tools/generate_fir_coeff.py - skia - Git at Google

 #!/usr/bin/python

 '''
 Copyright 2013 Google Inc.

 Use of this source code is governed by a BSD-style license that can be
 found in the LICENSE file.
 '''

 import math
 import pprint

 def withinStdDev(n):
   """Returns the percent of samples within n std deviations of the normal."""
   return math.erf(n / math.sqrt(2))

 def withinStdDevRange(a, b):
   """Returns the percent of samples within the std deviation range a, b"""
   if b < a:
     return 0;

   if a < 0:
     if b < 0:
       return (withinStdDev(-a) - withinStdDev(-b)) / 2;
     else:
       return (withinStdDev(-a) + withinStdDev(b)) / 2;
   else:
     return (withinStdDev(b) - withinStdDev(a)) / 2;


 #We have a bunch of smudged samples which represent the average coverage of a range.
 #We have a 'center' which may not line up with those samples.
 #From the 'center' we want to make a normal approximation where '5' sample width out we're at '3' std deviations.
 #The first and last samples may not be fully covered.

 #This is the sub-sample shift for each set of FIR coefficients (the centers of the lcds in the samples)
 #Each subpxl takes up 1/3 of a pixel, so they are centered at x=(i/n+1/2n), or 1/6, 3/6, 5/6 of a pixel.
 #Each sample takes up 1/4 of a pixel, so the results fall at (x*4)%1, or 2/3, 0, 1/3 of a sample.
 samples_per_pixel = 4
 subpxls_per_pixel = 3
 #sample_offsets is (frac, int) in sample units.
 sample_offsets = [math.modf((float(subpxl_index)/subpxls_per_pixel + 1.0/(2.0*subpxls_per_pixel))*samples_per_pixel) for subpxl_index in range(subpxls_per_pixel)]

 #How many samples to consider to the left and right of the subpxl center.
 sample_units_width = 5

 #The std deviation at sample_units_width.
 std_dev_max = 3

 #The target sum is in some fixed point representation.
 #Values larger the 1 in fixed point simulate ink spread.
 target_sum = 0x110

 for sample_offset, sample_align in sample_offsets:
   coeffs = []
   coeffs_rounded = []

   #We start at sample_offset - sample_units_width
   current_sample_left = sample_offset - sample_units_width
   current_std_dev_left = -std_dev_max

   done = False
   while not done:
     current_sample_right = math.floor(current_sample_left + 1)
     if current_sample_right > sample_offset + sample_units_width:
       done = True
       current_sample_right = sample_offset + sample_units_width
     current_std_dev_right = current_std_dev_left + ((current_sample_right - current_sample_left) / sample_units_width) * std_dev_max

     coverage = withinStdDevRange(current_std_dev_left, current_std_dev_right)
     coeffs.append(coverage * target_sum)
     coeffs_rounded.append(int(round(coverage * target_sum)))

     current_sample_left = current_sample_right
     current_std_dev_left = current_std_dev_right

   # Now we have the numbers we want, but our rounding needs to add up to target_sum.
   delta = 0
   coeffs_rounded_sum = sum(coeffs_rounded)
   if coeffs_rounded_sum > target_sum:
     # The coeffs add up to too much. Subtract 1 from the ones which were rounded up the most.
     delta = -1

   if coeffs_rounded_sum < target_sum:
     # The coeffs add up to too little. Add 1 to the ones which were rounded down the most.
     delta = 1

   if delta:
     print "Initial sum is 0x%0.2X, adjusting." % (coeffs_rounded_sum,)
     coeff_diff = [(coeff_rounded - coeff) * delta
                   for coeff, coeff_rounded in zip(coeffs, coeffs_rounded)]

     class IndexTracker:
       def __init__(self, index, item):
         self.index = index
         self.item = item
       def __lt__(self, other):
         return self.item < other.item
       def __repr__(self):
         return "arr[%d] == %s" % (self.index, repr(self.item))

     coeff_pkg = [IndexTracker(i, diff) for i, diff in enumerate(coeff_diff)]
     coeff_pkg.sort()

     # num_elements_to_force_round had better be < (2 * sample_units_width + 1) or
     # * our math was wildy wrong
     # * an awful lot of the curve is out side our sample
     # either is pretty bad, and probably means the results will not be useful.
     num_elements_to_force_round = abs(coeffs_rounded_sum - target_sum)
     for i in xrange(num_elements_to_force_round):
       print "Adding %d to index %d to force round %f." % (delta, coeff_pkg[i].index, coeffs[coeff_pkg[i].index])
       coeffs_rounded[coeff_pkg[i].index] += delta

   print "Prepending %d 0x00 for allignment." % (sample_align,)
   coeffs_rounded_aligned = ([0] * int(sample_align)) + coeffs_rounded

   print ', '.join(["0x%0.2X" % coeff_rounded for coeff_rounded in coeffs_rounded_aligned])
   print sum(coeffs), hex(sum(coeffs_rounded))
   print
	#!/usr/bin/python

	'''
	Copyright 2013 Google Inc.

