/* [<][>][^][v][top][bottom][index][help] */
// This may look like C code, but it is really -*- C++ -*-
//
// Copyright Bob Friesenhahn, 1999, 2000, 2001, 2002, 2003
//
// Definition and implementation of template functions for using
// Magick::Image with STL containers.
//
#ifndef Magick_STL_header
#define Magick_STL_header
#include "Magick++/Include.h"
#include <algorithm>
#include <functional>
#include <iterator>
#include <map>
#include <utility>
#include "Magick++/CoderInfo.h"
#include "Magick++/Drawable.h"
#include "Magick++/Exception.h"
#include "Magick++/Montage.h"
namespace Magick
{
//
// STL function object declarations/definitions
//
// Function objects provide the means to invoke an operation on one
// or more image objects in an STL-compatable container. The
// arguments to the function object constructor(s) are compatable
// with the arguments to the equivalent Image class method and
// provide the means to supply these options when the function
// object is invoked.
// For example, to read a GIF animation, set the color red to
// transparent for all frames, and write back out:
//
// list<image> images;
// readImages( &images, "animation.gif" );
// for_each( images.begin(), images.end(), transparentImage( "red" ) );
// writeImages( images.begin(), images.end(), "animation.gif" );
// Adaptive-blur image with specified blur factor
class MagickDLLDecl adaptiveBlurImage : public std::unary_function<Image&,void>
{
public:
adaptiveBlurImage( const double radius_ = 1, const double sigma_ = 0.5 );
void operator()( Image &image_ ) const;
private:
double _radius;
double _sigma;
};
// Local adaptive threshold image
// http://www.dai.ed.ac.uk/HIPR2/adpthrsh.htm
// Width x height define the size of the pixel neighborhood
// offset = constant to subtract from pixel neighborhood mean
class MagickDLLDecl adaptiveThresholdImage : public std::unary_function<Image&,void>
{
public:
adaptiveThresholdImage( const size_t width_,
const size_t height_,
const ::ssize_t offset_ = 0 );
void operator()( Image &image_ ) const;
private:
size_t _width;
size_t _height;
::ssize_t _offset;
};
// Add noise to image with specified noise type
class MagickDLLDecl addNoiseImage : public std::unary_function<Image&,void>
{
public:
addNoiseImage ( NoiseType noiseType_ );
void operator()( Image &image_ ) const;
private:
NoiseType _noiseType;
};
// Transform image by specified affine (or free transform) matrix.
class MagickDLLDecl affineTransformImage : public std::unary_function<Image&,void>
{
public:
affineTransformImage( const DrawableAffine &affine_ );
void operator()( Image &image_ ) const;
private:
DrawableAffine _affine;
};
// Annotate image (draw text on image)
class MagickDLLDecl annotateImage : public std::unary_function<Image&,void>
{
public:
// Annotate using specified text, and placement location
annotateImage ( const std::string &text_,
const Geometry &geometry_ );
// Annotate using specified text, bounding area, and placement
// gravity
annotateImage ( const std::string &text_,
const Geometry &geometry_,
const GravityType gravity_ );
// Annotate with text using specified text, bounding area,
// placement gravity, and rotation.
annotateImage ( const std::string &text_,
const Geometry &geometry_,
const GravityType gravity_,
const double degrees_ );
// Annotate with text (bounding area is entire image) and
// placement gravity.
annotateImage ( const std::string &text_,
const GravityType gravity_ );
void operator()( Image &image_ ) const;
private:
// Copy constructor and assignment are not supported
annotateImage(const annotateImage&);
annotateImage& operator=(const annotateImage&);
const std::string _text;
const Geometry _geometry;
const GravityType _gravity;
const double _degrees;
};
// Blur image with specified blur factor
class MagickDLLDecl blurImage : public std::unary_function<Image&,void>
{
public:
blurImage( const double radius_ = 1, const double sigma_ = 0.5 );
void operator()( Image &image_ ) const;
private:
double _radius;
double _sigma;
};
// Border image (add border to image)
class MagickDLLDecl borderImage : public std::unary_function<Image&,void>
{
public:
borderImage( const Geometry &geometry_ = borderGeometryDefault );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// Extract channel from image
class MagickDLLDecl channelImage : public std::unary_function<Image&,void>
{
public:
channelImage( const ChannelType channel_ );
void operator()( Image &image_ ) const;
private:
ChannelType _channel;
};
// Charcoal effect image (looks like charcoal sketch)
class MagickDLLDecl charcoalImage : public std::unary_function<Image&,void>
{
public:
charcoalImage( const double radius_ = 1, const double sigma_ = 0.5 );
void operator()( Image &image_ ) const;
private:
double _radius;
double _sigma;
};
// Chop image (remove vertical or horizontal subregion of image)
class MagickDLLDecl chopImage : public std::unary_function<Image&,void>
{
public:
chopImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// Accepts a lightweight Color Correction Collection (CCC) file which solely
// contains one or more color corrections and applies the correction to the
// image.
class MagickDLLDecl cdlImage : public std::unary_function<Image&,void>
{
public:
cdlImage( const std::string &cdl_ );
void operator()( Image &image_ ) const;
private:
std::string _cdl;
};
// Colorize image using pen color at specified percent opacity
class MagickDLLDecl colorizeImage : public std::unary_function<Image&,void>
{
public:
colorizeImage( const unsigned int opacityRed_,
const unsigned int opacityGreen_,
const unsigned int opacityBlue_,
const Color &penColor_ );
colorizeImage( const unsigned int opacity_,
const Color &penColor_ );
void operator()( Image &image_ ) const;
private:
unsigned int _opacityRed;
unsigned int _opacityGreen;
unsigned int _opacityBlue;
Color _penColor;
};
// Apply a color matrix to the image channels. The user supplied
// matrix may be of order 1 to 5 (1x1 through 5x5).
class MagickDLLDecl colorMatrixImage : public std::unary_function<Image&,void>
{
public:
colorMatrixImage( const size_t order_,
const double *color_matrix_ );
void operator()( Image &image_ ) const;
private:
size_t _order;
const double *_color_matrix;
};
// Convert the image colorspace representation
class MagickDLLDecl colorSpaceImage : public std::unary_function<Image&,void>
{
public:
colorSpaceImage( ColorspaceType colorSpace_ );
void operator()( Image &image_ ) const;
private:
ColorspaceType _colorSpace;
};
// Comment image (add comment string to image)
class MagickDLLDecl commentImage : public std::unary_function<Image&,void>
{
public:
commentImage( const std::string &comment_ );
void operator()( Image &image_ ) const;
private:
std::string _comment;
};
// Compose an image onto another at specified offset and using
// specified algorithm
class MagickDLLDecl compositeImage : public std::unary_function<Image&,void>
{
public:
compositeImage( const Image &compositeImage_,
::ssize_t xOffset_,
::ssize_t yOffset_,
CompositeOperator compose_ = InCompositeOp );
compositeImage( const Image &compositeImage_,
const Geometry &offset_,
CompositeOperator compose_ = InCompositeOp );
void operator()( Image &image_ ) const;
private:
Image _compositeImage;
::ssize_t _xOffset;
::ssize_t _yOffset;
CompositeOperator _compose;
};
// Contrast image (enhance intensity differences in image)
class MagickDLLDecl contrastImage : public std::unary_function<Image&,void>
{
public:
contrastImage( const size_t sharpen_ );
void operator()( Image &image_ ) const;
private:
size_t _sharpen;
};
// Crop image (subregion of original image)
class MagickDLLDecl cropImage : public std::unary_function<Image&,void>
{
public:
cropImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// Cycle image colormap
class MagickDLLDecl cycleColormapImage : public std::unary_function<Image&,void>
{
public:
cycleColormapImage( const ::ssize_t amount_ );
void operator()( Image &image_ ) const;
private:
::ssize_t _amount;
};
// Despeckle image (reduce speckle noise)
class MagickDLLDecl despeckleImage : public std::unary_function<Image&,void>
{
public:
despeckleImage( void );
void operator()( Image &image_ ) const;
private:
};
// Distort image. distorts an image using various distortion methods, by
// mapping color lookups of the source image to a new destination image
// usally of the same size as the source image, unless 'bestfit' is set to
// true.
