Prima::Image - Bitmap routines
use Prima qw(Application); # create a new image from scratch my $i = Prima::Image-> new( width => 32, height => 32, type => im::BW, # same as im::bpp1 | im::GrayScale ); # draw something $i-> begin_paint; $i-> color( cl::White); $i-> ellipse( 5, 5, 10, 10); $i-> end_paint; # mangle $i-> size( 64, 64); # file operations $i-> save('a.gif') or die "Error saving:$@\n"; $i-> load('a.gif') or die "Error loading:$@\n"; # draw on screen $::application-> begin_paint; # an image is drawn as specified by its palette $::application-> set( color => cl::Red, backColor => cl::Green); $::application-> put_image( 100, 100, $i); # a bitmap is drawn as specified by destination device colors $::application-> put_image( 200, 100, $i-> bitmap);
Prima::Image, Prima::Icon and Prima::DeviceBitmap are classes for bitmap handling, including file and graphic input and output. Prima::Image and Prima::DeviceBitmap are descendants of Prima::Drawable and represent bitmaps, stored in memory. Prima::Icon is a descendant of Prima::Image and contains a transparency mask along with the regular data.
Images usually are represented as a memory area, where pixel data are stored row-wise. The Prima toolkit is no exception, however, it does not assume that the GUI system uses the same memory format. The implicit conversion routines are called when Prima::Image is about to be drawn onto the screen, for example. The conversions are not always efficient, therefore the Prima::DeviceBitmap class is introduced to represent a bitmap, stored in the system memory in the system pixel format. These two basic classes serve the different needs, but can be easily converted to each other, with
bitmap methods. Prima::Image is a more general bitmap representation, capable of file and graphic input and output, plus it is supplied with number of conversion and scaling functions. The Prima::DeviceBitmap class has almost none of additional functionality, and is targeted to efficient graphic input and output.
Note: If you're looking for information how to display an image, this is not the manual page. Look either at Prima::ImageViewer, or use
stretch_image ( Prima::Drawable ) inside your widget's onPaint.
As descendants of Prima::Drawable, all Prima::Image, Prima::Icon and Prima::DeviceBitmap objects are subject to three-state painting mode - normal ( disabled ), painting ( enabled ) and informational. Prima::DeviceBitmap is, however, exists only in the enabled state, and can not be switched to the other two.
When an object enters the enabled state, it serves as a canvas, and all Prima::Drawable operations can be performed on it. When the object is back to the disabled state, the graphic information is stored into the object associated memory, in the pixel format, supported by the toolkit. This information can be visualized by using one of
Prima::Drawable::put_image group methods. If the object enters the enabled state again, the graphic information is presented as an initial state of a bitmap.
It must be noted, that if an implicit conversion takes place after an object enters and before it leaves the enabled state, as it is with Prima::Image and Prima::Icon, the bitmap is converted to the system pixel format. During such conversion some information can be lost, due to down-sampling, and there is no way to preserve the information. This does not happen with Prima::DeviceBitmap.
Image objects can be drawn upon images, as well as on the screen and Prima::Widget objects. This operation is performed via one of Prima::Drawable::put_image group methods ( see Prima::Drawable), and can be called with the image object disregarding the paint state. The following code illustrates the dualism of an image object, where it can serve both as a drawing surface and as a drawing tool:
my $a = Prima::Image-> create( width => 100, height => 100, type => im::RGB); $a-> begin_paint; $a-> clear; $a-> color( cl::Green); $a-> fill_ellipse( 50, 50, 30, 30); $a-> end_paint; $a-> rop( rop::XorPut); $a-> put_image( 10, 10, $a); $::application-> begin_paint; $::application-> put_image( 0, 0, $a); $::application-> end_paint;
It must be noted, that
put_image_indirect are only painting methods that allow drawing on an image that is in its paint-disabled state. Moreover, in such context they only allow
Prima::Image descendants to be passed as a source image object. This functionality does not imply that the image is internally switched to the paint-enabled state and back; the painting is performed without switching and without interference with the system's graphical layer.