	Use of this source code is governed by a BSD-style license that can be
	found in the LICENSE file.
	'''

	import math
	import pprint

	def withinStdDev(n):
	"""Returns the percent of samples within n std deviations of the normal."""
	return math.erf(n / math.sqrt(2))

	def withinStdDevRange(a, b):
	"""Returns the percent of samples within the std deviation range a, b"""
	if b < a:
	return 0;

	if a < 0:
	if b < 0:
	return (withinStdDev(-a) - withinStdDev(-b)) / 2;
	else:
	return (withinStdDev(-a) + withinStdDev(b)) / 2;
	else:
	return (withinStdDev(b) - withinStdDev(a)) / 2;


	#We have a bunch of smudged samples which represent the average coverage of a range.
	#We have a 'center' which may not line up with those samples.
	#From the 'center' we want to make a normal approximation where '5' sample width out we're at '3' std deviations.
	#The first and last samples may not be fully covered.

	#This is the sub-sample shift for each set of FIR coefficients (the centers of the lcds in the samples)
	#Each subpxl takes up 1/3 of a pixel, so they are centered at x=(i/n+1/2n), or 1/6, 3/6, 5/6 of a pixel.
	#Each sample takes up 1/4 of a pixel, so the results fall at (x*4)%1, or 2/3, 0, 1/3 of a sample.
	samples_per_pixel = 4
	subpxls_per_pixel = 3
	#sample_offsets is (frac, int) in sample units.
	sample_offsets = [math.modf((float(subpxl_index)/subpxls_per_pixel + 1.0/(2.0subpxls_per_pixel))samples_per_pixel) for subpxl_index in range(subpxls_per_pixel)]

	#How many samples to consider to the left and right of the subpxl center.
	sample_units_width = 5

	#The std deviation at sample_units_width.
	std_dev_max = 3

	#The target sum is in some fixed point representation.
	#Values larger the 1 in fixed point simulate ink spread.
	target_sum = 0x110

	for sample_offset, sample_align in sample_offsets:
	coeffs = []
	coeffs_rounded = []

	#We start at sample_offset - sample_units_width
	current_sample_left = sample_offset - sample_units_width
	current_std_dev_left = -std_dev_max

	done = False
	while not done:
	current_sample_right = math.floor(current_sample_left + 1)
	if current_sample_right > sample_offset + sample_units_width:
	done = True
	current_sample_right = sample_offset + sample_units_width
	current_std_dev_right = current_std_dev_left + ((current_sample_right - current_sample_left) / sample_units_width) * std_dev_max

	coverage = withinStdDevRange(current_std_dev_left, current_std_dev_right)
	coeffs.append(coverage * target_sum)
	coeffs_rounded.append(int(round(coverage * target_sum)))

	current_sample_left = current_sample_right
	current_std_dev_left = current_std_dev_right

	# Now we have the numbers we want, but our rounding needs to add up to target_sum.
	delta = 0
	coeffs_rounded_sum = sum(coeffs_rounded)
	if coeffs_rounded_sum > target_sum:
	# The coeffs add up to too much. Subtract 1 from the ones which were rounded up the most.
	delta = -1

	if coeffs_rounded_sum < target_sum:
	# The coeffs add up to too little. Add 1 to the ones which were rounded down the most.
	delta = 1

	if delta:
	print "Initial sum is 0x%0.2X, adjusting." % (coeffs_rounded_sum,)
	coeff_diff = [(coeff_rounded - coeff) * delta
	for coeff, coeff_rounded in zip(coeffs, coeffs_rounded)]

	class IndexTracker:
	def __init__(self, index, item):
	self.index = index
	self.item = item
	def __lt__(self, other):
	return self.item < other.item
	def __repr__(self):
	return "arr[%d] == %s" % (self.index, repr(self.item))

	coeff_pkg = [IndexTracker(i, diff) for i, diff in enumerate(coeff_diff)]
	coeff_pkg.sort()

	# num_elements_to_force_round had better be < (2 * sample_units_width + 1) or
	# * our math was wildy wrong
	# * an awful lot of the curve is out side our sample
	# either is pretty bad, and probably means the results will not be useful.
	num_elements_to_force_round = abs(coeffs_rounded_sum - target_sum)
	for i in xrange(num_elements_to_force_round):
	print "Adding %d to index %d to force round %f." % (delta, coeff_pkg[i].index, coeffs[coeff_pkg[i].index])
	coeffs_rounded[coeff_pkg[i].index] += delta

	print "Prepending %d 0x00 for allignment." % (sample_align,)
	coeffs_rounded_aligned = ([0] * int(sample_align)) + coeffs_rounded

	print ', '.join(["0x%0.2X" % coeff_rounded for coeff_rounded in coeffs_rounded_aligned])
	print sum(coeffs), hex(sum(coeffs_rounded))
	print