Replace prolog module by new, more generic resource module and replace prolog
[PyX/mjg.git] / manual / bitmap.tex
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1 \chapter{Bitmaps}
2 \section{Introduction}
3 \PyX{} focuses on the creation of scaleable vector graphics. However,
4 \PyX{} also allows for the output of bitmap images. Still, the support
5 for creation and handling of bitmap images is quite limited. On the
6 other hand the interfaces are built that way, that its trivial to
7 combine \PyX{} with the ``Python Image Library'', also known as
8 ``PIL''.
10 The creation of a bitmap can be performed out of some unpacked binary
11 data by first creating image instances:
12 \begin{verbatim}
13 from pyx import *
14 image_bw = bitmap.image(2, 2, "L", "\0\377\377\0")
15 image_rgb = bitmap.image(3, 2, "RGB", "\77\77\77\177\177\177\277\277\277"
16 "\377\0\0\0\377\0\0\0\377")
17 \end{verbatim}
18 Now \code{image_bw} is a $2\times2$ grayscale image. The bitmap data
19 is provided by a string, which contains two black (\code{"\e 0" ==
20 chr(0)}) and two white (\code{"\e 377" == chr(255)}) pixels. Currently
21 the values per (colour) channel is fixed to 8 bits. The coloured image
22 \code{image_rgb} has $3\times2$ pixels containing a row of 3 different
23 gray values and a row of the three colours red, green, and blue.
25 The images can then be wrapped into \code{bitmap} instances by:
26 \begin{verbatim}
27 bitmap_bw = bitmap.bitmap(0, 1, image_bw, height=0.8)
28 bitmap_rgb = bitmap.bitmap(0, 0, image_rgb, height=0.8)
29 \end{verbatim}
30 When constructing a \code{bitmap} instance you have to specify a
31 certain position by the first two arguments fixing the bitmaps lower
32 left corner. Some optional arguments control further properties. Since
33 in this example there is no information about the dpi-value of the
34 images, we have to specify at least a \code{width} or a \code{height}
35 of the bitmap.
37 The bitmaps are now to be inserted into a canvas:
38 \begin{verbatim}
39 c = canvas.canvas()
40 c.insert(bitmap_bw)
41 c.insert(bitmap_rgb)
42 c.writeEPSfile("bitmap")
43 \end{verbatim}
44 Figure~\ref{fig:bitmap} shows the resulting output.
45 \begin{figure}[ht]
46 \centerline{\includegraphics{bitmap}}
47 \caption{An introductory bitmap example.}
48 \label{fig:bitmap}
49 \end{figure}
51 \section{Bitmap module}
52 \declaremodule{}{bitmap}
53 \modulesynopsis{Bitmap support}
55 \begin{classdesc}{image}{width, height, mode, data, compressed=None}
56 This class is a container for image data. \var{width} and
57 \var{height} are the size of the image in pixel. \var{mode} is one
58 of \code{\textquotedbl L\textquotedbl}, \code{\textquotedbl
59 RGB\textquotedbl} or \code{\textquotedbl CMYK\textquotedbl} for
60 grayscale, rgb, or cmyk colours, respectively. \var{data} is the
61 bitmap data as a string, where each single character represents a
62 colour value with ordinal range \code{0} to \code{255}. Each pixel
63 is described by the appropriate number of colour components
64 according to \var{mode}. The pixels are listed row by row one after
65 the other starting at the upper left corner of the image.
67 \var{compressed} might be set to \code{\textquotedbl
68 Flate\textquotedbl} or \code{\textquotedbl DCT\textquotedbl} to
69 provide already compressed data. Note that those data will be passed
70 to PostScript without further checks, \emph{i.e.} this option is for
71 experts only.
72 \end{classdesc}
74 \begin{classdesc}{jpegimage}{file}
75 This class is specialized to read data from a JPEG/JFIF-file.
76 \var{file} is either an open file handle (it only has to provide a
77 \method{read()} method; the file should be opened in binary mode) or
78 a string. In the latter case \class{jpegimage} will try to open a
79 file named like \var{file} for reading.
81 The contents of the file is checked for some JPEG/JFIF format
82 markers in order to identify the size and dpi resolution of the
83 image for further usage. These checks will typically fail for
84 invalid data. The data are not uncompressed, but directly inserted
85 into the output stream (for invalid data the result will be invalid
86 PostScript). Thus there is no quality loss by recompressing the data
87 as it would occur when recompressing the uncompressed stream with
88 the lossy jpeg compression method.
89 \end{classdesc}
91 \begin{classdesc}{bitmap}{xpos, ypos, image, width=None, height=None,
92 ratio=None, storedata=0, maxstrlen=4093, compressmode="Flate",
93 flatecompresslevel=6, dctquality=75, dctoptimize=1,
94 dctprogression=0}
95 \var{xpos} and \var{ypos} are the position of the lower left corner
96 of the image. This position might be modified by some additional
97 transformations when inserting the bitmap into a canvas. \var{image}
98 is an instance of \class{image} or \class{jpegimage} but it can also
99 be an image instance from the ``Python Image Library''.
101 \var{width}, \var{height}, and \var{ratio} adjust the size of the
102 image. At least \var{width} or \var{height} needs to be given, when
103 no dpi information is available from \var{image}.
105 \var{storedata} is a flag indicating, that the (still compressed)
106 image data should be put into the printers memory instead of writing
107 it as a stream into the PostScript file. While this feature consumes
108 memory of the PostScript interpreter, it allows for multiple usage
109 of the image without including the image data several times in the
110 PostScript file.
112 \var{maxstrlen} defines a maximal string length when \var{storedata}
113 is enabled. Since the data must be kept in the PostScript
114 interpreters memory, it is stored in strings. While most
115 interpreters do not allow for an arbitrary string length (a common
116 limit is 65535 characters), a limit for the string length is set.
117 When more data need to be stored, a list of strings will be used.
118 Note that lists are also subject to some implementation limits. Since
119 a typical value is 65535 entries, in combination a huge amount of
120 memory can be used.
122 Valid values for \var{compressmode} currently are
123 \code{\textquotedbl Flate\textquotedbl} (zlib compression),
124 \code{\textquotedbl DCT\textquotedbl} (jpeg compression), or
125 \code{None} (disabling the compression). The zlib compression makes
126 use of the zlib module as it is part of the standard Python
127 distribution. The jpeg compression is available for those
128 \var{image} instances only, which support the creation of a
129 jpeg-compressed stream, \emph{e.g.} images from the ``Python Image
130 Library'' with jpeg support installed. The compression must be
131 disabled when the image data is already compressed.
133 \var{flatecompresslevel} is a parameter of the zlib compression.
134 \var{dctquality}, \var{dctoptimize}, and \var{dctprogression} are
135 parameters of the jpeg compression. Note, that the progression
136 feature of the jpeg compression should be turned off in order to
137 produce valid PostScript. Also the optimization feature is known to
138 produce errors on certain printers.
139 \end{classdesc}