#!/usr/bin/env python # $URL$ # $Rev$ # png.py - PNG encoder/decoder in pure Python # # Copyright (C) 2006 Johann C. Rocholl # Portions Copyright (C) 2009 David Jones # And probably portions Copyright (C) 2006 Nicko van Someren # # Original concept by Johann C. Rocholl. # # LICENSE (The MIT License) # # Permission is hereby granted, free of charge, to any person # obtaining a copy of this software and associated documentation files # (the "Software"), to deal in the Software without restriction, # including without limitation the rights to use, copy, modify, merge, # publish, distribute, sublicense, and/or sell copies of the Software, # and to permit persons to whom the Software is furnished to do so, # subject to the following conditions: # # The above copyright notice and this permission notice shall be # included in all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, # EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF # MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND # NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS # BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN # ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN # CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE # SOFTWARE. # # Changelog (recent first): # 2009-03-11 David: interlaced bit depth < 8 (writing). # 2009-03-10 David: interlaced bit depth < 8 (reading). # 2009-03-04 David: Flat and Boxed pixel formats. # 2009-02-26 David: Palette support (writing). # 2009-02-23 David: Bit-depths < 8; better PNM support. # 2006-06-17 Nicko: Reworked into a class, faster interlacing. # 2006-06-17 Johann: Very simple prototype PNG decoder. # 2006-06-17 Nicko: Test suite with various image generators. # 2006-06-17 Nicko: Alpha-channel, grey-scale, 16-bit/plane support. # 2006-06-15 Johann: Scanline iterator interface for large input files. # 2006-06-09 Johann: Very simple prototype PNG encoder. # Incorporated into Bangai-O Development Tools by drj on 2009-02-11 from # http://trac.browsershots.org/browser/trunk/pypng/lib/png.py?rev=2885 # Incorporated into pypng by drj on 2009-03-12 from # //depot/prj/bangaio/master/code/png.py#67 """ Pure Python PNG Reader/Writer This Python module implements support for PNG images (see PNG specification at http://www.w3.org/TR/2003/REC-PNG-20031110/ ). It reads and writes PNG files with all allowable bit depths (1/2/4/8/16/24/32/48/64 bits per pixel) and colour combinations: greyscale (1/2/4/8/16 bit); RGB, RGBA, LA (greyscale with alpha) with 8/16 bits per channel; colour mapped images (1/2/4/8 bit). Adam7 interlacing is supported for reading and writing. A number of optional chunks can be specified (when writing) and understood (when reading): ``tRNS``, ``bKGD``, ``gAMA``. For help, type ``import png; help(png)`` in your python interpreter. A good place to start is the :class:`Reader` and :class:`Writer` classes. Requires Python 2.3. Limited support is available for Python 2.2, but not everything works. Best with Python 2.4 and higher. Installation is trivial, but see the ``README.txt`` file (with the source distribution) for details. This file can also be used as a command-line utility to convert `Netpbm `_ PNM files to PNG, and the reverse conversion from PNG to PNM. The interface is similar to that of the ``pnmtopng`` program from Netpbm. Type ``python png.py --help`` at the shell prompt for usage and a list of options. A note on spelling and terminology ---------------------------------- Generally British English spelling is used in the documentation. So that's "greyscale" and "colour". This not only matches the author's native language, it's also used by the PNG specification. The major colour models supported by PNG (and hence by PyPNG) are: greyscale, RGB, greyscale--alpha, RGB--alpha. These are sometimes referred to using the abbreviations: L, RGB, LA, RGBA. In this case each letter abbreviates a single channel: *L* is for Luminance or Luma or Lightness which is the channel used in greyscale images; *R*, *G*, *B* stand for Red, Green, Blue, the components of a colour image; *A* stands for Alpha, the opacity channel (used for transparency effects, but higher values are more opaque, so it makes sense to call it opacity). A note on formats ----------------- When getting pixel data out of this module (reading) and presenting data to this module (writing) there are a number of ways the data could be represented as a Python value. Generally this module uses one of three formats called "flat row flat pixel", "boxed row flat pixel", and "boxed row boxed pixel". Basically the concern is whether each pixel and each row comes in its own little tuple (box), or not. Consider an image that is 3 pixels wide by 2 pixels high, and each pixel has RGB components: Boxed row flat pixel:: list([R,G,B, R,G,B, R,G,B], [R,G,B, R,G,B, R,G,B]) Each row appears as its own list, but the pixels are flattened so that three values for one pixel simply follow the three values for the previous pixel. This is the most common format used, because it provides a good compromise between space and convenience. PyPNG regards itself as at liberty to replace any sequence type with any sufficiently compatible other sequence type; in practice each row is an array (from the array module), and the outer list is sometimes an iterator rather than an explicit list (so that streaming is possible). Flat row flat pixel:: [R,G,B, R,G,B, R,G,B, R,G,B, R,G,B, R,G,B] The entire image is one single giant sequence of colour values. Generally an array will be used (to save space), not a list. Boxed row boxed pixel:: list([ (R,G,B), (R,G,B), (R,G,B) ], [ (R,G,B), (R,G,B), (R,G,B) ]) Each row appears in its own list, but each pixel also appears in its own tuple. A serious memory burn in Python. In all cases the top row comes first, and for each row the pixels are ordered from left-to-right. Within a pixel the values appear in the order, R-G-B-A (or L-A for greyscale--alpha). There is a fourth format, mentioned because it is used internally, is close to what lies inside a PNG file itself, and has some support from the public API. This format is called packed. When packed, each row is a sequence of bytes (integers from 0 to 255), just as it is before PNG scanline filtering is applied. When the bit depth is 8 this is essentially the same as boxed row flat pixel; when the bit depth is less than 8, several pixels are packed into each byte; when the bit depth is 16 (the only value more than 8 that is supported by the PNG image format) each pixel value is decomposed into 2 bytes (and `packed` is a misnomer). This format is used by the :meth:`Writer.write_packed` method. It isn't usually a convenient format, but may be just right if the source data for the PNG image comes from something that uses a similar format (for example, 1-bit BMPs, or another PNG file). And now, my famous members -------------------------- """ # http://www.python.org/doc/2.2.3/whatsnew/node5.html from __future__ import generators __version__ = "$URL$ $Rev$" from array import array try: # See :pyver:old import itertools except: pass import math # http://www.python.org/doc/2.4.4/lib/module-operator.html import operator import struct import sys import zlib # http://www.python.org/doc/2.4.4/lib/module-warnings.html import warnings try: import pyximport pyximport.install() import cpngfilters as pngfilters except ImportError: pass __all__ = ['Image', 'Reader', 'Writer', 'write_chunks', 'from_array'] # The PNG signature. # http://www.w3.org/TR/PNG/#5PNG-file-signature _signature = struct.pack('8B', 137, 80, 78, 71, 13, 10, 26, 10) _adam7 = ((0, 0, 8, 8), (4, 0, 8, 8), (0, 4, 4, 8), (2, 0, 4, 4), (0, 2, 2, 4), (1, 0, 2, 2), (0, 1, 1, 2)) def group(s, n): # See # http://www.python.org/doc/2.6/library/functions.html#zip return zip(*[iter(s)]*n) def isarray(x): """Same as ``isinstance(x, array)`` except on Python 2.2, where it always returns ``False``. This helps PyPNG work on Python 2.2. """ try: return isinstance(x, array) except: return False try: # see :pyver:old array.tostring except: def tostring(row): l = len(row) return struct.pack('%dB' % l, *row) else: def tostring(row): """Convert row of bytes to string. Expects `row` to be an ``array``. """ return row.tostring() # Conditionally convert to bytes. Works on Python 2 and Python 3. try: bytes('', 'ascii') def strtobytes(x): return bytes(x, 'iso8859-1') def bytestostr(x): return str(x, 'iso8859-1') except: strtobytes = str bytestostr = str def interleave_planes(ipixels, apixels, ipsize, apsize): """ Interleave (colour) planes, e.g. RGB + A = RGBA. Return an array of pixels consisting of the `ipsize` elements of data from each pixel in `ipixels` followed by the `apsize` elements of data from each pixel in `apixels`. Conventionally `ipixels` and `apixels` are byte arrays so the sizes are bytes, but it actually works with any arrays of the same type. The returned array is the same type as the input arrays which should be the same type as each other. """ itotal = len(ipixels) atotal = len(apixels) newtotal = itotal + atotal newpsize = ipsize + apsize # Set up the output buffer # See http://www.python.org/doc/2.4.4/lib/module-array.html#l2h-1356 out = array(ipixels.typecode) # It's annoying that there is no cheap way to set the array size :-( out.extend(ipixels) out.extend(apixels) # Interleave in the pixel data for i in range(ipsize): out[i:newtotal:newpsize] = ipixels[i:itotal:ipsize] for i in range(apsize): out[i+ipsize:newtotal:newpsize] = apixels[i:atotal:apsize] return out def check_palette(palette): """Check a palette argument (to the :class:`Writer` class) for validity. Returns the palette as a list if okay; raises an exception otherwise. """ # None is the default and is allowed. if palette is None: return None p = list(palette) if not (0 < len(p) <= 256): raise ValueError("a palette must have between 1 and 256 entries") seen_triple = False for i,t in enumerate(p): if len(t) not in (3,4): raise ValueError( "palette entry %d: entries must be 3- or 4-tuples." % i) if len(t) == 3: seen_triple = True if seen_triple and len(t) == 4: raise ValueError( "palette entry %d: all 4-tuples must precede all 3-tuples" % i) for x in t: if int(x) != x or not(0 <= x <= 255): raise ValueError( "palette entry %d: values must be integer: 0 <= x <= 255" % i) return p class Error(Exception): prefix = 'Error' def __str__(self): return self.prefix + ': ' + ' '.join(self.args) class FormatError(Error): """Problem with input file format. In other words, PNG file does not conform to the specification in some way and is invalid. """ prefix = 'FormatError' class ChunkError(FormatError): prefix = 'ChunkError' class Writer: """ PNG encoder in pure Python. """ def __init__(self, width=None, height=None, size=None, greyscale=False, alpha=False, bitdepth=8, palette=None, transparent=None, background=None, gamma=None, compression=None, interlace=False, bytes_per_sample=None, # deprecated planes=None, colormap=None, maxval=None, chunk_limit=2**20): """ Create a PNG encoder object. Arguments: width, height Image size in pixels, as two separate arguments. size Image size (w,h) in pixels, as single argument. greyscale Input data is greyscale, not RGB. alpha Input data has alpha channel (RGBA or LA). bitdepth Bit depth: from 1 to 16. palette Create a palette for a colour mapped image (colour type 3). transparent Specify a transparent colour (create a ``tRNS`` chunk). background Specify a default background colour (create a ``bKGD`` chunk). gamma Specify a gamma value (create a ``gAMA`` chunk). compression zlib compression level: 0 (none) to 9 (more compressed); default: -1 or None. interlace Create an interlaced image. chunk_limit Write multiple ``IDAT`` chunks to save memory. The image size (in pixels) can be specified either by using the `width` and `height` arguments, or with the single `size` argument. If `size` is used it should be a pair (*width*, *height*). `greyscale` and `alpha` are booleans that specify whether an image is greyscale (or colour), and whether it has an alpha channel (or not). `bitdepth` specifies the bit depth of the source pixel values. Each source pixel value must be an integer between 0 and ``2**bitdepth-1``. For example, 8-bit images have values between 0 and 255. PNG only stores images with bit depths of 1,2,4,8, or 16. When `bitdepth` is not one of these values, the next highest valid bit depth is selected, and an ``sBIT`` (significant bits) chunk is generated that specifies the original precision of the source image. In this case the supplied pixel values will be rescaled to fit the range of the selected bit depth. The details of which bit depth / colour model combinations the PNG file format supports directly, are somewhat arcane (refer to the PNG specification for full details). Briefly: "small" bit depths (1,2,4) are only allowed with greyscale and colour mapped images; colour mapped images cannot have bit depth 16. For colour mapped images (in other words, when the `palette` argument is specified) the `bitdepth` argument must match one of the valid PNG bit depths: 1, 2, 4, or 8. (It is valid to have a PNG image with a palette and an ``sBIT`` chunk, but the meaning is slightly different; it would be awkward to press the `bitdepth` argument into service for this.) The `palette` option, when specified, causes a colour mapped image to be created: the PNG colour type is set to 3; greyscale must not be set; alpha must not be set; transparent must not be set; the bit depth must be 1,2,4, or 8. When a colour mapped image is created, the pixel values are palette indexes and the `bitdepth` argument specifies the size of these indexes (not the size of the colour values in the palette). The palette argument value should be a sequence of 3- or 4-tuples. 