def output_map(f_obs, r_free_flags, xray_structure, mask_data, filename,
params, log):
f_calc = f_obs.structure_factors_from_scatterers(
xray_structure=xray_structure).f_calc()
mask = f_obs.structure_factors_from_map(map=mask_data,
use_scale=True,
anomalous_flag=False,
use_sg=False)
# is it really use_sg = false?
fmodel = mmtbx.f_model.manager(f_obs=f_obs,
r_free_flags=r_free_flags,
f_calc=f_calc,
f_mask=mask)
fmodel.update_all_scales()
print >> log, "r_work=%6.4f r_free=%6.4f" % (fmodel.r_work(),
fmodel.r_free())
print >> log, "*" * 79
mc_diff = map_tools.electron_density_map(fmodel=fmodel).map_coefficients(
map_type="mFo-DFc", isotropize=True, fill_missing=False)
if (params.mask_output and filename != 'bias_omit'):
ccp4_map.write_ccp4_map(file_name="mask_" + filename + ".ccp4",
unit_cell=f_obs.unit_cell(),
space_group=f_obs.space_group(),
map_data=mask_data,
labels=flex.std_string([""]))
return mc_diff
def output_map(f_obs, r_free_flags, xray_structure, mask_data, filename, params,
log):
f_calc = f_obs.structure_factors_from_scatterers(
xray_structure = xray_structure).f_calc()
mask = f_obs.structure_factors_from_map(
map = mask_data,
use_scale = True,
anomalous_flag = False,
use_sg = False)
# is it really use_sg = false?
fmodel = mmtbx.f_model.manager(
f_obs = f_obs,
r_free_flags = r_free_flags,
f_calc = f_calc,
f_mask = mask)
fmodel.update_all_scales()
print >> log, "r_work=%6.4f r_free=%6.4f" % (fmodel.r_work(), fmodel.r_free())
print >> log, "*"*79
mc_diff = map_tools.electron_density_map(
fmodel = fmodel).map_coefficients(
map_type = "mFo-DFc",
isotropize = True,
fill_missing = False)
if (params.mask_output and filename != 'bias_omit'):
ccp4_map.write_ccp4_map(
file_name = "mask_"+filename+".ccp4",
unit_cell = f_obs.unit_cell(),
space_group = f_obs.space_group(),
map_data = mask_data,
labels = flex.std_string([""]))
return mc_diff
def compute_map(fmodel, crystal_gridding, map_type):
map_coefficients = map_tools.electron_density_map(
fmodel=fmodel).map_coefficients(map_type=map_type,
isotropize=True,
fill_missing=False)
fft_map = cctbx.miller.fft_map(crystal_gridding=crystal_gridding,
fourier_coefficients=map_coefficients)
fft_map.apply_sigma_scaling()
return fft_map.real_map_unpadded()
def compute_map(fmodel, crystal_gridding, map_type):
map_coefficients = map_tools.electron_density_map(
fmodel = fmodel).map_coefficients(
map_type = map_type,
isotropize = True,
fill_missing = False)
fft_map = cctbx.miller.fft_map(
crystal_gridding = crystal_gridding,
fourier_coefficients = map_coefficients)
fft_map.apply_sigma_scaling()
return fft_map.real_map_unpadded()
def get_map(fmodel):
map_coeffs = map_tools.electron_density_map(fmodel = fmodel).map_coefficients(
map_type = "2mFo-DFc",
isotropize = True,
fill_missing = False)
crystal_gridding = fmodel.f_obs().crystal_gridding(
d_min = fmodel.f_obs().d_min(),
symmetry_flags = maptbx.use_space_group_symmetry,
resolution_factor = 1./4)
fft_map = miller.fft_map(
crystal_gridding = crystal_gridding,
fourier_coefficients = map_coeffs)
fft_map.apply_sigma_scaling()
return fft_map.real_map_unpadded()
def get_poler_diff_map(f_obs):
fmodel = mmtbx.f_model.manager(f_obs=f_obs,
r_free_flags=r_free_flags,
f_calc=f_calc,
f_mask=f_mask)
fmodel.update_all_scales(remove_outliers=False)
mc_diff = map_tools.electron_density_map(
fmodel=fmodel).map_coefficients(map_type="mFo-DFc",
isotropize=True,
fill_missing=False)
fft_map = miller.fft_map(crystal_gridding=cpm_obj.crystal_gridding,
fourier_coefficients=mc_diff)
fft_map.apply_sigma_scaling()
map_data = fft_map.real_map_unpadded()
return mmtbx.utils.extract_box_around_model_and_map(
xray_structure=xrs_selected, map_data=map_data, box_cushion=2.1)
def get_fmodel_and_map_coefficients(self, xray_structure, mask_data):
f_calc = self.f_obs.structure_factors_from_scatterers(
xray_structure=xray_structure).f_calc()
mask = self.f_obs.structure_factors_from_map(map=mask_data,
use_scale=True,
anomalous_flag=False,
use_sg=False)
