def get_cc_penalty(fit_entry):
if 'corr_folded' in cc_penalty_model:
return fit_entry['fit_terms']['cc_penalty']['corr_folded']['penalty']
if 'corr_not_folded' in cc_penalty_model:
return fit_entry['fit_terms']['cc_penalty']['corr_not_folded']['penalty']
if 'ls_folded_norm' in cc_penalty_model:
return fit_entry['fit_terms']['cc_penalty']['ls_norm']
elif 'ls_norm_not_folded' in cc_penalty_model:
return fit_entry['fit_terms']['cc_penalty']['ls_norm_not_folded']
if 'ls_no_norm' in cc_penalty_model:
return fit_entry['fit_terms']['cc_penalty']['ls_no_norm']
debug_p('No clinical cases penalty found. This should not happen!')
return None
def weighted_ccs_combos(hfca_id, weighted_ccs_model_agg_by_hfca):
debug_p('Generating clinical cases combos')
samples_by_cluster = {}
num_clusters = len(weighted_ccs_model_agg_by_hfca) # number of clusters in the given hfca
'''
# determine number of sample clinical cases timeseries per cluster to satisfy the minimum number of combos (cartesian product cardinality) of clinical case time series per hfcas
satisfied = False
sample_size_ccs_per_cluster = 1
while not satisfied:
if math.pow(num_clusters, sample_size_ccs_per_cluster) >= min_num_combos_per_hfca:
satisfied = True
break
sample_size_ccs_per_cluster = sample_size_ccs_per_cluster + 1
debug_p('sample size per cluster is ' + str(sample_size_ccs_per_cluster))
'''
# randomly sample clinical case time series per cluster
for cluster_id, ccs in weighted_ccs_model_agg_by_hfca.iteritems():
#sample_ccs = random.sample(ccs['weighted'], sample_size_ccs_per_cluster)
sample_ccs = random.sample(ccs['weighted'], sample_size)
samples_by_cluster[cluster_id] = sample_ccs
ccs_combos_hfca = []
shuffled_ccs = samples_by_cluster.values()
np.random.shuffle(shuffled_ccs)
# find a set of cartesian products on the randomly sampled clinical cases time series across clusters
for ccs_combo in it.product(*shuffled_ccs): # construct a cartesian product from the random samples of weighted clinical case traces within hfca_id
ccs_combos_hfca.append(ccs_combo)
if len(ccs_combos_hfca) >= min_num_combos_per_hfca:
break
debug_p('DONE generating clinical cases combos')
return ccs_combos_hfca, samples_by_cluster
def set_clinical_cases_penalty_by_corr(self, model_clinical_cases, cluster_id):
ccs_model_agg, ccs_ref_agg = get_cc_model_ref_traces(model_clinical_cases, cluster_id)
'''
cc_debug_agg = {}
cc_debug_agg['model'] = ccs_model_agg
cc_debug_agg['ref'] = ccs_ref_agg
with open('cc_debug_agg_'+cluster_id+'.json' ,'w') as ccd_f:
json.dump(cc_debug_agg, ccd_f, indent=3)
'''
'''
cc_debug_agg_clean = {}
cc_debug_agg_clean['model_clean'] = ccs_model_agg
cc_debug_agg_clean['ref_clean'] = ccs_ref_agg
with open('cc_debug_agg_clean'+cluster_id+'.json' ,'w') as ccd_f:
json.dump(cc_debug_agg_clean, ccd_f, indent=3)
'''
rho, p = spearmanr(ccs_ref_agg, ccs_model_agg)
self.clinical_cases_penalty = 1 - rho
self.clinical_cases_penalty_term = 1 - rho
#debug_p('clinical cases penalty ' + str(self.clinical_cases_penalty))
self.clinical_cases_penalty_weight = cc_weight
#debug_p('weighted clinical cases penalty ' + str(self.clinical_cases_penalty_weight*self.clinical_cases_penalty))
self.rho = rho
self.p_val = p
if rho > 0.75:
debug_p('clinical cases rho ' + str(rho))
debug_p('clinical cases p-value ' + str(p))
debug_p('clinical cases penalty ' + str(self.clinical_cases_penalty))
debug_p('weighted clinical cases penalty ' + str(self.clinical_cases_penalty_weight*self.clinical_cases_penalty))
def get_prevalence_based_cc(best_fits, all_fits, calib_data):
weighted_ccs_by_hfca_id_file_path = os.path.join(sim_data_dir, weighted_ccs_by_hfca_id_file)
hfca_ids = get_hfca_ids()
debug_p('Getting clinical cases samples based on prevalence optimal regions')
weighted_ccs_model_agg_by_hfca = {}
for hfca_id in hfca_ids:
hfca_id = str(hfca_id)
weighted_ccs_model_agg_by_hfca[hfca_id] = {}
cluster_ids = hfca_id_2_cluster_ids(hfca_id)
for cluster_id in cluster_ids:
cluster_cat = get_cluster_category(cluster_id)
sims_opt_region = get_prevalence_opt_region_sims(best_fits, all_fits, cluster_id)