3-tuples specify RGB palette entries; 4-tuples specify RGBA palette entries. If both 4-tuples and 3-tuples appear in the sequence then all the 4-tuples must come before all the 3-tuples. A ``PLTE`` chunk is created; if there are 4-tuples then a ``tRNS`` chunk is created as well. The ``PLTE`` chunk will contain all the RGB triples in the same sequence; the ``tRNS`` chunk will contain the alpha channel for all the 4-tuples, in the same sequence. Palette entries are always 8-bit. If specified, the `transparent` and `background` parameters must be a tuple with three integer values for red, green, blue, or a simple integer (or singleton tuple) for a greyscale image. If specified, the `gamma` parameter must be a positive number (generally, a float). A ``gAMA`` chunk will be created. Note that this will not change the values of the pixels as they appear in the PNG file, they are assumed to have already been converted appropriately for the gamma specified. The `compression` argument specifies the compression level to be used by the ``zlib`` module. Values from 1 to 9 specify compression, with 9 being "more compressed" (usually smaller and slower, but it doesn't always work out that way). 0 means no compression. -1 and ``None`` both mean that the default level of compession will be picked by the ``zlib`` module (which is generally acceptable). If `interlace` is true then an interlaced image is created (using PNG's so far only interace method, *Adam7*). This does not affect how the pixels should be presented to the encoder, rather it changes how they are arranged into the PNG file. On slow connexions interlaced images can be partially decoded by the browser to give a rough view of the image that is successively refined as more image data appears. .. note :: Enabling the `interlace` option requires the entire image to be processed in working memory. `chunk_limit` is used to limit the amount of memory used whilst compressing the image. In order to avoid using large amounts of memory, multiple ``IDAT`` chunks may be created. """ # At the moment the `planes` argument is ignored; # its purpose is to act as a dummy so that # ``Writer(x, y, **info)`` works, where `info` is a dictionary # returned by Reader.read and friends. # Ditto for `colormap`. # A couple of helper functions come first. Best skipped if you # are reading through. def isinteger(x): try: return int(x) == x except: return False def check_color(c, which): """Checks that a colour argument for transparent or background options is the right form. Also "corrects" bare integers to 1-tuples. """ if c is None: return c if greyscale: try: l = len(c) except TypeError: c = (c,) if len(c) != 1: raise ValueError("%s for greyscale must be 1-tuple" % which) if not isinteger(c[0]): raise ValueError( "%s colour for greyscale must be integer" % which) else: if not (len(c) == 3 and isinteger(c[0]) and isinteger(c[1]) and isinteger(c[2])): raise ValueError( "%s colour must be a triple of integers" % which) return c if size: if len(size) != 2: raise ValueError( "size argument should be a pair (width, height)") if width is not None and width != size[0]: raise ValueError( "size[0] (%r) and width (%r) should match when both are used." % (size[0], width)) if height is not None and height != size[1]: raise ValueError( "size[1] (%r) and height (%r) should match when both are used." % (size[1], height)) width,height = size del size if width <= 0 or height <= 0: raise ValueError("width and height must be greater than zero") if not isinteger(width) or not isinteger(height): raise ValueError("width and height must be integers") # http://www.w3.org/TR/PNG/#7Integers-and-byte-order if width > 2**32-1 or height > 2**32-1: raise ValueError("width and height cannot exceed 2**32-1") if alpha and transparent is not None: raise ValueError( "transparent colour not allowed with alpha channel") if bytes_per_sample is not None: warnings.warn('please use bitdepth instead of bytes_per_sample', DeprecationWarning) if bytes_per_sample not in (0.125, 0.25, 0.5, 1, 2): raise ValueError( "bytes per sample must be .125, .25, .5, 1, or 2") bitdepth = int(8*bytes_per_sample) del bytes_per_sample if not isinteger(bitdepth) or bitdepth < 1 or 16 < bitdepth: raise ValueError("bitdepth (%r) must be a postive integer <= 16" % bitdepth) self.rescale = None if palette: if bitdepth not in (1,2,4,8): raise ValueError("with palette, bitdepth must be 1, 2, 4, or 8") if transparent is not None: raise ValueError("transparent and palette not compatible") if alpha: raise ValueError("alpha and palette not compatible") if greyscale: raise ValueError("greyscale and palette not compatible") else: # No palette, check for sBIT chunk generation. if alpha or not greyscale: if bitdepth not in (8,16): targetbitdepth = (8,16)[bitdepth > 8] self.rescale = (bitdepth, targetbitdepth) bitdepth = targetbitdepth del targetbitdepth else: assert greyscale assert not alpha if bitdepth not in (1,2,4,8,16): if bitdepth > 8: targetbitdepth = 16 elif bitdepth == 3: targetbitdepth = 4 else: assert bitdepth in (5,6,7) targetbitdepth = 8 self.rescale = (bitdepth, targetbitdepth) bitdepth = targetbitdepth del targetbitdepth if bitdepth < 8 and (alpha or not greyscale and not palette): raise ValueError( "bitdepth < 8 only permitted with greyscale or palette") if bitdepth > 8 and palette: raise ValueError( "bit depth must be 8 or less for images with palette") transparent = check_color(transparent, 'transparent') background = check_color(background, 'background') # It's important that the true boolean values (greyscale, alpha, # colormap, interlace) are converted to bool because Iverson's # convention is relied upon later on. self.width = width self.height = height self.transparent = transparent self.background = background self.gamma = gamma self.greyscale = bool(greyscale) self.alpha = bool(alpha) self.colormap = bool(palette) self.bitdepth = int(bitdepth) self.compression = compression self.chunk_limit = chunk_limit self.interlace = bool(interlace) self.palette = check_palette(palette) self.color_type = 4*self.alpha + 2*(not greyscale) + 1*self.colormap assert self.color_type in (0,2,3,4,6) self.color_planes = (3,1)[self.greyscale or self.colormap] self.planes = self.color_planes + self.alpha # :todo: fix for bitdepth < 8 self.psize = (self.bitdepth/8) * self.planes def make_palette(self): """Create the byte sequences for a ``PLTE`` and if necessary a ``tRNS`` chunk. Returned as a pair (*p*, *t*). *t* will be ``None`` if no ``tRNS`` chunk is necessary. """ p = array('B') t = array('B') for x in self.palette: p.extend(x[0:3]) if len(x) > 3: t.append(x[3]) p = tostring(p) t = tostring(t) if t: return p,t return p,None def write(self, outfile, rows): """Write a PNG image to the output file. `rows` should be an iterable that yields each row in boxed row flat pixel format. The rows should be the rows of the original image, so there should be ``self.height`` rows of ``self.width * self.planes`` values. If `interlace` is specified (when creating the instance), then an interlaced PNG file will be written. Supply the rows in the normal image order; the interlacing is carried out internally. .. note :: Interlacing will require the entire image to be in working memory. """ if self.interlace: fmt = 'BH'[self.bitdepth > 8] a = array(fmt, itertools.chain(*rows)) return self.write_array(outfile, a) else: nrows = self.write_passes(outfile, rows) if nrows != self.height: raise ValueError( "rows supplied (%d) does not match height (%d)" % (nrows, self.height)) def write_passes(self, outfile, rows, packed=False): """ Write a PNG image to the output file. Most users are expected to find the :meth:`write` or :meth:`write_array` method more convenient. The rows should be given to this method in the order that they appear in the output file. For straightlaced images, this is the usual top to bottom ordering, but for interlaced images the rows should have already been interlaced before passing them to this function. `rows` should be an iterable that yields each row. When `packed` is ``False`` the rows should be in boxed row flat pixel format; when `packed` is ``True`` each row should be a packed sequence of bytes. """ # http://www.w3.org/TR/PNG/#5PNG-file-signature outfile.write(_signature) # http://www.w3.org/TR/PNG/#11IHDR write_chunk(outfile, 'IHDR', struct.pack("!2I5B", self.width, self.height, self.bitdepth, self.color_type, 0, 0, self.interlace)) # See :chunk:order # http://www.w3.org/TR/PNG/#11gAMA if self.gamma is not None: write_chunk(outfile, 'gAMA', struct.pack("!L", int(round(self.gamma*1e5)))) # See :chunk:order # http://www.w3.org/TR/PNG/#11sBIT if self.rescale: write_chunk(outfile, 'sBIT', struct.pack('%dB' % self.planes, *[self.rescale[0]]*self.planes)) # :chunk:order: Without a palette (PLTE chunk), ordering is # relatively relaxed. With one, gAMA chunk must precede PLTE # chunk which must precede tRNS and bKGD. # See http://www.w3.org/TR/PNG/#5ChunkOrdering if self.palette: p,t = self.make_palette() write_chunk(outfile, 'PLTE', p) if t: # tRNS chunk is optional. Only needed if palette entries # have alpha. write_chunk(outfile, 'tRNS', t) # http://www.w3.org/TR/PNG/#11tRNS if self.transparent is not None: if self.greyscale: write_chunk(outfile, 'tRNS', struct.pack("!1H", *self.transparent)) else: write_chunk(outfile, 'tRNS', struct.pack("!3H", *self.transparent)) # http://www.w3.org/TR/PNG/#11bKGD if self.background is not None: if self.greyscale: write_chunk(outfile, 'bKGD', struct.pack("!1H", *self.background)) else: write_chunk(outfile, 'bKGD', struct.pack("!3H", *self.background)) # http://www.w3.org/TR/PNG/#11IDAT if self.compression is not None: compressor = zlib.compressobj(self.compression) else: compressor = zlib.compressobj() # Choose an extend function based on the bitdepth. The extend # function packs/decomposes the pixel values into bytes and # stuffs them onto the data array. data = array('B') if self.bitdepth == 8 or packed: extend = data.extend elif self.bitdepth == 16: # Decompose into bytes def extend(sl): fmt = '!%dH' % len(sl) data.extend(array('B', struct.pack(fmt, *sl))) else: # Pack into bytes assert self.bitdepth < 8 # samples per byte spb = int(8/self.bitdepth) def extend(sl): a = array('B', sl) # Adding padding bytes so we can group into a whole # number of spb-tuples. l = float(len(a)) extra = math.ceil(l / float(spb))*spb - l a.extend([0]*int(extra)) # Pack into bytes l = group(a, spb) l = map(lambda e: reduce(lambda x,y: (x << self.bitdepth) + y, e), l) data.extend(l) if self.rescale: oldextend = extend factor = \ float(2**self.rescale[1]-1) / float(2**self.rescale[0]-1) def extend(sl): oldextend(map(lambda x: int(round(factor*x)), sl)) # Build the first row, testing mostly to see if we need to # changed the extend function to cope with NumPy integer types # (they cause our ordinary definition of extend to fail, so we # wrap it). See # http://code.google.com/p/pypng/issues/detail?id=44 enumrows = enumerate(rows) del rows # First row's filter type. data.append(0) # :todo: Certain exceptions in the call to ``.next()`` or the # following try would indicate no row data supplied. # Should catch. i,row = enumrows.next() try: # If this fails... extend(row) except: # ... try a version that converts the values to int first. # Not only does this work for the (slightly broken) NumPy # types, there are probably lots of other, unknown, "nearly" # int types it works for. def wrapmapint(f): return lambda sl: f(map(int, sl)) extend = wrapmapint(extend) del wrapmapint extend(row) for i,row in enumrows: # Add "None" filter type. Currently, it's essential that # this filter type be used for every scanline as we do not # mark the first row of a reduced pass image; that means we # could accidentally compute the wrong filtered scanline if # we used "up", "average", or "paeth" on such a line. data.append(0) extend(row) if len(data) > self.chunk_limit: compressed = compressor.compress(tostring(data)) if len(compressed): # print >> sys.stderr, len(data), len(compressed) write_chunk(outfile, 'IDAT', compressed) # Because of our very witty definition of ``extend``, # above, we must re-use the same ``data`` object. Hence # we use ``del`` to empty this one, rather than create a # fresh one (which would be my natural FP instinct). del data[:] if len(data): compressed = compressor.compress(tostring(data)) else: compressed = '' flushed = compressor.flush() if len(compressed) or len(flushed): # print >> sys.stderr, len(data), len(compressed), len(flushed) write_chunk(outfile, 'IDAT', compressed + flushed) # http://www.w3.org/TR/PNG/#11IEND write_chunk(outfile, 'IEND') return i+1 def write_array(self, outfile, pixels): """ Write an array in flat row flat pixel format as a