class MagickDLLDecl distortImage : public std::unary_function<Image&,void>
{
public:
distortImage( const Magick::DistortImageMethod method_,
const size_t number_arguments_,
const double *arguments_,
const bool bestfit_ );
distortImage( const Magick::DistortImageMethod method_,
const size_t number_arguments_,
const double *arguments_ );
void operator()( Image &image_ ) const;
private:
DistortImageMethod _method;
size_t _number_arguments;
const double *_arguments;
bool _bestfit;
};
// Draw on image
class MagickDLLDecl drawImage : public std::unary_function<Image&,void>
{
public:
// Draw on image using a single drawable
// Store in list to make implementation easier
drawImage( const Drawable &drawable_ );
// Draw on image using a drawable list
drawImage( const DrawableList &drawable_ );
void operator()( Image &image_ ) const;
private:
DrawableList _drawableList;
};
// Edge image (hilight edges in image)
class MagickDLLDecl edgeImage : public std::unary_function<Image&,void>
{
public:
edgeImage( const double radius_ = 0.0 );
void operator()( Image &image_ ) const;
private:
double _radius;
};
// Emboss image (hilight edges with 3D effect)
class MagickDLLDecl embossImage : public std::unary_function<Image&,void>
{
public:
embossImage( void );
embossImage( const double radius_, const double sigma_ );
void operator()( Image &image_ ) const;
private:
double _radius;
double _sigma;
};
// Enhance image (minimize noise)
class MagickDLLDecl enhanceImage : public std::unary_function<Image&,void>
{
public:
enhanceImage( void );
void operator()( Image &image_ ) const;
private:
};
// Equalize image (histogram equalization)
class MagickDLLDecl equalizeImage : public std::unary_function<Image&,void>
{
public:
equalizeImage( void );
void operator()( Image &image_ ) const;
private:
};
// Color to use when filling drawn objects
class MagickDLLDecl fillColorImage : public std::unary_function<Image&,void>
{
public:
fillColorImage( const Color &fillColor_ );
void operator()( Image &image_ ) const;
private:
Color _fillColor;
};
// Flip image (reflect each scanline in the vertical direction)
class MagickDLLDecl flipImage : public std::unary_function<Image&,void>
{
public:
flipImage( void );
void operator()( Image &image_ ) const;
private:
};
// Flood-fill image with color
class MagickDLLDecl floodFillColorImage : public std::unary_function<Image&,void>
{
public:
// Flood-fill color across pixels starting at target-pixel and
// stopping at pixels matching specified border color.
// Uses current fuzz setting when determining color match.
floodFillColorImage( const ::ssize_t x_,
const ::ssize_t y_,
const Color &fillColor_ );
floodFillColorImage( const Geometry &point_,
const Color &fillColor_ );
// Flood-fill color across pixels starting at target-pixel and
// stopping at pixels matching specified border color.
// Uses current fuzz setting when determining color match.
floodFillColorImage( const ::ssize_t x_,
const ::ssize_t y_,
const Color &fillColor_,
const Color &borderColor_ );
floodFillColorImage( const Geometry &point_,
const Color &fillColor_,
const Color &borderColor_ );
void operator()( Image &image_ ) const;
private:
::ssize_t _x;
::ssize_t _y;
Color _fillColor;
Color _borderColor;
};
// Flood-fill image with texture
class MagickDLLDecl floodFillTextureImage : public std::unary_function<Image&,void>
{
public:
// Flood-fill texture across pixels that match the color of the
// target pixel and are neighbors of the target pixel.
// Uses current fuzz setting when determining color match.
floodFillTextureImage( const ::ssize_t x_,
const ::ssize_t y_,
const Image &texture_ );
floodFillTextureImage( const Geometry &point_,
const Image &texture_ );
// Flood-fill texture across pixels starting at target-pixel and
// stopping at pixels matching specified border color.
// Uses current fuzz setting when determining color match.
floodFillTextureImage( const ::ssize_t x_,
const ::ssize_t y_,
const Image &texture_,
const Color &borderColor_ );
floodFillTextureImage( const Geometry &point_,
const Image &texture_,
const Color &borderColor_ );
void operator()( Image &image_ ) const;
private:
::ssize_t _x;
::ssize_t _y;
Image _texture;
Color _borderColor;
};
// Flop image (reflect each scanline in the horizontal direction)
class MagickDLLDecl flopImage : public std::unary_function<Image&,void>
{
public:
flopImage( void );
void operator()( Image &image_ ) const;
private:
};
// Frame image
class MagickDLLDecl frameImage : public std::unary_function<Image&,void>
{
public:
frameImage( const Geometry &geometry_ = frameGeometryDefault );
frameImage( const size_t width_, const size_t height_,
const ::ssize_t innerBevel_ = 6, const ::ssize_t outerBevel_ = 6 );
void operator()( Image &image_ ) const;
private:
size_t _width;
size_t _height;
::ssize_t _outerBevel;
::ssize_t _innerBevel;
};
// Gamma correct image
class MagickDLLDecl gammaImage : public std::unary_function<Image&,void>
{
public:
gammaImage( const double gamma_ );
gammaImage ( const double gammaRed_,
const double gammaGreen_,
const double gammaBlue_ );
void operator()( Image &image_ ) const;
private:
double _gammaRed;
double _gammaGreen;
double _gammaBlue;
};
// Gaussian blur image
// The number of neighbor pixels to be included in the convolution
// mask is specified by 'width_'. The standard deviation of the
// gaussian bell curve is specified by 'sigma_'.
class MagickDLLDecl gaussianBlurImage : public std::unary_function<Image&,void>
{
public:
gaussianBlurImage( const double width_, const double sigma_ );
void operator()( Image &image_ ) const;
private:
double _width;
double _sigma;
};
// Apply a color lookup table (Hald CLUT) to the image.
class MagickDLLDecl haldClutImage : public std::unary_function<Image&,void>
{
public:
haldClutImage( const Image &haldClutImage_ );
void operator()( Image &image_ ) const;
private:
Image _haldClutImage;
};
// Implode image (special effect)
class MagickDLLDecl implodeImage : public std::unary_function<Image&,void>
{
public:
implodeImage( const double factor_ = 50 );
void operator()( Image &image_ ) const;
private:
double _factor;
};
// implements the inverse discrete Fourier transform (IFT) of the image
// either as a magnitude / phase or real / imaginary image pair.
