DstInfo)
else if DstInfo.IsFloatingPoint then
FloatToFloat(NumPixels, Bits, NewData, SrcInfo, DstInfo)
else
FloatToChannel(NumPixels, Bits, NewData, SrcInfo, DstInfo);
end
else
begin
// Source: standard multi channel image
if DstInfo.IsIndexed then
ChannelToIndex(NumPixels, Bits, NewData, SrcInfo, DstInfo, NewPal)
else if DstInfo.HasGrayChannel then
ChannelToGray(NumPixels, Bits, NewData, SrcInfo, DstInfo)
else if DstInfo.IsFloatingPoint then
ChannelToFloat(NumPixels, Bits, NewData, SrcInfo, DstInfo)
else
ChannelToChannel(NumPixels, Bits, NewData, SrcInfo, DstInfo);
end;
FreeMemNil(Bits);
FreeMemNil(Palette);
Format := DestFormat;
Bits := NewData;
Size := NewSize;
Palette := NewPal;
end
else
ConvertSpecial(Image, SrcInfo, DstInfo);
Assert(SrcInfo.Format <> Image.Format);
Result := True;
except
raise UpdateExceptMessage(GetExceptObject, SErrorConvertImage, [GetFormatName(DestFormat), ImageToStr(Image)]);
end;
end;
function FlipImage(var Image: TImageData): Boolean;
var
P1, P2, Buff: Pointer;
WidthBytes, I: LongInt;
OldFmt: TImageFormat;
begin
Result := False;
OldFmt := Image.Format;
if TestImage(Image) then
with Image do
try
if ImageFormatInfos[OldFmt].IsSpecial then
ConvertImage(Image, ifDefault);
WidthBytes := Width * ImageFormatInfos[Format].BytesPerPixel;
GetMem(Buff, WidthBytes);
try
// Swap all scanlines of image
for I := 0 to Height div 2 - 1 do
begin
P1 := @PByteArray(Bits)[I * WidthBytes];
P2 := @PByteArray(Bits)[(Height - I - 1) * WidthBytes];
Move(P1^, Buff^, WidthBytes);
Move(P2^, P1^, WidthBytes);
Move(Buff^, P2^, WidthBytes);
end;
finally
FreeMemNil(Buff);
end;
if OldFmt <> Format then
ConvertImage(Image, OldFmt);
Result := True;
except
RaiseImaging(SErrorFlipImage, [ImageToStr(Image)]);
end;
end;
function MirrorImage(var Image: TImageData): Boolean;
var
Scanline: PByte;
Buff: TColorFPRec;
Bpp, Y, X, WidthDiv2, WidthBytes, XLeft, XRight: LongInt;
OldFmt: TImageFormat;
begin
Result := False;
OldFmt := Image.Format;
if TestImage(Image) then
with Image do
try
if ImageFormatInfos[OldFmt].IsSpecial then
ConvertImage(Image, ifDefault);
Bpp := ImageFormatInfos[Format].BytesPerPixel;
WidthDiv2 := Width div 2;
WidthBytes := Width * Bpp;
// Mirror all pixels on each scanline of image
for Y := 0 to Height - 1 do
begin
Scanline := @PByteArray(Bits)[Y * WidthBytes];
XLeft := 0;
XRight := (Width - 1) * Bpp;
for X := 0 to WidthDiv2 - 1 do
begin
CopyPixel(@PByteArray(Scanline)[XLeft], @Buff, Bpp);
CopyPixel(@PByteArray(Scanline)[XRight],
@PByteArray(Scanline)[XLeft], Bpp);
CopyPixel(@Buff, @PByteArray(Scanline)[XRight], Bpp);
Inc(XLeft, Bpp);
Dec(XRight, Bpp);
end;
end;
if OldFmt <> Format then
ConvertImage(Image, OldFmt);
Result := True;
except
RaiseImaging(SErrorMirrorImage, [ImageToStr(Image)]);
end;
end;
function ResizeImage(var Image: TImageData; NewWidth, NewHeight: LongInt;
Filter: TResizeFilter): Boolean;
var
WorkImage: TImageData;
begin
Assert((NewWidth > 0) and (NewHeight > 0), 'New width or height is zero.');
Result := False;
if TestImage(Image) and ((Image.Width <> NewWidth) or (Image.Height <> NewHeight)) then
try
InitImage(WorkImage);
// Create new image with desired dimensions
NewImage(NewWidth, NewHeight, Image.Format, WorkImage);
// Stretch pixels from old image to new one
StretchRect(Image, 0, 0, Image.Width, Image.Height,
WorkImage, 0, 0, WorkImage.Width, WorkImage.Height, Filter);
// Free old image and assign new image to it
FreeMemNil(Image.Bits);
if Image.Palette <> nil then
begin
FreeMem(WorkImage.Palette);
WorkImage.Palette := Image.Palette;
end;
Image := WorkImage;
Result := True;
except
raise UpdateExceptMessage(GetExceptObject, SErrorResizeImage, [ImageToStr(Image)]);
end;
end;
function SwapChannels(var Image: TImageData; SrcChannel, DstChannel: LongInt): Boolean;
var
I, NumPixels: LongInt;
Info: PImageFormatInfo;
Swap, Alpha: Word;
Data: PByte;
Pix64: TColor64Rec;
PixF: TColorFPRec;
SwapF: Single;
begin
Assert((SrcChannel in [0..3]) and (DstChannel in [0..3]));
Result := False;
if TestImage(Image) and (SrcChannel <> DstChannel) then
with Image do
try
NumPixels := Width * Height;
Info := ImageFormatInfos[Format];
Data := Bits;
if (Info.Format = ifR8G8B8) or ((Info.Format = ifA8R8G8B8) and
(SrcChannel <> ChannelAlpha) and (DstChannel <> ChannelAlpha)) then
begin
// Swap channels of most common formats R8G8B8 and A8R8G8B8 (no alpha)
for I := 0 to NumPixels - 1 do
with PColor24Rec(Data)^ do
begin
Swap := Channels[SrcChannel];
Channels[SrcChannel] := Channels[DstChannel];
Channels[DstChannel] := Swap;
Inc(Data, Info.BytesPerPixel);
end;
end
else if Info.IsIndexed then
begin
// Swap palette channels of indexed images
SwapChannelsOfPalette(Palette, Info.PaletteEntries, SrcChannel, DstChannel)
end
else if Info.IsFloatingPoint then
begin
// Swap channels of floating point images
for I := 0 to NumPixels - 1 do
begin
FloatGetSrcPixel(Data, Info, PixF);
with PixF do
begin
SwapF := Channels[SrcChannel];
Channels[SrcChannel] := Channels[DstChannel];
Channels[DstChannel] := SwapF;
end;
FloatSetDstPixel(Data, Info, PixF);
Inc(Data, Info.BytesPerPixel);
end;
end
else if Info.IsSpecial then
begin
// Swap channels of special format images
ConvertImage(Image, ifDefault);
SwapChannels(Image, SrcChannel, DstChannel);
ConvertImage(Image, Info.Format);
end
else if Info.HasGrayChannel and Info.HasAlphaChannel and
((SrcChannel = ChannelAlpha) or (DstChannel = ChannelAlpha)) then
begin
for I := 0 to NumPixels - 1 do
begin
// If we have grayscale image with alpha and alpha is channel
// to be swapped, we swap it. No other alternative for gray images,
// just alpha and something
GrayGetSrcPixel(Data, Info, Pix64, Alpha);
Swap := Alpha;
Alpha := Pix64.A;
Pix64.A := Swap;
GraySetDstPixel(Data, Info, Pix64, Alpha);
Inc(Data, Info.BytesPerPixel);
end;
end
else
begin
// Then do general swap on other channel image formats
for I := 0 to NumPixels - 1 do
begin
ChannelGetSrcPixel(Data, Info, Pix64);
with Pix64 do
begin
Swap := Channels[SrcChannel];
Channels[SrcChannel] := Channels[DstChannel];
Channels[DstChannel] := Swap;
end;
ChannelSetDstPixel(Data, Info, Pix64);
Inc(Data, Info.BytesPerPixel);
end;
end;
Result := True;
except
RaiseImaging(SErrorSwapImage, [ImageToStr(Image)]);
end;
end;
function ReduceColors(var Image: TImageData; MaxColors: LongInt): Boolean;
var
TmpInfo: TImageFormatInfo;
Data, Index: PWord;
I, NumPixels: LongInt;
Pal: PPalette32;
Col:PColor32Rec;
OldFmt: TImageFormat;
begin
Result := False;
if TestImage(Image) then
with Image do
try
// First create temp image info and allocate output bits and palette
MaxColors := ClampInt(MaxColors, 2, High(Word));
OldFmt := Format;
FillChar(TmpInfo, SizeOf(TmpInfo), 0);
TmpInfo.PaletteEntries := MaxColors;
TmpInfo.BytesPerPixel := 2;
NumPixels := Width * Height;
GetMem(Data, NumPixels * TmpInfo.BytesPerPixel);
GetMem(Pal, MaxColors * SizeOf(TColor32Rec));
ConvertImage(Image, ifA8R8G8B8);
// We use median cut algorithm to create reduced palette and to
// fill Data with indices to this palette
ReduceColorsMedianCut(NumPixels, Bits, PByte(Data),
ImageFormatInfos[Format], @TmpInfo, MaxColors, ColorReductionMask, Pal);
Col := Bits;
Index := Data;
// Then we write reduced colors to the input image
for I := 0 to NumPixels - 1 do
begin
Col.Color := Pal[Index^].Color;
Inc(Col);
Inc(Index);
end;
FreeMemNil(Data);
FreeMemNil(Pal);
// And convert it to its original format
ConvertImage(Image, OldFmt);
Result := True;
except
RaiseImaging(SErrorReduceColors, [MaxColors, ImageToStr(Image)]);
end;
end;
function GenerateMipMaps(const Image: TImageData; Levels: LongInt;
var MipMaps: TDynImageDataArray): Boolean;
var
Width, Height, I, Count: LongInt;
Info: TImageFormatInfo;
CompatibleCopy: TImageData;
begin
Result := False;
if TestImage(Image) then
try
Width := Image.Width;
Height := Image.Height;
// We compute number of possible mipmap levels and if
// the given levels are invalid or zero we use this value
Count := GetNumMipMapLevels(Width, Height);
if (Levels <= 0) or (Levels > Count) then
Levels := Count;
// If we have special format image we create copy to allow pixel access.
// This is also done in FillMipMapLevel which is called for each level
// but then the main big image would be converted to compatible
// for every level.