# assume sample size is always less than the size of the population!
sample_sims_opt_region = random.sample(sims_opt_region, sample_size)
for i, (sample_group_key, sample_sim_key) in enumerate(sample_sims_opt_region):
sample_cc_trace = calib_data[cluster_cat][sample_group_key][sample_sim_key]
cc_cluster_weight_factor = get_cc_cluster_weight_factor(cluster_id) # accounting for health seeking behavior data
cc_cluster_weight_factor = (cluster_2_mean_pop(cluster_id)/(calib_node_pop + 0.0)) * cc_cluster_weight_factor # accounting for real cluster population (mean across all rounds)
ccs_model_agg, ccs_ref_agg = get_cc_model_ref_traces(sample_cc_trace, cluster_id, cc_cluster_weight_factor)
ccs_model_agg_unweighted, ccs_ref_agg_unweighted = get_cc_model_ref_traces(sample_cc_trace, cluster_id)
if not cluster_id in weighted_ccs_model_agg_by_hfca[hfca_id]:
weighted_ccs_model_agg_by_hfca[hfca_id][cluster_id] = {
'weighted':[],
'unweighted':[]
}
weighted_ccs_model_agg_by_hfca[hfca_id][cluster_id]['weighted'].append(ccs_model_agg)
weighted_ccs_model_agg_by_hfca[hfca_id][cluster_id]['unweighted'].append((sample_group_key,sample_sim_key,ccs_model_agg_unweighted))
with open(weighted_ccs_by_hfca_id_file_path, 'w') as w_ccs_f:
json.dump(weighted_ccs_model_agg_by_hfca, w_ccs_f, indent = 3)
debug_p('DONE getting clinical cases samples based on prevalence optimal regions')
debug_p('Saved clinical cases samples based on prevalence optimal regions to ' + weighted_ccs_by_hfca_id_file_path)
return weighted_ccs_model_agg_by_hfca
def refresh_school_info(
homepage_response='',
a_task: utils.Atask = object(),
# homepage_response='',
sess=object,
m_headers={},
m_cookies={},
schl_abbr='',
sql_conn=object,
# tb_schl_lib_stmp = 'schl_lib_stmp',
# platform=utils.GBCF.PLATFORM['IGTL'],
) -> dict:
# info_dict for return
user_conf_dict = {}
libid_and_name = {}
# sql_param example : (schl_abbr, schl_nm,open_time, libid, clssrm_nm, seatmap_json)
sql_param = []
# get open time
# usage_rules_url = 'https://wechat.v2.traceint.com/index.php/center/rule.html'
usage_rules_url = a_task.BASE_URL['rules']
html_opentime = utils.get_response(url=usage_rules_url,
sess=sess,
m_headers=m_headers,
m_cookies=m_cookies,
verify_key='使用规则')
# utils.debug_p('get_opentime=', html_opentime)
open_time = get_opentime(html_opentime)
user_conf_dict['open_time'] = open_time
# url_host = 'https://wechat.v2.traceint.com'
# path_homepage = '/index.php/reserve/index.html?f=wechat'
# if not homepage_url:
# homepage_url = url_host + path_homepage
homepage_url = a_task.BASE_URL['home_page']
if not homepage_response:
# homepage_response is none
homepage_response = utils.get_response(url=homepage_url,
sess=sess,
m_headers=m_headers,
m_cookies=m_cookies,
verify_key='')
# get_name
user_name, school_name = get_name(homepage_response)
user_conf_dict['user_name'] = user_name
user_conf_dict['schl_abbr'] = schl_abbr.lower()
user_conf_dict['school_name'] = school_name
# get_classroom clssrm:list[dict{}] [{'name':classroom_name,'libid':libid, 'path':classroom_path},{}]
clssrm = get_classroom(homepage_response)
# entry seat map page
for i in range(len(clssrm)):
try:
time.sleep(0.2)
# {'name':classroom_name,'libid':libid, 'path':classroom_path}
cr = clssrm[i]
libid_and_name[cr['libid']] = cr['classroom_name']
path_seat_map_page = cr['path']
# get seat page response
seat_map_page = utils.get_response(url=a_task.BASE_URL['host'] +
path_seat_map_page,
sess=sess,
m_headers=m_headers,
m_cookies=m_cookies)
if not seat_map_page:
utils.debug_p(
'[E]: crawldata.py -> refresh_school_info() -> seat_map_page is none'
)
return {}
# parse, seat_map = {seat_num : coordinate, seat_num2 : coordinate2, }
seat_map = get_seatmap(seat_map_page)
if not seat_map:
# get seat_map failed
continue