class MagickDLLDecl inverseFourierTransformImage : public std::unary_function<Image&,void>
{
public:
inverseFourierTransformImage( const Image &phaseImage_ );
void operator()( Image &image_ ) const;
private:
Image _phaseImage;
};
// Set image validity. Valid images become empty (inValid) if
// argument is false.
class MagickDLLDecl isValidImage : public std::unary_function<Image&,void>
{
public:
isValidImage( const bool isValid_ );
void operator()( Image &image_ ) const;
private:
bool _isValid;
};
// Label image
class MagickDLLDecl labelImage : public std::unary_function<Image&,void>
{
public:
labelImage( const std::string &label_ );
void operator()( Image &image_ ) const;
private:
std::string _label;
};
// Level image
class MagickDLLDecl levelImage : public std::unary_function<Image&,void>
{
public:
levelImage( const double black_point,
const double white_point,
const double mid_point=1.0 );
void operator()( Image &image_ ) const;
private:
double _black_point;
double _white_point;
double _mid_point;
};
// Level image channel
class MagickDLLDecl levelChannelImage : public std::unary_function<Image&,void>
{
public:
levelChannelImage( const Magick::ChannelType channel,
const double black_point,
const double white_point,
const double mid_point=1.0 );
void operator()( Image &image_ ) const;
private:
Magick::ChannelType _channel;
double _black_point;
double _white_point;
double _mid_point;
};
// Magnify image by integral size
class MagickDLLDecl magnifyImage : public std::unary_function<Image&,void>
{
public:
magnifyImage( void );
void operator()( Image &image_ ) const;
private:
};
// Remap image colors with closest color from reference image
class MagickDLLDecl mapImage : public std::unary_function<Image&,void>
{
public:
mapImage( const Image &mapImage_ ,
const bool dither_ = false );
void operator()( Image &image_ ) const;
private:
Image _mapImage;
bool _dither;
};
// Floodfill designated area with a matte value
class MagickDLLDecl matteFloodfillImage : public std::unary_function<Image&,void>
{
public:
matteFloodfillImage( const Color &target_ ,
const unsigned int matte_,
const ::ssize_t x_, const ::ssize_t y_,
const PaintMethod method_ );
void operator()( Image &image_ ) const;
private:
Color _target;
unsigned int _matte;
::ssize_t _x;
::ssize_t _y;
PaintMethod _method;
};
// Filter image by replacing each pixel component with the median
// color in a circular neighborhood
class MagickDLLDecl medianFilterImage : public std::unary_function<Image&,void>
{
public:
medianFilterImage( const double radius_ = 0.0 );
void operator()( Image &image_ ) const;
private:
double _radius;
};
// Reduce image by integral size
class MagickDLLDecl minifyImage : public std::unary_function<Image&,void>
{
public:
minifyImage( void );
void operator()( Image &image_ ) const;
private:
};
// Modulate percent hue, saturation, and brightness of an image
class MagickDLLDecl modulateImage : public std::unary_function<Image&,void>
{
public:
modulateImage( const double brightness_,
const double saturation_,
const double hue_ );
void operator()( Image &image_ ) const;
private:
double _brightness;
double _saturation;
double _hue;
};
// Negate colors in image. Set grayscale to only negate grayscale
// values in image.
class MagickDLLDecl negateImage : public std::unary_function<Image&,void>
{
public:
negateImage( const bool grayscale_ = false );
void operator()( Image &image_ ) const;
private:
bool _grayscale;
};
// Normalize image (increase contrast by normalizing the pixel
// values to span the full range of color values)
class MagickDLLDecl normalizeImage : public std::unary_function<Image&,void>
{
public:
normalizeImage( void );
void operator()( Image &image_ ) const;
private:
};
// Oilpaint image (image looks like oil painting)
class MagickDLLDecl oilPaintImage : public std::unary_function<Image&,void>
{
public:
oilPaintImage( const double radius_ = 3 );
void operator()( Image &image_ ) const;
private:
double _radius;
};
// Set or attenuate the image opacity channel. If the image pixels
// are opaque then they are set to the specified opacity value,
// otherwise they are blended with the supplied opacity value. The
// value of opacity_ ranges from 0 (completely opaque) to
// QuantumRange. The defines OpaqueOpacity and TransparentOpacity are
// available to specify completely opaque or completely transparent,
// respectively.
class MagickDLLDecl opacityImage : public std::unary_function<Image&,void>
{
public:
opacityImage( const unsigned int opacity_ );
void operator()( Image &image_ ) const;
private:
unsigned int _opacity;
};
// Change color of opaque pixel to specified pen color.
class MagickDLLDecl opaqueImage : public std::unary_function<Image&,void>
{
public:
opaqueImage( const Color &opaqueColor_,
const Color &penColor_ );
void operator()( Image &image_ ) const;
private:
Color _opaqueColor;
Color _penColor;
};
// Quantize image (reduce number of colors)
class MagickDLLDecl quantizeImage : public std::unary_function<Image&,void>
{
public:
quantizeImage( const bool measureError_ = false );
void operator()( Image &image_ ) const;
private:
bool _measureError;
};
// Raise image (lighten or darken the edges of an image to give a
// 3-D raised or lowered effect)
class MagickDLLDecl raiseImage : public std::unary_function<Image&,void>
{
public:
raiseImage( const Geometry &geometry_ = raiseGeometryDefault,
const bool raisedFlag_ = false );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
bool _raisedFlag;
};
// Reduce noise in image using a noise peak elimination filter
class MagickDLLDecl reduceNoiseImage : public std::unary_function<Image&,void>
{
public:
reduceNoiseImage( void );
reduceNoiseImage (const size_t order_ );
void operator()( Image &image_ ) const;
private:
size_t _order;
};
// Resize image to specified size.
class MagickDLLDecl resizeImage : public std::unary_function<Image&,void>
{
public:
resizeImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// Roll image (rolls image vertically and horizontally) by specified
// number of columnms and rows)
class MagickDLLDecl rollImage : public std::unary_function<Image&,void>
{
public:
rollImage( const Geometry &roll_ );
rollImage( const ::ssize_t columns_, const ::ssize_t rows_ );
void operator()( Image &image_ ) const;
private:
size_t _columns;
size_t _rows;
};
// Rotate image counter-clockwise by specified number of degrees.
class MagickDLLDecl rotateImage : public std::unary_function<Image&,void>
{
public:
rotateImage( const double degrees_ );
void operator()( Image &image_ ) const;
private:
double _degrees;
};
// Resize image by using pixel sampling algorithm
class MagickDLLDecl sampleImage : public std::unary_function<Image&,void>
{
public:
sampleImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// Resize image by using simple ratio algorithm
class MagickDLLDecl scaleImage : public std::unary_function<Image&,void>
{
public:
scaleImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// Segment (coalesce similar image components) by analyzing the
// histograms of the color components and identifying units that are
// homogeneous with the fuzzy c-means technique.