PNG file on the output file. See also :meth:`write` method. """ if self.interlace: self.write_passes(outfile, self.array_scanlines_interlace(pixels)) else: self.write_passes(outfile, self.array_scanlines(pixels)) def write_packed(self, outfile, rows): """ Write PNG file to `outfile`. The pixel data comes from `rows` which should be in boxed row packed format. Each row should be a sequence of packed bytes. Technically, this method does work for interlaced images but it is best avoided. For interlaced images, the rows should be presented in the order that they appear in the file. This method should not be used when the source image bit depth is not one naturally supported by PNG; the bit depth should be 1, 2, 4, 8, or 16. """ if self.rescale: raise Error("write_packed method not suitable for bit depth %d" % self.rescale[0]) return self.write_passes(outfile, rows, packed=True) def convert_pnm(self, infile, outfile): """ Convert a PNM file containing raw pixel data into a PNG file with the parameters set in the writer object. Works for (binary) PGM, PPM, and PAM formats. """ if self.interlace: pixels = array('B') pixels.fromfile(infile, (self.bitdepth/8) * self.color_planes * self.width * self.height) self.write_passes(outfile, self.array_scanlines_interlace(pixels)) else: self.write_passes(outfile, self.file_scanlines(infile)) def convert_ppm_and_pgm(self, ppmfile, pgmfile, outfile): """ Convert a PPM and PGM file containing raw pixel data into a PNG outfile with the parameters set in the writer object. """ pixels = array('B') pixels.fromfile(ppmfile, (self.bitdepth/8) * self.color_planes * self.width * self.height) apixels = array('B') apixels.fromfile(pgmfile, (self.bitdepth/8) * self.width * self.height) pixels = interleave_planes(pixels, apixels, (self.bitdepth/8) * self.color_planes, (self.bitdepth/8)) if self.interlace: self.write_passes(outfile, self.array_scanlines_interlace(pixels)) else: self.write_passes(outfile, self.array_scanlines(pixels)) def file_scanlines(self, infile): """ Generates boxed rows in flat pixel format, from the input file `infile`. It assumes that the input file is in a "Netpbm-like" binary format, and is positioned at the beginning of the first pixel. The number of pixels to read is taken from the image dimensions (`width`, `height`, `planes`) and the number of bytes per value is implied by the image `bitdepth`. """ # Values per row vpr = self.width * self.planes row_bytes = vpr if self.bitdepth > 8: assert self.bitdepth == 16 row_bytes *= 2 fmt = '>%dH' % vpr def line(): return array('H', struct.unpack(fmt, infile.read(row_bytes))) else: def line(): scanline = array('B', infile.read(row_bytes)) return scanline for y in range(self.height): yield line() def array_scanlines(self, pixels): """ Generates boxed rows (flat pixels) from flat rows (flat pixels) in an array. """ # Values per row vpr = self.width * self.planes stop = 0 for y in range(self.height): start = stop stop = start + vpr yield pixels[start:stop] def array_scanlines_interlace(self, pixels): """ Generator for interlaced scanlines from an array. `pixels` is the full source image in flat row flat pixel format. The generator yields each scanline of the reduced passes in turn, in boxed row flat pixel format. """ # http://www.w3.org/TR/PNG/#8InterlaceMethods # Array type. fmt = 'BH'[self.bitdepth > 8] # Value per row vpr = self.width * self.planes for xstart, ystart, xstep, ystep in _adam7: if xstart >= self.width: continue # Pixels per row (of reduced image) ppr = int(math.ceil((self.width-xstart)/float(xstep))) # number of values in reduced image row. row_len = ppr*self.planes for y in range(ystart, self.height, ystep): if xstep == 1: offset = y * vpr yield pixels[offset:offset+vpr] else: row = array(fmt) # There's no easier way to set the length of an array row.extend(pixels[0:row_len]) offset = y * vpr + xstart * self.planes end_offset = (y+1) * vpr skip = self.planes * xstep for i in range(self.planes): row[i::self.planes] = \ pixels[offset+i:end_offset:skip] yield row def write_chunk(outfile, tag, data=strtobytes('')): """ Write a PNG chunk to the output file, including length and checksum. """ # http://www.w3.org/TR/PNG/#5Chunk-layout outfile.write(struct.pack("!I", len(data))) tag = strtobytes(tag) outfile.write(tag) outfile.write(data) checksum = zlib.crc32(tag) checksum = zlib.crc32(data, checksum) checksum &= 2**32-1 outfile.write(struct.pack("!I", checksum)) def write_chunks(out, chunks): """Create a PNG file by writing out the chunks.""" out.write(_signature) for chunk in chunks: write_chunk(out, *chunk) def filter_scanline(type, line, fo, prev=None): """Apply a scanline filter to a scanline. `type` specifies the filter type (0 to 4); `line` specifies the current (unfiltered) scanline as a sequence of bytes; `prev` specifies the previous (unfiltered) scanline as a sequence of bytes. `fo` specifies the filter offset; normally this is size of a pixel in bytes (the number of bytes per sample times the number of channels), but when this is < 1 (for bit depths < 8) then the filter offset is 1. """ assert 0 <= type < 5 # The output array. Which, pathetically, we extend one-byte at a # time (fortunately this is linear). out = array('B', [type]) def sub(): ai = -fo for x in line: if ai >= 0: x = (x - line[ai]) & 0xff out.append(x) ai += 1 def up(): for i,x in enumerate(line): x = (x - prev[i]) & 0xff out.append(x) def average(): ai = -fo for i,x in enumerate(line): if ai >= 0: x = (x - ((line[ai] + prev[i]) >> 1)) & 0xff else: x = (x - (prev[i] >> 1)) & 0xff out.append(x) ai += 1 def paeth(): # http://www.w3.org/TR/PNG/#9Filter-type-4-Paeth ai = -fo # also used for ci for i,x in enumerate(line): a = 0 b = prev[i] c = 0 if ai >= 0: a = line[ai] c = prev[ai] p = a + b - c pa = abs(p - a) pb = abs(p - b) pc = abs(p - c) if pa <= pb and pa <= pc: Pr = a elif pb <= pc: Pr = b else: Pr = c x = (x - Pr) & 0xff out.append(x) ai += 1 if not prev: # We're on the first line. Some of the filters can be reduced # to simpler cases which makes handling the line "off the top" # of the image simpler. "up" becomes "none"; "paeth" becomes # "left" (non-trivial, but true). "average" needs to be handled # specially. if type == 2: # "up" return line # type = 0 elif type == 3: prev = [0]*len(line) elif type == 4: # "paeth" type = 1 if type == 0: out.extend(line) elif type == 1: sub() elif type == 2: up() elif type == 3: average() else: # type == 4 paeth() return out def from_array(a, mode=None, info={}): """Create a PNG :class:`Image` object from a 2- or 3-dimensional array. One application of this function is easy PIL-style saving: ``png.from_array(pixels, 'L').save('foo.png')``. .. note : The use of the term *3-dimensional* is for marketing purposes only. It doesn't actually work. Please bear with us. Meanwhile enjoy the complimentary snacks (on request) and please use a 2-dimensional array. Unless they are specified using the *info* parameter, the PNG's height and width are taken from the array size. For a 3 dimensional array the first axis is the height; the second axis is the width; and the third axis is the channel number. Thus an RGB image that is 16 pixels high and 8 wide will use an array that is 16x8x3. For 2 dimensional arrays the first axis is the height, but the second axis is ``width*channels``, so an RGB image that is 16 pixels high and 8 wide will use a 2-dimensional array that is 16x24 (each row will be 8*3==24 sample values). *mode* is a string that specifies the image colour format in a PIL-style mode. It can be: ``'L'`` greyscale (1 channel) ``'LA'`` greyscale with alpha (2 channel) ``'RGB'`` colour image (3 channel) ``'RGBA'`` colour image with alpha (4 channel) The mode string can also specify the bit depth (overriding how this function normally derives the bit depth, see below). Appending ``';16'`` to the mode will cause the PNG to be 16 bits per channel; any decimal from 1 to 16 can be used to specify the bit depth. When a 2-dimensional array is used *mode* determines how many channels the image has, and so allows the width to be derived from the second array dimension. The array is expected to be a ``numpy`` array, but it can be any suitable Python sequence. For example, a list of lists can be used: ``png.from_array([[0, 255, 0], [255, 0, 255]], 'L')``. The exact rules are: ``len(a)`` gives the first dimension, height; ``len(a[0])`` gives the second dimension; ``len(a[0][0])`` gives the third dimension, unless an exception is raised in which case a 2-dimensional array is assumed. It's slightly more complicated than that because an iterator of rows can be used, and it all still works. Using an iterator allows data to be streamed efficiently. The bit depth of the PNG is normally taken from the array element's datatype (but if *mode* specifies a bitdepth then that is used instead). The array element's datatype is determined in a way which is supposed to work both for ``numpy`` arrays and for Python ``array.array`` objects. A 1 byte datatype will give a bit depth of 8, a 2 byte datatype will give a bit depth of 16. If the datatype does not have an implicit size, for example it is a plain Python list of lists, as above, then a default of 8 is used. The *info* parameter is a dictionary that can be used to specify metadata (in the same style as the arguments to the :class:``png.Writer`` class). For this function the keys that are useful are: height overrides the height derived from the array dimensions and allows *a* to be an iterable. width overrides the width derived from the array dimensions. bitdepth overrides the bit depth derived from the element datatype (but must match *mode* if that also specifies a bit depth). Generally anything specified in the *info* dictionary will override any implicit choices that this function would otherwise make, but must match any explicit ones. For example, if the *info* dictionary has a ``greyscale`` key then this must be true when mode is ``'L'`` or ``'LA'`` and false when mode is ``'RGB'`` or ``'RGBA'``. """ # We abuse the *info* parameter by modifying it. Take a copy here. # (Also typechecks *info* to some extent). info = dict(info) # Syntax check mode string. bitdepth = None try: mode = mode.split(';') if len(mode) not in (1,2): raise Error() if mode[0] not in ('L', 'LA', 'RGB', 'RGBA'): raise Error() if len(mode) == 2: try: bitdepth = int(mode[1]) except: raise Error() except Error: raise Error("mode string should be 'RGB' or 'L;16' or similar.") mode = mode[0] # Get bitdepth from *mode* if possible. if bitdepth: if info.get('bitdepth') and bitdepth != info['bitdepth']: raise Error("mode bitdepth (%d) should match info bitdepth (%d)." % (bitdepth, info['bitdepth'])) info['bitdepth'] = bitdepth # Fill in and/or check entries in *info*. # Dimensions. if 'size' in info: # Check width, height, size all match where used. for dimension,axis in [('width', 0), ('height', 1)]: if dimension in info: if info[dimension] != info['size'][axis]: raise Error( "info[%r] shhould match info['size'][%r]." % (dimension, axis)) info['width'],info['height'] = info['size'] if 'height' not in info: try: l = len(a) except: raise Error( "len(a) does not work, supply info['height'] instead.") info['height'] = l # Colour format. if 'greyscale' in info: if bool(info['greyscale']) != ('L' in mode): raise Error("info['greyscale'] should match mode.") info['greyscale'] = 'L' in mode if 'alpha' in info: if bool(info['alpha']) != ('A' in mode): raise Error("info['alpha'] should match mode.") info['alpha'] = 'A' in mode planes = len(mode) if 'planes' in info: if info['planes'] != planes: raise Error("info['planes'] should match mode.") # In order to work out whether we the array is 2D or 3D we need its # first row, which requires that we take a copy of its iterator. # We may also need the first row to derive width and bitdepth. a,t = itertools.tee(a) row = t.next() del t try: row[0][0] threed = True testelement = row[0] except: threed = False testelement = row if 'width' not in info: if threed: width = len(row) else: width = len(row) // planes info['width'] = width # Not implemented yet assert not threed if 'bitdepth' not in info: try: dtype = testelement.dtype # goto the "else:" clause. Sorry. except: try: # Try a Python array.array. bitdepth = 8 * testelement.itemsize except: # We can't determine it from the array element's # datatype, use a default of 8. bitdepth = 8 else: # If we got here without exception, we now assume that # the array is a numpy array. if dtype.kind == 'b': bitdepth = 1 else: bitdepth = 8 * dtype.itemsize info['bitdepth'] = bitdepth for thing in 'width height bitdepth greyscale alpha'.split(): assert thing in info return Image(a, info) # So that refugee's from PIL feel more at home. Not documented. fromarray = from_array class Image: """A PNG image. You can create an :class:`Image` object from an array of pixels by calling :meth:`png.from_array`. It can be saved to disk with the :meth:`save` method.""" def __init__(self, rows, info): """ .. note :: The constructor is not public. Please do not call it. """ self.rows = rows self.info = info def save(self, file): """Save the image to *file*. If *file* looks like an open file descriptor then it is used, otherwise it is treated as a filename and a fresh file