GetImageFormatInfo(Image.Format, Info);
if Info.IsSpecial then
begin
InitImage(CompatibleCopy);
CloneImage(Image, CompatibleCopy);
ConvertImage(CompatibleCopy, ifDefault);
end
else
CompatibleCopy := Image;
FreeImagesInArray(MipMaps);
SetLength(MipMaps, Levels);
CloneImage(Image, MipMaps[0]);
for I := 1 to Levels - 1 do
begin
Width := Width shr 1;
Height := Height shr 1;
if Width < 1 then Width := 1;
if Height < 1 then Height := 1;
FillMipMapLevel(CompatibleCopy, Width, Height, MipMaps[I]);
end;
if CompatibleCopy.Format <> MipMaps[0].Format then
begin
// Must convert smaller levels to proper format
for I := 1 to High(MipMaps) do
ConvertImage(MipMaps[I], MipMaps[0].Format);
FreeImage(CompatibleCopy);
end;
Result := True;
except
RaiseImaging(SErrorGenerateMipMaps, [Levels, ImageToStr(Image)]);
end;
end;
function MapImageToPalette(var Image: TImageData; Pal: PPalette32;
Entries: LongInt): Boolean;
function FindNearestColor(Pal: PPalette32; Entries: LongInt; Col: TColor32Rec): LongInt;
var
I, MinDif, Dif: LongInt;
begin
Result := 0;
MinDif := 1020;
for I := 0 to Entries - 1 do
with Pal[I] do
begin
Dif := Abs(R - Col.R);
if Dif > MinDif then Continue;
Dif := Dif + Abs(G - Col.G);
if Dif > MinDif then Continue;
Dif := Dif + Abs(B - Col.B);
if Dif > MinDif then Continue;
Dif := Dif + Abs(A - Col.A);
if Dif < MinDif then
begin
MinDif := Dif;
Result := I;
end;
end;
end;
var
I, MaxEntries: LongInt;
PIndex: PByte;
PColor: PColor32Rec;
CloneARGB: TImageData;
Info: PImageFormatInfo;
begin
Assert((Entries >= 2) and (Entries <= 256));
Result := False;
if TestImage(Image) then
try
// We create clone of source image in A8R8G8B8 and
// then recreate source image in ifIndex8 format
// with palette taken from Pal parameter
InitImage(CloneARGB);
CloneImage(Image, CloneARGB);
ConvertImage(CloneARGB, ifA8R8G8B8);
FreeImage(Image);
NewImage(CloneARGB.Width, CloneARGB.Height, ifIndex8, Image);
Info := ImageFormatInfos[Image.Format];
MaxEntries := Min(Info.PaletteEntries, Entries);
Move(Pal^, Image.Palette^, MaxEntries * SizeOf(TColor32Rec));
PIndex := Image.Bits;
PColor := CloneARGB.Bits;
// For every pixel of ARGB clone we find closest color in
// given palette and assign its index to resulting image's pixel
// procedure used here is very slow but simple and memory usage friendly
// (contrary to other methods)
for I := 0 to Image.Width * Image.Height - 1 do
begin
PIndex^ := Byte(FindNearestColor(Image.Palette, MaxEntries, PColor^));
Inc(PIndex);
Inc(PColor);
end;
FreeImage(CloneARGB);
Result := True;
except
raise UpdateExceptMessage(GetExceptObject, SErrorMapImage, [ImageToStr(Image)]);
end;
end;
function SplitImage(var Image: TImageData; var Chunks: TDynImageDataArray;
ChunkWidth, ChunkHeight: LongInt; var XChunks, YChunks: LongInt;
PreserveSize: Boolean; Fill: Pointer): Boolean;
var
X, Y, XTrunc, YTrunc: LongInt;
NotOnEdge: Boolean;
Info: PImageFormatInfo;
OldFmt: TImageFormat;
begin
Assert((ChunkWidth > 0) and (ChunkHeight > 0));
Result := False;
OldFmt := Image.Format;
FreeImagesInArray(Chunks);
if TestImage(Image) then
try
Info := ImageFormatInfos[Image.Format];
if Info.IsSpecial then
ConvertImage(Image, ifDefault);
// We compute make sure that chunks are not larger than source image or negative
ChunkWidth := ClampInt(ChunkWidth, 0, Image.Width);
ChunkHeight := ClampInt(ChunkHeight, 0, Image.Height);
// Number of chunks along X and Y axes is computed
XChunks := Trunc(Ceil(Image.Width / ChunkWidth));
YChunks := Trunc(Ceil(Image.Height / ChunkHeight));
SetLength(Chunks, XChunks * YChunks);
// For every chunk we create new image and copy a portion of
// the source image to it. If chunk is on the edge of the source image
// we fill enpty space with Fill pixel data if PreserveSize is set or
// make the chunk smaller if it is not set
for Y := 0 to YChunks - 1 do
for X := 0 to XChunks - 1 do
begin
// Determine if current chunk is on the edge of original image
NotOnEdge := ((X < XChunks - 1) and (Y < YChunks - 1)) or
((Image.Width mod ChunkWidth = 0) and (Image.Height mod ChunkHeight = 0));
if PreserveSize or NotOnEdge then
begin
// We should preserve chunk sizes or we are somewhere inside original image
NewImage(ChunkWidth, ChunkHeight, Image.Format, Chunks[Y * XChunks + X]);
if (not NotOnEdge) and (Fill <> nil) then
FillRect(Chunks[Y * XChunks + X], 0, 0, ChunkWidth, ChunkHeight, Fill);
CopyRect(Image, X * ChunkWidth, Y * ChunkHeight, ChunkWidth, ChunkHeight,
Chunks[Y * XChunks + X], 0, 0);
end
else
begin
// Create smaller edge chunk
XTrunc := Image.Width - X * ChunkWidth;
YTrunc := Image.Height - Y * ChunkHeight;
NewImage(XTrunc, YTrunc, Image.Format, Chunks[Y * XChunks + X]);
CopyRect(Image, X * ChunkWidth, Y * ChunkHeight, XTrunc, YTrunc,
Chunks[Y * XChunks + X], 0, 0);
end;
// If source image is in indexed format we copy its palette to chunk
if Info.IsIndexed then
begin
Move(Image.Palette^, Chunks[Y * XChunks + X].Palette^,
Info.PaletteEntries * SizeOf(TColor32Rec));
end;
end;
if OldFmt <> Image.Format then
begin
ConvertImage(Image, OldFmt);
for X := 0 to Length(Chunks) - 1 do
ConvertImage(Chunks[X], OldFmt);
end;
Result := True;
except
raise UpdateExceptMessage(GetExceptObject, SErrorSplitImage,
[ImageToStr(Image), ChunkWidth, ChunkHeight]);
end;
end;
function MakePaletteForImages(var Images: TDynImageDataArray; Pal: PPalette32;
MaxColors: LongInt; ConvertImages: Boolean): Boolean;
var
I: Integer;
SrcInfo, DstInfo: PImageFormatInfo;
Target, TempImage: TImageData;
DstFormat: TImageFormat;
begin
Assert((Pal <> nil) and (MaxColors > 0));
Result := False;
InitImage(TempImage);
if TestImagesInArray(Images) then
try
// Null the color histogram
ReduceColorsMedianCut(0, nil, nil, nil, nil, 0, 0, nil, [raCreateHistogram]);
for I := 0 to Length(Images) - 1 do
begin
SrcInfo := ImageFormatInfos[Images[I].Format];
if SrcInfo.IsIndexed or SrcInfo.IsSpecial then
begin
// create temp image in supported format for updating histogram
CloneImage(Images[I], TempImage);
ConvertImage(TempImage, ifA8R8G8B8);
SrcInfo := ImageFormatInfos[TempImage.Format];
end
else
TempImage := Images[I];
// Update histogram with colors of each input image
ReduceColorsMedianCut(TempImage.Width * TempImage.Height, TempImage.Bits,
nil, SrcInfo, nil, MaxColors, ColorReductionMask, nil, [raUpdateHistogram]);
if Images[I].Bits <> TempImage.Bits then
FreeImage(TempImage);
end;
// Construct reduced color map from the histogram
ReduceColorsMedianCut(0, nil, nil, nil, nil, MaxColors, ColorReductionMask,
Pal, [raMakeColorMap]);
if ConvertImages then
begin
DstFormat := ifIndex8;
DstInfo := ImageFormatInfos[DstFormat];
MaxColors := Min(DstInfo.PaletteEntries, MaxColors);
for I := 0 to Length(Images) - 1 do
begin
SrcInfo := ImageFormatInfos[Images[I].Format];
if SrcInfo.IsIndexed or SrcInfo.IsSpecial then
begin
// If source image is in format not supported by ReduceColorsMedianCut
// we convert it
ConvertImage(Images[I], ifA8R8G8B8);
SrcInfo := ImageFormatInfos[Images[I].Format];
end;
InitImage(Target);
NewImage(Images[I].Width, Images[I].Height, DstFormat, Target);
// We map each input image to reduced palette and replace
// image in array with mapped image
ReduceColorsMedianCut(Images[I].Width * Images[I].Height, Images[I].Bits,
Target.Bits, SrcInfo, DstInfo, MaxColors, 0, nil, [raMapImage]);
Move(Pal^, Target.Palette^, MaxColors * SizeOf(TColor32Rec));
FreeImage(Images[I]);
Images[I] := Target;
end;
end;
Result := True;
except
RaiseImaging(SErrorMakePaletteForImages, [MaxColors, Length(Images)]);
end;
end;
procedure RotateImage(var Image: TImageData; Angle: Single);
var
OldFmt: TImageFormat;
procedure XShear(var Src, Dst: TImageData; Row, Offset, Weight, Bpp: Integer);
var
I, J, XPos: Integer;
PixSrc, PixLeft, PixOldLeft: TColor32Rec;
LineDst: PByteArray;
SrcPtr: PColor32;
begin
SrcPtr := @PByteArray(Src.Bits)[Row * Src.Width * Bpp];
LineDst := @PByteArray(Dst.Bits)[Row * Dst.Width * Bpp];
PixOldLeft.Color := 0;
for I := 0 to Src.Width - 1 do
begin
CopyPixel(SrcPtr, @PixSrc, Bpp);
for J := 0 to Bpp - 1 do
PixLeft.Channels[J] := MulDiv(PixSrc.Channels[J], Weight, 256);
XPos := I + Offset;
if (XPos >= 0) and (XPos < Dst.Width) then
begin
for J := 0 to Bpp - 1 do
PixSrc.Channels[J] := ClampToByte(PixSrc.Channels[J] - (PixLeft.Channels[J] - PixOldLeft.Channels[J]));
CopyPixel(@PixSrc, @LineDst[XPos * Bpp], Bpp);
end;
PixOldLeft := PixLeft;
Inc(PByte(SrcPtr), Bpp);
end;
XPos := Src.Width + Offset;
if XPos < Dst.Width then
CopyPixel(@PixOldLeft, @LineDst[XPos * Bpp], Bpp);
end;
procedure YShear(var Src, Dst: TImageData; Col, Offset, Weight, Bpp: Integer);
var
I, J, YPos: Integer;
PixSrc, PixLeft, PixOldLeft: TColor32Rec;
SrcPtr: PByte;
begin
SrcPtr := @PByteArray(Src.Bits)[Col * Bpp];
PixOldLeft.Color := 0;
for I := 0 to Src.Height - 1 do
begin
CopyPixel(SrcPtr, @PixSrc, Bpp);
for J := 0 to Bpp - 1 do
PixLeft.Channels[J] := MulDiv(PixSrc.Channels[J], Weight, 256);
YPos := I + Offset;
if (YPos >= 0) and (YPos < Dst.Height) then
begin
for J := 0 to Bpp - 1 do
PixSrc.Channels[J] := ClampToByte(PixSrc.Channels[J] - (PixLeft.Channels[J] - PixOldLeft.Channels[J]));
CopyPixel(@PixSrc, @PByteArray(Dst.Bits)[(YPos * Dst.Width + Col) * Bpp], Bpp);
end;
PixOldLeft := PixLeft;
Inc(SrcPtr, Src.Width * Bpp);
end;
YPos := Src.Height + Offset;
if YPos < Dst.Height then
CopyPixel(@PixOldLeft, @PByteArray(Dst.Bits)[(YPos * Dst.Width + Col) * Bpp], Bpp);
end;
procedure Rotate45(var Image: TImageData; Angle: Single);
var
TempImage1, TempImage2: TImageData;
AngleRad, AngleTan, AngleSin, AngleCos, Shear: Single;
I, DstWidth, DstHeight, SrcWidth, SrcHeight, Bpp: Integer;
SrcFmt, TempFormat: TImageFormat;
Info: TImageFormatInfo;
begin
AngleRad := Angle * Pi / 180;
AngleSin := Sin(AngleRad);
AngleCos := Cos(AngleRad);