// Also uses QuantizeColorSpace and Verbose image attributes
class MagickDLLDecl segmentImage : public std::unary_function<Image&,void>
{
public:
segmentImage( const double clusterThreshold_ = 1.0,
const double smoothingThreshold_ = 1.5 );
void operator()( Image &image_ ) const;
private:
double _clusterThreshold;
double _smoothingThreshold;
};
// Shade image using distant light source
class MagickDLLDecl shadeImage : public std::unary_function<Image&,void>
{
public:
shadeImage( const double azimuth_ = 30,
const double elevation_ = 30,
const bool colorShading_ = false );
void operator()( Image &image_ ) const;
private:
double _azimuth;
double _elevation;
bool _colorShading;
};
// Sharpen pixels in image
class MagickDLLDecl sharpenImage : public std::unary_function<Image&,void>
{
public:
sharpenImage( const double radius_ = 1, const double sigma_ = 0.5 );
void operator()( Image &image_ ) const;
private:
double _radius;
double _sigma;
};
// Shave pixels from image edges.
class MagickDLLDecl shaveImage : public std::unary_function<Image&,void>
{
public:
shaveImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// Shear image (create parallelogram by sliding image by X or Y axis)
class MagickDLLDecl shearImage : public std::unary_function<Image&,void>
{
public:
shearImage( const double xShearAngle_,
const double yShearAngle_ );
void operator()( Image &image_ ) const;
private:
double _xShearAngle;
double _yShearAngle;
};
// Solarize image (similar to effect seen when exposing a
// photographic film to light during the development process)
class MagickDLLDecl solarizeImage : public std::unary_function<Image&,void>
{
public:
solarizeImage( const double factor_ );
void operator()( Image &image_ ) const;
private:
double _factor;
};
// Splice the background color into the image.
class MagickDLLDecl spliceImage : public std::unary_function<Image&,void>
{
public:
spliceImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// Spread pixels randomly within image by specified ammount
class MagickDLLDecl spreadImage : public std::unary_function<Image&,void>
{
public:
spreadImage( const size_t amount_ = 3 );
void operator()( Image &image_ ) const;
private:
size_t _amount;
};
// Add a digital watermark to the image (based on second image)
class MagickDLLDecl steganoImage : public std::unary_function<Image&,void>
{
public:
steganoImage( const Image &waterMark_ );
void operator()( Image &image_ ) const;
private:
Image _waterMark;
};
// Create an image which appears in stereo when viewed with red-blue glasses
// (Red image on left, blue on right)
class MagickDLLDecl stereoImage : public std::unary_function<Image&,void>
{
public:
stereoImage( const Image &rightImage_ );
void operator()( Image &image_ ) const;
private:
Image _rightImage;
};
// Color to use when drawing object outlines
class MagickDLLDecl strokeColorImage : public std::unary_function<Image&,void>
{
public:
strokeColorImage( const Color &strokeColor_ );
void operator()( Image &image_ ) const;
private:
Color _strokeColor;
};
// Swirl image (image pixels are rotated by degrees)
class MagickDLLDecl swirlImage : public std::unary_function<Image&,void>
{
public:
swirlImage( const double degrees_ );
void operator()( Image &image_ ) const;
private:
double _degrees;
};
// Channel a texture on image background
class MagickDLLDecl textureImage : public std::unary_function<Image&,void>
{
public:
textureImage( const Image &texture_ );
void operator()( Image &image_ ) const;
private:
Image _texture;
};
// Threshold image
class MagickDLLDecl thresholdImage : public std::unary_function<Image&,void>
{
public:
thresholdImage( const double threshold_ );
void operator()( Image &image_ ) const;
private:
double _threshold;
};
// Transform image based on image and crop geometries
class MagickDLLDecl transformImage : public std::unary_function<Image&,void>
{
public:
transformImage( const Geometry &imageGeometry_ );
transformImage( const Geometry &imageGeometry_,
const Geometry &cropGeometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _imageGeometry;
Geometry _cropGeometry;
};
// Set image color to transparent
class MagickDLLDecl transparentImage : public std::unary_function<Image&,void>
{
public:
transparentImage( const Color& color_ );
void operator()( Image &image_ ) const;
private:
Color _color;
};
// Trim edges that are the background color from the image
class MagickDLLDecl trimImage : public std::unary_function<Image&,void>
{
public:
trimImage( void );
void operator()( Image &image_ ) const;
private:
};
// Map image pixels to a sine wave
class MagickDLLDecl waveImage : public std::unary_function<Image&,void>
{
public:
waveImage( const double amplitude_ = 25.0,
const double wavelength_ = 150.0 );
void operator()( Image &image_ ) const;
private:
double _amplitude;
double _wavelength;
};
// Zoom image to specified size.
class MagickDLLDecl zoomImage : public std::unary_function<Image&,void>
{
public:
zoomImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
//
// Function object image attribute accessors
//
// Anti-alias Postscript and TrueType fonts (default true)
class MagickDLLDecl antiAliasImage : public std::unary_function<Image&,void>
{
public:
antiAliasImage( const bool flag_ );
void operator()( Image &image_ ) const;
private:
bool _flag;
};
// Join images into a single multi-image file
class MagickDLLDecl adjoinImage : public std::unary_function<Image&,void>
{
public:
adjoinImage( const bool flag_ );
void operator()( Image &image_ ) const;
private:
bool _flag;
};
// Time in 1/100ths of a second which must expire before displaying
// the next image in an animated sequence.
class MagickDLLDecl animationDelayImage : public std::unary_function<Image&,void>
{
public:
animationDelayImage( const size_t delay_ );
void operator()( Image &image_ ) const;
private:
size_t _delay;
};
// Number of iterations to loop an animation (e.g. Netscape loop
// extension) for.
class MagickDLLDecl animationIterationsImage : public std::unary_function<Image&,void>
{
public:
animationIterationsImage( const size_t iterations_ );
void operator()( Image &image_ ) const;
private:
size_t _iterations;
};
// Image background color
class MagickDLLDecl backgroundColorImage : public std::unary_function<Image&,void>
{
public:
backgroundColorImage( const Color &color_ );
void operator()( Image &image_ ) const;
private:
Color _color;
};
// Name of texture image to tile onto the image background
class MagickDLLDecl backgroundTextureImage : public std::unary_function<Image&,void>
{
public:
backgroundTextureImage( const std::string &backgroundTexture_ );
void operator()( Image &image_ ) const;
private:
std::string _backgroundTexture;
};
// Image border color
class MagickDLLDecl borderColorImage : public std::unary_function<Image&,void>
{
public:
borderColorImage( const Color &color_ );
void operator()( Image &image_ ) const;
private:
Color _color;
};
// Text bounding-box base color (default none)
class MagickDLLDecl boxColorImage : public std::unary_function<Image&,void>
{
public:
boxColorImage( const Color &boxColor_ );
void operator()( Image &image_ ) const;
private:
Color _boxColor;
};
// Chromaticity blue primary point (e.g. x=0.15, y=0.06)
class MagickDLLDecl chromaBluePrimaryImage : public std::unary_function<Image&,void>
{
public:
chromaBluePrimaryImage( const double x_, const double y_ );
void operator()( Image &image_ ) const;
private:
double _x;
double _y;
};
// Chromaticity green primary point (e.g. x=0.3, y=0.6)
class MagickDLLDecl chromaGreenPrimaryImage : public std::unary_function<Image&,void>
{
public:
chromaGreenPrimaryImage( const double x_, const double y_ );
void operator()( Image &image_ ) const;
private:
double _x;
double _y;
};
// Chromaticity red primary point (e.g. x=0.64, y=0.33)
class MagickDLLDecl chromaRedPrimaryImage : public std::unary_function<Image&,void>
{
public:
chromaRedPrimaryImage( const double x_, const double y_ );
void operator()( Image &image_ ) const;
private:
double _x;
double _y;
};
// Chromaticity white point (e.g. x=0.3127, y=0.329)
class MagickDLLDecl chromaWhitePointImage : public std::unary_function<Image&,void>
{
public:
chromaWhitePointImage( const double x_, const double y_ );
void operator()( Image &image_ ) const;
private:
double _x;
double _y;
};
// Colors within this distance are considered equal
class MagickDLLDecl colorFuzzImage : public std::unary_function<Image&,void>
{
public:
colorFuzzImage( const double fuzz_ );
void operator()( Image &image_ ) const;
private:
double _fuzz;
};
// Color at colormap position index_
class MagickDLLDecl colorMapImage : public std::unary_function<Image&,void>
{
public:
colorMapImage( const size_t index_, const Color &color_ );
void operator()( Image &image_ ) const;
private:
size_t _index;
Color _color;
};
// Composition operator to be used when composition is implicitly used
// (such as for image flattening).