is opened. In general, you can only call this method once; after it has been called the first time and the PNG image has been saved, the source data will have been streamed, and cannot be streamed again. """ w = Writer(**self.info) try: file.write def close(): pass except: file = open(file, 'wb') def close(): file.close() try: w.write(file, self.rows) finally: close() class _readable: """ A simple file-like interface for strings and arrays. """ def __init__(self, buf): self.buf = buf self.offset = 0 def read(self, n): r = self.buf[self.offset:self.offset+n] if isarray(r): r = r.tostring() self.offset += n return r class Reader: """ PNG decoder in pure Python. """ def __init__(self, _guess=None, **kw): """ Create a PNG decoder object. The constructor expects exactly one keyword argument. If you supply a positional argument instead, it will guess the input type. You can choose among the following keyword arguments: filename Name of input file (a PNG file). file A file-like object (object with a read() method). bytes ``array`` or ``string`` with PNG data. """ if ((_guess is not None and len(kw) != 0) or (_guess is None and len(kw) != 1)): raise TypeError("Reader() takes exactly 1 argument") # Will be the first 8 bytes, later on. See validate_signature. self.signature = None self.transparent = None # A pair of (len,type) if a chunk has been read but its data and # checksum have not (in other words the file position is just # past the 4 bytes that specify the chunk type). See preamble # method for how this is used. self.atchunk = None if _guess is not None: if isarray(_guess): kw["bytes"] = _guess elif isinstance(_guess, str): kw["filename"] = _guess elif isinstance(_guess, file): kw["file"] = _guess if "filename" in kw: self.file = open(kw["filename"], "rb") elif "file" in kw: self.file = kw["file"] elif "bytes" in kw: self.file = _readable(kw["bytes"]) else: raise TypeError("expecting filename, file or bytes array") def chunk(self, seek=None, lenient=False): """ Read the next PNG chunk from the input file; returns a (*type*,*data*) tuple. *type* is the chunk's type as a string (all PNG chunk types are 4 characters long). *data* is the chunk's data content, as a string. If the optional `seek` argument is specified then it will keep reading chunks until it either runs out of file or finds the type specified by the argument. Note that in general the order of chunks in PNGs is unspecified, so using `seek` can cause you to miss chunks. If the optional `lenient` argument evaluates to True, checksum failures will raise warnings rather than exceptions. """ self.validate_signature() while True: # http://www.w3.org/TR/PNG/#5Chunk-layout if not self.atchunk: self.atchunk = self.chunklentype() length,type = self.atchunk self.atchunk = None data = self.file.read(length) if len(data) != length: raise ChunkError('Chunk %s too short for required %i octets.' % (type, length)) checksum = self.file.read(4) if len(checksum) != 4: raise ValueError('Chunk %s too short for checksum.', tag) if seek and type != seek: continue verify = zlib.crc32(strtobytes(type)) verify = zlib.crc32(data, verify) # Whether the output from zlib.crc32 is signed or not varies # according to hideous implementation details, see # http://bugs.python.org/issue1202 . # We coerce it to be positive here (in a way which works on # Python 2.3 and older). verify &= 2**32 - 1 verify = struct.pack('!I', verify) if checksum != verify: # print repr(checksum) (a, ) = struct.unpack('!I', checksum) (b, ) = struct.unpack('!I', verify) message = "Checksum error in %s chunk: 0x%08X != 0x%08X." % (type, a, b) if lenient: warnings.warn(message, RuntimeWarning) else: raise ChunkError(message) return type, data def chunks(self): """Return an iterator that will yield each chunk as a (*chunktype*, *content*) pair. """ while True: t,v = self.chunk() yield t,v if t == 'IEND': break def undo_filter(self, filter_type, scanline, previous): """Undo the filter for a scanline. `scanline` is a sequence of bytes that does not include the initial filter type byte. `previous` is decoded previous scanline (for straightlaced images this is the previous pixel row, but for interlaced images, it is the previous scanline in the reduced image, which in general is not the previous pixel row in the final image). When there is no previous scanline (the first row of a straightlaced image, or the first row in one of the passes in an interlaced image), then this argument should be ``None``. The scanline will have the effects of filtering removed, and the result will be returned as a fresh sequence of bytes. """ # :todo: Would it be better to update scanline in place? # Yes, with the Cython extension making the undo_filter fast, # updating scanline inplace makes the code 3 times faster # (reading 50 images of 800x800 went from 40s to 16s) result = scanline if filter_type == 0: return result if filter_type not in (1,2,3,4): raise FormatError('Invalid PNG Filter Type.' ' See http://www.w3.org/TR/2003/REC-PNG-20031110/#9Filters .') # Filter unit. The stride from one pixel to the corresponding # byte from the previous previous. Normally this is the pixel # size in bytes, but when this is smaller than 1, the previous # byte is used instead. fu = max(1, self.psize) # For the first line of a pass, synthesize a dummy previous # line. An alternative approach would be to observe that on the # first line 'up' is the same as 'null', 'paeth' is the same # as 'sub', with only 'average' requiring any special case. if not previous: previous = array('B', [0]*len(scanline)) def sub(): """Undo sub filter.""" ai = 0 # Loops starts at index fu. Observe that the initial part # of the result is already filled in correctly with # scanline. for i in range(fu, len(result)): x = scanline[i] a = result[ai] result[i] = (x + a) & 0xff ai += 1 def up(): """Undo up filter.""" for i in range(len(result)): x = scanline[i] b = previous[i] result[i] = (x + b) & 0xff def average(): """Undo average filter.""" ai = -fu for i in range(len(result)): x = scanline[i] if ai < 0: a = 0 else: a = result[ai] b = previous[i] result[i] = (x + ((a + b) >> 1)) & 0xff ai += 1 def paeth(): """Undo Paeth filter.""" # Also used for ci. ai = -fu for i in range(len(result)): x = scanline[i] if ai < 0: a = c = 0 else: a = result[ai] c = previous[ai] b = previous[i] p = a + b - c pa = abs(p - a) pb = abs(p - b) pc = abs(p - c) if pa <= pb and pa <= pc: pr = a elif pb <= pc: pr = b else: pr = c result[i] = (x + pr) & 0xff ai += 1 # Call appropriate filter algorithm. Note that 0 has already # been dealt with. (None, pngfilters.undo_filter_sub, pngfilters.undo_filter_up, pngfilters.undo_filter_average, pngfilters.undo_filter_paeth)[filter_type](fu, scanline, previous, result) return result def deinterlace(self, raw): """ Read raw pixel data, undo filters, deinterlace, and flatten. Return in flat row flat pixel format. """ # print >> sys.stderr, ("Reading interlaced, w=%s, r=%s, planes=%s," + # " bpp=%s") % (self.width, self.height, self.planes, self.bps) # Values per row (of the target image) vpr = self.width * self.planes # Make a result array, and make it big enough. Interleaving # writes to the output array randomly (well, not quite), so the # entire output array must be in memory. fmt = 'BH'[self.bitdepth > 8] a = array(fmt, [0]*vpr*self.height) source_offset = 0 for xstart, ystart, xstep, ystep in _adam7: # print >> sys.stderr, "Adam7: start=%s,%s step=%s,%s" % ( # xstart, ystart, xstep, ystep) if xstart >= self.width: continue # The previous (reconstructed) scanline. None at the # beginning of a pass to indicate that there is no previous # line. recon = None # Pixels per row (reduced pass image) ppr = int(math.ceil((self.width-xstart)/float(xstep))) # Row size in bytes for this pass. row_size = int(math.ceil(self.psize * ppr)) for y in range(ystart, self.height, ystep): filter_type = raw[source_offset] source_offset += 1 scanline = raw[source_offset:source_offset+row_size] source_offset += row_size recon = self.undo_filter(filter_type, scanline, recon) # Convert so that there is one element per pixel value flat = self.serialtoflat(recon, ppr) if xstep == 1: assert xstart == 0 offset = y * vpr a[offset:offset+vpr] = flat else: offset = y * vpr + xstart * self.planes end_offset = (y+1) * vpr skip = self.planes * xstep for i in range(self.planes): a[offset+i:end_offset:skip] = \ flat[i::self.planes] return a def iterboxed(self, rows): """Iterator that yields each scanline in boxed row flat pixel format. `rows` should be an iterator that yields the bytes of each row in turn. """ def asvalues(raw): """Convert a row of raw bytes into a flat row. Result may or may not share with argument""" if self.bitdepth == 8: return raw if self.bitdepth == 16: raw = tostring(raw) return array('H', struct.unpack('!%dH' % (len(raw)//2), raw)) assert self.bitdepth < 8 width = self.width # Samples per byte spb = 8//self.bitdepth out = array('B') mask = 2**self.bitdepth - 1 shifts = map(self.bitdepth.__mul__, reversed(range(spb))) for o in raw: out.extend(map(lambda i: mask&(o>>i), shifts)) return out[:width] return itertools.imap(asvalues, rows) def serialtoflat(self, bytes, width=None): """Convert serial format (byte stream) pixel data to flat row flat pixel. """ if self.bitdepth == 8: return bytes if self.bitdepth == 16: bytes = tostring(bytes) return array('H', struct.unpack('!%dH' % (len(bytes)//2), bytes)) assert self.bitdepth < 8 if width is None: width = self.width # Samples per byte spb = 8//self.bitdepth out = array('B') mask = 2**self.bitdepth - 1 shifts = map(self.bitdepth.__mul__, reversed(range(spb))) l = width for o in bytes: out.extend([(mask&(o>>s)) for s in shifts][:l]) l -= spb if l <= 0: l = width return out def iterstraight(self, raw): """Iterator that undoes the effect of filtering, and yields each row in serialised format (as a sequence of bytes). Assumes input is straightlaced. `raw` should be an iterable that yields the raw bytes in chunks of arbitrary size.""" # length of row, in bytes rb = self.row_bytes a = array('B') # The previous (reconstructed) scanline. None indicates first # line of image. recon = None for some in raw: a.extend(some) while len(a) >= rb + 1: filter_type = a[0] scanline = a[1:rb+1] del a[:rb+1] recon = self.undo_filter(filter_type, scanline, recon) yield recon if len(a) != 0: # :file:format We get here with a file format error: when the # available bytes (after decompressing) do not pack into exact # rows. raise FormatError( 'Wrong size for decompressed IDAT chunk.') assert len(a) == 0 def validate_signature(self): """If signature (header) has not been read then read and validate it; otherwise do nothing. """ if self.signature: return self.signature = self.file.read(8) if self.signature != _signature: raise FormatError("PNG file has invalid signature.") def preamble(self, lenient=False): """ Extract the image metadata by reading the initial part of the PNG file up to the start of the ``IDAT`` chunk. All the chunks that precede the ``IDAT`` chunk are read and either processed for metadata or discarded. If the optional `lenient` argument evaluates to True, checksum failures will raise warnings rather than exceptions. """ self.validate_signature() while True: if not self.atchunk: self.atchunk = self.chunklentype() if self.atchunk is None: raise FormatError( 'This PNG file has no IDAT chunks.') if self.atchunk[1] == 'IDAT': return self.process_chunk(lenient=lenient) def chunklentype(self): """Reads just enough of the input to determine the next chunk's length and type, returned as a (*length*, *type*) pair where *type* is a string. If there are no more chunks, ``None`` is returned. """ x = self.file.read(8) if not x: return None if len(x) != 8: raise FormatError( 'End of file whilst reading chunk length and type.') length,type = struct.unpack('!I4s', x) type = bytestostr(type) if length > 2**31-1: raise FormatError('Chunk %s is too large: %d.' % (type,length)) return length,type def process_chunk(self, lenient=False): """Process the next chunk and its data. This only processes the following chunk types, all others are ignored: ``IHDR``, ``PLTE``, ``bKGD``, ``tRNS``, ``gAMA``, ``sBIT``. If the optional `lenient` argument evaluates to True, checksum failures will raise warnings rather than exceptions. """ type, data = self.chunk(lenient=lenient) if type == 'IHDR': # http://www.w3.org/TR/PNG/#11IHDR if len(data) != 13: raise FormatError('IHDR chunk has incorrect length.') (self.width, self.height, self.bitdepth, self.color_type, self.compression, self.filter, self.interlace) = struct.unpack("!2I5B", data) # Check that the header specifies only valid combinations. if self.bitdepth not in (1,2,4,8,16): raise Error("invalid bit depth %d" % self.bitdepth) if self.color_type not in (0,2,3,4,6): raise Error("invalid colour type %d" % self.color_type) # Check indexed (palettized) images have 8 or fewer bits # per pixel; check only indexed or greyscale images have # fewer than 8 bits per pixel. if ((self.color_type & 1 and self.bitdepth > 8) or (self.bitdepth < 8 and self.color_type not in (0,3))): raise FormatError("Illegal combination of bit depth (%d)" " and colour type (%d)." " See http://www.w3.org/TR/2003/REC-PNG-20031110/#table111 ." % (self.bitdepth, self.color_type)) if self.compression != 0: raise Error("unknown compression method %d" % self.compression) if self.filter != 0: raise FormatError("Unknown filter method %d," " see http://www.w3.org/TR/2003/REC-PNG-20031110/#9Filters ." % self.filter) if self.interlace not in (0,1): raise FormatError("Unknown interlace method %d," " see http://www.w3.org/TR/2003/REC-PNG-20031110/#8InterlaceMethods ." % self.interlace) # Derived values # http://www.w3.org/TR/PNG/#6Colour-values colormap = bool(self.color_type & 1) greyscale = not (self.color_type & 2) alpha = bool(self.color_type & 4) color_planes = (3,1)[greyscale or colormap] planes = color_planes + alpha self.colormap = colormap self.greyscale = greyscale self.alpha = alpha self.color_planes = color_planes self.planes = planes self.psize = float(self.bitdepth)/float(8) * planes if int(self.psize) == self.psize: self.psize = int(self.psize) self.row_bytes = int(math.ceil(self.width * self.psize)) # Stores PLTE chunk if present, and is used to check # chunk ordering constraints. self.plte = None # Stores tRNS chunk if present, and is used to check chunk # ordering constraints. self.trns = None # Stores sbit chunk if present. self.sbit = None elif type == 'PLTE': # http://www.w3.org/TR/PNG/#11PLTE if self.plte: warnings.warn("Multiple PLTE chunks present.") self.plte = data if len(data) % 3 != 0: raise FormatError( "PLTE chunk's length should be a multiple of 3.") if len(data) > (2**self.bitdepth)*3: raise FormatError("PLTE chunk is too long.") if len(data) == 0: raise FormatError("Empty PLTE is not allowed.") elif type == 'bKGD': try: if self.colormap: if not self.plte: warnings.warn( "PLTE chunk is required before bKGD chunk.") self.background = struct.unpack('B', data) else: self.background = struct.unpack("!