# cr: {'classroom_name':classroom_name,'libid':libid, 'path':classroom_path} + {seat_map:...}
cr['seat_map'] = seat_map
clssrm[i] = cr
# (platform, schl_abbr, schl_nm, open_time, libid, clssrm_nm, seatmap_json)
sql_param.append(
(a_task.platform, schl_abbr, school_name, open_time,
int(cr['libid']), cr['classroom_name'],
json.dumps(cr['seat_map'])))
except Exception as e:
utils.debug_p(
'refresh_school_info has a seat_map_page error; cr[\'classroom_name\']=',
clssrm[i].get('classroom_name', 'null-classroom_name'),
traceback.format_exc())
debug_p('[refresh_school_info]', 'sql_param=', sql_param)
if len(sql_param) == 0:
user_conf_dict['classroom'] = []
return user_conf_dict
user_conf_dict['classroom'] = clssrm
# insert/REPLACE into sqlite3
insert_many_sql = 'REPLACE INTO ' + utils.SqlAct.tb_schl_lib_stmp + \
'(platform, schl_abbr, schl_nm, open_time, libid, clssrm_nm, seatmap_json) ' + \
'VALUES(?, ?, ?, ?, ?, ?, ?);'
cur = sql_conn.cursor()
cur.executemany(insert_many_sql, sql_param)
sql_conn.commit()
# {user_name:'',schl_abbr:'', school_name:'','open_time':'06:10', classroom:[{'classroom_name':classroom_name,'libid':libid, 'path':classroom_path,'seat_map':''},{},{}...]}
## { ,schl_abbr:'', school_name:'','open_time':'06:10', classroom:[{'classroom_name':classroom_name,'libid':libid, 'seat_map':''},{},{}...]}
libid_set = set([str(_[4]) for _ in sql_param])
user_conf_dict['classroom'] = [
_ for _ in user_conf_dict['classroom'] if str(_['libid']) in libid_set
]
return user_conf_dict
def fit(self):
models_list_prime = calib_data_2_models_list(self.calib_data)
best_fits = {}
all_fits = {}
#all_fits = {'fit':{'min_residual':float('inf')}, }
all_fits['min_residual'] = float('inf')
all_fits['max_residual'] = 0.0
all_fits['models'] = {}
debug_p('category ' + self.category)
for idx,cluster_id in enumerate(c2c(self.category)):
models_list = copy.deepcopy(models_list_prime)
print "Processing cluster " + cluster_id + "."
debug_p('Processing cluster ' + cluster_id + " in " + self.category + ".")
itn_traj = cluster_2_itn_traj(cluster_id)
drug_cov = cluster_2_drug_cov(cluster_id)
# prune models to the ones matching prior data
cluster_models = []
for model in models_list:
model_meta = model.get_meta()
if model_meta['group_key'] == get_sim_group_key(itn_traj, drug_cov):
#debug_p('model id before kariba conversion ' + str(model.get_model_id()))
group_key = model_meta['group_key']
sim_key = model_meta['sim_key']
model = KaribaModel(model, self.calib_data[group_key][sim_key], cluster_id, all_fits = self.fit_terms)
#model = kariba_model
#debug_p('model id after kariba conversion ' + str(model.get_model_id()))
cluster_models.append(model)
surv_data = {}
all_ref_objs_found = True
for channel_code in objectives_channel_codes:
if channel_code == 'prevalence':
prev_data = c2p(cluster_id)
if prev_data:
surv_data[channel_code] = prev_data
else:
msg = 'Prevalence objective reference data was not found!\n Skipping cluster ' + cluster_id + ' fit!'
print msg
all_ref_objs_found = False
else:
msg = "Channel objective" + channel_code + " not implemented yet!\nSetting objective reference data to None."
warn_p(msg)
surv_data[channel_code] = None
# one of the reference objective channels was not found; skipping cluster fit!
if not all_ref_objs_found:
continue
ref = d2f(surv_data)
# adjust highest possible fit to account for RDT+ model in dtk not reflecting reality at the upper end
obj_prev = ref.get_obj_by_name('prevalence')
d_points = obj_prev.get_points()
obj_prev.set_points([min(point, rdt_max) for point in d_points])
fitting_set = FittingSet(cluster_id, cluster_models, ref)
if load_prevalence_mse:
fit = Fit(fitting_set, type = 'mmse_distance_cached')
else:
fit = Fit(fitting_set)
best_fit_model = fit.best_fit_mmse_distance()
min_residual = fit.get_min_residual()