class MagickDLLDecl composeImage : public std::unary_function<Image&,void>
{
public:
composeImage( const CompositeOperator compose_ );
void operator()( Image &image_ ) const;
private:
CompositeOperator _compose;
};
// Compression type
class MagickDLLDecl compressTypeImage : public std::unary_function<Image&,void>
{
public:
compressTypeImage( const CompressionType compressType_ );
void operator()( Image &image_ ) const;
private:
CompressionType _compressType;
};
// Vertical and horizontal resolution in pixels of the image
class MagickDLLDecl densityImage : public std::unary_function<Image&,void>
{
public:
densityImage( const Geometry &geomery_ );
void operator()( Image &image_ ) const;
private:
Geometry _geomery;
};
// Image depth (bits allocated to red/green/blue components)
class MagickDLLDecl depthImage : public std::unary_function<Image&,void>
{
public:
depthImage( const size_t depth_ );
void operator()( Image &image_ ) const;
private:
size_t _depth;
};
// Endianness (LSBEndian like Intel or MSBEndian like SPARC) for image
// formats which support endian-specific options.
class MagickDLLDecl endianImage : public std::unary_function<Image&,void>
{
public:
endianImage( const EndianType endian_ );
void operator()( Image &image_ ) const;
private:
EndianType _endian;
};
// Image file name
class MagickDLLDecl fileNameImage : public std::unary_function<Image&,void>
{
public:
fileNameImage( const std::string &fileName_ );
void operator()( Image &image_ ) const;
private:
std::string _fileName;
};
// Filter to use when resizing image
class MagickDLLDecl filterTypeImage : public std::unary_function<Image&,void>
{
public:
filterTypeImage( const FilterTypes filterType_ );
void operator()( Image &image_ ) const;
private:
FilterTypes _filterType;
};
// Text rendering font
class MagickDLLDecl fontImage : public std::unary_function<Image&,void>
{
public:
fontImage( const std::string &font_ );
void operator()( Image &image_ ) const;
private:
std::string _font;
};
// Font point size
class MagickDLLDecl fontPointsizeImage : public std::unary_function<Image&,void>
{
public:
fontPointsizeImage( const size_t pointsize_ );
void operator()( Image &image_ ) const;
private:
size_t _pointsize;
};
// GIF disposal method
class MagickDLLDecl gifDisposeMethodImage : public std::unary_function<Image&,void>
{
public:
gifDisposeMethodImage( const size_t disposeMethod_ );
void operator()( Image &image_ ) const;
private:
size_t _disposeMethod;
};
// Type of interlacing to use
class MagickDLLDecl interlaceTypeImage : public std::unary_function<Image&,void>
{
public:
interlaceTypeImage( const InterlaceType interlace_ );
void operator()( Image &image_ ) const;
private:
InterlaceType _interlace;
};
// Linewidth for drawing vector objects (default one)
class MagickDLLDecl lineWidthImage : public std::unary_function<Image&,void>
{
public:
lineWidthImage( const double lineWidth_ );
void operator()( Image &image_ ) const;
private:
double _lineWidth;
};
// File type magick identifier (.e.g "GIF")
class MagickDLLDecl magickImage : public std::unary_function<Image&,void>
{
public:
magickImage( const std::string &magick_ );
void operator()( Image &image_ ) const;
private:
std::string _magick;
};
// Image supports transparent color
class MagickDLLDecl matteImage : public std::unary_function<Image&,void>
{
public:
matteImage( const bool matteFlag_ );
void operator()( Image &image_ ) const;
private:
bool _matteFlag;
};
// Transparent color
class MagickDLLDecl matteColorImage : public std::unary_function<Image&,void>
{
public:
matteColorImage( const Color &matteColor_ );
void operator()( Image &image_ ) const;
private:
Color _matteColor;
};
// Indicate that image is black and white
class MagickDLLDecl monochromeImage : public std::unary_function<Image&,void>
{
public:
monochromeImage( const bool monochromeFlag_ );
void operator()( Image &image_ ) const;
private:
bool _monochromeFlag;
};
// Pen color
class MagickDLLDecl penColorImage : public std::unary_function<Image&,void>
{
public:
penColorImage( const Color &penColor_ );
void operator()( Image &image_ ) const;
private:
Color _penColor;
};
// Pen texture image.
class MagickDLLDecl penTextureImage : public std::unary_function<Image&,void>
{
public:
penTextureImage( const Image &penTexture_ );
void operator()( Image &image_ ) const;
private:
Image _penTexture;
};
// Set pixel color at location x & y.
class MagickDLLDecl pixelColorImage : public std::unary_function<Image&,void>
{
public:
pixelColorImage( const ::ssize_t x_,
const ::ssize_t y_,
const Color &color_);
void operator()( Image &image_ ) const;
private:
::ssize_t _x;
::ssize_t _y;
Color _color;
};
// Postscript page size.
class MagickDLLDecl pageImage : public std::unary_function<Image&,void>
{
public:
pageImage( const Geometry &pageSize_ );
void operator()( Image &image_ ) const;
private:
Geometry _pageSize;
};
// JPEG/MIFF/PNG compression level (default 75).
class MagickDLLDecl qualityImage : public std::unary_function<Image&,void>
{
public:
qualityImage( const size_t quality_ );
void operator()( Image &image_ ) const;
private:
size_t _quality;
};
// Maximum number of colors to quantize to
class MagickDLLDecl quantizeColorsImage : public std::unary_function<Image&,void>
{
public:
quantizeColorsImage( const size_t colors_ );
void operator()( Image &image_ ) const;
private:
size_t _colors;
};
// Colorspace to quantize in.
class MagickDLLDecl quantizeColorSpaceImage : public std::unary_function<Image&,void>
{
public:
quantizeColorSpaceImage( const ColorspaceType colorSpace_ );
void operator()( Image &image_ ) const;
private:
ColorspaceType _colorSpace;
};
// Dither image during quantization (default true).