%dH" % self.color_planes, data) except struct.error: raise FormatError("bKGD chunk has incorrect length.") elif type == 'tRNS': # http://www.w3.org/TR/PNG/#11tRNS self.trns = data if self.colormap: if not self.plte: warnings.warn("PLTE chunk is required before tRNS chunk.") else: if len(data) > len(self.plte)/3: # Was warning, but promoted to Error as it # would otherwise cause pain later on. raise FormatError("tRNS chunk is too long.") else: if self.alpha: raise FormatError( "tRNS chunk is not valid with colour type %d." % self.color_type) try: self.transparent = \ struct.unpack("!%dH" % self.color_planes, data) except struct.error: raise FormatError("tRNS chunk has incorrect length.") elif type == 'gAMA': try: self.gamma = struct.unpack("!L", data)[0] / 100000.0 except struct.error: raise FormatError("gAMA chunk has incorrect length.") elif type == 'sBIT': self.sbit = data if (self.colormap and len(data) != 3 or not self.colormap and len(data) != self.planes): raise FormatError("sBIT chunk has incorrect length.") def read(self, lenient=False): """ Read the PNG file and decode it. Returns (`width`, `height`, `pixels`, `metadata`). May use excessive memory. `pixels` are returned in boxed row flat pixel format. If the optional `lenient` argument evaluates to True, checksum failures will raise warnings rather than exceptions. """ def iteridat(): """Iterator that yields all the ``IDAT`` chunks as strings.""" while True: try: type, data = self.chunk(lenient=lenient) except ValueError, e: raise ChunkError(e.args[0]) if type == 'IEND': # http://www.w3.org/TR/PNG/#11IEND break if type != 'IDAT': continue # type == 'IDAT' # http://www.w3.org/TR/PNG/#11IDAT if self.colormap and not self.plte: warnings.warn("PLTE chunk is required before IDAT chunk") yield data def iterdecomp(idat): """Iterator that yields decompressed strings. `idat` should be an iterator that yields the ``IDAT`` chunk data. """ # Currently, with no max_length paramter to decompress, this # routine will do one yield per IDAT chunk. So not very # incremental. d = zlib.decompressobj() # Each IDAT chunk is passed to the decompressor, then any # remaining state is decompressed out. for data in idat: # :todo: add a max_length argument here to limit output # size. yield array('B', d.decompress(data)) yield array('B', d.flush()) self.preamble(lenient=lenient) raw = iterdecomp(iteridat()) if self.interlace: raw = array('B', itertools.chain(*raw)) arraycode = 'BH'[self.bitdepth>8] # Like :meth:`group` but producing an array.array object for # each row. pixels = itertools.imap(lambda *row: array(arraycode, row), *[iter(self.deinterlace(raw))]*self.width*self.planes) else: pixels = self.iterboxed(self.iterstraight(raw)) meta = dict() for attr in 'greyscale alpha planes bitdepth interlace'.split(): meta[attr] = getattr(self, attr) meta['size'] = (self.width, self.height) for attr in 'gamma transparent background'.split(): a = getattr(self, attr, None) if a is not None: meta[attr] = a if self.plte: meta['palette'] = self.palette() return self.width, self.height, pixels, meta def read_flat(self): """ Read a PNG file and decode it into flat row flat pixel format. Returns (*width*, *height*, *pixels*, *metadata*). May use excessive memory. `pixels` are returned in flat row flat pixel format. See also the :meth:`read` method which returns pixels in the more stream-friendly boxed row flat pixel format. """ x, y, pixel, meta = self.read() arraycode = 'BH'[meta['bitdepth']>8] pixel = array(arraycode, itertools.chain(*pixel)) return x, y, pixel, meta def palette(self, alpha='natural'): """Returns a palette that is a sequence of 3-tuples or 4-tuples, synthesizing it from the ``PLTE`` and ``tRNS`` chunks. These chunks should have already been processed (for example, by calling the :meth:`preamble` method). All the tuples are the same size: 3-tuples if there is no ``tRNS`` chunk, 4-tuples when there is a ``tRNS`` chunk. Assumes that the image is colour type 3 and therefore a ``PLTE`` chunk is required. If the `alpha` argument is ``'force'`` then an alpha channel is always added, forcing the result to be a sequence of 4-tuples. """ if not self.plte: raise FormatError( "Required PLTE chunk is missing in colour type 3 image.") plte = group(array('B', self.plte), 3) if self.trns or alpha == 'force': trns = array('B', self.trns or '') trns.extend([255]*(len(plte)-len(trns))) plte = map(operator.add, plte, group(trns, 1)) return plte def asDirect(self): """Returns the image data as a direct representation of an ``x * y * planes`` array. This method is intended to remove the need for callers to deal with palettes and transparency themselves. Images with a palette (colour type 3) are converted to RGB or RGBA; images with transparency (a ``tRNS`` chunk) are converted to LA or RGBA as appropriate. When returned in this format the pixel values represent the colour value directly without needing to refer to palettes or transparency information. Like the :meth:`read` method this method returns a 4-tuple: (*width*, *height*, *pixels*, *meta*) This method normally returns pixel values with the bit depth they have in the source image, but when the source PNG has an ``sBIT`` chunk it is inspected and can reduce the bit depth of the result pixels; pixel values will be reduced according to the bit depth specified in the ``sBIT`` chunk (PNG nerds should note a single result bit depth is used for all channels; the maximum of the ones specified in the ``sBIT`` chunk. An RGB565 image will be rescaled to 6-bit RGB666). The *meta* dictionary that is returned reflects the `direct` format and not the original source image. For example, an RGB source image with a ``tRNS`` chunk to represent a transparent colour, will have ``planes=3`` and ``alpha=False`` for the source image, but the *meta* dictionary returned by this method will have ``planes=4`` and ``alpha=True`` because an alpha channel is synthesized and added. *pixels* is the pixel data in boxed row flat pixel format (just like the :meth:`read` method). All the other aspects of the image data are not changed. """ self.preamble() # Simple case, no conversion necessary. if not self.colormap and not self.trns and not self.sbit: return self.read() x,y,pixels,meta = self.read() if self.colormap: meta['colormap'] = False meta['alpha'] = bool(self.trns) meta['bitdepth'] = 8 meta['planes'] = 3 + bool(self.trns) plte = self.palette() def iterpal(pixels): for row in pixels: row = map(plte.__getitem__, row) yield array('B', itertools.chain(*row)) pixels = iterpal(pixels) elif self.trns: # It would be nice if there was some reasonable way of doing # this without generating a whole load of intermediate tuples. # But tuples does seem like the easiest way, with no other way # clearly much simpler or much faster. (Actually, the L to LA # conversion could perhaps go faster (all those 1-tuples!), but # I still wonder whether the code proliferation is worth it) it = self.transparent maxval = 2**meta['bitdepth']-1 planes = meta['planes'] meta['alpha'] = True meta['planes'] += 1 typecode = 'BH'[meta['bitdepth']>8] def itertrns(pixels): for row in pixels: # For each row we group it into pixels, then form a # characterisation vector that says whether each pixel # is opaque or not. Then we convert True/False to # 0/maxval (by multiplication), and add it as the extra # channel. row = group(row, planes) opa = map(it.__ne__, row) opa = map(maxval.__mul__, opa) opa = zip(opa) # convert to 1-tuples yield array(typecode, itertools.chain(*map(operator.add, row, opa))) pixels = itertrns(pixels) targetbitdepth = None if self.sbit: sbit = struct.unpack('%dB' % len(self.sbit), self.sbit) targetbitdepth = max(sbit) if targetbitdepth > meta['bitdepth']: raise Error('sBIT chunk %r exceeds bitdepth %d' % (sbit,self.bitdepth)) if min(sbit) <= 0: raise Error('sBIT chunk %r has a 0-entry' % sbit) if targetbitdepth == meta['bitdepth']: targetbitdepth = None if targetbitdepth: shift = meta['bitdepth'] - targetbitdepth meta['bitdepth'] = targetbitdepth def itershift(pixels): for row in pixels: yield map(shift.__rrshift__, row) pixels = itershift(pixels) return x,y,pixels,meta def asFloat(self, maxval=1.0): """Return image pixels as per :meth:`asDirect` method, but scale all pixel values to be floating point values between 0.0 and *maxval*. """ x,y,pixels,info = self.asDirect() sourcemaxval = 2**info['bitdepth']-1 del info['bitdepth'] info['maxval'] = float(maxval) factor = float(maxval)/float(sourcemaxval) def iterfloat(): for row in pixels: yield map(factor.__mul__, row) return x,y,iterfloat(),info def _as_rescale(self, get, targetbitdepth): """Helper used by :meth:`asRGB8` and :meth:`asRGBA8`.""" width,height,pixels,meta = get() maxval = 2**meta['bitdepth'] - 1 targetmaxval = 2**targetbitdepth - 1 factor = float(targetmaxval) / float(maxval) meta['bitdepth'] = targetbitdepth def iterscale(): for row in pixels: yield map(lambda x: int(round(x*factor)), row) if maxval == targetmaxval: return width, height, pixels, meta else: return width, height, iterscale(), meta def asRGB8(self): """Return the image data as an RGB pixels with 8-bits per sample. This is like the :meth:`asRGB` method except that this method additionally rescales the values so that they are all between 0 and 255 (8-bit). In the case where the source image has a bit depth < 8 the transformation preserves all the information; where the source image has bit depth > 8, then rescaling to 8-bit values loses precision. No dithering is performed. Like :meth:`asRGB`, an alpha channel in the source image will raise an exception. This function returns a 4-tuple: (*width*, *height*, *pixels*, *metadata*). *width*, *height*, *metadata* are as per the :meth:`read` method. *pixels* is the pixel data in boxed row flat pixel format. """ return self._as_rescale(self.asRGB, 8) def asRGBA8(self): """Return the image data as RGBA pixels with 8-bits per sample. This method is similar to :meth:`asRGB8` and :meth:`asRGBA`: The result pixels have an alpha channel, *and* values are rescaled to the range 0 to 255. The alpha channel is synthesized if necessary (with a small speed penalty). """ return self._as_rescale(self.asRGBA, 8) def asRGB(self): """Return image as RGB pixels. RGB colour images are passed through unchanged; greyscales are expanded into RGB triplets (there is a small speed overhead for doing this). An alpha channel in the source image will raise an exception. The return values are as for the :meth:`read` method except that the *metadata* reflect the returned pixels, not the source image. In particular, for this method ``metadata['greyscale']`` will be ``False``. """ width,height,pixels,meta = self.asDirect() if meta['alpha']: raise Error("will not convert image with alpha channel to RGB") if not meta['greyscale']: return width,height,pixels,meta meta['greyscale'] = False typecode = 'BH'[meta['bitdepth'] > 8] def iterrgb(): for row in pixels: a = array(typecode, [0]) * 3 * width for i in range(3): a[i::3] = row yield a return width,height,iterrgb(),meta def asRGBA(self): """Return image as RGBA pixels. Greyscales are expanded into RGB triplets; an alpha channel is synthesized if necessary. The return values are as for the :meth:`read` method except that the *metadata* reflect the returned pixels, not the source image. In particular, for this method ``metadata['greyscale']`` will be ``False``, and ``metadata['alpha']`` will be ``True``. """ width,height,pixels,meta = self.asDirect() if meta['alpha'] and