max_residual = fit.get_max_residual()
if min_residual < all_fits['min_residual']:
all_fits['min_residual'] = min_residual
if max_residual > all_fits['max_residual']:
all_fits['max_residual'] = max_residual
if best_fit_model:
temp_h, const_h, itn_level, drug_coverage_level = get_model_params(best_fit_model)
best_fit_meta = best_fit_model.get_meta()
best_fits[cluster_id] = {}
best_fits[cluster_id]['habs'] = {}
best_fits[cluster_id]['habs']['const_h'] = const_h
best_fits[cluster_id]['habs']['temp_h'] = temp_h
best_fits[cluster_id]['ITN_cov'] = itn_level
best_fits[cluster_id]['category'] = self.category
best_fits[cluster_id]['MSAT_cov'] = drug_coverage_level
best_fits[cluster_id]['sim_id'] = best_fit_meta['sim_id']
best_fits[cluster_id]['sim_key'] = best_fit_meta['sim_key']
best_fits[cluster_id]['group_key'] = best_fit_meta['group_key']
best_fits[cluster_id]['fit_value'] = best_fit_model.get_fit_val()
best_fits[cluster_id]['sim_avg_reinfection_rate'] = best_fit_model.get_sim_avg_reinfection_rate()
best_fits[cluster_id]['ref_avg_reinfection_rate'] = best_fit_model.get_ref_avg_reinfection_rate()
best_fits[cluster_id]['prevalence'] = best_fit_model.get_objective_by_name('prevalence').get_points()
# redundancy; to be refactored via FitEntry class
best_fits[cluster_id]['fit'] = {}
best_fits[cluster_id]['fit']['value'] = best_fit_model.get_fit_val()
best_fits[cluster_id]['fit']['temp_h'] = temp_h
best_fits[cluster_id]['fit']['const_h'] = const_h
best_fits[cluster_id]['fit']['ITN_cov'] = itn_level
best_fits[cluster_id]['fit']['MSAT_cov'] = drug_coverage_level
best_fits[cluster_id]['fit']['sim_id'] = best_fit_meta['sim_id']
best_fits[cluster_id]['fit']['sim_key'] = best_fit_meta['sim_key']
best_fits[cluster_id]['mse'] = {}
best_fits[cluster_id]['mse']['value'] = fit.get_min_mses()['prevalence']['value'] # get mmse for objective prevalence
best_fit_mse_model = fit.get_min_mses()['prevalence']['model']
temp_h, const_h, itn_level, drug_coverage_level = get_model_params(best_fit_mse_model)
model_meta_data = best_fit_mse_model.get_meta()
best_fits[cluster_id]['mse']['temp_h'] = temp_h
best_fits[cluster_id]['mse']['const_h'] = const_h
best_fits[cluster_id]['mse']['ITN_cov'] = itn_level
best_fits[cluster_id]['mse']['MSAT_cov'] = drug_coverage_level
best_fits[cluster_id]['mse']['sim_id'] = model_meta_data['sim_id']
best_fits[cluster_id]['mse']['sim_key'] = model_meta_data['sim_key']
best_fits[cluster_id]['cc_penalty'] = {}
best_fits[cluster_id]['cc_penalty']['value'] = fit.get_min_penalties()['prevalence']['value'] # get clinical penalty for objective prevalence; at present this is just the clinical cases penalty; if reinfection is considered the code needs to be adjusted
best_fit_cc_penalty_model = fit.get_min_penalties()['prevalence']['model']
temp_h, const_h, itn_level, drug_coverage_level = get_model_params(best_fit_cc_penalty_model)
model_meta_data = best_fit_cc_penalty_model.get_meta()
best_fits[cluster_id]['cc_penalty']['temp_h'] = temp_h
best_fits[cluster_id]['cc_penalty']['const_h'] = const_h
best_fits[cluster_id]['cc_penalty']['ITN_cov'] = itn_level
best_fits[cluster_id]['cc_penalty']['MSAT_cov'] = drug_coverage_level
best_fits[cluster_id]['cc_penalty']['sim_id'] = model_meta_data['sim_id']
best_fits[cluster_id]['cc_penalty']['sim_key'] = model_meta_data['sim_key']
rho = best_fit_model.get_rho()
p_val = best_fit_model.get_p_val()
if rho and p_val :
best_fits[cluster_id]['rho'] = rho
best_fits[cluster_id]['p_val'] = p_val
debug_p('rho' + str(rho))
debug_p('p_val' + str(p_val))
else:
msg = "something went wrong and the best fit for " + cluster_id + " could not be found."
warn_p(msg)
all_fits['models'][cluster_id] = cluster_models
#all_fits['models'][cluster_id] = fit.get_fitting_set_models()
print str(idx+1) + " clusters have been processed."