# To check: is it really use_sg = false?
fmodel = mmtbx.f_model.manager(f_obs=self.f_obs,
r_free_flags=self.r_free_flags,
f_calc=f_calc,
f_mask=mask)
fmodel.update_all_scales()
mc_fofc = map_tools.electron_density_map(
fmodel=fmodel).map_coefficients(map_type="mFo-DFc",
isotropize=True,
fill_missing=False)
return fmodel, mc_fofc
def get_poler_diff_map(f_obs):
fmodel = mmtbx.f_model.manager(
f_obs = f_obs,
r_free_flags = r_free_flags,
f_calc = f_calc,
f_mask = f_mask)
fmodel.update_all_scales(remove_outliers=False)
mc_diff = map_tools.electron_density_map(
fmodel = fmodel).map_coefficients(
map_type = "mFo-DFc",
isotropize = True,
fill_missing = False)
fft_map = miller.fft_map(
crystal_gridding = cpm_obj.crystal_gridding,
fourier_coefficients = mc_diff)
fft_map.apply_sigma_scaling()
map_data = fft_map.real_map_unpadded()
return mmtbx.utils.extract_box_around_model_and_map(
xray_structure = xrs_selected,
map_data = map_data,
box_cushion = 2.1)
def get_polder_diff_map(self, f_obs, r_free_flags, f_calc, f_mask,
model_selected, box_cushion):
fmodel = mmtbx.f_model.manager(f_obs=f_obs,
r_free_flags=r_free_flags,
f_calc=f_calc,
f_mask=f_mask)
fmodel.update_all_scales(remove_outliers=False)
mc_diff = map_tools.electron_density_map(
fmodel=fmodel).map_coefficients(map_type="mFo-DFc",
isotropize=True,
fill_missing=False)
fft_map = miller.fft_map(crystal_gridding=self.crystal_gridding,
fourier_coefficients=mc_diff)
fft_map.apply_sigma_scaling()
mm = fft_map.as_map_manager()
import iotbx.map_and_model
inputs = iotbx.map_and_model.input(model=model_selected.deep_copy(),
map_manager=mm,
box=True)
return inputs.shift_manager()
def __init__(self,
f_obs,
r_free_flags,
xray_structure,
use_resolve,
use_omit,
use_max_map,
sharp,
use_unsharp_masking,
resolution_factor,
n_inner_loop=10,
n_outer_loop=10,
log=None):
adopt_init_args(self, locals())
if (self.log is None): self.log = sys.stdout
print("Start FEM...", file=self.log)
self.prepare_f_obs_and_flags()
self.mc_orig = self.compute_original_map()
self.b_overall = None
print("Create un-sharpened fmodel...", file=self.log)
self.fmodel_nosharp = self.create_fmodel(show=True).deep_copy()
if (self.sharp): self.remove_common_isotropic_adp()
print("Create fmodel...", file=self.log)
self.fmodel = self.create_fmodel(show=True)
self.crystal_gridding = self.f_obs.crystal_gridding(
d_min=self.fmodel.f_obs().d_min(),
symmetry_flags=maptbx.use_space_group_symmetry,
resolution_factor=self.resolution_factor)
# initial maps
print("Compute initial maps...", file=self.log)
self.mc = map_tools.electron_density_map(
fmodel=self.fmodel).map_coefficients(map_type="2mFo-DFc",
isotropize=True,
fill_missing=False)
self.mc_fill = map_tools.electron_density_map(
fmodel=self.fmodel).map_coefficients(map_type="2mFo-DFc",
isotropize=True,
fill_missing=True)
print("Finding typical atom volumes...", file=self.log)
