201 lines
5.5 KiB
Python
201 lines
5.5 KiB
Python
"""Color Database.
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To create a class that contains color lookup methods, use the module global
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function `get_colordb(file)'. This function will try to examine the file to
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figure out what the format of the file is. If it can't figure out the file
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format, or it has trouble reading the file, None is returned. You can pass
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get_colordb() an optional filetype argument.
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Supporte file types are:
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X_RGB_TXT -- X Consortium rgb.txt format files. Three columns of numbers
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from 0 .. 255 separated by whitespace. Arbitrary trailing
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columns used as the color name.
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"""
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import sys
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import string
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import re
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from types import *
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import operator
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class BadColor(Exception):
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pass
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DEFAULT_DB = None
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# generic class
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class ColorDB:
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def __init__(self, fp, lineno):
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# Maintain several dictionaries for indexing into the color database.
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# Note that while Tk supports RGB intensities of 4, 8, 12, or 16 bits,
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# for now we only support 8 bit intensities. At least on OpenWindows,
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# all intensities in the /usr/openwin/lib/rgb.txt file are 8-bit
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#
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# key is (red, green, blue) tuple, value is (name, [aliases])
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self.__byrgb = {}
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#
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# key is name, value is (red, green, blue)
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self.__byname = {}
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#
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while 1:
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line = fp.readline()
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if not line:
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break
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# get this compiled regular expression from derived class
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mo = self._re.match(line)
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if not mo:
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sys.stderr.write('Error in %s, line %d\n' % (fp.name, lineno))
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lineno = lineno + 1
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continue
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#
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# extract the red, green, blue, and name
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#
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red, green, blue = map(int, mo.group('red', 'green', 'blue'))
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name = mo.group('name')
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keyname = string.lower(name)
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#
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# TBD: for now the `name' is just the first named color with the
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# rgb values we find. Later, we might want to make the two word
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# version the `name', or the CapitalizedVersion, etc.
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#
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key = (red, green, blue)
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foundname, aliases = self.__byrgb.get(key, (name, []))
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if foundname <> name and foundname not in aliases:
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aliases.append(name)
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self.__byrgb[key] = (foundname, aliases)
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#
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# add to byname lookup
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#
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self.__byname[keyname] = key
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lineno = lineno + 1
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def find_byrgb(self, rgbtuple):
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try:
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return self.__byrgb[rgbtuple]
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except KeyError:
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raise BadColor(rgbtuple)
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def find_byname(self, name):
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name = string.lower(name)
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try:
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return self.__byname[name]
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except KeyError:
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raise BadColor(name)
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def nearest(self, rgbtuple):
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# TBD: use Voronoi diagrams, Delaunay triangulation, or octree for
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# speeding up the locating of nearest point. Exhaustive search is
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# inefficient, but may be fast enough.
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red, green, blue = rgbtuple
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nearest = -1
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nearest_name = ''
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for name, aliases in self.__byrgb.values():
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r, g, b = self.__byname[string.lower(name)]
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rdelta = red - r
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gdelta = green - g
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bdelta = blue - b
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distance = rdelta * rdelta + gdelta * gdelta + bdelta * bdelta
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if nearest == -1 or distance < nearest:
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nearest = distance
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nearest_name = name
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return nearest_name
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class RGBColorDB(ColorDB):
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_re = re.compile(
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'\s*(?P<red>\d+)\s+(?P<green>\d+)\s+(?P<blue>\d+)\s+(?P<name>.*)')
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# format is a tuple (RE, SCANLINES, CLASS) where RE is a compiled regular
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# expression, SCANLINES is the number of header lines to scan, and CLASS is
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# the class to instantiate if a match is found
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X_RGB_TXT = re.compile('XConsortium'), 1, RGBColorDB
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def get_colordb(file, filetype=X_RGB_TXT):
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colordb = None
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fp = None
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typere, scanlines, class_ = filetype
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try:
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try:
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lineno = 0
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fp = open(file)
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while lineno < scanlines:
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line = fp.readline()
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if not line:
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break
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mo = typere.search(line)
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if mo:
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colordb = class_(fp, lineno)
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break
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lineno = lineno + 1
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except IOError:
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pass
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finally:
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if fp:
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fp.close()
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# save a global copy
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global DEFAULT_DB
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DEFAULT_DB = colordb
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return colordb
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_namedict = {}
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def rrggbb_to_triplet(color, atoi=string.atoi):
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"""Converts a #rrggbb color to the tuple (red, green, blue)."""
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rgbtuple = _namedict.get(color)
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if rgbtuple is None:
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assert color[0] == '#'
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red = color[1:3]
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green = color[3:5]
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blue = color[5:7]
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rgbtuple = (atoi(red, 16), atoi(green, 16), atoi(blue, 16))
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_namedict[color] = rgbtuple
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return rgbtuple
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_tripdict = {}
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def triplet_to_rrggbb(rgbtuple):
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"""Converts a (red, green, blue) tuple to #rrggbb."""
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hexname = _tripdict.get(rgbtuple)
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if hexname is None:
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hexname = '#%02x%02x%02x' % rgbtuple
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_tripdict[rgbtuple] = hexname
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return hexname
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_maxtuple = (256.0,) * 3
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def triplet_to_pmwrgb(rgbtuple):
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return map(operator.__div__, rgbtuple, _maxtuple)
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if __name__ == '__main__':
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import string
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colordb = get_colordb('/usr/openwin/lib/rgb.txt')
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if not colordb:
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print 'No parseable color database found'
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sys.exit(1)
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# on my system, this color matches exactly
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target = 'navy'
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target = 'snow'
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red, green, blue = colordb.find_byname(target)
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print target, ':', red, green, blue, hex(rrggbb)
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name, aliases = colordb.find_byrgb((red, green, blue))
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print 'name:', name, 'aliases:', string.join(aliases, ", ")
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target = (1, 1, 128) # nearest to navy
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target = (145, 238, 144) # nearest to lightgreen
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target = (255, 251, 250) # snow
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print 'finding nearest to', target, '...'
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import time
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t0 = time.time()
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nearest = apply(colordb.nearest, target)
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t1 = time.time()
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print 'found nearest color', nearest, 'in', t1-t0, 'seconds'
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