debug_p( str(idx+1) + " clusters have been processed in category " + self.category)
'''
if idx > 0:
break
'''
return best_fits, all_fits
def best_fit_mmse_distance(self, cached = False):
models_list = self.fitting_set.get_models_list()
ref = self.fitting_set.get_ref()
min_distance = float('inf')
min_mses = {}
min_penalties = {}
# assume all models have the same objectives and initialize min obj penalty to inf
# initialize model minimizer to first model in list
for obj in models_list[0].get_objectives():
min_penalties[obj.get_name()] = {}
min_penalties[obj.get_name()]['value'] = float('inf')
min_penalties[obj.get_name()]['model'] = models_list[0]
min_mses[obj.get_name()] = {}
min_mses[obj.get_name()]['value'] = float('inf')
min_mses[obj.get_name()]['model'] = models_list[0]
best_fit = None
debug_p(len(models_list))
debug_p('======================================================================================')
for model in models_list:
distance = None
mse = 0.0
for obj in model.get_objectives():
m_points = obj.get_points() # model values for this obj
d_points = ref.get_obj_by_name(obj.get_name()).get_points() # reference data values for this obj
#debug_p('m_points len: ' + str(len(m_points)))
#debug_p('d_points len: ' + str(len(d_points)))
points_weights = obj.get_points_weights()
if not cached:
mse = self.mse(m_points, d_points, points_weights)
else:
mse = model.get_cached_mse()
if not mse == None:
if mse <= min_mses[obj.get_name()]['value']:
min_mses[obj.get_name()]['value'] = mse
min_mses[obj.get_name()]['model'] = model
if obj.get_model_penalty() <= min_penalties[obj.get_name()]['value']:
min_penalties[obj.get_name()]['value'] = obj.get_model_penalty()
min_penalties[obj.get_name()]['model'] = model
if distance == None:
#debug_p('obj weight: ' + str(obj.get_weight()))
#debug_p('obj model penalty: ' + str(obj.get_model_penalty()))
distance = obj.get_weight()*(mse + obj.get_model_penalty())
else:
#debug_p('obj weight: ' + str(obj.get_weight()))
#debug_p('distance ' + str(distance))
distance = distance + obj.get_weight()*(mse + obj.get_model_penalty())
model.set_mse(mse)
if distance:
# a bit redundant since we also find min_distance; will need to adjust
if distance < self.min_residual:
self.min_residual = distance
if distance > self.max_residual:
self.max_residual = distance
if distance <= min_distance:
debug_p('current best distance ' + str(min_distance))
if best_fit:
#debug_p('current best fit model ' + str(best_fit.get_model_id()))
debug_p('current best fit model mmse ' + str(best_fit.get_fit_val()))
#debug_p('model ' + str(model.get_model_id()))
debug_p('improving fit ' + str(distance))
debug_p('fit difference ' + str(distance - min_distance))
min_distance = distance
model.set_fit_val(min_distance)
best_fit = model
else:
model.set_fit_val(distance)
#debug_p('best_fit ' + str(best_fit))
self.min_mses = min_mses
self.min_penalties = min_penalties
return best_fit
def plot_calib_prev_traces(self):
count = 0
for cluster_id, cluster_record in self.best_fits.iteritems():
debug_p('Plotting prevalence trace for cluster ' + cluster_id + ' in category ' + self.category)
#fig = plt.figure(cluster, figsize=(11, 4), dpi=100, facecolor='white')
fig = plt.figure(cluster_id, figsize=(9.2, 4), dpi=100, facecolor='white')
gs = gridspec.GridSpec(1, 2)
ymax = 16
scale_int = np.array(range(0,ymax+1))
pal = cm = plt.get_cmap('jet')
cNorm = colors.Normalize(vmin=0, vmax=ymax+1)
scalarMap = cmx.ScalarMappable(norm=cNorm, cmap=pal)
ax = plt.subplot(gs[0:2])
ax.set_xlim(2150,3010)
ref = self.get_ref(cluster_id)
if not ref:
# no reference object could be constructed; no data found; return w/o plotting
return
with open(os.path.join(sim_data_dir,weighted_ccs_by_hfca_id_file), 'r') as wccs_f:
cluster_ccs_samples = json.load(wccs_f)
hfca_id = cluster_id.split('_')[0]
count_labels = 0
for (group_key, sim_key, ccs) in cluster_ccs_samples[hfca_id][cluster_id]['unweighted']:
prev_trace = self.calib_data[group_key][sim_key]['prevalence']
if count_labels == 0:
ax.plot(range(2150, 3000), prev_trace[2149:2999], alpha=0.35, linewidth=0.5, color = 'magenta', label = 'Opt 5-percentile samples for cluster ' + cluster_id)
count_labels += 1
else:
ax.plot(range(2150, 3000), prev_trace[2149:2999], alpha=0.35, linewidth=0.5, color = 'magenta', marker = None)
opt_sim_key = cluster_record['sim_key']
opt_group_key = cluster_record['group_key']
opt_const_h = cluster_record['habs']['const_h']
opt_x_temp_h = cluster_record['habs']['temp_h']
opt_itn = cluster_record['ITN_cov']
opt_drug = cluster_record['MSAT_cov']
opt_fit_value = cluster_record['fit_value']
opt_prev_trace = self.calib_data[opt_group_key][opt_sim_key]['prevalence']
ax.plot(range(2150, 3000), opt_prev_trace[2149:2999], alpha=1, linewidth=2.0, c = 'black', label = 'Best fit: prevalence + clinical cases: eff. constant=' + str(opt_const_h*opt_x_temp_h) + ', all='+str(opt_x_temp_h) + ', drug cov.' + str(opt_drug) + ', ITN dist. = '+str(opt_itn))
sim_key = cluster_record['mse']['sim_key']
# avoid doing that and add group_key to corresponding terms in best_fits
group_key = sim_key_2_group_key(sim_key)
const_h = cluster_record['mse']['const_h']
x_temp_h = cluster_record['mse']['temp_h']
itn = cluster_record['mse']['ITN_cov']
drug = cluster_record['mse']['MSAT_cov']
prev_trace_by_prev = self.calib_data[group_key][sim_key]['prevalence']
ax.plot(range(2150, 3000), prev_trace_by_prev[2149:2999], alpha=1, linewidth=2.0, c = 'magenta', label = 'Best fit: prevalence: eff. constant=' + str(const_h*x_temp_h) + ', all='+str(x_temp_h) + ', drug cov.' + str(drug) + ', ITN dist. = '+str(itn))
sim_key = cluster_record['cc_penalty']['sim_key']
group_key = sim_key_2_group_key(sim_key)
const_h = cluster_record['cc_penalty']['const_h']
x_temp_h = cluster_record['cc_penalty']['temp_h']
itn = cluster_record['cc_penalty']['ITN_cov']
drug = cluster_record['cc_penalty']['MSAT_cov']
prev_trace_by_cc = self.calib_data[group_key][sim_key]['prevalence']
ax.plot(range(2150, 3000), prev_trace_by_cc[2149:2999], alpha=1, linewidth=2.0, c = 'blue', label = 'Best fit: clinical cases: eff. constant=' + str(const_h*x_temp_h) + ', all='+str(x_temp_h) + ', drug cov.' + str(drug) + ', ITN dist. = '+str(itn))
obs_prevs = ref.to_dict()['prevalence']['d_points']
label_obs_prev_shown = False
label_sim_prev_shown = False
max_obs_prev = 0.0
for i,prev in enumerate(obs_prevs):
if prev != 'nan':
if max_obs_prev < prev:
max_obs_prev = prev
if not label_obs_prev_shown:
label_obs_prev = 'Observed prevalence'
label_obs_prev_shown = True
else:
label_obs_prev = None
ax.scatter(channels_sample_points['prevalence'][i], prev, c = 'red', facecolor = 'red', marker='o', s = 40, label = label_obs_prev, zorder=200)
if not label_sim_prev_shown:
label_sim_prev = 'Best fit simulated prevalence at rnds.'