AngleTan := Sin(AngleRad / 2) / Cos(AngleRad / 2);
SrcWidth := Image.Width;
SrcHeight := Image.Height;
SrcFmt := Image.Format;
if not (SrcFmt in [ifR8G8B8..ifX8R8G8B8, ifGray8..ifGray32, ifA16Gray16]) then
ConvertImage(Image, ifA8R8G8B8);
TempFormat := Image.Format;
GetImageFormatInfo(TempFormat, Info);
Bpp := Info.BytesPerPixel;
// 1st shear (horizontal)
DstWidth := Trunc(SrcWidth + SrcHeight * Abs(AngleTan) + 0.5);
DstHeight := SrcHeight;
InitImage(TempImage1);
NewImage(DstWidth, DstHeight, TempFormat, TempImage1);
for I := 0 to DstHeight - 1 do
begin
if AngleTan >= 0 then
Shear := (I + 0.5) * AngleTan
else
Shear := (I - DstHeight + 0.5) * AngleTan;
XShear(Image, TempImage1, I, Floor(Shear), Trunc(255 * (Shear - Floor(Shear)) + 1), Bpp);
end;
// 2nd shear (vertical)
FreeImage(Image);
DstHeight := Trunc(SrcWidth * Abs(AngleSin) + SrcHeight * AngleCos + 0.5) + 1;
InitImage(TempImage2);
NewImage(DstWidth, DstHeight, TempFormat, TempImage2);
if AngleSin >= 0 then
Shear := (SrcWidth - 1) * AngleSin
else
Shear := (SrcWidth - DstWidth) * -AngleSin;
for I := 0 to DstWidth - 1 do
begin
YShear(TempImage1, TempImage2, I, Floor(Shear), Trunc(255 * (Shear - Floor(Shear)) + 1), Bpp);
Shear := Shear - AngleSin;
end;
// 3rd shear (horizontal)
FreeImage(TempImage1);
DstWidth := Trunc(SrcHeight * Abs(AngleSin) + SrcWidth * AngleCos + 0.5) + 1;
NewImage(DstWidth, DstHeight, TempFormat, Image);
if AngleSin >= 0 then
Shear := (SrcWidth - 1) * AngleSin * -AngleTan
else
Shear := ((SrcWidth - 1) * -AngleSin + (1 - DstHeight)) * AngleTan;
for I := 0 to DstHeight - 1 do
begin
XShear(TempImage2, Image, I, Floor(Shear), Trunc(255 * (Shear - Floor(Shear)) + 1), Bpp);
Shear := Shear + AngleTan;
end;
FreeImage(TempImage2);
if Image.Format <> SrcFmt then
ConvertImage(Image, SrcFmt);
end;
procedure RotateMul90(var Image: TImageData; Angle: Integer);
var
RotImage: TImageData;
X, Y, BytesPerPixel: Integer;
RotPix, Pix: PByte;
begin
InitImage(RotImage);
BytesPerPixel := ImageFormatInfos[Image.Format].BytesPerPixel;
if ((Angle = 90) or (Angle = 270)) and (Image.Width <> Image.Height) then
NewImage(Image.Height, Image.Width, Image.Format, RotImage)
else
NewImage(Image.Width, Image.Height, Image.Format, RotImage);
RotPix := RotImage.Bits;
case Angle of
90:
begin
for Y := 0 to RotImage.Height - 1 do
begin
Pix := @PByteArray(Image.Bits)[(Image.Width - Y - 1) * BytesPerPixel];
for X := 0 to RotImage.Width - 1 do
begin
CopyPixel(Pix, RotPix, BytesPerPixel);
Inc(RotPix, BytesPerPixel);
Inc(Pix, Image.Width * BytesPerPixel);
end;
end;
end;
180:
begin
Pix := @PByteArray(Image.Bits)[((Image.Height - 1) * Image.Width +
(Image.Width - 1)) * BytesPerPixel];
for Y := 0 to RotImage.Height - 1 do
for X := 0 to RotImage.Width - 1 do
begin
CopyPixel(Pix, RotPix, BytesPerPixel);
Inc(RotPix, BytesPerPixel);
Dec(Pix, BytesPerPixel);
end;
end;
270:
begin
for Y := 0 to RotImage.Height - 1 do
begin
Pix := @PByteArray(Image.Bits)[((Image.Height - 1) * Image.Width + Y) * BytesPerPixel];
for X := 0 to RotImage.Width - 1 do
begin
CopyPixel(Pix, RotPix, BytesPerPixel);
Inc(RotPix, BytesPerPixel);
Dec(Pix, Image.Width * BytesPerPixel);
end;
end;
end;
end;
FreeMemNil(Image.Bits);
RotImage.Palette := Image.Palette;
Image := RotImage;
end;
begin
if TestImage(Image) then
try
while Angle >= 360 do
Angle := Angle - 360;
while Angle < 0 do
Angle := Angle + 360;
if (Angle = 0) or (Abs(Angle) = 360) then
Exit;
OldFmt := Image.Format;
if ImageFormatInfos[Image.Format].IsSpecial then
ConvertImage(Image, ifDefault);
if (Angle > 45) and (Angle <= 135) then
begin
RotateMul90(Image, 90);
Angle := Angle - 90;
end
else if (Angle > 135) and (Angle <= 225) then
begin
RotateMul90(Image, 180);
Angle := Angle - 180;
end
else if (Angle > 225) and (Angle <= 315) then
begin
RotateMul90(Image, 270);
Angle := Angle - 270;
end;
if Angle <> 0 then
Rotate45(Image, Angle);
if OldFmt <> Image.Format then
ConvertImage(Image, OldFmt);
except
raise UpdateExceptMessage(GetExceptObject, SErrorRotateImage, [ImageToStr(Image), Angle]);
end;
end;
{ Drawing/Pixel functions }
function CopyRect(const SrcImage: TImageData; SrcX, SrcY, Width, Height: LongInt;
var DstImage: TImageData; DstX, DstY: LongInt): Boolean;
var
Info: PImageFormatInfo;
I, SrcWidthBytes, DstWidthBytes, MoveBytes: LongInt;
SrcPointer, DstPointer: PByte;
WorkImage: TImageData;
OldFormat: TImageFormat;
begin
Result := False;
OldFormat := ifUnknown;
if TestImage(SrcImage) and TestImage(DstImage) then
try
// Make sure we are still copying image to image, not invalid pointer to protected memory
ClipCopyBounds(SrcX, SrcY, Width, Height, DstX, DstY, SrcImage.Width, SrcImage.Height,
Rect(0, 0, DstImage.Width, DstImage.Height));
if (Width > 0) and (Height > 0) then
begin
Info := ImageFormatInfos[DstImage.Format];
if Info.IsSpecial then
begin
// If dest image is in special format we convert it to default
OldFormat := Info.Format;
ConvertImage(DstImage, ifDefault);
Info := ImageFormatInfos[DstImage.Format];
end;
if SrcImage.Format <> DstImage.Format then
begin
// If images are in different format source is converted to dest's format
InitImage(WorkImage);
CloneImage(SrcImage, WorkImage);
ConvertImage(WorkImage, DstImage.Format);
end
else
WorkImage := SrcImage;
MoveBytes := Width * Info.BytesPerPixel;
DstWidthBytes := DstImage.Width * Info.BytesPerPixel;
DstPointer := @PByteArray(DstImage.Bits)[DstY * DstWidthBytes +
DstX * Info.BytesPerPixel];
SrcWidthBytes := WorkImage.Width * Info.BytesPerPixel;
SrcPointer := @PByteArray(WorkImage.Bits)[SrcY * SrcWidthBytes +
SrcX * Info.BytesPerPixel];
for I := 0 to Height - 1 do
begin
Move(SrcPointer^, DstPointer^, MoveBytes);
Inc(SrcPointer, SrcWidthBytes);
Inc(DstPointer, DstWidthBytes);
end;
// If dest image was in special format we convert it back
if OldFormat <> ifUnknown then
ConvertImage(DstImage, OldFormat);
// Working image must be freed if it is not the same as source image
if WorkImage.Bits <> SrcImage.Bits then
FreeImage(WorkImage);
Result := True;
end;
except
RaiseImaging(SErrorCopyRect, [ImageToStr(SrcImage), ImageToStr(DstImage)]);
end;
end;
function FillRect(var Image: TImageData; X, Y, Width, Height: LongInt;
FillColor: Pointer): Boolean;
var
Info: PImageFormatInfo;
I, J, ImageWidthBytes, RectWidthBytes, Bpp: Longint;
LinePointer, PixPointer: PByte;
OldFmt: TImageFormat;
begin
Result := False;
if TestImage(Image) then
try
ClipRectBounds(X, Y, Width, Height, Rect(0, 0, Image.Width, Image.Height));
if (Width > 0) and (Height > 0) then
begin
OldFmt := Image.Format;
if ImageFormatInfos[OldFmt].IsSpecial then
ConvertImage(Image, ifDefault);
Info := ImageFormatInfos[Image.Format];
Bpp := Info.BytesPerPixel;
ImageWidthBytes := Image.Width * Bpp;
RectWidthBytes := Width * Bpp;
LinePointer := @PByteArray(Image.Bits)[Y * ImageWidthBytes + X * Bpp];
for I := 0 to Height - 1 do
begin
case Bpp of
1: FillMemoryByte(LinePointer, RectWidthBytes, PByte(FillColor)^);
2: FillMemoryWord(LinePointer, RectWidthBytes, PWord(FillColor)^);
4: FillMemoryLongWord(LinePointer, RectWidthBytes, PLongWord(FillColor)^);
else
PixPointer := LinePointer;
for J := 0 to Width - 1 do
begin
CopyPixel(FillColor, PixPointer, Bpp);
Inc(PixPointer, Bpp);
end;
end;
Inc(LinePointer, ImageWidthBytes);
end;
if OldFmt <> Image.Format then
ConvertImage(Image, OldFmt);
end;
Result := True;
except
RaiseImaging(SErrorFillRect, [X, Y, Width, Height, ImageToStr(Image)]);
end;
end;
function ReplaceColor(var Image: TImageData; X, Y, Width, Height: LongInt;
OldColor, NewColor: Pointer): Boolean;
var
Info: PImageFormatInfo;
I, J, WidthBytes, Bpp: Longint;
LinePointer, PixPointer: PByte;
OldFmt: TImageFormat;
begin
Assert((OldColor <> nil) and (NewColor <> nil));
Result := False;
if TestImage(Image) then
try
ClipRectBounds(X, Y, Width, Height, Rect(0, 0, Image.Width, Image.Height));
if (Width > 0) and (Height > 0) then
begin
OldFmt := Image.Format;
if ImageFormatInfos[OldFmt].IsSpecial then
ConvertImage(Image, ifDefault);
Info := ImageFormatInfos[Image.Format];
Bpp := Info.BytesPerPixel;
WidthBytes := Image.Width * Bpp;
LinePointer := @PByteArray(Image.Bits)[Y * WidthBytes + X * Bpp];
for I := 0 to Height - 1 do
begin
PixPointer := LinePointer;
for J := 0 to Width - 1 do
begin
if ComparePixels(PixPointer, OldColor, Bpp) then
CopyPixel(NewColor, PixPointer, Bpp);
Inc(PixPointer, Bpp);
end;
Inc(LinePointer, WidthBytes);
end;
if OldFmt <> Image.Format then
ConvertImage(Image, OldFmt);
end;
Result := True;
except
RaiseImaging(SErrorReplaceColor, [X, Y, Width, Height, ImageToStr(Image)]);
end;
end;
function StretchRect(const SrcImage: TImageData; SrcX, SrcY, SrcWidth,
SrcHeight: LongInt; var DstImage: TImageData; DstX, DstY, DstWidth,
DstHeight: LongInt; Filter: TResizeFilter): Boolean;
var
Info: PImageFormatInfo;
WorkImage: TImageData;
OldFormat: TImageFormat;
Resampling: TSamplingFilter;
begin
Result := False;
OldFormat := ifUnknown;
if TestImage(SrcImage) and TestImage(DstImage) then
try
// Make sure we are still copying image to image, not invalid pointer to protected memory
ClipStretchBounds(SrcX, SrcY, SrcWidth, SrcHeight, DstX, DstY, DstWidth, DstHeight,
SrcImage.Width, SrcImage.Height, Rect(0, 0, DstImage.Width, DstImage.Height));
if (SrcWidth = DstWidth) and (SrcHeight = DstHeight) then
begin
// If source and dest rectangles have the same size call CopyRect
Result := CopyRect(SrcImage, SrcX, SrcY, SrcWidth, SrcHeight, DstImage, DstX, DstY);
end
else if (SrcWidth > 0) and (SrcHeight > 0) and (DstWidth > 0) and (DstHeight > 0) then
begin
// If source and dest rectangles don't have the same size we do stretch
Info := ImageFormatInfos[DstImage.Format];
if Info.IsSpecial then
begin
// If dest image is in special format we convert it to default
OldFormat := Info.Format;