class MagickDLLDecl quantizeDitherImage : public std::unary_function<Image&,void>
{
public:
quantizeDitherImage( const bool ditherFlag_ );
void operator()( Image &image_ ) const;
private:
bool _ditherFlag;
};
// Quantization tree-depth
class MagickDLLDecl quantizeTreeDepthImage : public std::unary_function<Image&,void>
{
public:
quantizeTreeDepthImage( const size_t treeDepth_ );
void operator()( Image &image_ ) const;
private:
size_t _treeDepth;
};
// The type of rendering intent
class MagickDLLDecl renderingIntentImage : public std::unary_function<Image&,void>
{
public:
renderingIntentImage( const RenderingIntent renderingIntent_ );
void operator()( Image &image_ ) const;
private:
RenderingIntent _renderingIntent;
};
// Units of image resolution
class MagickDLLDecl resolutionUnitsImage : public std::unary_function<Image&,void>
{
public:
resolutionUnitsImage( const ResolutionType resolutionUnits_ );
void operator()( Image &image_ ) const;
private:
ResolutionType _resolutionUnits;
};
// Image scene number
class MagickDLLDecl sceneImage : public std::unary_function<Image&,void>
{
public:
sceneImage( const size_t scene_ );
void operator()( Image &image_ ) const;
private:
size_t _scene;
};
// adjust the image contrast with a non-linear sigmoidal contrast algorithm
class MagickDLLDecl sigmoidalContrastImage : public std::unary_function<Image&,void>
{
public:
sigmoidalContrastImage( const size_t sharpen_,
const double contrast,
const double midpoint = QuantumRange / 2.0 );
void operator()( Image &image_ ) const;
private:
size_t _sharpen;
double contrast;
double midpoint;
};
// Width and height of a raw image
class MagickDLLDecl sizeImage : public std::unary_function<Image&,void>
{
public:
sizeImage( const Geometry &geometry_ );
void operator()( Image &image_ ) const;
private:
Geometry _geometry;
};
// stripImage strips an image of all profiles and comments.
class MagickDLLDecl stripImage : public std::unary_function<Image&,void>
{
public:
stripImage( void );
void operator()( Image &image_ ) const;
private:
};
// Subimage of an image sequence
class MagickDLLDecl subImageImage : public std::unary_function<Image&,void>
{
public:
subImageImage( const size_t subImage_ );
void operator()( Image &image_ ) const;
private:
size_t _subImage;
};
// Number of images relative to the base image
class MagickDLLDecl subRangeImage : public std::unary_function<Image&,void>
{
public:
subRangeImage( const size_t subRange_ );
void operator()( Image &image_ ) const;
private:
size_t _subRange;
};
// Tile name
class MagickDLLDecl tileNameImage : public std::unary_function<Image&,void>
{
public:
tileNameImage( const std::string &tileName_ );
void operator()( Image &image_ ) const;
private:
std::string _tileName;
};
// Image storage type
class MagickDLLDecl typeImage : public std::unary_function<Image&,void>
{
public:
typeImage( const ImageType type_ );
void operator()( Image &image_ ) const;
private:
Magick::ImageType _type;
};
// Print detailed information about the image
class MagickDLLDecl verboseImage : public std::unary_function<Image&,void>
{
public:
verboseImage( const bool verbose_ );
void operator()( Image &image_ ) const;
private:
bool _verbose;
};
// FlashPix viewing parameters
class MagickDLLDecl viewImage : public std::unary_function<Image&,void>
{
public:
viewImage( const std::string &view_ );
void operator()( Image &image_ ) const;
private:
std::string _view;
};
// X11 display to display to, obtain fonts from, or to capture
// image from
class MagickDLLDecl x11DisplayImage : public std::unary_function<Image&,void>
{
public:
x11DisplayImage( const std::string &display_ );
void operator()( Image &image_ ) const;
private:
std::string _display;
};
//////////////////////////////////////////////////////////
//
// Implementation template definitions. Not for end-use.
//
//////////////////////////////////////////////////////////
// Link images together into an image list based on the ordering of
// the container implied by the iterator. This step is done in
// preparation for use with ImageMagick functions which operate on
// lists of images.
// Images are selected by range, first_ to last_ so that a subset of
// the container may be selected. Specify first_ via the
// container's begin() method and last_ via the container's end()
// method in order to specify the entire container.
template <class InputIterator>
void linkImages( InputIterator first_,
InputIterator last_ ) {
MagickCore::Image* previous = 0;
::ssize_t scene = 0;
for ( InputIterator iter = first_; iter != last_; ++iter )
{
// Unless we reduce the reference count to one, the same image
// structure may occur more than once in the container, causing
// the linked list to fail.
iter->modifyImage();
MagickCore::Image* current = iter->image();
current->previous = previous;
current->next = 0;
if ( previous != 0)
previous->next = current;
current->scene=scene;
++scene;
previous = current;
}
}
// Remove links added by linkImages. This should be called after the
// ImageMagick function call has completed to reset the image list
// back to its pristine un-linked state.
template <class InputIterator>
void unlinkImages( InputIterator first_,
InputIterator last_ ) {
for( InputIterator iter = first_; iter != last_; ++iter )
{
MagickCore::Image* image = iter->image();
image->previous = 0;
image->next = 0;
}
}
// Insert images in image list into existing container (appending to container)
// The images should not be deleted since only the image ownership is passed.
// The options are copied into the object.
template <class Container>
void insertImages( Container *sequence_,
MagickCore::Image* images_ ) {
MagickCore::Image *image = images_;
if ( image )
{
do
{
MagickCore::Image* next_image = image->next;
image->next = 0;
if (next_image != 0)
next_image->previous=0;
sequence_->push_back( Magick::Image( image ) );
image=next_image;
} while( image );
return;
}
}
///////////////////////////////////////////////////////////////////
//
// Template definitions for documented API
//
///////////////////////////////////////////////////////////////////
template <class InputIterator>
void animateImages( InputIterator first_,
InputIterator last_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
linkImages( first_, last_ );
MagickCore::AnimateImages( first_->imageInfo(), first_->image() );
MagickCore::GetImageException( first_->image(), &exceptionInfo );
unlinkImages( first_, last_ );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Append images from list into single image in either horizontal or
// vertical direction.
template <class InputIterator>
void appendImages( Image *appendedImage_,
InputIterator first_,
InputIterator last_,
bool stack_ = false) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
linkImages( first_, last_ );
MagickCore::Image* image = MagickCore::AppendImages( first_->image(),
(MagickBooleanType) stack_,
&exceptionInfo );
unlinkImages( first_, last_ );
appendedImage_->replaceImage( image );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Average a set of images.
// All the input images must be the same size in pixels.
template <class InputIterator>
void averageImages( Image *averagedImage_,
InputIterator first_,
InputIterator last_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
linkImages( first_, last_ );
MagickCore::Image* image = MagickCore::AverageImages( first_->image(),
&exceptionInfo );
unlinkImages( first_, last_ );
averagedImage_->replaceImage( image );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Merge a sequence of images.