label_sim_prev_shown = True
else:
label_sim_prev = None
ax.scatter(channels_sample_points['prevalence'][i], opt_prev_trace[channels_sample_points['prevalence'][i]], c = 'black', facecolor = 'none', marker='o', s = 60, label = label_sim_prev, zorder=150)
'''
count_traces = 0
for sim_key,fit_entry in self.all_fits[cluster_id].iteritems():
if sim_key == 'min_terms' or sim_key == 'max_terms':
continue
group_key = fit_entry['group_key']
fit_val = fit_entry['fit_val']
const_h = fit_entry['const_h']
x_temp_h = fit_entry['x_temp_h']
#if sim_key == opt_sim_key or fit_val > opt_fit_value + opt_fit_value*subopt_plots_threshold or count_traces > 10:
#if fit_entry['fit_terms']['mse'] <= satp(z, sample_size_percentile):
#do not plot optimal traces since we've already plotted it ;also do not plot too many suboptimal traces
# continue
prev_trace = self.calib_data[group_key][sim_key]['prevalence']
marker = self.get_marker(sim_key, count_traces)
#ax.plot(range(2180, 3000), prev_trace[2179:2999], alpha=0.75, linewidth=0.5, marker = marker, markersize = 0.5*opt_marker_size, label = 'eff. constant=' + str(const_h*x_temp_h) + ', all='+str(x_temp_h))
#ax.plot(range(2180, 3000), prev_trace[2179:2999], alpha=0.75, linewidth=0.5, marker = marker, markersize = 0.5*opt_marker_size)
ax.plot(range(2150, 3000), prev_trace[2149:2999], alpha=0.75, linewidth=0.5)
for i,prev in enumerate(obs_prevs):
ax.scatter(channels_sample_points['prevalence'][i], prev_trace[channels_sample_points['prevalence'][i]], marker = marker, c = 'black', facecolor = 'none', s = 30)
count_traces = count_traces + 1
'''
ax.set_ylim(0,min(max(max_obs_prev, max(opt_prev_trace))+0.1,1))
plt.xlabel('Time (days)', fontsize=8)
plt.ylabel('Prevalence (population fraction)', fontsize=8)
plt.legend(loc=1, fontsize=8)
plt.title('Prevalence timeseries', fontsize = 8, fontweight = 'bold', color = 'black')
plt.gca().tick_params(axis='x', labelsize=8)
plt.gca().tick_params(axis='y', labelsize=8)
plt.tight_layout()
output_plot_file_path = os.path.join(self.root_sweep_dir, traces_plots_dir, traces_base_file_name + cluster_id + '.png')
plt.savefig(output_plot_file_path, dpi = 300, format='png')
plt.close()
count = count + 1
def plot_weighted_cc_per_hfca(self, weighted_ccs_model_agg_by_hfca, ccs_model_agg_by_hfca_cluster_id):
clusters_processed = 0
for hfca_id, weighted_ccs_combos in weighted_ccs_model_agg_by_hfca.iteritems():
weighted_ccs_by_bin = {}
for i in range(0, cc_num_fold_bins):
weighted_ccs_by_bin[i] = []
for weighted_ccs_combo in weighted_ccs_combos:
sum_weighted_ccs = cc_num_fold_bins * [0]
for weighted_ccs in weighted_ccs_combo:
sum_weighted_ccs = np.add(sum_weighted_ccs, weighted_ccs)
for i in range(0, cc_num_fold_bins):
weighted_ccs_by_bin[i].append(sum_weighted_ccs[i])
per_bottom = []
per_top = []
per_median = []
for i in range(0, cc_num_fold_bins):
weighted_ccs_by_bin_idx = weighted_ccs_by_bin[i]
per_bottom.append( satp(weighted_ccs_by_bin_idx, 2.5) )
per_top.append( satp(weighted_ccs_by_bin_idx, 97.5) )
per_median.append( satp(weighted_ccs_by_bin_idx, 50) )
'''
debug_p('length of weighted ccs_combos array ' + str(len(weighted_ccs_combos)))
'''
debug_p('length of bin 0 in weighted_ccs_by_bin ' + str(len(weighted_ccs_by_bin[0])))
for cluster_id in hfca_id_2_cluster_ids(hfca_id):
fig = plt.figure(cluster_id, figsize=(9.2, 4), dpi=100, facecolor='white')
gs = gridspec.GridSpec(1, 4)
ax = plt.subplot(gs[0:4])
x_smooth = np.linspace(0, cc_num_fold_bins-1,60)
