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setfont2/tools/un-fuzzy.py

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#!/usr/bin/env python
#
# This tool depends on the "pygame" package.
#
# The Ben NanoNote has a "delta" arrangement of the pixels on its LCD:
#
# even rows: R G B|R G B|..
# odd rows: G B R|G B R|..
#
# Note that the odd-numbered rows are shifted 1/6th of pixel width left.
#
# A white pixel at (0,1) will appear shifted 1/6th of a pixel left relative to
# a white pixel at (0,0) resulting in jaggies on vertical lines.
#
# This tool processes a sheet of 8x8 font glyphs into a sheet of 4x8 font
# glyphs using individual green and magenta "pixels" to achieve twice the
# horizontal resolution. It also compensates for the unusual screen on the
# NanoNote.
#
# NOTE: On the even rows, a single pixel is discarded that would have been made
# up of the red component of the first column along with the blue component of
# the last column. On odds rows, the green component of the first column is
# discarded. This means that last column of the source image is ignored.
#
# Example usage:
#
2010-10-14 00:40:55 +03:00
# tools/un-fuzzy.py fonts/pre-4x8-font.png /tmp/un-fuzzy-4x8-font.tga
#
# Then use GIMP to convert the .tga file to a .pnm file. Imagemagick seems to
# create P3 .pnm files yet setfont2 can only load P6 .pnm files presently.
#
import sys
import pygame
# Check and grab the command line arguments
if len( sys.argv) < 3:
print "Use: %s source-image-file target-image-file(BMP|TGA) [grid]" % sys.argv[0]
sys.exit( 1)
path_to_source_file = sys.argv[ 1]
path_to_target_file = sys.argv[ 2]
grid = ( 4 == len( sys.argv))
# Load the source image and create the target image with the same number of
# rows but half the number of columns
source_image = pygame.image.load( path_to_source_file)
target_image = pygame.Surface( (source_image.get_width()/2, source_image.get_height()))
class Colour:
def __init__( self):
self.red = 0
self.green = 0
self.blue = 0
def isnt_black( self):
return self.red != 0 or self.green != 0 or self.blue != 0
def __repr__( self):
return "(%i,%i,%i)" % ( self.red, self.green, self.blue)
def update_pixel( self, location, colour):
current_state = list( self.get_at( location))
# NOTE that the new luminances are logical-ORed with the current state of
# the pixels since no component should be added to twice, which means that
# no overflow of component values should be possible
current_state[ 0] |= colour.red
current_state[ 1] |= colour.green
current_state[ 2] |= colour.blue
self.set_at( location, current_state)
for row in range( source_image.get_height()):
for column in range( source_image.get_width() - 1):
pixel = source_image.get_at( (column, row))
# "pixel" should be monochrome
red = pixel[ 0]
green = pixel[ 1]
blue = pixel[ 2]
if red != green or green != blue:
raise Exception("not monochrome at (%i,%i)"%( column, row))
luminance = red
# The pixel at ( x, y) in the target image encodes two virtual pixels: one
# from the green component and one from the magenta component made by
# combining the blue component and the red component of the pixel
# immediately to the right of this pixel
# For odd-numbered rows the virtual pixels are:
# 1) magenta made from blue and red
# 2) the green component of the pixel to the right
# The luminance of the pixel at ( x, y) in the source image is encoded in
# different ways depending whether the row is odd or even-numbered and
# whether the column is odd or even-numbered
left = Colour()
right = Colour()
# If preparing SubLCD for a grid-based LCD rather than a Delta LCD..
if grid:
if 0 == column & 1:
# The luminance of this pixel is provided by the green component of the
# pixel at ( x, y)
left.green = luminance
else:
# The luminance of this pixel is provided by the magenta component that
# is distributed across two pixels ( the blue component of the pixel at
# ( x, y) and the red component of the pixel at ( x+1, y))
left.blue = luminance
right.red = luminance
else:
# If this row is even-numbered..
if 0 == row & 1:
# If this column is even-numbered..
if 0 == column & 1:
# The luminance of this pixel is provided by the green component of the
# pixel at ( x, y)
left.green = luminance
else:
# The luminance of this pixel is provided by the magenta component that
# is distributed across two pixels ( the blue component of the pixel at
# ( x, y) and the red component of the pixel at ( x+1, y))
left.blue = luminance
right.red = luminance
else:
if 0 == column & 1:
# The luminance of this pixel is provided by the magenta component (
# the sum of the red and blue components) of the pixel at ( x, y)
left.red = luminance
left.blue = luminance
else:
# The luminance of this pixel is provided by the green component of the
# pixel at ( x+1, y)
right.green = luminance
update_pixel( target_image, (column/2,row), left)
#print repr((column,row))
#print "L"+repr(left)
#print "R"+repr(right)
if right.isnt_black():
update_pixel( target_image, (column/2+1,row), right)
pygame.image.save( target_image, path_to_target_file)