ConvertImage(DstImage, ifDefault);
Info := ImageFormatInfos[DstImage.Format];
end;
if SrcImage.Format <> DstImage.Format then
begin
// If images are in different format source is converted to dest's format
InitImage(WorkImage);
CloneImage(SrcImage, WorkImage);
ConvertImage(WorkImage, DstImage.Format);
end
else
WorkImage := SrcImage;
// Only pixel resize is supported for indexed images
if Info.IsIndexed then
Filter := rfNearest;
if Filter = rfNearest then
begin
StretchNearest(WorkImage, SrcX, SrcY, SrcWidth, SrcHeight,
DstImage, DstX, DstY, DstWidth, DstHeight);
end
else
begin
Resampling := sfNearest;
case Filter of
rfBilinear: Resampling := sfLinear;
rfBicubic: Resampling := DefaultCubicFilter;
rfLanczos: Resampling := sfLanczos;
end;
StretchResample(WorkImage, SrcX, SrcY, SrcWidth, SrcHeight,
DstImage, DstX, DstY, DstWidth, DstHeight, Resampling);
end;
// If dest image was in special format we convert it back
if OldFormat <> ifUnknown then
ConvertImage(DstImage, OldFormat);
// Working image must be freed if it is not the same as source image
if WorkImage.Bits <> SrcImage.Bits then
FreeImage(WorkImage);
Result := True;
end;
except
RaiseImaging(SErrorStretchRect, [ImageToStr(SrcImage), ImageToStr(DstImage)]);
end;
end;
procedure GetPixelDirect(const Image: TImageData; X, Y: LongInt; Pixel: Pointer);
var
BytesPerPixel: LongInt;
begin
Assert(Pixel <> nil);
BytesPerPixel := ImageFormatInfos[Image.Format].BytesPerPixel;
CopyPixel(@PByteArray(Image.Bits)[(Y * Image.Width + X) * BytesPerPixel],
Pixel, BytesPerPixel);
end;
procedure SetPixelDirect(const Image: TImageData; X, Y: LongInt; Pixel: Pointer);
var
BytesPerPixel: LongInt;
begin
Assert(Pixel <> nil);
BytesPerPixel := ImageFormatInfos[Image.Format].BytesPerPixel;
CopyPixel(Pixel, @PByteArray(Image.Bits)[(Y * Image.Width + X) * BytesPerPixel],
BytesPerPixel);
end;
function GetPixel32(const Image: TImageData; X, Y: LongInt): TColor32Rec;
var
Info: PImageFormatInfo;
Data: PByte;
begin
Info := ImageFormatInfos[Image.Format];
Data := @PByteArray(Image.Bits)[(Y * Image.Width + X) * Info.BytesPerPixel];
Result := GetPixel32Generic(Data, Info, Image.Palette);
end;
procedure SetPixel32(const Image: TImageData; X, Y: LongInt; const Color: TColor32Rec);
var
Info: PImageFormatInfo;
Data: PByte;
begin
Info := ImageFormatInfos[Image.Format];
Data := @PByteArray(Image.Bits)[(Y * Image.Width + X) * Info.BytesPerPixel];
SetPixel32Generic(Data, Info, Image.Palette, Color);
end;
function GetPixelFP(const Image: TImageData; X, Y: LongInt): TColorFPRec;
var
Info: PImageFormatInfo;
Data: PByte;
begin
Info := ImageFormatInfos[Image.Format];
Data := @PByteArray(Image.Bits)[(Y * Image.Width + X) * Info.BytesPerPixel];
Result := GetPixelFPGeneric(Data, Info, Image.Palette);
end;
procedure SetPixelFP(const Image: TImageData; X, Y: LongInt; const Color: TColorFPRec);
var
Info: PImageFormatInfo;
Data: PByte;
begin
Info := ImageFormatInfos[Image.Format];
Data := @PByteArray(Image.Bits)[(Y * Image.Width + X) * Info.BytesPerPixel];
SetPixelFPGeneric(Data, Info, Image.Palette, Color);
end;
{ Palette Functions }
procedure NewPalette(Entries: LongInt; var Pal: PPalette32);
begin
Assert((Entries > 2) and (Entries <= 65535));
try
GetMem(Pal, Entries * SizeOf(TColor32Rec));
FillChar(Pal^, Entries * SizeOf(TColor32Rec), $FF);
except
RaiseImaging(SErrorNewPalette, [Entries]);
end;
end;
procedure FreePalette(var Pal: PPalette32);
begin
try
FreeMemNil(Pal);
except
RaiseImaging(SErrorFreePalette, [Pal]);
end;
end;
procedure CopyPalette(SrcPal, DstPal: PPalette32; SrcIdx, DstIdx, Count: LongInt);
begin
Assert((SrcPal <> nil) and (DstPal <> nil));
Assert((SrcIdx >= 0) and (DstIdx >= 0) and (Count >= 0));
try
Move(SrcPal[SrcIdx], DstPal[DstIdx], Count * SizeOf(TColor32Rec));
except
RaiseImaging(SErrorCopyPalette, [Count, SrcPal, DstPal]);
end;
end;
function FindColor(Pal: PPalette32; Entries: LongInt; Color: TColor32):
LongInt;
var
Col: TColor32Rec;
I, MinDif, Dif: LongInt;
begin
Assert(Pal <> nil);
Result := -1;
Col.Color := Color;
try
// First try to find exact match
for I := 0 to Entries - 1 do
with Pal[I] do
begin
if (A = Col.A) and (R = Col.R) and
(G = Col.G) and (B = Col.B) then
begin
Result := I;
Exit;
end;
end;
// If exact match was not found, find nearest color
MinDif := 1020;
for I := 0 to Entries - 1 do
with Pal[I] do
begin
Dif := Abs(R - Col.R);
if Dif > MinDif then Continue;
Dif := Dif + Abs(G - Col.G);
if Dif > MinDif then Continue;
Dif := Dif + Abs(B - Col.B);
if Dif > MinDif then Continue;
Dif := Dif + Abs(A - Col.A);
if Dif < MinDif then
begin
MinDif := Dif;
Result := I;
end;
end;
except
RaiseImaging(SErrorFindColor, [Pal, Entries]);
end;
end;
procedure FillGrayscalePalette(Pal: PPalette32; Entries: LongInt);
var
I: LongInt;
begin
Assert(Pal <> nil);
try
for I := 0 to Entries - 1 do
with Pal[I] do
begin
A := $FF;
R := Byte(I);
G := Byte(I);
B := Byte(I);
end;
except
RaiseImaging(SErrorGrayscalePalette, [Pal, Entries]);
end;
end;
procedure FillCustomPalette(Pal: PPalette32; Entries: LongInt; RBits, GBits,
BBits: Byte; Alpha: Byte = $FF);
var
I, TotalBits, MaxEntries: LongInt;
begin
Assert(Pal <> nil);
TotalBits := RBits + GBits + BBits;
MaxEntries := Min(Pow2Int(TotalBits), Entries);
FillChar(Pal^, Entries * SizeOf(TColor32Rec), 0);
try
for I := 0 to MaxEntries - 1 do
with Pal[I] do
begin
A := Alpha;
if RBits > 0 then
R := ((I shr Max(0, GBits + BBits - 1)) and (1 shl RBits - 1)) * 255 div (1 shl RBits - 1);
if GBits > 0 then
G := ((I shr Max(0, BBits - 1)) and (1 shl GBits - 1)) * 255 div (1 shl GBits - 1);
if BBits > 0 then
B := ((I shr 0) and (1 shl BBits - 1)) * 255 div (1 shl BBits - 1);
end;
except
RaiseImaging(SErrorCustomPalette, [Pal, Entries]);
end;
end;
procedure SwapChannelsOfPalette(Pal: PPalette32; Entries, SrcChannel,
DstChannel: LongInt);
var
I: LongInt;
Swap: Byte;
begin
Assert(Pal <> nil);
Assert((SrcChannel in [0..3]) and (DstChannel in [0..3]));
try
for I := 0 to Entries - 1 do
with Pal[I] do
begin
Swap := Channels[SrcChannel];
Channels[SrcChannel] := Channels[DstChannel];
Channels[DstChannel] := Swap;
end;
except
RaiseImaging(SErrorSwapPalette, [Pal, Entries]);
end;
end;
{ Options Functions }
function SetOption(OptionId, Value: LongInt): Boolean;
begin
Result := False;
if (OptionId >= 0) and (OptionId < Length(Options)) and
(Options[OptionID] <> nil) then
begin
Options[OptionID]^ := CheckOptionValue(OptionId, Value);
Result := True;
end;
end;
function GetOption(OptionId: LongInt): LongInt;
begin
Result := InvalidOption;
if (OptionId >= 0) and (OptionId < Length(Options)) and
(Options[OptionID] <> nil) then
begin
Result := Options[OptionID]^;
end;
end;
function PushOptions: Boolean;
begin
Result := OptionStack.Push;
end;
function PopOptions: Boolean;
begin
Result := OptionStack.Pop;
end;
{ Image Format Functions }
function GetImageFormatInfo(Format: TImageFormat; out Info: TImageFormatInfo): Boolean;
begin
FillChar(Info, SizeOf(Info), 0);
if ImageFormatInfos[Format] <> nil then
begin
Info := ImageFormatInfos[Format]^;
Result := True;
end
else
Result := False;
end;
function GetPixelsSize(Format: TImageFormat; Width, Height: LongInt): LongInt;
begin
if ImageFormatInfos[Format] <> nil then
Result := ImageFormatInfos[Format].GetPixelsSize(Format, Width, Height)
else
Result := 0;
end;
{ IO Functions }
procedure SetUserFileIO(OpenProc: TOpenProc;
CloseProc: TCloseProc; EofProc: TEofProc; SeekProc: TSeekProc; TellProc:
TTellProc; ReadProc: TReadProc; WriteProc: TWriteProc);
begin
FileIO.Open := OpenProc;
FileIO.Close := CloseProc;
FileIO.Eof := EofProc;
FileIO.Seek := SeekProc;
FileIO.Tell := TellProc;
FileIO.Read := ReadProc;
FileIO.Write := WriteProc;
end;
procedure ResetFileIO;
begin
FileIO := OriginalFileIO;
end;
{ Raw Image IO Functions }
procedure ReadRawImage(Handle: TImagingHandle; Width, Height: Integer;
Format: TImageFormat; var Image: TImageData; Offset, RowLength: Integer);
var
WidthBytes, I: Integer;
Info: PImageFormatInfo;
begin
Info := ImageFormatInfos[Format];
// Calc scanline size
WidthBytes := Info.GetPixelsSize(Format, Width, 1);
if RowLength = 0 then
RowLength := WidthBytes;
// Create new image if needed - don't need to allocate new one if there is already
// one with desired size and format
if (Image.Width <> Width) or (Image.Height <> Height) or (Image.Format <> Format) then
NewImage(Width, Height, Format, Image);
// Move past the header
IO.Seek(Handle, Offset, smFromCurrent);
// Read scanlines from input
for I := 0 to Height - 1 do
begin
IO.Read(Handle, @PByteArray(Image.Bits)[I * WidthBytes], WidthBytes);
IO.Seek(Handle, RowLength - WidthBytes, smFromCurrent);
end;
end;
procedure ReadRawImageFromFile(const FileName: string; Width, Height: Integer;
Format: TImageFormat; var Image: TImageData; Offset, RowLength: Integer);
var
Handle: TImagingHandle;
begin
Assert(FileName <> '');
// Set IO ops to file ops and open given file
SetFileIO;
Handle := IO.Open(PChar(FileName), omReadOnly);
try
ReadRawImage(Handle, Width, Height, Format, Image, Offset, RowLength);
finally
IO.Close(Handle);
end;
end;
procedure ReadRawImageFromStream(Stream: TStream; Width, Height: Integer;
Format: TImageFormat; var Image: TImageData; Offset, RowLength: Integer);
var
Handle: TImagingHandle;
begin
Assert(Stream <> nil);
if Stream.Size - Stream.Position = 0 then
RaiseImaging(SErrorEmptyStream, []);
// Set IO ops to stream ops and open given stream
SetStreamIO;
Handle := IO.Open(Pointer(Stream), omReadOnly);
try
ReadRawImage(Handle, Width, Height, Format, Image, Offset, RowLength);
finally
IO.Close(Handle);
end;
end;
procedure ReadRawImageFromMemory(Data: Pointer; DataSize: Integer; Width, Height: Integer;
Format: TImageFormat; var Image: TImageData; Offset, RowLength: Integer);
var
Handle: TImagingHandle;