self.selection = good_atoms_selection(
crystal_gridding=self.crystal_gridding,
map_coeffs=self.mc_fill,
xray_structure=self.fmodel.xray_structure)
# main FEM loop
m = self.outer_loop()
m = low_volume_density_elimination(m=m,
fmodel=self.fmodel,
selection=self.selection)
self.zero_below_threshold(m=m)
# HE
m = maptbx.volume_scale(map=m, n_bins=10000).map_data()
# create Fourier ripples filter
sel = m < 0.5
msk = m.set_selected(sel, 0)
sel = msk >= 0.5
msk = msk.set_selected(sel, 1)
#XXX maptbx.sharpen(map_data=m, index_span=2, n_averages=1,
#XXX allow_negatives=False)
# Use Resolve filter
m_resolve = self.resolve_filter_map()
if (m_resolve is not None): m = m * m_resolve
# Use OMIT
if (self.use_omit):
comit = mmtbx.maps.composite_omit_map.run(
fmodel=self.fmodel_nosharp,
crystal_gridding=self.crystal_gridding,
box_size_as_fraction=0.2,
max_boxes=2000,
neutral_volume_box_cushion_width=2,
full_resolution_map=True,
log=self.log)
omit_map = comit.as_p1_map()
#ccp4_map(cg=self.crystal_gridding, file_name="omit1.ccp4", map_data=omit_map)
omit_map = low_volume_density_elimination(m=omit_map,
fmodel=self.fmodel,
selection=self.selection,
end=16)
#ccp4_map(cg=self.crystal_gridding, file_name="omit2.ccp4", map_data=omit_map)
sel = omit_map < 1.5
omit_map = omit_map.set_selected(sel, 0)
sel = omit_map >= 1.5
omit_map = omit_map.set_selected(sel, 1)
m = m * omit_map
#
# Extra filter: seems to ne redundant, TBD.
#
#omit_mc = comit.result_as_sf()
#omit_map = get_map(mc=omit_mc, cg=self.crystal_gridding)
#omit_map = low_volume_density_elimination(m=omit_map, fmodel=self.fmodel, selection=self.selection)
#ccp4_map(cg=self.crystal_gridding, file_name="omit2.ccp4", map_data=omit_map)
#sel = omit_map<0.5
#omit_map = omit_map.set_selected(sel, 0)
#sel = omit_map>=0.5
#omit_map = omit_map.set_selected(sel, 1)
#m = m * omit_map
#
self.mc_result = self.mc_fill.structure_factors_from_map(
map=m, use_scale=True, anomalous_flag=False, use_sg=False)
if (self.sharp):
self.mc_result = mmtbx.maps.b_factor_sharpening_by_map_kurtosis_maximization(
map_coeffs=self.mc_result, show=True, b_only=False)
self.map_result = get_map(mc=self.mc_result,
cg=self.crystal_gridding) * msk
def compute_original_map(self):
return map_tools.electron_density_map(fmodel=self.create_fmodel(
update_f_part1=False)).map_coefficients(map_type="2mFo-DFc",
isotropize=False,
fill_missing=False)
def __init__(
self,
fmodel,
map_type = "2mFo-DFc",
mask_data = None,
crystal_gridding = None,
number_of_kicks = 100,
macro_cycles = 10,
kick_completeness = 0.95,
omit = True):
fmodel = self.convert_to_non_anomalous(fmodel=fmodel)
from mmtbx import map_tools
self.mc_orig = map_tools.electron_density_map(
fmodel=fmodel).map_coefficients(
map_type = "2mFo-DFc",
isotropize = True,
fill_missing = False)
md_orig = get_map(map_coeffs=self.mc_orig, crystal_gridding=crystal_gridding)