// This is useful for GIF animation sequences that have page
// offsets and disposal methods. A container to contain
// the updated image sequence is passed via the coalescedImages_
// option.
template <class InputIterator, class Container >
void coalesceImages( Container *coalescedImages_,
InputIterator first_,
InputIterator last_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
// Build image list
linkImages( first_, last_ );
MagickCore::Image* images = MagickCore::CoalesceImages( first_->image(),
&exceptionInfo);
// Unlink image list
unlinkImages( first_, last_ );
// Ensure container is empty
coalescedImages_->clear();
// Move images to container
insertImages( coalescedImages_, images );
// Report any error
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Return format coders matching specified conditions.
//
// The default (if no match terms are supplied) is to return all
// available format coders.
//
// For example, to return all readable formats:
// list<CoderInfo> coderList;
// coderInfoList( &coderList, CoderInfo::TrueMatch, CoderInfo::AnyMatch, CoderInfo::AnyMatch)
//
template <class Container >
void coderInfoList( Container *container_,
CoderInfo::MatchType isReadable_ = CoderInfo::AnyMatch,
CoderInfo::MatchType isWritable_ = CoderInfo::AnyMatch,
CoderInfo::MatchType isMultiFrame_ = CoderInfo::AnyMatch
) {
// Obtain first entry in MagickInfo list
size_t number_formats;
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
char **coder_list =
MagickCore::GetMagickList( "*", &number_formats, &exceptionInfo );
if( !coder_list )
{
throwException( exceptionInfo );
throwExceptionExplicit(MagickCore::MissingDelegateError,
"Coder array not returned!", 0 );
}
// Clear out container
container_->clear();
for ( ::ssize_t i=0; i < (::ssize_t) number_formats; i++)
{
const MagickCore::MagickInfo *magick_info =
MagickCore::GetMagickInfo( coder_list[i], &exceptionInfo );
coder_list[i]=(char *)
MagickCore::RelinquishMagickMemory( coder_list[i] );
// Skip stealth coders
if ( magick_info->stealth )
continue;
try {
CoderInfo coderInfo( magick_info->name );
// Test isReadable_
if ( isReadable_ != CoderInfo::AnyMatch &&
(( coderInfo.isReadable() && isReadable_ != CoderInfo::TrueMatch ) ||
( !coderInfo.isReadable() && isReadable_ != CoderInfo::FalseMatch )) )
continue;
// Test isWritable_
if ( isWritable_ != CoderInfo::AnyMatch &&
(( coderInfo.isWritable() && isWritable_ != CoderInfo::TrueMatch ) ||
( !coderInfo.isWritable() && isWritable_ != CoderInfo::FalseMatch )) )
continue;
// Test isMultiFrame_
if ( isMultiFrame_ != CoderInfo::AnyMatch &&
(( coderInfo.isMultiFrame() && isMultiFrame_ != CoderInfo::TrueMatch ) ||
( !coderInfo.isMultiFrame() && isMultiFrame_ != CoderInfo::FalseMatch )) )
continue;
// Append matches to container
container_->push_back( coderInfo );
}
// Intentionally ignore missing module errors
catch ( Magick::ErrorModule )
{
continue;
}
}
coder_list=(char **) MagickCore::RelinquishMagickMemory( coder_list );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
//
// Fill container with color histogram.
// Entries are of type "std::pair<Color,size_t>". Use the pair
// "first" member to access the Color and the "second" member to access
// the number of times the color occurs in the image.
//
// For example:
//
// Using <map>:
//
// Image image("image.miff");
// map<Color,size_t> histogram;
// colorHistogram( &histogram, image );
// std::map<Color,size_t>::const_iterator p=histogram.begin();
// while (p != histogram.end())
// {
// cout << setw(10) << (int)p->second << ": ("
// << setw(quantum_width) << (int)p->first.redQuantum() << ","
// << setw(quantum_width) << (int)p->first.greenQuantum() << ","
// << setw(quantum_width) << (int)p->first.blueQuantum() << ")"
// << endl;
// p++;
// }
//
// Using <vector>:
//
// Image image("image.miff");
// std::vector<std::pair<Color,size_t> > histogram;
// colorHistogram( &histogram, image );
// std::vector<std::pair<Color,size_t> >::const_iterator p=histogram.begin();
// while (p != histogram.end())
// {
// cout << setw(10) << (int)p->second << ": ("
// << setw(quantum_width) << (int)p->first.redQuantum() << ","
// << setw(quantum_width) << (int)p->first.greenQuantum() << ","
// << setw(quantum_width) << (int)p->first.blueQuantum() << ")"
// << endl;
// p++;
// }
template <class Container >
void colorHistogram( Container *histogram_, const Image image)
{
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
// Obtain histogram array
size_t colors;
MagickCore::ColorPacket *histogram_array =
MagickCore::GetImageHistogram( image.constImage(), &colors, &exceptionInfo );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
// Clear out container
histogram_->clear();
// Transfer histogram array to container
for ( size_t i=0; i < colors; i++)
{
histogram_->insert(histogram_->end(),std::pair<const Color,size_t>
( Color(histogram_array[i].pixel.red,
histogram_array[i].pixel.green,
histogram_array[i].pixel.blue),
(size_t) histogram_array[i].count) );
}
// Deallocate histogram array
histogram_array=(MagickCore::ColorPacket *)
MagickCore::RelinquishMagickMemory(histogram_array);
}
// Break down an image sequence into constituent parts. This is
// useful for creating GIF or MNG animation sequences.
template <class InputIterator, class Container >
void deconstructImages( Container *deconstructedImages_,
InputIterator first_,
InputIterator last_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
// Build image list
linkImages( first_, last_ );
MagickCore::Image* images = DeconstructImages( first_->image(),
&exceptionInfo);
// Unlink image list
unlinkImages( first_, last_ );
// Ensure container is empty
deconstructedImages_->clear();
// Move images to container
insertImages( deconstructedImages_, images );
// Report any error
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
//
// Display an image sequence
//
template <class InputIterator>
void displayImages( InputIterator first_,
InputIterator last_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
linkImages( first_, last_ );
MagickCore::DisplayImages( first_->imageInfo(), first_->image() );
MagickCore::GetImageException( first_->image(), &exceptionInfo );
unlinkImages( first_, last_ );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Merge a sequence of image frames which represent image layers.
// This is useful for combining Photoshop layers into a single image.
template <class InputIterator>
void flattenImages( Image *flattendImage_,
InputIterator first_,
InputIterator last_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
linkImages( first_, last_ );
MagickCore::Image* image = MagickCore::MergeImageLayers( first_->image(),
FlattenLayer,&exceptionInfo );
unlinkImages( first_, last_ );
flattendImage_->replaceImage( image );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Implements the discrete Fourier transform (DFT) of the image either as a
// magnitude / phase or real / imaginary image pair.
template <class Container >
void forwardFourierTransformImage( Container *fourierImages_,
const Image &image_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
// Build image list
MagickCore::Image* images = ForwardFourierTransformImage(
image_.constImage(), MagickTrue, &exceptionInfo);
// Ensure container is empty
fourierImages_->clear();
// Move images to container
insertImages( fourierImages_, images );
// Report any error
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
template <class Container >
void forwardFourierTransformImage( Container *fourierImages_,
const Image &image_, const bool magnitude_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
// Build image list
MagickCore::Image* images = ForwardFourierTransformImage(
image_.constImage(), magnitude_ == true ? MagickTrue : MagickFalse,
&exceptionInfo);
// Ensure container is empty
fourierImages_->clear();
// Move images to container
insertImages( fourierImages_, images );
// Report any error
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Replace the colors of a sequence of images with the closest color
// from a reference image.