Another special case is a 1-bit ( monochrome ) DeviceBitmap. When it is drawn upon a drawable with bit depth greater than 1, the drawable's color and backColor properties are used to reflect 1 and 0 bits, respectively. On a 1-bit drawable this does not happen, and the color properties are not used.
Depending on the toolkit configuration, images can be read and written in different formats. This functionality in accessible via
save() methods. Prima::image-load is dedicated to the description of loading and saving parameters, that can be passed to the methods, so they can handle different aspects of file format-specific options, such as multi-frame operations, auto conversion when a format does not support a particular pixel format etc. In this document,
save() methods are illustrated only in their basic, single-frame functionality. When called with no extra parameters, these methods fail only if a disk I/O error occurred or an unknown image format was used.
When an image is loaded, the old bitmap memory content is discarded, and the image attributes are changed accordingly to the loaded image. Along with these, an image palette is loaded, if available, and a pixel format is assigned, closest or identical to the pixel format in the image file.
Prima::Image supports a number of pixel formats, governed by the
::type property. It is reflected by an integer value, a combination of
im::XXX constants. The whole set of pixel formats is represented by colored formats, like, 16-color, 256-color and 16M-color, and by gray-scale formats, mapped to C data types - unsigned char, unsigned short, unsigned long, float and double. The gray-scale formats are further subdivided to real-number formats and complex-number format; the last ones are represented by two real values per pixel, containing the real and the imaginary values.
Prima::Image can also be initialized from other formats, that it does not support, but can convert data from. Currently these are represented by a set of permutations of 32-bit RGBA format, and 24-bit BGR format. These formats can only be used in conjunction with
The conversions can be performed between any of the supported formats ( to do so,
::type property is to be set-called ). An image of any of these formats can be drawn on the screen, but if the system can not accept the pixel format ( as it is with non-integer or complex formats ), the bitmap data are implicitly converted. The conversion does not change the data if the image is about to be drawn; the conversion is performed only when the image is about to be served as a drawing surface. If, by any reason, it is desired that the pixel format is not to be changed, the
::preserveType property must be set to 1. It does not prevent the conversion, but it detects if the image was implicitly converted inside
end_paint() call, and reverts it to its previous pixel format.
There are situations, when pixel format must be changed together while down-sampling the image. One of four down-sampling methods can be selected - normal, 8x8 ordered halftoning, error diffusion, and error diffusion combined with optimized palette. These can be set to the
::conversion property with one of
ict::XXX constants. When there is no information loss,
::conversion property is not used.
Another special case of conversion is a conversion with a palette. The following calls,
$image-> type( im::bpp4); $image-> palette( $palette);
$image-> palette( $palette); $image-> type( im::bpp4);
produce different results, but none of these takes into account eventual palette remapping, because
::palette property does not change bitmap pixel data, but overwrites palette information. A proper call syntax here would be
$image-> set( palette => $palette, type => im::bpp4, );
This call produces also palette pixel mapping. This syntax is most powerful when conversion is set to
ict::Optimized ( by default ). It not only allows remapping or downsampling to a predefined colors set, but also can be used to limit palette size to a particular number, without knowing the actual values of the final color palette. For example, for an 24-bit image,
$image-> set( type => im::bpp8, palette => 32);
call would calculate colors in the image, compress them to an optimized palette of 32 cells and finally converts to a 8-bit format.
colormap can also be used.
The pixel values can be accessed in Prima::Drawable style, via
::pixel property. However, Prima::Image introduces several helper functions, for different aims. The
::data property is used to set or retrieve a scalar representation of bitmap data. The data are expected to be lined up to a 'line size' margin ( 4-byte boundary ), which is calculated as
$lineSize = int(( $image->width * ( $image-> type & im::BPP) + 31) / 32) * 4;
or returned from the read-only property
This is the line size for the data as lined up internally in memory, however
::data should not necessarily should be aligned like this, and can be accompanied with a write-only flag 'lineSize' if pixels are aligned differently:
$image-> set( width => 1, height=> 2); $image-> type( im::RGB); $image-> set( data => 'RGB----RGB----', lineSize => 7, ); print $image-> data, "\n"; output: RGB-RGB-
Internally, Prima contains images in memory so that the first scanline is the farthest away from the memory start; this is consistent with general Y-axis orientation in Prima drawable terminology, but might be inconvenient when importing data organized otherwise. Another write-only boolean flag
reverse can be set to 1 so data then are treated as if the first scanline of the image is the closest to the start of data:
$image-> set( width => 1, height=> 2, type => im::RGB); $image-> set( data => 'RGB-123-', reverse => 1, ); print $image-> data, "\n"; output: RGB-123-
Although it is possible to perform all kinds of calculations and modification with the pixels, returned by
::data, it is not advisable unless the speed does not matter. Standalone PDL package with help of PDL::PrimaImage package, and Prima-derived IPA package provide routines for data and image analysis. Also, Prima::Image::Magick connects ImageMagick with Prima. Prima::Image itself provides only the simplest statistic information, namely: lowest and highest pixel values, pixel sum, sum of square pixels, mean, variance, and standard deviation.