per_bottom_smooth = spline(range(0, cc_num_fold_bins),per_bottom,x_smooth)
per_top_smooth = spline(range(0, cc_num_fold_bins),per_top,x_smooth)
per_median_smooth = spline(range(0, cc_num_fold_bins),per_median,x_smooth)
ax.plot(x_smooth, per_bottom_smooth, alpha=1, linewidth=0.5, color = 'black', linestyle=':', label = '2.5 percentile HS weighted: prevalence space samples', marker = None)
ax.plot(x_smooth, per_top_smooth, alpha=1, linewidth=0.5, color = 'black', linestyle=':', label = '97.5 percentile HS weighted: prevalence space samples', marker = None)
ax.plot(x_smooth, per_median_smooth, alpha=1, linewidth=2.0, color = 'magenta', linestyle='-', label = 'median HS weighted: prevalence space samples', marker = None)
ax.fill_between(x_smooth, per_bottom_smooth, per_top_smooth, facecolor='gray', alpha=0.5, interpolate=True)
cluster_cat = get_cluster_category(cluster_id)
opt_group_key = self.best_fits[cluster_id]['group_key']
opt_sim_key_cc = self.best_fits[cluster_id]['cc_penalty']['sim_key']
cc_trace_opt_cc = self.calib_data[cluster_cat][opt_group_key][opt_sim_key_cc]
opt_sim_key_prev = self.best_fits[cluster_id]['mse']['sim_key']
cc_trace_opt_prev = self.calib_data[cluster_cat][opt_group_key][opt_sim_key_prev]
opt_sim_key_fit = self.best_fits[cluster_id]['fit']['sim_key']
cc_trace_opt_fit = self.calib_data[cluster_cat][opt_group_key][opt_sim_key_fit]
ccs_model_agg_cc, ccs_ref_agg = get_cc_model_ref_traces(cc_trace_opt_cc, cluster_id)
ccs_model_agg_prev, ccs_ref_agg = get_cc_model_ref_traces(cc_trace_opt_prev, cluster_id)
ccs_model_agg_fit, ccs_ref_agg = get_cc_model_ref_traces(cc_trace_opt_fit, cluster_id)
facility = hfca_id_2_facility(hfca_id)
ax.plot(range(0, len(ccs_model_agg_cc)), ccs_model_agg_cc, alpha=1, linewidth=1, color = 'blue', label = 'Best fit: clinical cases', marker = 's')
ax.plot(range(0, len(ccs_model_agg_prev)), ccs_model_agg_prev, alpha=1, linewidth=1, color = 'magenta', label = 'Best fit: prevalence', marker = 'o')
ax.plot(range(0, len(ccs_model_agg_fit)), ccs_model_agg_fit, alpha=1, linewidth=1, color = 'black', label = 'Best fit: prevalence + clinical cases', marker = '*')
ax.plot(range(0, len(ccs_ref_agg)), ccs_ref_agg, alpha=1, linewidth=2.0, linestyle = '-', color = 'red', label = 'Observed in ' + facility, marker = None)
for i,sample_ccs in enumerate(ccs_model_agg_by_hfca_cluster_id[hfca_id][cluster_id]['unweighted']):
if i == 0:
ax.plot(range(0, cc_num_fold_bins), sample_ccs[2], alpha=0.5, linewidth=0.5, color = 'magenta', label = 'Opt 5-percentile samples for cluster ' + cluster_id, marker = None)
#ax.plot(range(0, cc_num_fold_bins), sample_ccs[2])
else:
ax.plot(range(0, cc_num_fold_bins), sample_ccs[2], alpha=0.5, linewidth=0.5, color = 'magenta', marker = None)
plt.xlabel('6-week bins', fontsize=8)
plt.ylabel('Clinical cases', fontsize=8)
legend = plt.legend(loc=1, fontsize=8)
plt.xlim(0,8)
plt.title('Clinical cases timeseries', fontsize = 8, fontweight = 'bold', color = 'black')
plt.gca().tick_params(axis='x', labelsize=8)
plt.gca().tick_params(axis='y', labelsize=8)
plt.tight_layout()
output_plot_file_path = os.path.join(self.root_sweep_dir, weighted_cc_traces_plots_dir, weighted_cc_traces_base_file_name + cluster_id + '.png')
plt.savefig(output_plot_file_path, dpi = 300, format='png')
plt.close()
clusters_processed = clusters_processed + 1
debug_p('Processed weighting and plotting clinical cases for ' + str(clusters_processed) + ' clusters')
def plot_calib_cc_traces_clusters(self):
for cluster_id, cluster_record in self.best_fits.iteritems():