MemRec: TMemoryIORec;
begin
Assert((Data <> nil) and (DataSize > 0));
// Set IO ops to memory ops and open given stream
SetMemoryIO;
MemRec := PrepareMemIO(Data, DataSize);
Handle := IO.Open(@MemRec, omReadOnly);
try
ReadRawImage(Handle, Width, Height, Format, Image, Offset, RowLength);
finally
IO.Close(Handle);
end;
end;
procedure ReadRawImageRect(Data: Pointer; Left, Top, Width, Height: Integer;
var Image: TImageData; Offset, RowLength: Integer);
var
DestScanBytes, RectBytes, I: Integer;
Info: PImageFormatInfo;
Src, Dest: PByte;
begin
Assert(Data <> nil);
Assert((Left + Width <= Image.Width) and (Top + Height <= Image.Height));
Info := ImageFormatInfos[Image.Format];
// Calc scanline size
DestScanBytes := Info.GetPixelsSize(Info.Format, Image.Width, 1);
RectBytes := Info.GetPixelsSize(Info.Format, Width, 1);
if RowLength = 0 then
RowLength := RectBytes;
Src := Data;
Dest := @PByteArray(Image.Bits)[Top * DestScanBytes + Info.GetPixelsSize(Info.Format, Left, 1)];
// Move past the header
Inc(Src, Offset);
// Read lines into rect in the existing image
for I := 0 to Height - 1 do
begin
Move(Src^, Dest^, RectBytes);
Inc(Src, RowLength);
Inc(Dest, DestScanBytes);
end;
end;
procedure WriteRawImage(Handle: TImagingHandle; const Image: TImageData;
Offset, RowLength: Integer);
var
WidthBytes, I: Integer;
Info: PImageFormatInfo;
begin
Info := ImageFormatInfos[Image.Format];
// Calc scanline size
WidthBytes := Info.GetPixelsSize(Image.Format, Image.Width, 1);
if RowLength = 0 then
RowLength := WidthBytes;
// Move past the header
IO.Seek(Handle, Offset, smFromCurrent);
// Write scanlines to output
for I := 0 to Image.Height - 1 do
begin
IO.Write(Handle, @PByteArray(Image.Bits)[I * WidthBytes], WidthBytes);
IO.Seek(Handle, RowLength - WidthBytes, smFromCurrent);
end;
end;
procedure WriteRawImageToFile(const FileName: string; const Image: TImageData;
Offset, RowLength: Integer);
var
Handle: TImagingHandle;
begin
Assert(FileName <> '');
// Set IO ops to file ops and open given file
SetFileIO;
Handle := IO.Open(PChar(FileName), omCreate);
try
WriteRawImage(Handle, Image, Offset, RowLength);
finally
IO.Close(Handle);
end;
end;
procedure WriteRawImageToStream(Stream: TStream; const Image: TImageData;
Offset, RowLength: Integer);
var
Handle: TImagingHandle;
begin
Assert(Stream <> nil);
// Set IO ops to stream ops and open given stream
SetStreamIO;
Handle := IO.Open(Pointer(Stream), omCreate);
try
WriteRawImage(Handle, Image, Offset, RowLength);
finally
IO.Close(Handle);
end;
end;
procedure WriteRawImageToMemory(Data: Pointer; DataSize: Integer; const Image: TImageData;
Offset, RowLength: Integer);
var
Handle: TImagingHandle;
MemRec: TMemoryIORec;
begin
Assert((Data <> nil) and (DataSize > 0));
// Set IO ops to memory ops and open given stream
SetMemoryIO;
MemRec := PrepareMemIO(Data, DataSize);
Handle := IO.Open(@MemRec, omCreate);
try
WriteRawImage(Handle, Image, Offset, RowLength);
finally
IO.Close(Handle);
end;
end;
procedure WriteRawImageRect(Data: Pointer; Left, Top, Width, Height: Integer;
const Image: TImageData; Offset, RowLength: Integer);
var
SrcScanBytes, RectBytes, I: Integer;
Info: PImageFormatInfo;
Src, Dest: PByte;
begin
Assert(Data <> nil);
Assert((Left + Width <= Image.Width) and (Top + Height <= Image.Height));
Info := ImageFormatInfos[Image.Format];
// Calc scanline size
SrcScanBytes := Info.GetPixelsSize(Info.Format, Image.Width, 1);
RectBytes := Info.GetPixelsSize(Info.Format, Width, 1);
if RowLength = 0 then
RowLength := RectBytes;
Src := @PByteArray(Image.Bits)[Top * SrcScanBytes + Info.GetPixelsSize(Info.Format, Left, 1)];
Dest := Data;
// Move past the header
Inc(Dest, Offset);
// Write lines from rect of the existing image
for I := 0 to Height - 1 do
begin
Move(Src^, Dest^, RectBytes);
Inc(Dest, RowLength);
Inc(Src, SrcScanBytes);
end;
end;
{ Convenience/helper Functions }
procedure ResizeImageToFit(const SrcImage: TImageData; FitWidth, FitHeight: Integer;
Filter: TResizeFilter; var DestImage: TImageData);
var
CurSize, FitSize, DestSize: TSize;
begin
if not TestImage(SrcImage) then
raise EImagingError.Create(SErrorInvalidInputImage);
FitSize.CX := FitWidth;
FitSize.CY := FitHeight;
CurSize.CX := SrcImage.Width;
CurSize.CY := SrcImage.Height;
DestSize := ImagingUtility.ScaleSizeToFit(CurSize, FitSize);
NewImage(Max(DestSize.CX, 1), Max(DestSize.CY, 1), SrcImage.Format, DestImage);
if SrcImage.Palette <> nil then
CopyPalette(SrcImage.Palette, DestImage.Palette, 0, 0, ImageFormatInfos[SrcImage.Format].PaletteEntries);
StretchRect(SrcImage, 0, 0, CurSize.CX, CurSize.CY, DestImage, 0, 0,
DestSize.CX, DestSize.CY, Filter);
end;
{ Color constructor functions }
function Color24(R, G, B: Byte): TColor24Rec;
begin
Result.R := R;
Result.G := G;
Result.B := B;
end;
function Color32(A, R, G, B: Byte): TColor32Rec;
begin
Result.A := A;
Result.R := R;
Result.G := G;
Result.B := B;
end;
function Color48(R, G, B: Word): TColor48Rec;
begin
Result.R := R;
Result.G := G;
Result.B := B;
end;
function Color64(A, R, G, B: Word): TColor64Rec;
begin
Result.A := A;
Result.R := R;
Result.G := G;
Result.B := B;
end;
function ColorFP(A, R, G, B: Single): TColorFPRec;
begin
Result.A := A;
Result.R := R;
Result.G := G;
Result.B := B;
end;
function ColorHF(A, R, G, B: THalfFloat): TColorHFRec;
begin
Result.A := A;
Result.R := R;
Result.G := G;
Result.B := B;
end;
function GetAlphaValue(Color32: TColor32): Byte;
begin
Result := Color32 shr 24;
end;
function GetRedValue(Color32: TColor32): Byte;
begin
Result := (Color32 shr 16) and $FF;
end;
function GetGreenValue(Color32: TColor32): Byte;
begin
Result := (Color32 shr 8) and $FF;
end;
function GetBlueValue(Color32: TColor32): Byte;
begin
Result := Color32 and $FF;
end;
{ ------------------------------------------------------------------------
Other Imaging Stuff
------------------------------------------------------------------------}
function GetFormatName(Format: TImageFormat): string;
begin
if ImageFormatInfos[Format] <> nil then
Result := ImageFormatInfos[Format].Name
else
Result := SUnknownFormat;
end;
function ImageToStr(const Image: TImageData): string;
var
ImgSize: Integer;
begin
if TestImage(Image) then
with Image do
begin
ImgSize := Size;
if ImgSize > 8192 then
ImgSize := ImgSize div 1024;
Result := SysUtils.Format(SImageInfo, [@Image, Width, Height,
GetFormatName(Format), ImgSize + 0.0, Iff(ImgSize = Size, 'B', 'KiB'), Bits,
Palette]);
end
else
Result := SysUtils.Format(SImageInfoInvalid, [@Image]);
end;
function GetVersionStr: string;
begin
Result := Format('%.1d.%.2d', [ImagingVersionMajor, ImagingVersionMinor]);
end;
function IffFormat(Condition: Boolean; const TruePart, FalsePart: TImageFormat): TImageFormat;
begin
if Condition then
Result := TruePart
else
Result := FalsePart;
end;
procedure RegisterImageFileFormat(AClass: TImageFileFormatClass);
begin
Assert(AClass <> nil);
if ImageFileFormats = nil then
ImageFileFormats := TList.Create;
if GlobalMetadata = nil then
GlobalMetadata := TMetadata.Create;
if ImageFileFormats <> nil then
ImageFileFormats.Add(AClass.Create);
end;
function RegisterOption(OptionId: LongInt; Variable: PLongInt): Boolean;
begin
Result := False;
if Options = nil then
InitOptions;
Assert(Variable <> nil);
if OptionId >= Length(Options) then
SetLength(Options, OptionId + InitialOptions);
if (OptionId >= 0) and (OptionId < Length(Options)) {and (Options[OptionId] = nil) - must be able to override existing } then
begin
Options[OptionId] := Variable;
Result := True;
end;
end;
function FindImageFileFormatByExt(const Ext: string): TImageFileFormat;
var
I: LongInt;
begin
Result := nil;
for I := ImageFileFormats.Count - 1 downto 0 do
if TImageFileFormat(ImageFileFormats[I]).Extensions.IndexOf(Ext) >= 0 then
begin
Result := TImageFileFormat(ImageFileFormats[I]);
Exit;
end;
end;
function FindImageFileFormatByName(const FileName: string): TImageFileFormat;
var
I: LongInt;
begin
Result := nil;
for I := ImageFileFormats.Count - 1 downto 0 do
if TImageFileFormat(ImageFileFormats[I]).TestFileName(FileName) then
begin
Result := TImageFileFormat(ImageFileFormats[I]);
Exit;
end;
end;
function FindImageFileFormatByClass(AClass: TImageFileFormatClass): TImageFileFormat;
var
I: LongInt;
begin
Result := nil;
for I := 0 to ImageFileFormats.Count - 1 do
if TImageFileFormat(ImageFileFormats[I]) is AClass then
begin
Result := TObject(ImageFileFormats[I]) as TImageFileFormat;
Break;
end;
end;
function GetFileFormatCount: LongInt;
begin
Result := ImageFileFormats.Count;
end;
function GetFileFormatAtIndex(Index: LongInt): TImageFileFormat;
begin
if (Index >= 0) and (Index < ImageFileFormats.Count) then
Result := TImageFileFormat(ImageFileFormats[Index])
else
Result := nil;
end;
function GetImageFileFormatsFilter(OpenFileFilter: Boolean): string;
var
I, J, Count: LongInt;
Descriptions: string;
Filters, CurFilter: string;
FileFormat: TImageFileFormat;
begin
Descriptions := '';
Filters := '';
Count := 0;
for I := 0 to ImageFileFormats.Count - 1 do
begin
FileFormat := TObject(ImageFileFormats[I]) as TImageFileFormat;
// If we are creating filter for save dialog and this format cannot save
// files the we skip it
if not OpenFileFilter and not FileFormat.CanSave then
Continue;
CurFilter := '';
for J := 0 to FileFormat.Masks.Count - 1 do
begin
CurFilter := CurFilter + FileFormat.Masks[J];
if J < FileFormat.Masks.Count - 1 then
CurFilter := CurFilter + ';';
end;
FmtStr(Descriptions, '%s%s (%s)|%2:s', [Descriptions, FileFormat.Name, CurFilter]);
if Filters <> '' then
FmtStr(Filters, '%s;%s', [Filters, CurFilter])
else
Filters := CurFilter;
if I < ImageFileFormats.Count - 1 then
Descriptions := Descriptions + '|';
Inc(Count);
end;
if (Count > 1) and OpenFileFilter then