Some of image functionality can be used standalone, with all other parts of the toolkit being uninitialized. The functionality is limited to loading and saving files, and reading and writing pixels (outside begin_paint only). All other calls are ignored.
This feature is useful in non-interactive programs, running in evnironments with no GUI access, a cgi-script with no access to X11 display, for example. Normally, Prima fails to start in such situations, but can be told not to initialize its GUI part by explicitly operating system-dependent options. To do so, invoke
in the beginning of your program. See Prima::noX11 for more.
Prima::Icon inherits all properties of Prima::Image, and it also provides a 1-bit depth transparency mask. This mask can also be loaded and saved into image files, if the format supports a transparency information.
Similar to Prima::Image::data property, Prima::Icon::mask property provides access to the binary mask data. The mask can be updated automatically, after an icon object was subject to painting, resizing, or other destructive change. The auxiliary properties
::maskIndex regulate mask update procedure. For example, if an icon was loaded with the color ( vs. bitmap ) transparency information, the binary mask will be generated anyway, but it will be also recorded that a particular color serves as a transparent indicator, so eventual conversions can rely on the color value, instead of the mask bitmap.
If an icon is drawn upon a graphic canvas, the image output is constrained to the mask. On raster displays it is typically simulated by a combination of and- and xor- operation modes, therefore attempts to put an icon with
::rop, different from
rop::CopyPut, usually fail.
A color palette, used for representing 1, 4, and 8-bit bitmaps, when an image object is to be visualized. @PALETTE contains individual colors component triplets, in RGB format. For example, black-and-white monochrome image may contain colormap as
Selects the type of dithering algorithm to be used for pixel down-sampling. TYPE is one of
ict::None - no dithering ict::Ordered - 8x8 ordered halftone dithering ict::ErrorDiffusion - error diffusion dithering with static palette ict::Optimized - error diffusion dithering with optimized palette
As an example, if a 4x4 color image with every pixel set to RGB(32,32,32), converted to a 1-bit image, the following results occur:
ict::None: [ 0 0 0 0 ] [ 0 0 0 0 ] [ 0 0 0 0 ] [ 0 0 0 0 ] ict::Ordered: [ 0 0 0 0 ] [ 0 0 1 0 ] [ 0 0 0 0 ] [ 1 0 0 0 ] ict::ErrorDiffusion, ict::Ordered: [ 0 0 1 0 ] [ 0 0 0 1 ] [ 0 0 0 0 ] [ 0 0 0 0 ]
Provides access to the bitmap data. On get-call, returns all bitmap pixels, aligned to 4-byte boundary. On set-call, stores the provided data with same alignment. The alignment can be altered by submitting 'lineSize' write-only flag to set call; the ordering of scan lines can be altered by setting 'reverse' write-only flag ( see "Data access" ).
Manages the vertical dimension of the image data. On set-call, the image data are changed accordingly to the new height, and depending on
::vScaling property, the pixel values are either scaled or truncated.
If 1, the bitmap data will be scaled when image changes its horizontal extent. If 0, the data will be stripped or padded with zeros.
A read-only property, returning the length of an image row in bytes, as represented internally in memory. Data returned by
::data property are aligned with
::lineSize bytes per row, and setting
::data expects data aligned with this value, unless
lineSize is set together with
data to indicate another alignment. See "Data access" for more.