# model missing
self.complete_set = map_tools.resolve_dm_map(
fmodel = fmodel,
map_coeffs = self.mc_orig,
pdb_inp = None,
use_model_hl = True,
fill = True)
md_complete_set = get_map(map_coeffs=self.complete_set, crystal_gridding=crystal_gridding)
self.missing = self.complete_set.lone_set(self.mc_orig)
# Kick map coefficients
md_kick = kick_map_coeffs(
map_coeffs = self.mc_orig,
crystal_gridding = crystal_gridding,
number_of_kicks = number_of_kicks,
macro_cycles = macro_cycles,
missing = self.missing,
kick_completeness = kick_completeness)
self.mc_kick = self.map_coeffs_from_map(map_data=md_kick)
# Kick fmodel
md_fm = kick_fmodel(
fmodel = fmodel,
map_type = map_type,
crystal_gridding = crystal_gridding,
number_of_kicks = number_of_kicks,
macro_cycles = macro_cycles,
missing = self.missing,
kick_completeness = kick_completeness)
self.mc_fm = self.map_coeffs_from_map(map_data=md_fm)
if(omit):
# Kick OMIT map
com1 = mmtbx.maps.composite_omit_map.run(
crystal_gridding = crystal_gridding,
fmodel = fmodel.deep_copy(), # XXX
full_resolution_map = True,
box_size_as_fraction = 0.03)
md_com1 = kick_map_coeffs(
map_coeffs = com1.map_coefficients(),
crystal_gridding = crystal_gridding,
number_of_kicks = number_of_kicks,
macro_cycles = macro_cycles,
phases_only = True,
missing = self.missing,
kick_completeness = kick_completeness)
self.mc_com1 = self.map_coeffs_from_map(map_data=md_com1)
# Kick OMIT map 2
com2 = mmtbx.maps.composite_omit_map.run(
crystal_gridding = crystal_gridding,
fmodel = fmodel.deep_copy(), # XXX
full_resolution_map = True,
box_size_as_fraction = 0.03)
md_com2 = kick_map_coeffs(
map_coeffs = com2.map_coefficients(),
crystal_gridding = crystal_gridding,
number_of_kicks = number_of_kicks,
macro_cycles = macro_cycles,
phases_only = True,
missing = self.missing,
kick_completeness = kick_completeness)
self.mc_com2 = self.map_coeffs_from_map(map_data=md_com2)
# combine maps
def intersect(m1,m2, use_average):
maptbx.intersection(
map_data_1 = m1,
map_data_2 = m2,
thresholds = flex.double([0,0.1,0.2,0.3,0.4,0.5]),
average = False)
if(use_average): return (m1+m2)/2
else: return m1
m = (md_kick + md_fm)/2
m = intersect(m, md_kick, use_average=True)
m = intersect(m, md_fm, use_average=True)
if(omit):
m = intersect(m, md_com1, use_average=False)
m = intersect(m, md_com2, use_average=False)
m = intersect(m, md_orig, use_average=False)
m = intersect(m, md_complete_set, use_average=False)
self.map_data_result = m
self.mc_result = self.map_coeffs_from_map(map_data=self.map_data_result)
def __init__(
self,
f_obs,
r_free_flags,
xray_structure,
use_resolve,
use_omit,
use_max_map,
sharp,
use_unsharp_masking,
resolution_factor,
n_inner_loop = 10,
n_outer_loop = 10,
log = None):
adopt_init_args(self, locals())
if(self.log is None): self.log = sys.stdout
print >> self.log, "Start FEM..."