FmtStr(Descriptions, '%s (%s)|%1:s|%s', [SAllFilter, Filters, Descriptions]);
Result := Descriptions;
end;
function GetFilterIndexExtension(Index: LongInt; OpenFileFilter: Boolean): string;
var
I, Count: LongInt;
FileFormat: TImageFileFormat;
begin
// -1 because filter indices are in 1..n range
Index := Index - 1;
Result := '';
if OpenFileFilter then
begin
if Index > 0 then
Index := Index - 1;
end;
if (Index >= 0) and (Index < ImageFileFormats.Count) then
begin
Count := 0;
for I := 0 to ImageFileFormats.Count - 1 do
begin
FileFormat := TObject(ImageFileFormats[I]) as TImageFileFormat;
if not OpenFileFilter and not FileFormat.CanSave then
Continue;
if Index = Count then
begin
if FileFormat.Extensions.Count > 0 then
Result := FileFormat.Extensions[0];
Exit;
end;
Inc(Count);
end;
end;
end;
function GetFileNameFilterIndex(const FileName: string; OpenFileFilter: Boolean): LongInt;
var
I: LongInt;
FileFormat: TImageFileFormat;
begin
Result := 0;
for I := 0 to ImageFileFormats.Count - 1 do
begin
FileFormat := TObject(ImageFileFormats[I]) as TImageFileFormat;
if not OpenFileFilter and not FileFormat.CanSave then
Continue;
if FileFormat.TestFileName(FileName) then
begin
// +1 because filter indices are in 1..n range
Inc(Result);
if OpenFileFilter then
Inc(Result);
Exit;
end;
Inc(Result);
end;
Result := -1;
end;
function GetIO: TIOFunctions;
begin
Result := IO;
end;
procedure RaiseImaging(const Msg: string; const Args: array of const);
var
WholeMsg: string;
begin
WholeMsg := Msg;
if GetExceptObject <> nil then
begin
WholeMsg := WholeMsg + ' ' + SExceptMsg + ': ' +
GetExceptObject.Message;
end;
raise EImagingError.CreateFmt(WholeMsg, Args);
end;
procedure RaiseImaging(const Msg: string);
begin
RaiseImaging(Msg, []);
end;
{ Internal unit functions }
function CheckOptionValue(OptionId, Value: LongInt): LongInt;
begin
case OptionId of
ImagingColorReductionMask:
Result := ClampInt(Value, 0, $FF);
ImagingLoadOverrideFormat, ImagingSaveOverrideFormat:
Result := Iff(ImagingFormats.IsImageFormatValid(TImageFormat(Value)),
Value, LongInt(ifUnknown));
ImagingMipMapFilter: Result := ClampInt(Value, Ord(Low(TSamplingFilter)),
Ord(High(TSamplingFilter)));
else
Result := Value;
end;
end;
procedure SetFileIO;
begin
IO := FileIO;
end;
procedure SetStreamIO;
begin
IO := StreamIO;
end;
procedure SetMemoryIO;
begin
IO := MemoryIO;
end;
procedure InitImageFormats;
begin
ImagingFormats.InitImageFormats(ImageFormatInfos);
end;
procedure FreeImageFileFormats;
var
I: LongInt;
begin
if ImageFileFormats <> nil then
for I := 0 to ImageFileFormats.Count - 1 do
TImageFileFormat(ImageFileFormats[I]).Free;
FreeAndNil(ImageFileFormats);
end;
procedure InitOptions;
begin
SetLength(Options, InitialOptions);
OptionStack := TOptionStack.Create;
end;
procedure FreeOptions;
begin
SetLength(Options, 0);
FreeAndNil(OptionStack);
end;
{
TImageFileFormat class implementation
}
constructor TImageFileFormat.Create(AMetadata: TMetadata);
begin
inherited Create;
FName := SUnknownFormat;
FExtensions := TStringList.Create;
FMasks := TStringList.Create;
if AMetadata = nil then
FMetadata := GlobalMetadata
else
FMetadata := AMetadata;
Define;
end;
destructor TImageFileFormat.Destroy;
begin
FExtensions.Free;
FMasks.Free;
inherited Destroy;
end;
procedure TImageFileFormat.Define;
begin
end;
function TImageFileFormat.PrepareLoad(Handle: TImagingHandle;
var Images: TDynImageDataArray; OnlyFirstFrame: Boolean): Boolean;
begin
FMetadata.ClearMetaItems; // Clear old metadata
FreeImagesInArray(Images);
SetLength(Images, 0);
Result := Handle <> nil;
end;
function TImageFileFormat.PostLoadCheck(var Images: TDynImageDataArray;
LoadResult: Boolean): Boolean;
var
I: LongInt;
begin
if not LoadResult then
begin
FreeImagesInArray(Images);
SetLength(Images, 0);
Result := False;
end
else
begin
Result := (Length(Images) > 0) and TestImagesInArray(Images);
if Result then
begin
// Convert to overriden format if it is set
if LoadOverrideFormat <> ifUnknown then
for I := Low(Images) to High(Images) do
ConvertImage(Images[I], LoadOverrideFormat);
end;
end;
end;
function TImageFileFormat.PrepareSave(Handle: TImagingHandle;
const Images: TDynImageDataArray; var Index: Integer): Boolean;
var
Len, I: LongInt;
begin
CheckOptionsValidity;
Result := False;
if CanSave then
begin
Len := Length(Images);
Assert(Len > 0);
// If there are no images to be saved exit
if Len = 0 then Exit;
// Check index of image to be saved (-1 as index means save all images)
if IsMultiImageFormat then
begin
if (Index >= Len) then
Index := 0;
if Index < 0 then
begin
Index := 0;
FFirstIdx := 0;
FLastIdx := Len - 1;
end
else
begin
FFirstIdx := Index;
FLastIdx := Index;
end;
for I := FFirstIdx to FLastIdx - 1 do
begin
if not TestImage(Images[I]) then
Exit;
end;
end
else
begin
if (Index >= Len) or (Index < 0) then
Index := 0;
if not TestImage(Images[Index]) then
Exit;
end;
Result := True;
end;
end;
procedure TImageFileFormat.AddMasks(const AMasks: string);
var
I: LongInt;
Ext: string;
begin
FExtensions.Clear;
FMasks.CommaText := AMasks;
FMasks.Delimiter := ';';
for I := 0 to FMasks.Count - 1 do
begin
FMasks[I] := Trim(FMasks[I]);
Ext := GetFileExt(FMasks[I]);
if (Ext <> '') and (Ext <> '*') then
FExtensions.Add(Ext);
end;
end;
function TImageFileFormat.GetFormatInfo(Format: TImageFormat): TImageFormatInfo;
begin
Result := ImageFormatInfos[Format]^;
end;
function TImageFileFormat.GetSupportedFormats: TImageFormats;
begin
Result := FSupportedFormats;
end;
function TImageFileFormat.LoadData(Handle: TImagingHandle;
var Images: TDynImageDataArray; OnlyFirstFrame: Boolean): Boolean;
begin
Result := False;
RaiseImaging(SFileFormatCanNotLoad, [FName]);
end;
function TImageFileFormat.SaveData(Handle: TImagingHandle;
const Images: TDynImageDataArray; Index: LongInt): Boolean;
begin
Result := False;
RaiseImaging(SFileFormatCanNotSave, [FName]);
end;
procedure TImageFileFormat.ConvertToSupported(var Image: TImageData;
const Info: TImageFormatInfo);
begin
end;
function TImageFileFormat.IsSupported(const Image: TImageData): Boolean;
begin
Result := Image.Format in GetSupportedFormats;
end;
function TImageFileFormat.LoadFromFile(const FileName: string;
var Images: TDynImageDataArray; OnlyFirstLevel: Boolean): Boolean;
var
Handle: TImagingHandle;
begin
Result := False;
if CanLoad then
try
// Set IO ops to file ops and open given file
SetFileIO;
Handle := IO.Open(PChar(FileName), omReadOnly);
try
// Test if file contains valid image and if so then load it
if TestFormat(Handle) then
begin
Result := PrepareLoad(Handle, Images, OnlyFirstLevel) and
LoadData(Handle, Images, OnlyFirstlevel);
Result := PostLoadCheck(Images, Result);
end
else
RaiseImaging(SFileNotValid, [FileName, Name]);
finally
IO.Close(Handle);
end;
except
RaiseImaging(SErrorLoadingFile, [FileName, FExtensions[0]]);
end;
end;
function TImageFileFormat.LoadFromStream(Stream: TStream;
var Images: TDynImageDataArray; OnlyFirstLevel: Boolean): Boolean;
var
Handle: TImagingHandle;
OldPosition: Int64;
begin
Result := False;
OldPosition := Stream.Position;
if CanLoad then
try
// Set IO ops to stream ops and "open" given memory
SetStreamIO;
Handle := IO.Open(Pointer(Stream), omReadOnly);
try
// Test if stream contains valid image and if so then load it
if TestFormat(Handle) then
begin
Result := PrepareLoad(Handle, Images, OnlyFirstLevel) and
LoadData(Handle, Images, OnlyFirstlevel);
Result := PostLoadCheck(Images, Result);
end
else
RaiseImaging(SStreamNotValid, [@Stream, Name]);
finally
IO.Close(Handle);
end;
except
Stream.Position := OldPosition;
FreeImagesInArray(Images);
RaiseImaging(SErrorLoadingStream, [@Stream, FExtensions[0]]);
end;
end;
function TImageFileFormat.LoadFromMemory(Data: Pointer; Size: LongInt; var
Images: TDynImageDataArray; OnlyFirstLevel: Boolean): Boolean;
var
Handle: TImagingHandle;
IORec: TMemoryIORec;
begin
Result := False;
if CanLoad then
try
// Set IO ops to memory ops and "open" given memory
SetMemoryIO;
IORec := PrepareMemIO(Data, Size);
Handle := IO.Open(@IORec,omReadOnly);
try
// Test if memory contains valid image and if so then load it
if TestFormat(Handle) then
begin
Result := PrepareLoad(Handle, Images, OnlyFirstLevel) and
LoadData(Handle, Images, OnlyFirstlevel);
Result := PostLoadCheck(Images, Result);
end
else
RaiseImaging(SMemoryNotValid, [Data, Size, Name]);
finally
IO.Close(Handle);
end;
except
RaiseImaging(SErrorLoadingMemory, [Data, Size, FExtensions[0]]);
end;
end;
function TImageFileFormat.SaveToFile(const FileName: string;
const Images: TDynImageDataArray; OnlyFirstLevel: Boolean): Boolean;
var
Handle: TImagingHandle;
Len, Index, I: LongInt;
Ext, FName: string;
begin
Result := False;
if CanSave and TestImagesInArray(Images) then
try
SetFileIO;
Len := Length(Images);
if IsMultiImageFormat or
(not IsMultiImageFormat and (OnlyFirstLevel or (Len = 1))) then
begin
Handle := IO.Open(PChar(FileName), GetSaveOpenMode);
try
if OnlyFirstLevel then
Index := 0
else
Index := -1;
// Write multi image to one file
Result := PrepareSave(Handle, Images, Index) and SaveData(Handle, Images, Index);
finally
IO.Close(Handle);
end;
end
else
begin
// Write multi image to file sequence
Ext := ExtractFileExt(FileName);
FName := ChangeFileExt(FileName, '');
Result := True;
for I := 0 to Len - 1 do
begin
Handle := IO.Open(PChar(Format(FName + '%.3d' + Ext, [I])), GetSaveOpenMode);
try
Index := I;
Result := Result and PrepareSave(Handle, Images, Index) and
SaveData(Handle, Images, Index);
if not Result then
Break;
finally
IO.Close(Handle);
end;
end;
end;
except
raise UpdateExceptMessage(GetExceptObject, SErrorSavingFile, [FileName, FExtensions[0]]);
end;
end;
function TImageFileFormat.SaveToStream(Stream: TStream;
const Images: TDynImageDataArray; OnlyFirstLevel: Boolean): Boolean;
var
Handle: TImagingHandle;