Returns mean value of pixels. Mean value is
::sum of pixel values, divided by number of pixels.
A color palette, used for representing 1, 4, and 8-bit bitmaps, when an image object is to be visualized. @PALETTE contains individual color component triplets, in BGR format. For example, black-and-white monochrome image may contain palette as
Provides per-pixel access to the image data when image object is in disabled paint state. Otherwise, same as
If 1, reverts the image type to its old value if an implicit conversion was called during
Returns maximum pixel value in the image data.
Returns minimum pixel value in the image data.
Manages dimensions of the image. On set-call, the image data are changed accordingly to the new dimensions, and depending on
::hScaling properties, the pixel values are either scaled or truncated.
Returns one of calculated values, that correspond to INDEX, which is one of the following
is::RangeLo - minimum pixel value is::RangeHi - maximum pixel value is::Mean - mean value is::Variance - variance is::StdDev - standard deviation is::Sum - sum of pixel values is::Sum2 - sum of squares of pixel values
The values are re-calculated on request and cached. On set-call VALUE is stored in the cache, and is returned on next get-call. The cached values are discarded every time the image data changes.
These values are also accessible via set of alias properties:
Returns standard deviation of the image data. Standard deviation is the square root of
Returns sum of pixel values of the image data
Returns sum of squares of pixel values of the image data
Governs the image pixel format type. TYPE is a combination of
im::XXX constants. The constants are collected in groups:
Bit-depth constants provide size of pixel is bits. Their actual value is same as number of bits, so
im::bpp1 value is 1,
im::bpp4 - 4, etc. The valid constants represent bit depths from 1 to 128:
im::bpp1 im::bpp4 im::bpp8 im::bpp16 im::bpp24 im::bpp32 im::bpp64 im::bpp128
The following values designate the pixel format category:
im::Color im::GrayScale im::RealNumber im::ComplexNumber im::TrigComplexNumber im::SignedInt
im::Color is 0, whereas other category constants represented by unique bit value, so combination of
im::ComplexNumber is possible.
There also several mnemonic constants defined:
im::Mono - im::bpp1 im::BW - im::bpp1 | im::GrayScale im::16 - im::bpp4 im::Nibble - im::bpp4 im::256 - im::bpp8 im::RGB - im::bpp24 im::Triple - im::bpp24 im::Byte - gray 8-bit unsigned integer im::Short - gray 16-bit unsigned integer im::Long - gray 32-bit unsigned integer im::Float - float im::Double - double im::Complex - dual float im::DComplex - dual double im::TrigComplex - dual float im::TrigDComplex - dual double
Bit depths of float- and double- derived pixel formats depend on a platform.
The groups can be masked out with the mask values:
im::BPP - bit depth constants im::Category - category constants im::FMT - extra format constants
The extra formats are the pixel formats, not supported by
::type, but recognized within the combined set-call, like
$image-> set( type => im::fmtBGRI, data => 'BGR-BGR-', );
The data, supplied with the extra image format specification will be converted to the closest supported format. Currently, the following extra pixel formats are recognized:
im::fmtBGR im::fmtRGBI im::fmtIRGB im::fmtBGRI im::fmtIBGR
Returns variance of pixel values of the image data. Variance is
::sum2, divided by number of pixels minus square of
::sum of pixel values.
If 1, the bitmap data will be scaled when image changes its vertical extent. If 0, the data will be stripped or padded with zeros.
Manages the horizontal dimension of the image data. On set-call, the image data are changed accordingly to the new width, and depending on
::hScaling property, the pixel values are either scaled or truncated.
Selects whether the mask information should be updated automatically with
::data change or not. Every
::data change is mirrored in
::mask, using TYPE, one of
am::None - no mask update performed am::MaskColor - mask update based on ::maskColor property am::MaskIndex - mask update based on ::maskIndex property am::Auto - mask update based on corner pixel values
::maskColor color value is used as a transparent color if TYPE is
am::MaskColor. The transparency mask generation algorithm, turned on by
am::Auto checks corner pixel values, assuming that majority of the corner pixels represents a transparent color. Once such color is found, the mask is generated as in
::maskIndex is the same as
::maskColor, except that it points to a specific color index in the palette.
