def calculate_adjusted_sa(ma,phases,b,
resolution=None,
d_min_ratio=None,
solvent_fraction=None,
region_weight=None,
max_regions_to_test=None,
sa_percent=None,
fraction_occupied=None,
wrapping=None,
n_real=None):
map_data=get_sharpened_map(ma,phases,b,resolution,n_real=n_real,
d_min_ratio=d_min_ratio)
from cctbx.maptbx.segment_and_split_map import score_map
from libtbx.utils import null_out
si=score_map(
map_data=map_data,
solvent_fraction=solvent_fraction,
fraction_occupied=fraction_occupied,
wrapping=wrapping,
sa_percent=sa_percent,
region_weight=region_weight,
max_regions_to_test=max_regions_to_test,
out=null_out())
return si.adjusted_sa
def calculate_adjusted_sa(ma,phases,b,
d_cut=None,
solvent_fraction=None,
region_weight=None,
max_regions_to_test=None,
sa_percent=None,
fraction_occupied=None,
wrapping=None,
n_real=None):
map_data=get_sharpened_map(ma,phases,b,d_cut,n_real=n_real)
from cctbx.maptbx.segment_and_split_map import score_map
from libtbx.utils import null_out
si=score_map(
map_data=map_data,
solvent_fraction=solvent_fraction,
fraction_occupied=fraction_occupied,
wrapping=wrapping,
sa_percent=sa_percent,
region_weight=region_weight,
max_regions_to_test=max_regions_to_test,
out=null_out())
return si.adjusted_sa