self.prepare_f_obs_and_flags()
self.mc_orig = self.compute_original_map()
self.b_overall = None
print >> self.log, "Create un-sharpened fmodel..."
self.fmodel_nosharp = self.create_fmodel(show=True).deep_copy()
if(self.sharp): self.remove_common_isotropic_adp()
print >> self.log, "Create fmodel..."
self.fmodel = self.create_fmodel(show=True)
self.crystal_gridding = self.f_obs.crystal_gridding(
d_min = self.fmodel.f_obs().d_min(),
symmetry_flags = maptbx.use_space_group_symmetry,
resolution_factor = self.resolution_factor)
# initial maps
print >> self.log, "Compute initial maps..."
self.mc = map_tools.electron_density_map(
fmodel=self.fmodel).map_coefficients(
map_type = "2mFo-DFc",
isotropize = True,
fill_missing = False)
self.mc_fill = map_tools.electron_density_map(
fmodel=self.fmodel).map_coefficients(
map_type = "2mFo-DFc",
isotropize = True,
fill_missing = True)
print >> self.log, "Finding typical atom volumes..."
self.selection = good_atoms_selection(
crystal_gridding = self.crystal_gridding,
map_coeffs = self.mc_fill,
xray_structure = self.fmodel.xray_structure)
# main FEM loop
m = self.outer_loop()
m = low_volume_density_elimination(m=m, fmodel=self.fmodel,
selection=self.selection)
self.zero_below_threshold(m = m)
# HE
m = maptbx.volume_scale(map = m, n_bins = 10000).map_data()
# create Fourier ripples filter
sel = m<0.5
msk = m.set_selected(sel, 0)
sel = msk>=0.5
msk = msk.set_selected(sel, 1)
#XXX maptbx.sharpen(map_data=m, index_span=2, n_averages=1,
#XXX allow_negatives=False)
# Use Resolve filter
m_resolve = self.resolve_filter_map()
if(m_resolve is not None): m = m * m_resolve
# Use OMIT
if(self.use_omit):
comit = mmtbx.maps.composite_omit_map.run(
fmodel = self.fmodel_nosharp,
crystal_gridding = self.crystal_gridding,
box_size_as_fraction = 0.2,
max_boxes = 2000,
neutral_volume_box_cushion_width = 2,
full_resolution_map = True,
log = self.log)
omit_map = comit.as_p1_map()
#ccp4_map(cg=self.crystal_gridding, file_name="omit1.ccp4", map_data=omit_map)
omit_map = low_volume_density_elimination(m=omit_map, fmodel=self.fmodel,
selection=self.selection,end=16)
#ccp4_map(cg=self.crystal_gridding, file_name="omit2.ccp4", map_data=omit_map)
sel = omit_map<1.5
omit_map = omit_map.set_selected(sel, 0)
sel = omit_map>=1.5
omit_map = omit_map.set_selected(sel, 1)