::data is stretched,
::mask is stretched accordingly, disregarding the
Provides access to the transparency bitmap. On get-call, returns all bitmap pixels, aligned to 4-byte boundary in 1-bit format. On set-call, stores the provided transparency data with same alignment.
::autoMasking set to
am::MaskColor, COLOR is used as a transparency value.
::autoMasking set to
am::MaskIndex, INDEXth color in teh current palette is used as a transparency value.
A read-only property, that can only be set during creation, reflects whether the system bitmap is black-and-white 1-bit (monochrome) or not. The color depth of a bitmap can be read via
get_bpp() method; monochrome bitmaps always have bit depth of 1.
Returns newly created Prima::DeviceBitmap instance, with the image dimensions and with the bitmap pixel values copied to.
Returns array of hashes, each describing the supported image format. If the array is empty, the toolkit was set up so it can not load and save images.
See Prima::image-load for details.
This method can be called without object instance.
Returns a duplicate of the object, a newly created Prima::Image, with all information copied to it.
Returns a newly created image object with WIDTH and HEIGHT dimensions, initialized with pixel data from X_OFFSET and Y_OFFSET in the bitmap.
Returns the bit depth of the pixel format. Same as
::type & im::BPP.
Returns a system handle for an image object.
Loads image from file FILENAME or stream FILEGLOB into an object, and returns the success flag. The semantics of
load() is extensive, and can be influenced by PARAMETERS hash.
load() can be called either in a context of an existing object, then a boolean success flag is returned, or in a class context, then a newly created object ( or
undef ) is returned. If an error occurs,
$@ variable contains the error description string. These two invocation semantics are equivalent:
my $x = Prima::Image-> create(); die "$@" unless $x-> load( ... );
my $x = Prima::Image-> load( ... ); die "$@" unless $x;
See Prima::image-load for details.
NB! When loading from streams on win32, mind
Performs iterative mapping of bitmap pixels, setting every pixel to
::color property with respect to
::rop type if a pixel equals to COLOR, and to
::backColor property with respect to
::rop2 type otherwise.
rop::NoOper type can be used for color masking.
width => 4, height => 1, data => [ 1, 2, 3, 4] color => 10, backColor => 20, rop => rop::CopyPut rop2 => rop::CopyPut input: map(2) output: [ 20, 10, 20, 20 ] rop2 => rop::NoOper input: map(2) output: [ 1, 10, 3, 4 ]
Performs linear scaling of gray pixel values from range (SRC_LOW - SRC_HIGH) to range (DEST_LOW - DEST_HIGH). Can be used to visualize gray non-8 bit pixel values, by the code:
$image-> resample( $image-> rangeLo, $image-> rangeHi, 0, 255);
Stores image data into image file FILENAME or stream FILEGLOB, and returns the success flag. The semantics of
save() is extensive, and can be influenced by PARAMETERS hash. If error occurs,
$@ variable contains error description string.
Note that when saving to a stream,
codecID must be explicitly given in
See Prima::image-load for details.
NB! When saving to streams on win32, mind
Prima::Image-specific events occur only from inside load call, to report image loading progress. Not all codecs (currently JPEG,PNG,TIFF only) are able to report the progress to the caller. See "Loading with progress indicator" in Prima::image-load for details, "watch_load_progress" in Prima::ImageViewer and "load" in Prima::ImageDialog for suggested use.
Called whenever image header is read, and image dimensions and pixel type is changed accordingly to accomodate image data.
Called whenever image data that cover area designated by X,Y,WIDTH,HEIGHT is acquired. Use
eventDelay to limit the rate of
Returns two new Prima::Image objects of same dimension. Pixels in the first is are duplicated from
::data storage, in the second - from
Copies information from DATA and MASK images into
::mask property. DATA and MASK are expected to be images of same dimension.
Returns a newly created Prima::Icon object instance, with the pixel information copied from the object.
Returns a newly created Prima::Image object instance, with the pixel information copied from the object.
Returns a system handle for a system bitmap object.
Dmitry Karasik, <firstname.lastname@example.org>.