not meta['greyscale']: return width,height,pixels,meta typecode = 'BH'[meta['bitdepth'] > 8] maxval = 2**meta['bitdepth'] - 1 maxbuffer = struct.pack('=' + typecode, maxval) * 4 * width def newarray(): return array(typecode, maxbuffer) if meta['alpha'] and meta['greyscale']: # LA to RGBA def convert(): for row in pixels: # Create a fresh target row, then copy L channel # into first three target channels, and A channel # into fourth channel. a = newarray() pngfilters.convert_la_to_rgba(row, a) yield a elif meta['greyscale']: # L to RGBA def convert(): for row in pixels: a = newarray() pngfilters.convert_l_to_rgba(row, a) yield a else: assert not meta['alpha'] and not meta['greyscale'] # RGB to RGBA def convert(): for row in pixels: a = newarray() pngfilters.convert_rgb_to_rgba(row, a) yield a meta['alpha'] = True meta['greyscale'] = False return width,height,convert(),meta # === Legacy Version Support === # :pyver:old: PyPNG works on Python versions 2.3 and 2.2, but not # without some awkward problems. Really PyPNG works on Python 2.4 (and # above); it works on Pythons 2.3 and 2.2 by virtue of fixing up # problems here. It's a bit ugly (which is why it's hidden down here). # # Generally the strategy is one of pretending that we're running on # Python 2.4 (or above), and patching up the library support on earlier # versions so that it looks enough like Python 2.4. When it comes to # Python 2.2 there is one thing we cannot patch: extended slices # http://www.python.org/doc/2.3/whatsnew/section-slices.html. # Instead we simply declare that features that are implemented using # extended slices will not work on Python 2.2. # # In order to work on Python 2.3 we fix up a recurring annoyance involving # the array type. In Python 2.3 an array cannot be initialised with an # array, and it cannot be extended with a list (or other sequence). # Both of those are repeated issues in the code. Whilst I would not # normally tolerate this sort of behaviour, here we "shim" a replacement # for array into place (and hope no-ones notices). You never read this. # # In an amusing case of warty hacks on top of warty hacks... the array # shimming we try and do only works on Python 2.3 and above (you can't # subclass array.array in Python 2.2). So to get it working on Python # 2.2 we go for something much simpler and (probably) way slower. try: array('B').extend([]) array('B', array('B')) except: # Expect to get here on Python 2.3 try: class _array_shim(array): true_array = array def __new__(cls, typecode, init=None): super_new = super(_array_shim, cls).__new__ it = super_new(cls, typecode) if init is None: return it it.extend(init) return it def extend(self, extension): super_extend = super(_array_shim, self).extend if isinstance(extension, self.true_array): return super_extend(extension) if not isinstance(extension, (list, str)): # Convert to list. Allows iterators to work. extension = list(extension) return super_extend(self.true_array(self.typecode, extension)) array = _array_shim except: # Expect to get here on Python 2.2 def array(typecode, init=()): if type(init) == str: return map(ord, init) return list(init) # Further hacks to get it limping along on Python 2.2 try: enumerate except: def enumerate(seq): i=0 for x in seq: yield i,x i += 1 try: reversed except: def reversed(l): l = list(l) l.reverse() for x in l: yield x try: itertools except: class _dummy_itertools: pass itertools = _dummy_itertools() def _itertools_imap(f, seq): for x in seq: yield f(x) itertools.imap = _itertools_imap def _itertools_chain(*iterables): for it in iterables: for element in it: yield element itertools.chain = _itertools_chain # === Support for users without Cython === try: pngfilters except: class pngfilters(object): def undo_filter_sub(filter_unit, scanline, previous, result): """Undo sub filter.""" ai = 0 # Loops starts at index fu. Observe that the initial part # of the result is already filled in correctly with # scanline. for i in range(filter_unit, len(result)): x = scanline[i] a = result[ai] result[i] = (x + a) & 0xff ai += 1 undo_filter_sub = staticmethod(undo_filter_sub) def undo_filter_up(filter_unit, scanline, previous, result): """Undo up filter.""" for i in range(len(result)): x = scanline[i] b = previous[i] result[i] = (x + b) & 0xff undo_filter_up = staticmethod(undo_filter_up) def undo_filter_average(filter_unit, scanline, previous, result): """Undo up filter.""" ai = -filter_unit for i in range(len(result)): x = scanline[i] if ai < 0: a = 0 else: a = result[ai] b = previous[i] result[i] = (x + ((a + b) >> 1)) & 0xff ai += 1 undo_filter_average = staticmethod(undo_filter_average) def undo_filter_paeth(filter_unit, scanline, previous, result): """Undo Paeth filter.""" # Also used for ci. ai = -filter_unit for i in range(len(result)): x = scanline[i] if ai < 0: a = c = 0 else: a = result[ai] c = previous[ai] b = previous[i] p = a + b - c pa = abs(p - a) pb = abs(p - b) pc = abs(p - c) if pa <= pb and pa <= pc: pr = a elif pb <= pc: pr = b else: pr = c result[i] = (x + pr) & 0xff ai += 1 undo_filter_paeth = staticmethod(undo_filter_paeth) def convert_la_to_rgba(row, result): for i in range(3): result[i::4] = row[0::2] result[3::4] = row[1::2] convert_la_to_rgba = staticmethod(convert_la_to_rgba) def convert_l_to_rgba(row, result): """Convert a grayscale image to RGBA. This method assumes the alpha channel in result is already correctly initialized.""" for i in range(3): result[i::4] = row convert_l_to_rgba = staticmethod(convert_l_to_rgba) def convert_rgb_to_rgba(row, result): """Convert an RGB image to RGBA. This method assumes the alpha channel in result is already correctly initialized.""" for i in range(3): result[i::4] = row[i::3] convert_rgb_to_rgba = staticmethod(convert_rgb_to_rgba) # === Internal Test Support === # This section comprises the tests that are internally validated (as # opposed to tests which produce output files that are externally # validated). Primarily they are unittests. # Note that it is difficult to internally validate the results of # writing a PNG file. The only thing we can do is read it back in # again, which merely checks consistency, not that the PNG file we # produce is valid. # Run the tests from the command line: # python -c 'import png;png.test()' # (For an in-memory binary file IO object) We use BytesIO where # available, otherwise we use StringIO, but name it BytesIO. try: from io import BytesIO except: from StringIO import StringIO as BytesIO import tempfile # http://www.python.org/doc/2.4.4/lib/module-unittest.html import unittest def test(): unittest.main(__name__) def topngbytes(name, rows, x, y, **k): """Convenience function for creating a PNG file "in memory" as a string. Creates a :class:`Writer` instance using the keyword arguments, then passes `rows` to its :meth:`Writer.write` method. The resulting PNG file is returned as a string. `name` is used to identify the file for debugging. """ import os print name f = BytesIO() w = Writer(x, y, **k) w.write(f, rows) if os.environ.get('PYPNG_TEST_TMP'): w = open(name, 'wb') w.write(f.getvalue()) w.close() return f.getvalue() def testWithIO(inp, out, f): """Calls the function `f` with ``sys.stdin`` changed to `inp` and ``sys.stdout`` changed to `out`. They are restored when `f` returns. This function returns whatever `f` returns. """ import os try: oldin,sys.stdin = sys.stdin,inp oldout,sys.stdout = sys.stdout,out x = f() finally: sys.stdin = oldin sys.stdout = oldout if os.environ.get('PYPNG_TEST_TMP') and hasattr(out,'getvalue'): name = mycallersname() if name: w = open(name+'.png', 'wb') w.write(out.getvalue()) w.close() return x def mycallersname(): """Returns the name of the caller of the caller of this function (hence the name of the caller of the function in which "mycallersname()" textually appears). Returns None if this cannot be determined.""" # http://docs.python.org/library/inspect.html#the-interpreter-stack import inspect frame = inspect.currentframe() if not frame: return None frame_,filename_,lineno_,funname,linelist_,listi_ = ( inspect.getouterframes(frame)[2]) return funname def seqtobytes(s): """Convert a sequence of integers to a *bytes* instance. Good for plastering over Python 2 / Python 3 cracks. """ return strtobytes(''.join(chr(x) for x in s)) class Test(unittest.TestCase): # This member is used by the superclass. If we don't define a new # class here then when we use self.assertRaises() and the PyPNG code # raises an assertion then we get no proper traceback. I can't work # out why, but defining a new class here means we get a proper # traceback. class failureException(Exception): pass def helperLN(self, n): mask = (1 << n) - 1 # Use small chunk_limit so that multiple chunk writing is # tested. Making it a test for Issue 20. w = Writer(15, 17, greyscale=True, bitdepth=n, chunk_limit=99) f = BytesIO() w.write_array(f, array('B', map(mask.__and__, range(1, 256)))) r = Reader(bytes=f.getvalue()) x,y,pixels,meta = r.read() self.assertEqual(x, 15) self.assertEqual(y, 17) self.assertEqual(list(itertools.chain(*pixels)), map(mask.__and__, range(1,256))) def testL8(self): return self.helperLN(8) def testL4(self): return self.helperLN(4) def testL2(self): "Also tests asRGB8." w = Writer(1, 4, greyscale=True, bitdepth=2) f = BytesIO() w.write_array(f, array('B', range(4))) r = Reader(bytes=f.getvalue()) x,y,pixels,meta = r.asRGB8() self.assertEqual(x, 1) self.assertEqual(y, 4) for i,row in enumerate(pixels): self.assertEqual(len(row), 3) self.assertEqual(list(row), [0x55*i]*3) def testP2(self): "2-bit palette." a = (255,255,255) b = (200,120,120) c = (50,99,50) w = Writer(1, 4, bitdepth=2, palette=[a,b,c]) f = BytesIO() w.write_array(f, array('B', (0,1,1,2))) r = Reader(bytes=f.getvalue()) x,y,pixels,meta = r.asRGB8() self.assertEqual(x, 1) self.assertEqual(y, 4) self.assertEqual(map(list, pixels), map(list, [a, b, b, c])) def testPtrns(self): "Test colour type 3 and tRNS chunk (and 4-bit palette)." a = (50,99,50,50) b = (200,120,120,80) c = (255,255,255) d = (200,120,120) e = (50,99,50) w = Writer(3, 3, bitdepth=4, palette=[a,b,c,d,e]) f = BytesIO() w.write_array(f, array('B', (4, 3, 2, 3, 2, 0, 2, 0, 1))) r = Reader(bytes=f.getvalue()) x,y,pixels,meta = r.asRGBA8() self.assertEqual(x, 3) self.assertEqual(y, 3) c = c+(255,) d = d+(255,) e = e+(255,) boxed = [(e,d,c),(d,c,a),(c,a,b)] flat = map(lambda row: itertools.chain(*row), boxed) self.assertEqual(map(list, pixels), map(list, flat)) def testRGBtoRGBA(self): "asRGBA8() on colour type 2 source.""" # Test for Issue 26 r = Reader(bytes=_pngsuite['basn2c08']) x,y,pixels,meta = r.asRGBA8() # Test the pixels at row 9 columns 0 and 1. row9 = list(pixels)[9] self.assertEqual(list(row9[0:8]), [0xff, 0xdf, 0xff, 0xff, 0xff, 0xde, 0xff, 0xff]) def testLtoRGBA(self): "asRGBA() on grey source.""" # Test for Issue 60 r = Reader(bytes=_pngsuite['basi0g08']) x,y,pixels,meta = r.asRGBA() row9 = list(list(pixels)[9]) self.assertEqual(row9[0:8], [222, 222, 222, 255, 221, 221, 221, 255]) def testCtrns(self): "Test colour type 2 and tRNS chunk." # Test for Issue 25 r = Reader(bytes=_pngsuite['tbrn2c08']) x,y,pixels,meta = r.asRGBA8() # I just happen to know that the first pixel is transparent. # In particular it should be #7f7f7f00 row0 = list(pixels)[0] self.assertEqual(tuple(row0[0:4]), (0x7f, 0x7f, 0x7f, 0x00)) def testAdam7read(self): """Adam7 interlace reading. Specifically, test that for images in the PngSuite that have both an interlaced and straightlaced pair that both images from the pair produce the same array of pixels.""" for candidate in _pngsuite: if not candidate.startswith('basn'): continue candi = candidate.replace('n', 'i') if candi not in _pngsuite: continue print 'adam7 read', candidate straight = Reader(bytes=_pngsuite[candidate]) adam7 = Reader(bytes=_pngsuite[candi]) # Just compare the pixels. Ignore x,y (because they're # likely to be correct?); metadata is ignored because the # "interlace" member differs. Lame. straight = straight.read()[2] adam7 = adam7.read()[2] self.assertEqual(map(list, straight), map(list, adam7)) def testAdam7write(self): """Adam7 interlace writing. For each test image in the PngSuite, write an interlaced and a straightlaced version. Decode both, and compare results. """ # Not such a great test, because the only way we can check what # we have written is to read it back again. for name,bytes in _pngsuite.items(): # Only certain colour types supported for this test. if name[3:5] not in ['n0', 'n2', 'n4', 'n6']: continue it = Reader(bytes=bytes) x,y,pixels,meta = it.read() pngi = topngbytes('adam7wn'+name+'.png', pixels, x=x, y=y, bitdepth=it.bitdepth, greyscale=it.greyscale, alpha=it.alpha, transparent=it.transparent, interlace=False) x,y,ps,meta = Reader(bytes=pngi).read() it = Reader(bytes=bytes) x,y,pixels,meta = it.read() pngs = topngbytes('adam7wi'+name+'.png', pixels, x=x, y=y, bitdepth=it.bitdepth, greyscale=it.greyscale, alpha=it.alpha, transparent=it.transparent, interlace=True) x,y,pi,meta = Reader(bytes=pngs).read() self.assertEqual(map(list, ps), map(list, pi)) def testPGMin(self): """Test that the command line tool can read PGM files.""" def do(): return _main(['testPGMin']) s = BytesIO() s.write(strtobytes('P5 2 2 