m = m * omit_map
#
# Extra filter: seems to ne redundant, TBD.
#
#omit_mc = comit.result_as_sf()
#omit_map = get_map(mc=omit_mc, cg=self.crystal_gridding)
#omit_map = low_volume_density_elimination(m=omit_map, fmodel=self.fmodel, selection=self.selection)
#ccp4_map(cg=self.crystal_gridding, file_name="omit2.ccp4", map_data=omit_map)
#sel = omit_map<0.5
#omit_map = omit_map.set_selected(sel, 0)
#sel = omit_map>=0.5
#omit_map = omit_map.set_selected(sel, 1)
#m = m * omit_map
#
self.mc_result = self.mc_fill.structure_factors_from_map(
map = m,
use_scale = True,
anomalous_flag = False,
use_sg = False)
if(self.sharp):
self.mc_result=mmtbx.maps.b_factor_sharpening_by_map_kurtosis_maximization(
map_coeffs=self.mc_result, show=True, b_only=False)
self.map_result = get_map(mc=self.mc_result, cg=self.crystal_gridding)*msk
def compute_original_map(self):
return map_tools.electron_density_map(
fmodel = self.create_fmodel(update_f_part1=False)).map_coefficients(
map_type = "2mFo-DFc",
isotropize = False,
fill_missing = False)
def __init__(self,
fmodel,
map_type="2mFo-DFc",
mask_data=None,
crystal_gridding=None,
number_of_kicks=100,
macro_cycles=10,
kick_completeness=0.95,
omit=True):
fmodel = self.convert_to_non_anomalous(fmodel=fmodel)
from mmtbx import map_tools
self.mc_orig = map_tools.electron_density_map(
fmodel=fmodel).map_coefficients(map_type="2mFo-DFc",
isotropize=True,
fill_missing=False)
md_orig = get_map(map_coeffs=self.mc_orig,
crystal_gridding=crystal_gridding)
# model missing
self.complete_set = map_tools.resolve_dm_map(fmodel=fmodel,
map_coeffs=self.mc_orig,
pdb_inp=None,
use_model_hl=True,
fill=True)
md_complete_set = get_map(map_coeffs=self.complete_set,
crystal_gridding=crystal_gridding)
self.missing = self.complete_set.lone_set(self.mc_orig)
# Kick map coefficients
md_kick = kick_map_coeffs(map_coeffs=self.mc_orig,
crystal_gridding=crystal_gridding,
number_of_kicks=number_of_kicks,
macro_cycles=macro_cycles,
missing=self.missing,
kick_completeness=kick_completeness)
self.mc_kick = self.map_coeffs_from_map(map_data=md_kick)
# Kick fmodel
md_fm = kick_fmodel(fmodel=fmodel,
map_type=map_type,
crystal_gridding=crystal_gridding,
number_of_kicks=number_of_kicks,
macro_cycles=macro_cycles,
missing=self.missing,
kick_completeness=kick_completeness)
self.mc_fm = self.map_coeffs_from_map(map_data=md_fm)
if (omit):
# Kick OMIT map
com1 = mmtbx.maps.composite_omit_map.run(
crystal_gridding=crystal_gridding,
fmodel=fmodel.deep_copy(), # XXX
full_resolution_map=True,
box_size_as_fraction=0.03)
md_com1 = kick_map_coeffs(map_coeffs=com1.map_coefficients(),
crystal_gridding=crystal_gridding,
number_of_kicks=number_of_kicks,
macro_cycles=macro_cycles,
phases_only=True,
missing=self.missing,
kick_completeness=kick_completeness)
self.mc_com1 = self.map_coeffs_from_map(map_data=md_com1)
# Kick OMIT map 2
com2 = mmtbx.maps.composite_omit_map.run(
crystal_gridding=crystal_gridding,
fmodel=fmodel.deep_copy(), # XXX
full_resolution_map=True,
box_size_as_fraction=0.03)
md_com2 = kick_map_coeffs(map_coeffs=com2.map_coefficients(),
crystal_gridding=crystal_gridding,
number_of_kicks=number_of_kicks,
macro_cycles=macro_cycles,
phases_only=True,
missing=self.missing,
kick_completeness=kick_completeness)
self.mc_com2 = self.map_coeffs_from_map(map_data=md_com2)
# combine maps
def intersect(m1, m2, use_average):
maptbx.intersection(map_data_1=m1,
map_data_2=m2,
thresholds=flex.double(
[0, 0.1, 0.2, 0.3, 0.4, 0.5]),
average=False)
if (use_average): return (m1 + m2) / 2
else: return m1
m = (md_kick + md_fm) / 2
m = intersect(m, md_kick, use_average=True)
m = intersect(m, md_fm, use_average=True)
if (omit):
m = intersect(m, md_com1, use_average=False)
m = intersect(m, md_com2, use_average=False)
m = intersect(m, md_orig, use_average=False)
m = intersect(m, md_complete_set, use_average=False)
self.map_data_result = m
self.mc_result = self.map_coeffs_from_map(
map_data=self.map_data_result)