// Set dither_ to true to enable dithering. Set measureError_ to
// true in order to evaluate quantization error.
template <class InputIterator>
void mapImages( InputIterator first_,
InputIterator last_,
const Image& mapImage_,
bool dither_ = false,
bool measureError_ = false ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
MagickCore::QuantizeInfo quantizeInfo;
MagickCore::GetQuantizeInfo( &quantizeInfo );
quantizeInfo.dither = dither_ ? MagickCore::MagickTrue : MagickCore::MagickFalse;
linkImages( first_, last_ );
MagickCore::RemapImages( &quantizeInfo, first_->image(),
mapImage_.constImage());
MagickCore::GetImageException( first_->image(), &exceptionInfo );
if ( exceptionInfo.severity != MagickCore::UndefinedException )
{
unlinkImages( first_, last_ );
throwException( exceptionInfo );
}
MagickCore::Image* image = first_->image();
while( image )
{
// Calculate quantization error
if ( measureError_ )
{
MagickCore::GetImageQuantizeError( image );
if ( image->exception.severity > MagickCore::UndefinedException )
{
unlinkImages( first_, last_ );
throwException( exceptionInfo );
}
}
// Udate DirectClass representation of pixels
MagickCore::SyncImage( image );
if ( image->exception.severity > MagickCore::UndefinedException )
{
unlinkImages( first_, last_ );
throwException( exceptionInfo );
}
// Next image
image=image->next;
}
unlinkImages( first_, last_ );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Create a composite image by combining several separate images.
template <class Container, class InputIterator>
void montageImages( Container *montageImages_,
InputIterator first_,
InputIterator last_,
const Montage &montageOpts_ ) {
MagickCore::MontageInfo* montageInfo =
static_cast<MagickCore::MontageInfo*>(MagickCore::AcquireMagickMemory(sizeof(MagickCore::MontageInfo)));
// Update montage options with those set in montageOpts_
montageOpts_.updateMontageInfo( *montageInfo );
// Update options which must transfer to image options
if ( montageOpts_.label().length() != 0 )
first_->label( montageOpts_.label() );
// Create linked image list
linkImages( first_, last_ );
// Reset output container to pristine state
montageImages_->clear();
// Do montage
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
MagickCore::Image *images = MagickCore::MontageImages( first_->image(),
montageInfo,
&exceptionInfo );
if ( images != 0 )
{
insertImages( montageImages_, images );
}
// Clean up any allocated data in montageInfo
MagickCore::DestroyMontageInfo( montageInfo );
// Unlink linked image list
unlinkImages( first_, last_ );
// Report any montage error
throwException( exceptionInfo );
// Apply transparency to montage images
if ( montageImages_->size() > 0 && montageOpts_.transparentColor().isValid() )
{
for_each( first_, last_, transparentImage( montageOpts_.transparentColor() ) );
}
// Report any transparentImage() error
MagickCore::GetImageException( first_->image(), &exceptionInfo );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Morph a set of images
template <class InputIterator, class Container >
void morphImages( Container *morphedImages_,
InputIterator first_,
InputIterator last_,
size_t frames_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
// Build image list
linkImages( first_, last_ );
MagickCore::Image* images = MagickCore::MorphImages( first_->image(), frames_,
&exceptionInfo);
// Unlink image list
unlinkImages( first_, last_ );
// Ensure container is empty
morphedImages_->clear();
// Move images to container
insertImages( morphedImages_, images );
// Report any error
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Inlay a number of images to form a single coherent picture.
template <class InputIterator>
void mosaicImages( Image *mosaicImage_,
InputIterator first_,
InputIterator last_ ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
linkImages( first_, last_ );
MagickCore::Image* image = MagickCore::MergeImageLayers( first_->image(),
MosaicLayer,&exceptionInfo );
unlinkImages( first_, last_ );
mosaicImage_->replaceImage( image );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Quantize colors in images using current quantization settings
// Set measureError_ to true in order to measure quantization error
template <class InputIterator>
void quantizeImages( InputIterator first_,
InputIterator last_,
bool measureError_ = false ) {
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
linkImages( first_, last_ );
MagickCore::QuantizeImages( first_->quantizeInfo(),
first_->image() );
MagickCore::GetImageException( first_->image(), &exceptionInfo );
if ( exceptionInfo.severity > MagickCore::UndefinedException )
{
unlinkImages( first_, last_ );
throwException( exceptionInfo );
}
MagickCore::Image* image = first_->image();
while( image != 0 )
{
// Calculate quantization error
if ( measureError_ )
MagickCore::GetImageQuantizeError( image );
// Update DirectClass representation of pixels
MagickCore::SyncImage( image );
// Next image
image=image->next;
}
unlinkImages( first_, last_ );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Read images into existing container (appending to container)
// FIXME: need a way to specify options like size, depth, and density.
template <class Container>
void readImages( Container *sequence_,
const std::string &imageSpec_ ) {
MagickCore::ImageInfo *imageInfo = MagickCore::CloneImageInfo(0);
imageSpec_.copy( imageInfo->filename, MaxTextExtent-1 );
imageInfo->filename[ imageSpec_.length() ] = 0;
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
MagickCore::Image* images = MagickCore::ReadImage( imageInfo, &exceptionInfo );
MagickCore::DestroyImageInfo(imageInfo);
insertImages( sequence_, images);
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
template <class Container>
void readImages( Container *sequence_,
const Blob &blob_ ) {
MagickCore::ImageInfo *imageInfo = MagickCore::CloneImageInfo(0);
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
MagickCore::Image *images = MagickCore::BlobToImage( imageInfo,
blob_.data(),
blob_.length(), &exceptionInfo );
MagickCore::DestroyImageInfo(imageInfo);
insertImages( sequence_, images );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Write Images
template <class InputIterator>
void writeImages( InputIterator first_,
InputIterator last_,
const std::string &imageSpec_,
bool adjoin_ = true ) {
first_->adjoin( adjoin_ );
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
linkImages( first_, last_ );
::ssize_t errorStat = MagickCore::WriteImages( first_->constImageInfo(),
first_->image(),
imageSpec_.c_str(),
&exceptionInfo );
unlinkImages( first_, last_ );
if ( errorStat != false )
{
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
return;
}
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
// Write images to BLOB
template <class InputIterator>
void writeImages( InputIterator first_,
InputIterator last_,
Blob *blob_,
bool adjoin_ = true) {
first_->adjoin( adjoin_ );
linkImages( first_, last_ );
MagickCore::ExceptionInfo exceptionInfo;
MagickCore::GetExceptionInfo( &exceptionInfo );
size_t length = 2048; // Efficient size for small images
void* data = MagickCore::ImagesToBlob( first_->imageInfo(),
first_->image(),
&length,
&exceptionInfo);
blob_->updateNoCopy( data, length, Magick::Blob::MallocAllocator );
unlinkImages( first_, last_ );
throwException( exceptionInfo );
(void) MagickCore::DestroyExceptionInfo( &exceptionInfo );
}
} // namespace Magick
#endif // Magick_STL_header