3\n')) s.write(strtobytes('\x00\x01\x02\x03')) s.flush() s.seek(0) o = BytesIO() testWithIO(s, o, do) r = Reader(bytes=o.getvalue()) x,y,pixels,meta = r.read() self.assertTrue(r.greyscale) self.assertEqual(r.bitdepth, 2) def testPAMin(self): """Test that the command line tool can read PAM file.""" def do(): return _main(['testPAMin']) s = BytesIO() s.write(strtobytes('P7\nWIDTH 3\nHEIGHT 1\nDEPTH 4\nMAXVAL 255\n' 'TUPLTYPE RGB_ALPHA\nENDHDR\n')) # The pixels in flat row flat pixel format flat = [255,0,0,255, 0,255,0,120, 0,0,255,30] asbytes = seqtobytes(flat) s.write(asbytes) s.flush() s.seek(0) o = BytesIO() testWithIO(s, o, do) r = Reader(bytes=o.getvalue()) x,y,pixels,meta = r.read() self.assertTrue(r.alpha) self.assertTrue(not r.greyscale) self.assertEqual(list(itertools.chain(*pixels)), flat) def testLA4(self): """Create an LA image with bitdepth 4.""" bytes = topngbytes('la4.png', [[5, 12]], 1, 1, greyscale=True, alpha=True, bitdepth=4) sbit = Reader(bytes=bytes).chunk('sBIT')[1] self.assertEqual(sbit, strtobytes('\x04\x04')) def testPal(self): """Test that a palette PNG returns the palette in info.""" r = Reader(bytes=_pngsuite['basn3p04']) x,y,pixels,info = r.read() self.assertEqual(x, 32) self.assertEqual(y, 32) self.assertTrue('palette' in info) def testPalWrite(self): """Test metadata for paletted PNG can be passed from one PNG to another.""" r = Reader(bytes=_pngsuite['basn3p04']) x,y,pixels,info = r.read() w = Writer(**info) o = BytesIO() w.write(o, pixels) o.flush() o.seek(0) r = Reader(file=o) _,_,_,again_info = r.read() # Same palette self.assertEqual(again_info['palette'], info['palette']) def testPalExpand(self): """Test that bitdepth can be used to fiddle with pallete image.""" r = Reader(bytes=_pngsuite['basn3p04']) x,y,pixels,info = r.read() pixels = [list(row) for row in pixels] info['bitdepth'] = 8 w = Writer(**info) o = BytesIO() w.write(o, pixels) o.flush() o.seek(0) r = Reader(file=o) _,_,again_pixels,again_info = r.read() # Same pixels again_pixels = [list(row) for row in again_pixels] self.assertEqual(again_pixels, pixels) def testPNMsbit(self): """Test that PNM files can generates sBIT chunk.""" def do(): return _main(['testPNMsbit']) s = BytesIO() s.write(strtobytes('P6 8 1 1\n')) for pixel in range(8): s.write(struct.pack('>sys.stderr, "skipping numpy test" return rows = [map(numpy.uint16, range(0,0x10000,0x5555))] b = topngbytes('numpyuint16.png', rows, 4, 1, greyscale=True, alpha=False, bitdepth=16) def testNumpyuint8(self): """numpy uint8.""" try: import numpy except ImportError: print >>sys.stderr, "skipping numpy test" return rows = [map(numpy.uint8, range(0,0x100,0x55))] b = topngbytes('numpyuint8.png', rows, 4, 1, greyscale=True, alpha=False, bitdepth=8) def testNumpybool(self): """numpy bool.""" try: import numpy except ImportError: print >>sys.stderr, "skipping numpy test" return rows = [map(numpy.bool, [0,1])] b = topngbytes('numpybool.png', rows, 2, 1, greyscale=True, alpha=False, bitdepth=1) def testNumpyarray(self): """numpy array.""" try: import numpy except ImportError: print >>sys.stderr, "skipping numpy test" return pixels = numpy.array([[0,0x5555],[0x5555,0xaaaa]], numpy.uint16) img = from_array(pixels, 'L') img.save('testnumpyL16.png') def paeth(self, x, a, b, c): p = a + b - c pa = abs(p - a) pb = abs(p - b) pc = abs(p - c) if pa <= pb and pa <= pc: pr = a elif pb <= pc: pr = b else: pr = c return x - pr # test filters and unfilters def testFilterScanlineFirstLine(self): fo = 3 # bytes per pixel line = [30, 31, 32, 230, 231, 232] out = filter_scanline(0, line, fo, None) # none self.assertEqual(list(out), [0, 30, 31, 32, 230, 231, 232]) out = filter_scanline(1, line, fo, None) # sub self.assertEqual(list(out), [1, 30, 31, 32, 200, 200, 200]) out = filter_scanline(2, line, fo, None) # up # TODO: All filtered scanlines start with a byte indicating the filter # algorithm, except "up". Is this a bug? Should the expected output # start with 2 here? self.assertEqual(list(out), [30, 31, 32, 230, 231, 232]) out = filter_scanline(3, line, fo, None) # average self.assertEqual(list(out), [3, 30, 31, 32, 215, 216, 216]) out = filter_scanline(4, line, fo, None) # paeth self.assertEqual(list(out), [ 4, self.paeth(30, 0, 0, 0), self.paeth(31, 0, 0, 0), self.paeth(32, 0, 0, 0), self.paeth(230, 30, 0, 0), self.paeth(231, 31, 0, 0), self.paeth(232, 32, 0, 0) ]) def testFilterScanline(self): prev = [20, 21, 22, 210, 211, 212] line = [30, 32, 34, 230, 233, 236] fo = 3 out = filter_scanline(0, line, fo, prev) # none self.assertEqual(list(out), [0, 30, 32, 34, 230, 233, 236]) out = filter_scanline(1, line, fo, prev) # sub self.assertEqual(list(out), [1, 30, 32, 34, 200, 201, 202]) out = filter_scanline(2, line, fo, prev) # up self.assertEqual(list(out), [2, 10, 11, 12, 20, 22, 24]) out = filter_scanline(3, line, fo, prev) # average self.assertEqual(list(out), [3, 20, 22, 23, 110, 112, 113]) out = filter_scanline(4, line, fo, prev) # paeth self.assertEqual(list(out), [ 4, self.paeth(30, 0, 20, 0), self.paeth(32, 0, 21, 0), self.paeth(34, 0, 22, 0), self.paeth(230, 30, 210, 20), self.paeth(233, 32, 211, 21), self.paeth(236, 34, 212, 22) ]) def testUnfilterScanline(self): reader = Reader(bytes='') reader.psize = 3 scanprev = array('B', [20, 21, 22, 210, 211, 212]) scanline = array('B', [30, 32, 34, 230, 233, 236]) def cp(a): return array('B', a) out = reader.undo_filter(0, cp(scanline), cp(scanprev)) self.assertEqual(list(out), list(scanline)) # none out = reader.undo_filter(1, cp(scanline), cp(scanprev)) self.assertEqual(list(out), [30, 32, 34, 4, 9, 14]) # sub out = reader.undo_filter(2, cp(scanline), cp(scanprev)) self.assertEqual(list(out), [50, 53, 56, 184, 188, 192]) # up out = reader.undo_filter(3, cp(scanline), cp(scanprev)) self.assertEqual(list(out), [40, 42, 45, 99, 103, 108]) # average out = reader.undo_filter(4, cp(scanline), cp(scanprev)) self.assertEqual(list(out), [50, 53, 56, 184, 188, 192]) # paeth def testUnfilterScanlinePaeth(self): # This tests more edge cases in the paeth unfilter reader = Reader(bytes='') reader.psize = 3 scanprev = array('B', [2, 0, 0, 0, 9, 11]) scanline = array('B', [6, 10, 9, 100, 101, 102]) out = reader.undo_filter(4, scanline, scanprev) self.assertEqual(list(out), [8, 10, 9, 108, 111, 113]) # paeth def testIterstraight(self): def arraify(list_of_str): return [array('B', s) for s in list_of_str] reader = Reader(bytes='') reader.row_bytes = 6 reader.psize = 3 rows = reader.iterstraight(arraify(['\x00abcdef', '\x00ghijkl'])) self.assertEqual(list(rows), arraify(['abcdef', 'ghijkl'])) rows = reader.iterstraight(arraify(['\x00abc', 'def\x00ghijkl'])) self.assertEqual(list(rows), arraify(['abcdef', 'ghijkl'])) rows = reader.iterstraight(arraify(['\x00abcdef\x00ghijkl'])) self.assertEqual(list(rows), arraify(['abcdef', 'ghijkl'])) rows = reader.iterstraight(arraify(['\x00abcdef\x00ghi', 'jkl'])) self.assertEqual(list(rows), arraify(['abcdef', 'ghijkl'])) # === Command Line Support === def _dehex(s): """Liberally convert from hex string to binary string.""" import re import binascii # Remove all non-hexadecimal digits s = re.sub(r'[^a-fA-F\d]', '', s) # binscii.unhexlify works in Python 2 and Python 3 (unlike # thing.decode('hex')). return binascii.unhexlify(strtobytes(s)) def _enhex(s): """Convert from binary string (bytes) to hex string (str).""" import binascii return bytestostr(binascii.hexlify(s)) # Copies of PngSuite test files taken # from http://www.schaik.com/pngsuite/pngsuite_bas_png.html # on 2009-02-19 by drj and converted to hex. # Some of these are not actually in PngSuite (but maybe they should # be?), they use the same naming scheme, but start with a capital # letter. _pngsuite = { 'basi0g01': _dehex(""" 89504e470d0a1a0a0000000d49484452000000200000002001000000012c0677 cf0000000467414d41000186a031e8965f0000009049444154789c2d8d310ec2 300c45dfc682c415187a00a42e197ab81e83b127e00c5639001363a580d8582c 65c910357c4b78b0bfbfdf4f70168c19e7acb970a3f2d1ded9695ce5bf5963df d92aaf4c9fd927ea449e6487df5b9c36e799b91bdf082b4d4bd4014fe4014b01 ab7a17aee694d28d328a2d63837a70451e1648702d9a9ff4a11d2f7a51aa21e5 a18c7ffd0094e3511d661822f20000000049454e44ae426082 """), 'basi0g02': _dehex(""" 89504e470d0a1a0a0000000d49484452000000200000002002000000016ba60d 1f0000000467414d41000186a031e8965f0000005149444154789c635062e860 00e17286bb609c93c370ec189494960631366e4467b3ae675dcf10f521ea0303 90c1ca006444e11643482064114a4852c710baea3f18c31918020c30410403a6 0ac1a09239009c52804d85b6d97d0000000049454e44ae426082 """), 'basi0g04': _dehex(""" 89504e470d0a1a0a0000000d4948445200000020000000200400000001e4e6f8 bf0000000467414d41000186a031e8965f000000ae49444154789c658e5111c2 301044171c141c141c041c843a287510ea20d441c041c141c141c04191102454 03994998cecd7edcecedbb9bdbc3b2c2b6457545fbc4bac1be437347f7c66a77 3c23d60db15e88f5c5627338a5416c2e691a9b475a89cd27eda12895ae8dfdab 43d61e590764f5c83a226b40d669bec307f93247701687723abf31ff83a2284b a5b4ae6b63ac6520ad730ca4ed7b06d20e030369bd6720ed383290360406d24e 13811f2781eba9d34d07160000000049454e44ae426082 """), 'basi0g08': _dehex(""" 89504e470d0a1a0a0000000d4948445200000020000000200800000001211615 be0000000467414d41000186a031e8965f000000b549444154789cb5905d0ac2 3010849dbac81c42c47bf843cf253e8878b0aa17110f214bdca6be240f5d21a5 94ced3e49bcd322c1624115515154998aa424822a82a5624a1aa8a8b24c58f99 999908130989a04a00d76c2c09e76cf21adcb209393a6553577da17140a2c59e 70ecbfa388dff1f03b82fb82bd07f05f7cb13f80bb07ad2fd60c011c3c588eef f1f4e03bbec7ce832dca927aea005e431b625796345307b019c845e6bfc3bb98 769d84f9efb02ea6c00f9bb9ff45e81f9f280000000049454e44ae426082 """), 'basi0g16': _dehex(""" 89504e470d0a1a0a0000000d49484452000000200000002010000000017186c9 fd0000000467414d41000186a031e8965f000000e249444154789cb5913b0ec2 301044c7490aa8f85d81c3e4301c8f53a4ca0da8902c8144b3920b4043111282 23bc4956681a6bf5fc3c5a3ba0448912d91a4de2c38dd8e380231eede4c4f7a1 4677700bec7bd9b1d344689315a3418d1a6efbe5b8305ba01f8ff4808c063e26 c60d5c81edcf6c58c535e252839e93801b15c0a70d810ae0d306b205dc32b187 272b64057e4720ff0502154034831520154034c3df81400510cdf0015c86e5cc 5c79c639fddba9dcb5456b51d7980eb52d8e7d7fa620a75120d6064641a05120 b606771a05626b401a05f1f589827cf0fe44c1f0bae0055698ee8914fffffe00 00000049454e44ae426082 """), 'basi2c08': _dehex(""" 89504e470d0a1a0a0000000d49484452000000200000002008020000018b1fdd 350000000467414d41000186a031e8965f000000f249444154789cd59341aa04 210c44abc07b78133d59d37333bd89d76868b566d10cf4675af8596431a11662 7c5688919280e312257dd6a0a4cf1a01008ee312a5f3c69c37e6fcc3f47e6776 a07f8bdaf5b40feed2d33e025e2ff4fe2d4a63e1a16d91180b736d8bc45854c5 6d951863f4a7e0b66dcf09a900f3ffa2948d4091e53ca86c048a64390f662b50 4a999660ced906182b9a01a8be00a56404a6ede182b1223b4025e32c4de34304 63457680c93aada6c99b73865aab2fc094920d901a203f5ddfe1970d28456783 26cffbafeffcd30654f46d119be4793f827387fc0d189d5bc4d69a3c23d45a7f db803146578337df4d0a3121fc3d330000000049454e44ae426082 """), 'basi2c16': _dehex(""" 89504e470d0a1a0a0000000d4948445200000020000000201002000001db8f01 760000000467414d41000186a031e8965f0000020a49444154789cd5962173e3 3010853fcf1838cc61a1818185a53e56787fa13fa130852e3b5878b4b0b03081 b97f7030070b53e6b057a0a8912bbb9163b9f109ececbc59bd7dcf2b45492409 d66f00eb1dd83cb5497d65456aeb8e1040913b3b2c04504c936dd5a9c7e2c6eb b1b8f17a58e8d043da56f06f0f9f62e5217b6ba3a1b76f6c9e99e8696a2a72e2 c4fb1e4d452e92ec9652b807486d12b6669be00db38d9114b0c1961e375461a5 5f76682a85c367ad6f682ff53a9c2a353191764b78bb07d8ddc3c97c1950f391 6745c7b9852c73c2f212605a466a502705c8338069c8b9e84efab941eb393a97 d4c9fd63148314209f1c1d3434e847ead6380de291d6f26a25c1ebb5047f5f24 d85c49f0f22cc1d34282c72709cab90477bf25b89d49f0f351822297e0ea9704 f34c82bc94002448ede51866e5656aef5d7c6a385cb4d80e6a538ceba04e6df2 480e9aa84ddedb413bb5c97b3838456df2d4fec2c7a706983e7474d085fae820 a841776a83073838973ac0413fea2f1dc4a06e71108fda73109bdae48954ad60 bf867aac3ce44c7c1589a711cf8a81df9b219679d96d1cec3d8bbbeaa2012626 df8c7802eda201b2d2e0239b409868171fc104ba8b76f10b4da09f6817ffc609 c413ede267fd1fbab46880c90f80eccf0013185eb48b47ba03df2bdaadef3181 cb8976f18e13188768170f98c0f844bb78cb04c62ddac59d09fc3fa25dfc1da4 14deb3df1344f70000000049454e44ae426082 """), 'basi3p08': _dehex(""" 89504e470d0a1a0a0000000d494844520000002000000020080300000133a3ba 500000000467414d41000186a031e8965f00000300504c5445224400f5ffed77 ff77cbffff110a003a77002222ffff11ff110000222200ffac5566ff66ff6666 ff01ff221200dcffffccff994444ff005555220000cbcbff44440055ff55cbcb 00331a00ffecdcedffffe4ffcbffdcdc44ff446666ff330000442200ededff66 6600ffa444ffffaaeded0000cbcbfefffffdfffeffff0133ff33552a000101ff 8888ff00aaaa010100440000888800ffe4cbba5b0022ff22663200ffff99aaaa ff550000aaaa00cb630011ff11d4ffaa773a00ff4444dc6b0066000001ff0188 4200ecffdc6bdc00ffdcba00333300ed00ed7300ffff88994a0011ffff770000 ff8301ffbabafe7b00fffeff00cb00ff999922ffff880000ffff77008888ffdc ff1a33000000aa33ffff009900990000000001326600ffbaff44ffffffaaff00 770000fefeaa00004a9900ffff66ff22220000998bff1155ffffff0101ff88ff 005500001111fffffefffdfea4ff4466ffffff66ff003300ffff55ff77770000 88ff44ff00110077ffff006666ffffed000100fff5ed1111ffffff44ff22ffff eded11110088ffff00007793ff2200dcdc3333fffe00febabaff99ffff333300 63cb00baba00acff55ffffdcffff337bfe00ed00ed5555ffaaffffdcdcff5555 00000066dcdc00dc00dc83ff017777fffefeffffffcbff5555777700fefe00cb 00cb0000fe010200010000122200ffff220044449bff33ffd4aa0000559999ff 999900ba00ba2a5500ffcbcbb4ff66ff9b33ffffbaaa00aa42880053aa00ffaa aa0000ed00babaffff1100fe00000044009999990099ffcc99ba000088008800 dc00ff93220000dcfefffeaa5300770077020100cb0000000033ffedff00ba00 ff3333edffedffc488bcff7700aa00660066002222dc0000ffcbffdcffdcff8b 110000cb00010155005500880000002201ffffcbffcbed0000ff88884400445b ba00ffbc77ff99ff006600baffba00777773ed00fe00003300330000baff77ff 004400aaffaafffefe000011220022c4ff8800eded99ff99ff55ff002200ffb4 661100110a1100ff1111dcffbabaffff88ff88010001ff33ffb98ed362000002 a249444154789c65d0695c0b001806f03711a9904a94d24dac63292949e5a810 d244588a14ca5161d1a1323973252242d62157d12ae498c8124d25ca3a11398a 16e55a3cdffab0ffe7f77d7fcff3528645349b584c3187824d9d19d4ec2e3523 9eb0ae975cf8de02f2486d502191841b42967a1ad49e5ddc4265f69a899e26b5 e9e468181baae3a71a41b95669da8df2ea3594c1b31046d7b17bfb86592e4cbe d89b23e8db0af6304d756e60a8f4ad378bdc2552ae5948df1d35b52143141533 33bbbbababebeb3b3bc9c9c9c6c6c0c0d7b7b535323225a5aa8a02024a4bedec 0a0a2a2bcdcd7d7cf2f3a9a9c9cdcdd8b8adcdd5b5ababa828298982824a4ab2 b21212acadbdbc1414e2e24859b9a72730302f4f49292c4c57373c9c0a0b7372 8c8c1c1c3a3a92936d6dfdfd293e3e26262a4a4eaea2424b4b5fbfbc9c323278 3c0b0ba1303abaae8ecdeeed950d6669a9a7a7a141d4de9e9d5d5cdcd2229b94 c572716132f97cb1d8db9bc3110864a39795d9db6b6a26267a7a9a98d4d6a6a7 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49454e44ae426082 """), # A version of basn0g04 dithered down to 3 bits. 