Len, Index, I: LongInt;
OldPosition: Int64;
begin
Result := False;
OldPosition := Stream.Position;
if CanSave and TestImagesInArray(Images) then
try
SetStreamIO;
Handle := IO.Open(PChar(Stream), GetSaveOpenMode);
try
if IsMultiImageFormat or OnlyFirstLevel then
begin
if OnlyFirstLevel then
Index := 0
else
Index := -1;
// Write multi image in one run
Result := PrepareSave(Handle, Images, Index) and SaveData(Handle, Images, Index);
end
else
begin
// Write multi image to sequence
Result := True;
Len := Length(Images);
for I := 0 to Len - 1 do
begin
Index := I;
Result := Result and PrepareSave(Handle, Images, Index) and
SaveData(Handle, Images, Index);
if not Result then
Break;
end;
end;
finally
IO.Close(Handle);
end;
except
Stream.Position := OldPosition;
raise UpdateExceptMessage(GetExceptObject, SErrorSavingStream, [@Stream, FExtensions[0]]);
end;
end;
function TImageFileFormat.SaveToMemory(Data: Pointer; var Size: LongInt;
const Images: TDynImageDataArray; OnlyFirstLevel: Boolean): Boolean;
var
Handle: TImagingHandle;
Len, Index, I: LongInt;
IORec: TMemoryIORec;
begin
Result := False;
if CanSave and TestImagesInArray(Images) then
try
SetMemoryIO;
IORec := PrepareMemIO(Data, Size);
Handle := IO.Open(PChar(@IORec), GetSaveOpenMode);
try
if IsMultiImageFormat or OnlyFirstLevel then
begin
if OnlyFirstLevel then
Index := 0
else
Index := -1;
// Write multi image in one run
Result := PrepareSave(Handle, Images, Index) and SaveData(Handle, Images, Index);
end
else
begin
// Write multi image to sequence
Result := True;
Len := Length(Images);
for I := 0 to Len - 1 do
begin
Index := I;
Result := Result and PrepareSave(Handle, Images, Index) and
SaveData(Handle, Images, Index);
if not Result then
Break;
end;
end;
Size := IORec.Position;
finally
IO.Close(Handle);
end;
except
raise UpdateExceptMessage(GetExceptObject, SErrorSavingMemory, [Data, Size, FExtensions[0]]);
end;
end;
function TImageFileFormat.MakeCompatible(const Image: TImageData;
var Compatible: TImageData; out MustBeFreed: Boolean): Boolean;
begin
InitImage(Compatible);
if SaveOverrideFormat <> ifUnknown then
begin
// Save format override is active. Clone input and convert it to override format.
CloneImage(Image, Compatible);
ConvertImage(Compatible, SaveOverrideFormat);
// Now check if override format is supported by file format. If it is not
// then file format specific conversion (virtual method) is called.
Result := IsSupported(Compatible);
if not Result then
begin
ConvertToSupported(Compatible, GetFormatInfo(Compatible.Format));
Result := IsSupported(Compatible);
end;
end // Add IsCompatible function! not only checking by Format
else if IsSupported(Image) then
begin
// No save format override and input is in format supported by this
// file format. Just copy Image's fields to Compatible
Compatible := Image;
Result := True;
end
else
begin
// No override and input's format is not compatible with file format.
// Clone it and the call file format specific conversion (virtual method).
CloneImage(Image, Compatible);
ConvertToSupported(Compatible, GetFormatInfo(Compatible.Format));
Result := IsSupported(Compatible);
end;
// Tell the user that he must free Compatible after he's done with it
// (if necessary).
MustBeFreed := Image.Bits <> Compatible.Bits;
end;
function TImageFileFormat.TestFormat(Handle: TImagingHandle): Boolean;
begin
Result := False;
end;
function TImageFileFormat.TestFileName(const FileName: string): Boolean;
var
I: LongInt;
OnlyName: string;
begin
OnlyName := ExtractFileName(FileName);
// For each mask test if filename matches it
for I := 0 to FMasks.Count - 1 do
if StrMaskMatch(OnlyName, FMasks[I], False) then
begin
Result := True;
Exit;
end;
Result := False;
end;
procedure TImageFileFormat.CheckOptionsValidity;
begin
end;
function TImageFileFormat.GetCanLoad: Boolean;
begin
Result := ffLoad in FFeatures;
end;
function TImageFileFormat.GetCanSave: Boolean;
begin
Result := ffSave in FFeatures;
end;
function TImageFileFormat.GetIsMultiImageFormat: Boolean;
begin
Result := ffMultiImage in FFeatures;
end;
function TImageFileFormat.GetSaveOpenMode: TOpenMode;
begin
// TODO: fix
//if ffReadOnSave in FFeatures then
// Result := omReadWrite
//else
Result := omCreate;
end;
{ TOptionStack class implementation }
constructor TOptionStack.Create;
begin
inherited Create;
FPosition := -1;
end;
destructor TOptionStack.Destroy;
var
I: LongInt;
begin
for I := 0 to OptionStackDepth - 1 do
SetLength(FStack[I], 0);
inherited Destroy;
end;
function TOptionStack.Pop: Boolean;
var
I: LongInt;
begin
Result := False;
if FPosition >= 0 then
begin
SetLength(Options, Length(FStack[FPosition]));
for I := 0 to Length(FStack[FPosition]) - 1 do
if Options[I] <> nil then
Options[I]^ := FStack[FPosition, I];
Dec(FPosition);
Result := True;
end;
end;
function TOptionStack.Push: Boolean;
var
I: LongInt;
begin
Result := False;
if FPosition < OptionStackDepth - 1 then
begin
Inc(FPosition);
SetLength(FStack[FPosition], Length(Options));
for I := 0 to Length(Options) - 1 do
if Options[I] <> nil then
FStack[FPosition, I] := Options[I]^;
Result := True;
end;
end;
{ TMetadata }
procedure TMetadata.SetMetaItem(const Id: string; const Value: Variant;
ImageIndex: Integer);
begin
AddMetaToList(FLoadMetaItems, Id, Value, ImageIndex);
end;
procedure TMetadata.SetMetaItemForSaving(const Id: string; const Value: Variant;
ImageIndex: Integer);
begin
AddMetaToList(FSaveMetaItems, Id, Value, ImageIndex);
end;
procedure TMetadata.AddMetaToList(List: TStringList; const Id: string;
const Value: Variant; ImageIndex: Integer);
var
Item: TMetadataItem;
Idx: Integer;
FullId: string;
begin
FullId := GetMetaItemName(Id, ImageIndex);
if List.Find(FullId, Idx) then
(List.Objects[Idx] as TMetadataItem).Value := Value
else
begin
Item := TMetadataItem.Create;
Item.Id := Id;
Item.ImageIndex := ImageIndex;
Item.Value := Value;
List.AddObject(FullId, Item);
end;
end;
procedure TMetadata.ClearMetaItems;
begin
ClearMetaList(FLoadMetaItems);
end;
procedure TMetadata.ClearMetaItemsForSaving;
begin
ClearMetaList(FSaveMetaItems);
end;
procedure TMetadata.ClearMetaList(List: TStringList);
var
I: Integer;
begin
for I := 0 to List.Count - 1 do
List.Objects[I].Free;
List.Clear;
end;
procedure TMetadata.CopyLoadedMetaItemsForSaving;
var
I: Integer;
Copy, Orig: TMetadataItem;
begin
ClearMetaItemsForSaving;
for I := 0 to FLoadMetaItems.Count - 1 do
begin
Orig := TMetadataItem(FLoadMetaItems.Objects[I]);
Copy := TMetadataItem.Create;
Copy.Id := Orig.Id;
Copy.ImageIndex := Orig.ImageIndex;
Copy.Value := Orig.Value;
FSaveMetaItems.AddObject(GetMetaItemName(Copy.Id, Copy.ImageIndex), Copy);
end;
end;
constructor TMetadata.Create;
begin
inherited;
FLoadMetaItems := TStringList.Create;
FLoadMetaItems.Sorted := True;
FSaveMetaItems := TStringList.Create;
FSaveMetaItems.Sorted := True;
end;
destructor TMetadata.Destroy;
begin
ClearMetaItems;
ClearMetaItemsForSaving;
FLoadMetaItems.Free;
FSaveMetaItems.Free;
inherited;
end;
function TMetadata.GetMetaById(const Id: string): Variant;
var
Idx: Integer;
begin
if FLoadMetaItems.Find(Id, Idx) then
Result := (FLoadMetaItems.Objects[Idx] as TMetadataItem).Value
else
Result := Variants.Null;
end;
function TMetadata.GetMetaByIdMulti(const Id: string; ImageIndex: Integer): Variant;
begin
Result := GetMetaById(GetMetaItemName(Id, ImageIndex));
end;
function TMetadata.GetSaveMetaById(const Id: string): Variant;
var
Idx: Integer;
begin
if FSaveMetaItems.Find(Id, Idx) then
Result := (FSaveMetaItems.Objects[Idx] as TMetadataItem).Value
else
Result := Variants.Null;
end;
function TMetadata.GetSaveMetaByIdMulti(const Id: string;
ImageIndex: Integer): Variant;
begin
Result := GetSaveMetaById(GetMetaItemName(Id, ImageIndex));
end;
function TMetadata.GetMetaByIdx(Index: Integer): TMetadataItem;
begin
Result := FLoadMetaItems.Objects[Index] as TMetadataItem;
end;
function TMetadata.GetMetaCount: Integer;
begin
Result := FLoadMetaItems.Count;
end;
function TMetadata.GetMetaItemName(const Id: string;
ImageIndex: Integer): string;
begin
Result := Iff(ImageIndex = 0, Id, Format(SMetaIdForSubImage, [Id, ImageIndex]));
end;
function TMetadata.GetPhysicalPixelSize(ResUnit: TResolutionUnit; var XSize,
YSize: Single; MetaForSave: Boolean; ImageIndex: Integer): Boolean;
type
TGetter = function(const Id: string; ImageIndex: Integer): Variant of object;
var
Getter: TGetter;
XMeta, YMeta: Variant;
begin
if MetaForSave then
Getter := GetSaveMetaByIdMulti
else
Getter := GetMetaByIdMulti;
XMeta := Getter(SMetaPhysicalPixelSizeX, ImageIndex);
YMeta := Getter(SMetaPhysicalPixelSizeY, ImageIndex);
XSize := -1;
YSize := -1;
Result := not VarIsNull(XMeta) or not VarIsNull(YMeta);
if not Result then
Exit;
if not VarIsNull(XMeta) then
XSize := XMeta;
if not VarIsNull(YMeta) then
YSize := YMeta;
if XSize < 0 then
XSize := YSize;
if YSize < 0 then
YSize := XSize;
TranslateUnits(ResUnit, XSize, YSize);
end;
procedure TMetadata.SetPhysicalPixelSize(ResUnit: TResolutionUnit; XSize,
YSize: Single; MetaForSave: Boolean; ImageIndex: Integer);
type
TAdder = procedure(const Id: string; const Value: Variant; ImageIndex: Integer) of object;
var
Adder: TAdder;
begin
TranslateUnits(ResUnit, XSize, YSize);
if MetaForSave then
Adder := SetMetaItemForSaving
else
Adder := SetMetaItem;
Adder(SMetaPhysicalPixelSizeX, XSize, ImageIndex);
Adder(SMetaPhysicalPixelSizeY, YSize, ImageIndex);
end;
procedure TMetadata.TranslateUnits(ResolutionUnit: TResolutionUnit; var XRes,
YRes: Single);
var
UnitSize: Single;
begin
case ResolutionUnit of
ruDpi: UnitSize := 25400;
ruDpm: UnitSize := 1e06;
ruDpcm: UnitSize := 1e04;
else
UnitSize := 1;
end;
if ResolutionUnit <> ruSizeInMicroMeters then
begin
XRes := UnitSize / XRes;
YRes := UnitSize / YRes;
end;
end;
function TMetadata.HasMetaItem(const Id: string; ImageIndex: Integer): Boolean;
begin
Result := GetMetaByIdMulti(Id, ImageIndex) <> Variants.Null;
end;
function TMetadata.HasMetaItemForSaving(const Id: string; ImageIndex: Integer): Boolean;
begin
Result := GetSaveMetaByIdMulti(Id, ImageIndex) <> Variants.Null;
end;
initialization
{$IFDEF MEMCHECK}
{$IF CompilerVersion >= 18}
System.ReportMemoryLeaksOnShutdown := True;
{$IFEND}
{$ENDIF}
if GlobalMetadata = nil then
GlobalMetadata := TMetadata.Create;
if ImageFileFormats = nil then
ImageFileFormats := TList.Create;
InitImageFormats;
RegisterOption(ImagingColorReductionMask, @ColorReductionMask);
RegisterOption(ImagingLoadOverrideFormat, @LoadOverrideFormat);
RegisterOption(ImagingSaveOverrideFormat, @SaveOverrideFormat);
RegisterOption(ImagingMipMapFilter, @MipMapFilter);
RegisterOption(ImagingBinaryTreshold, @BinaryTreshold);
finalization
FreeOptions;
FreeImageFileFormats;
GlobalMetadata.Free;
{
File Notes:
-- TODOS ----------------------------------------------------
- nothing now
-- 0.80 ------------------------------------------------------
- Added new color records constructor functions (Color24(..), Color32(..)).
- Added convenience channel getters for TColor32 (GetGreenValue, ...).
-- 0.77.1 ---------------------------------------------------
- Updated IO Open functions according to changes in ImagingTypes.
- Fixed bug in SplitImage that could cause wrong size of edge chunks.
- Metadata support fixes and extensions (frame delays, animation loops).
-- 0.26.5 Changes/Bug Fixes ---------------------------------
- Started reworking exception raising to keep the original class type
(e.g. in NewImage EOutOfMemory could be raised but was hidden
by EImagingError raised afterwards in NewImage try/except).
- Fixed possible AV in Rotate45 subproc of RotateImage.
- Added ReadRawXXX and WriteRawXXX functions for raw image bits IO.
- Implemented ImagingBinaryTreshold option.
- Added support for simple image metadata loading/saving.
- Moved file format definition (name, exts, caps, ...) from
constructor to new Define method.
- Fixed some memory leaks caused by failures during image loading.
-- 0.26.3 Changes/Bug Fixes ---------------------------------
- Extended RotateImage to allow arbitrary angle rotations.
- Reversed the order file formats list is searched so
if you register a new one it will be found sooner than
built in formats.
- Fixed memory leak in ResizeImage ocurring when resizing
indexed images.
-- 0.26.1 Changes/Bug Fixes ---------------------------------
- Added position/size checks to LoadFromStream functions.
- Changed conditional compilation in impl. uses section to reflect changes
in LINK symbols.
-- 0.24.3 Changes/Bug Fixes ---------------------------------
- GenerateMipMaps now generates all smaller levels from
original big image (better results when using more advanced filters).
Also conversion to compatible image format is now done here not
in FillMipMapLevel (that is called for every mipmap level).
-- 0.23 Changes/Bug Fixes -----------------------------------
- MakePaletteForImages now works correctly for indexed and special format images
- Fixed bug in StretchRect: Image was not properly stretched if
src and dst dimensions differed only in height.
- ConvertImage now fills new image with zeroes to avoid random data in
some conversions (RGB->XRGB)
- Changed RegisterOption procedure to function
- Changed bunch of palette functions from low level interface to procedure
(there was no reason for them to be functions).
- Changed FreeImage and FreeImagesInArray functions to procedures.
- Added many assertions, come try-finally, other checks, and small code
and doc changes.
-- 0.21 Changes/Bug Fixes -----------------------------------
- GenerateMipMaps threw failed assertion when input was indexed or special,
fixed.
- Added CheckOptionsValidity to TImageFileFormat and its decendants.
- Unit ImagingExtras which registers file formats in Extras package
is now automatically added to uses clause if LINK_EXTRAS symbol is
defined in ImagingOptions.inc file.
- Added EnumFileFormats function to low level interface.
- Fixed bug in SwapChannels which could cause AV when swapping alpha
channel of A8R8G8B8 images.
- Converting loaded images to ImagingOverrideFormat is now done
in PostLoadCheck method to avoid code duplicity.
- Added GetFileFormatCount and GetFileFormatAtIndex functions
- Bug in ConvertImage: if some format was converted to similar format
only with swapped channels (R16G16B16<>B16G16R16) then channels were
swapped correctly but new data format (swapped one) was not set.
- Made TImageFileFormat.MakeCompatible public non-virtual method
(and modified its function). Created new virtual
ConvertToSupported which should be overriden by descendants.
Main reason for doint this is to avoid duplicate code that was in all
TImageFileFormat's descendants.
- Changed TImageFileFormat.GetFormatInfo's result type to TImageFormatInfo.
- Split overloaded FindImageFileFormat functions to
FindImageFileFormatByClass and FindImageFileFormatByExt and created new
FindImageFileFormatByName which operates on whole filenames.
- Function GetExtensionFilterIndex renamed to GetFileNameFilterIndex
(because it now works with filenames not extensions).
- DetermineFileFormat now first searches by filename and if not found
then by data.
- Added TestFileName method to TImageFileFormat.
- Updated GetImageFileFormatsFilter to uses Masks instead of Extensions
property of TImageFileFormat. Also you can now request
OpenDialog and SaveDialog type filters
- Added Masks property and AddMasks method to TImageFileFormat.
AddMasks replaces AddExtensions, it uses filename masks instead
of sime filename extensions to identify supported files.
- Changed TImageFileFormat.LoadData procedure to function and
moved varios duplicate code from its descandats (check index,...)
here to TImageFileFormat helper methods.
- Changed TImageFileFormat.SaveData procedure to function and
moved varios duplicate code from its descandats (check index,...)
here to TImageFileFormat helper methods.
- Removed RAISE_EXCEPTIONS define, exceptions are now raised everytime
- Added MustBeFreed parameter to TImageFileFormat.MakeComptible method
that indicates that compatible image returned by this method must be
freed after its usage.
-- 0.19 Changes/Bug Fixes -----------------------------------
- fixed bug in NewImage: if given format was ifDefault it wasn't
replaced with DefaultImageFormat constant which caused problems later
in other units
- fixed bug in RotateImage which caused that rotated special format
images were whole black
- LoadImageFromXXX and LoadMultiImageFromXXX now use DetermineXXXFormat
when choosing proper loader, this eliminated need for Ext parameter
in stream and memory loading functions
- added GetVersionStr function
- fixed bug in ResizeImage which caued indexed images to lose their
palette during process resulting in whole black image
- Clipping in ...Rect functions now uses clipping procs from ImagingUtility,
it also works better
- FillRect optimization for 8, 16, and 32 bit formats
- added pixel set/get functions to low level interface:
GetPixelDirect, SetPixelDirect, GetPixel32, SetPixel32,
GetPixelFP, SetPixelFP
- removed GetPixelBytes low level intf function - redundant
(same data can be obtained by GetImageFormatInfo)
- made small changes in many parts of library to compile
on AMD64 CPU (Linux with FPC)
- changed InitImage to procedure (function was pointless)
- Method TestFormat of TImageFileFormat class made public
(was protected)
- added function IsFileFormatSupported to low level interface
(contributed by Paul Michell)
- fixed some missing format arguments from error strings
which caused Format function to raise exception
- removed forgotten debug code that disabled filtered resizing of images with
channel bitcounts > 8
-- 0.17 Changes/Bug Fixes -----------------------------------
- changed order of parameters of CopyRect function
- GenerateMipMaps now filters mipmap levels
- ResizeImage functions was extended to allow bilinear and bicubic filtering
- added StretchRect function to low level interface
- added functions GetImageFileFormatsFilter, GetFilterIndexExtension,
and GetExtensionFilterIndex
-- 0.15 Changes/Bug Fixes -----------------------------------
- added function RotateImage to low level interface
- moved TImageFormatInfo record and types required by it to
ImagingTypes unit, changed GetImageFormatInfo low level
interface function to return TImageFormatInfo instead of short info
- added checking of options values validity before they are used
- fixed possible memory leak in CloneImage
- added ReplaceColor function to low level interface
- new function FindImageFileFormat by class added
-- 0.13 Changes/Bug Fixes -----------------------------------
- added DetermineFileFormat, DetermineStreamFormat, DetermineMemoryFormat,
GetPixelsSize functions to low level interface
- added NewPalette, CopyPalette, FreePalette functions
to low level interface
- added MapImageToPalette, FillRect, SplitImage, MakePaletteForImages
functions to low level interface
- fixed buggy FillCustomPalette function (possible div by zero and others)
- added CopyRect function to low level interface
- Member functions of TImageFormatInfo record implemented for all formats
- before saving images TestImagesInArray is called now
- added TestImagesInArray function to low level interface
- added GenerateMipMaps function to low level interface
- stream position in load/save from/to stream is now set to position before
function was called if error occurs
- when error occured during load/save from/to file file handle
was not released
- CloneImage returned always False
}
end.