'Basn0g03': _dehex(""" 89504e470d0a1a0a0000000d494844520000002000000020040000000093e1c8 2900000001734249540371d88211000000fd49444154789c6d90d18906210c84 c356f22356b2889588604301b112112b11d94a96bb495cf7fe87f32d996f2689 44741cc658e39c0b118f883e1f63cc89dafbc04c0f619d7d898396c54b875517 83f3a2e7ac09a2074430e7f497f00f1138a5444f82839c5206b1f51053cca968 63258821e7f2b5438aac16fbecc052b646e709de45cf18996b29648508728612 952ca606a73566d44612b876845e9a347084ea4868d2907ff06be4436c4b41a3 a3e1774285614c5affb40dbd931a526619d9fa18e4c2be420858de1df0e69893 a0e3e5523461be448561001042b7d4a15309ce2c57aef2ba89d1c13794a109d7 b5880aa27744fc5c4aecb5e7bcef5fe528ec6293a930690000000049454e44ae 426082 """), 'basn0g04': _dehex(""" 89504e470d0a1a0a0000000d494844520000002000000020040000000093e1c8 290000000467414d41000186a031e8965f0000004849444154789c6360601014 545232367671090d4d4b2b2f6720430095dbd1418e002a77e64c720450b9ab56 912380caddbd9b1c0154ee9933e408a072efde25470095fbee1d1902001f14ee 01eaff41fa0000000049454e44ae426082 """), 'basn0g08': _dehex(""" 89504e470d0a1a0a0000000d4948445200000020000000200800000000561125 280000000467414d41000186a031e8965f0000004149444154789c6364602400 1408c8b30c05058c0f0829f8f71f3f6079301c1430ca11906764a2795c0c0605 8c8ff0cafeffcff887e67131181430cae0956564040050e5fe7135e2d8590000 000049454e44ae426082 """), 'basn0g16': _dehex(""" 89504e470d0a1a0a0000000d49484452000000200000002010000000000681f9 6b0000000467414d41000186a031e8965f0000005e49444154789cd5d2310ac0 300c4351395bef7fc6dca093c0287b32d52a04a3d98f3f3880a7b857131363a0 3a82601d089900dd82f640ca04e816dc06422640b7a03d903201ba05b7819009 d02d680fa44c603f6f07ec4ff41938cf7f0016d84bd85fae2b9fd70000000049 454e44ae426082 """), 'basn2c08': _dehex(""" 89504e470d0a1a0a0000000d4948445200000020000000200802000000fc18ed a30000000467414d41000186a031e8965f0000004849444154789cedd5c10900 300c024085ec91fdb772133b442bf4a1f8cee12bb40d043b800a14f81ca0ede4 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ff000000ff99ddff00ff00bbffbb000044ff00ff44d2b049bd00000047494441 54789c63e8e8080d3d7366d5aaf27263e377ef66ce64204300952b28488e002a d7c5851c0154eeddbbe408a07119c81140e52a29912380ca4d4b23470095bb7b 37190200e0c4ead10f82057d0000000049454e44ae426082 """), 'basn6a08': _dehex(""" 89504e470d0a1a0a0000000d4948445200000020000000200806000000737a7a f40000000467414d41000186a031e8965f0000006f49444154789cedd6310a80 300c46e12764684fa1f73f55048f21c4ddc545781d52e85028fc1f4d28d98a01 305e7b7e9cffba33831d75054703ca06a8f90d58a0074e351e227d805c8254e3 1bb0420f5cdc2e0079208892ffe2a00136a07b4007943c1004d900195036407f 011bf00052201a9c160fb84c0000000049454e44ae426082 """), 'cs3n3p08': _dehex(""" 89504e470d0a1a0a0000000d494844520000002000000020080300000044a48a c60000000467414d41000186a031e8965f0000000373424954030303a392a042 00000054504c544592ff0000ff9200ffff00ff0000dbff00ff6dffb600006dff b6ff00ff9200dbff000049ffff2400ff000024ff0049ff0000ffdb00ff4900ff b6ffff0000ff2400b6ffffdb000092ffff6d000024ffff49006dff00df702b17 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header. `infile` should be positioned immediately after the initial 'P7' line (at the beginning of the second line). Returns are as for `read_pnm_header`. """ # Unlike PBM, PGM, and PPM, we can read the header a line at a time. header = dict() while True: l = infile.readline().strip() if l == strtobytes('ENDHDR'): break if not l: raise EOFError('PAM ended prematurely') if l[0] == strtobytes('#'): continue l = l.split(None, 1) if l[0] not in header: header[l[0]] = l[1] else: header[l[0]] += strtobytes(' ') + l[1] required = ['WIDTH', 'HEIGHT', 'DEPTH', 'MAXVAL'] required = [strtobytes(x) for x in required] WIDTH,HEIGHT,DEPTH,MAXVAL = required present = [x for x in required if x in header] if len(present) != len(required): raise Error('PAM file must specify WIDTH, HEIGHT, DEPTH, and MAXVAL') width = int(header[WIDTH]) height = int(header[HEIGHT]) depth = int(header[DEPTH]) maxval = int(header[MAXVAL]) if (width <= 0 or height <= 0 or depth <= 0 or maxval <= 0): raise Error( 'WIDTH, HEIGHT, DEPTH, MAXVAL must all be positive integers') return 'P7', width, height, depth, maxval def read_pnm_header(infile, supported=('P5','P6')): """ Read a PNM header, returning (format,width,height,depth,maxval). `width` and `height` are in pixels. `depth` is the number of channels in the image; for PBM and PGM it is synthesized as 1, for PPM as 3; for PAM images it is read from the header. `maxval` is synthesized (as 1) for PBM images. """ # Generally, see http://netpbm.sourceforge.net/doc/ppm.html # and http://netpbm.sourceforge.net/doc/pam.html supported = [strtobytes(x) for x in supported] # Technically 'P7' must be followed by a newline, so by using # rstrip() we are being liberal in what we accept. I think this # is acceptable. type = infile.read(3).rstrip() if type not in supported: raise NotImplementedError('file format %s not supported' % type) if type == strtobytes('P7'): # PAM header parsing is completely different. return read_pam_header(infile) # Expected number of tokens in header (3 for P4, 4 for P6) expected = 4 pbm = ('P1', 'P4') if type in pbm: expected = 3 header = [type] # We have to read the rest of the header byte by byte because the # final whitespace character (immediately following the MAXVAL in # the case of P6) may not be a newline. Of course all PNM files in # the wild use a newline at this point, so it's tempting to use # readline; but it would be wrong. def getc(): c = infile.read(1) if not c: raise Error('premature EOF reading PNM header') return c c = getc() while True: # Skip whitespace that precedes a token. while c.isspace(): c = getc() # Skip comments. while c == '#': while c not in '\n\r': c = getc() if not c.isdigit(): raise Error('unexpected character %s found in header' % c) # According to the specification it is legal to have comments # that appear in the middle of a token. # This is bonkers; I've never seen it; and it's a bit awkward to # code good lexers in Python (no goto). So we break on such # cases. token = strtobytes('') while c.isdigit(): token += c c = getc() # Slight hack. All "tokens" are decimal integers, so convert # them here. header.append(int(token)) if len(header) == expected: break # Skip comments (again) while c == '#': while c not in '\n\r': c = getc() if not c.isspace(): raise Error('expected header to end with whitespace, not %s' % c) if type in pbm: # synthesize a MAXVAL header.append(1) depth = (1,3)[type == strtobytes('P6')] return header[0], header[1], header[2], depth, header[3] def write_pnm(file, width, height, pixels, meta): """Write a Netpbm PNM/PAM file.""" bitdepth = meta['bitdepth'] maxval = 2**bitdepth - 1 # Rudely, the number of image planes can be used to determine # whether we are L (PGM), LA (PAM), RGB (PPM), or RGBA (PAM). planes = meta['planes'] # Can be an assert as long as we assume that pixels and meta came # from a PNG file. assert planes in (1,2,3,4) if planes in (1,3): if 1 == planes: # PGM # Could generate PBM if maxval is 1, but we don't (for one # thing, we'd have to convert the data, not just blat it # out). fmt = 'P5' else: # PPM fmt = 'P6' file.write('%s %d %d %d\n' % (fmt, width, height, maxval)) if planes in (2,4): # PAM # See http://netpbm.sourceforge.net/doc/pam.html if 2 == planes: tupltype = 'GRAYSCALE_ALPHA' else: tupltype = 'RGB_ALPHA' file.write('P7\nWIDTH %d\nHEIGHT %d\nDEPTH %d\nMAXVAL %d\n' 'TUPLTYPE %s\nENDHDR\n' % (width, height, planes, maxval, tupltype)) # Values per row vpr = planes * width # struct format fmt = '>%d' % vpr if maxval > 0xff: fmt = fmt + 'H' else: fmt = fmt + 'B' for row in pixels: file.write(struct.pack(fmt, *row)) file.flush() def color_triple(color): """ Convert a command line colour value to a RGB triple of integers. FIXME: Somewhere we need support for greyscale backgrounds etc. """ if color.startswith('#') and len(color) == 4: return (int(color[1], 16), int(color[2], 16), int(color[3], 16)) if color.startswith('#') and len(color) == 7: return (int(color[1:3], 16), int(color[3:5], 16), int(color[5:7], 16)) elif color.startswith('#') and len(color) == 13: return (int(color[1:5], 16), int(color[5:9], 16), int(color[9:13], 16)) def _add_common_options(parser): """Call *parser.add_option* for each of the options that are common between this PNG--PNM conversion tool and the gen tool. """ parser.add_option("-i", "--interlace", default=False, action="store_true", help="create an interlaced PNG file (Adam7)") parser.add_option("-t", "--transparent", action="store", type="string", metavar="#RRGGBB", help="mark the specified colour as transparent") parser.add_option("-b", "--background", action="store", type="string", metavar="#RRGGBB", help="save the specified background colour") parser.add_option("-g", "--gamma", action="store", type="float", metavar="value", help="save the specified gamma value") parser.add_option("-c", "--compression", action="store", type="int", metavar="level", help="zlib compression level (0-9)") return parser def _main(argv): """ Run the PNG encoder with options from the command line. """ # Parse command line arguments from optparse import OptionParser import re version = '%prog ' + re.sub(r'( ?\$|URL: |Rev:)', '', __version__) parser = OptionParser(version=version) parser.set_usage("%prog [options] [imagefile]") parser.add_option('-r', '--read-png', default=False, action='store_true', help='Read PNG, write PNM') parser.add_option("-a", "--alpha", action="store", type="string", metavar="pgmfile", help="alpha channel transparency (RGBA)") _add_common_options(parser) (options, args) = parser.parse_args(args=argv[1:]) # Convert options if options.transparent is not None: options.transparent = color_triple(options.transparent) if options.background is not None: options.background = color_triple(options.background) # Prepare input and output files if len(args) == 0: infilename = '-' infile = sys.stdin elif len(args) == 1: infilename = args[0] infile = open(infilename, 'rb') else: parser.error("more than one input file") outfile = sys.stdout if sys.platform == "win32": import msvcrt, os msvcrt.setmode(sys.stdout.fileno(), os.O_BINARY) if options.read_png: # Encode PNG to PPM png = Reader(file=infile) width,height,pixels,meta = png.asDirect() write_pnm(outfile, width, height, pixels, meta) else: # Encode PNM to PNG format, width, height, depth, maxval = \ read_pnm_header(infile, ('P5','P6','P7')) # When it comes to the variety of input formats, we do something # rather rude. Observe that L, LA, RGB, RGBA are the 4 colour # types supported by PNG and that they correspond to 1, 2, 3, 4 # channels respectively. So we use the number of channels in # the source image to determine which one we have. We do not # care about TUPLTYPE. greyscale = depth <= 2 pamalpha = depth in (2,4) supported = map(lambda x: 2**x-1, range(1,17)) try: mi = supported.index(maxval) except ValueError: raise NotImplementedError( 'your maxval (%s) not in supported list %s' % (maxval, str(supported))) bitdepth = mi+1 writer = Writer(width, height, greyscale=greyscale, bitdepth=bitdepth, interlace=options.interlace, transparent=options.transparent, background=options.background, alpha=bool(pamalpha or options.alpha), gamma=options.gamma, compression=options.compression) if options.alpha: pgmfile = open(options.alpha, 'rb') format, awidth, aheight, adepth, amaxval = \ read_pnm_header(pgmfile, 'P5') if amaxval != '255': raise NotImplementedError( 'maxval %s not supported for alpha channel' % amaxval) if (awidth, aheight) != (width, height): raise ValueError("alpha channel image size mismatch" " (%s has %sx%s but %s has %sx%s)" % (infilename, width, height, options.alpha, awidth, aheight)) writer.convert_ppm_and_pgm(infile, pgmfile, outfile) else: writer.convert_pnm(infile, outfile) if __name__ == '__main__': try: _main(sys.argv) except Error, e: print >>sys.stderr, e