debug_p('Plotting clinical cases trace for cluster ' + cluster_id + ' in category ' + self.category)
fig = plt.figure(cluster_id, figsize=(9.2, 4), dpi=100, facecolor='white')
opt_sim_key = cluster_record['sim_key']
opt_group_key = cluster_record['group_key']
opt_cc_trace = self.calib_data[opt_group_key][opt_sim_key]['cc']
ccs_model_agg, ccs_ref_agg = get_cc_model_ref_traces(opt_cc_trace, cluster_id)
#debug_p('model length ' + str(len(ccs_model_agg)))
#debug_p('ref length ' + str(len(ccs_ref_agg)))
hfca_id = cluster_id.split('_')[0]
facility = hfca_id_2_facility(hfca_id)
gs = gridspec.GridSpec(1, 4)
ymax = 16
scale_int = np.array(range(0,ymax+1))
pal = cm = plt.get_cmap('jet')
cNorm = colors.Normalize(vmin=0, vmax=ymax+1)
scalarMap = cmx.ScalarMappable(norm=cNorm, cmap=pal)
ax = plt.subplot(gs[0:4])
#ax.set_ylim(1000)
opt_const_h = cluster_record['habs']['const_h']
opt_x_temp_h = cluster_record['habs']['temp_h']
opt_itn = cluster_record['ITN_cov']
opt_drug = cluster_record['MSAT_cov']
opt_fit_value = cluster_record['fit_value']
# the following code only relevant for rank correlation cc penalty fit
opt_rho = None
opt_p_val = None
if 'rho' in cluster_record:
opt_rho = cluster_record['rho']
if 'p_val' in cluster_record:
opt_p_val = cluster_record['p_val']
'''
mod_dates, mod_cases = zip(*ccs_model_agg)
ref_dates, ref_cases = zip(*ccs_ref_agg)
'''
if opt_rho and opt_p_val:
ax.plot(range(0, len(ccs_model_agg)), ccs_model_agg, alpha=1, linewidth=2.0, c = 'black', label = 'Best fit: eff. constant=' + str(opt_const_h*opt_x_temp_h) + ', all='+str(opt_x_temp_h) + ', drug cov.' + str(opt_drug) + ', ITN dist. = '+str(opt_itn) + ', rho=' + str(opt_rho) + ', p-val=' + str(opt_p_val), marker = opt_marker, markersize = opt_marker_size)
else:
ax.plot(range(0, len(ccs_model_agg)), ccs_model_agg, alpha=1, linewidth=2.0, c = 'black', label = 'Best fit: eff. constant=' + str(opt_const_h*opt_x_temp_h) + ', all='+str(opt_x_temp_h) + ', drug cov.' + str(opt_drug) + ', ITN dist. = '+str(opt_itn), marker = opt_marker, markersize = opt_marker_size)
ax.plot(range(0, len(ccs_ref_agg)), ccs_ref_agg, alpha=1, linewidth=2.0, c = 'red', label = 'Observed in ' + facility)
'''
if opt_rho and opt_p_val:
ax.plot(mod_dates, mod_cases, alpha=1, linewidth=2.0, c = 'black', label = 'Best fit: eff. constant=' + str(opt_const_h*opt_x_temp_h) + ', all='+str(opt_x_temp_h) + ', drug cov.' + str(opt_drug) + ', ITN dist. = '+str(opt_itn) + ', rho=' + str(opt_rho) + ', p-val=' + str(opt_p_val), marker = opt_marker, markersize = opt_marker_size)
else:
ax.plot(mod_dates, mod_cases, alpha=1, linewidth=2.0, c = 'black', label = 'Best fit: eff. constant=' + str(opt_const_h*opt_x_temp_h) + ', all='+str(opt_x_temp_h) + ', drug cov.' + str(opt_drug) + ', ITN dist. = '+str(opt_itn), marker = opt_marker, markersize = opt_marker_size)
ax.bar(ref_dates, ref_cases, width=12,color='red',edgecolor='red', linewidth=0, label = 'Observed in ' + facility)
#ax.plot(dates, ccs_ref_agg, alpha=1, linewidth=2.0, c = 'red', label = 'Observed in ' + facility)
'''
count_traces = 0
for sim_key, fit_entry in self.all_fits[cluster_id].iteritems():
if sim_key == 'min_terms' or sim_key == 'max_terms':
continue
group_key = fit_entry['group_key']
fit_val = fit_entry['fit_val']
if sim_key == opt_sim_key or fit_val > opt_fit_value + opt_fit_value*subopt_plots_threshold or count_traces > 10:
# do not plot optimal traces since we've already plotted it ;also do not plot too suboptimal traces
continue
cc_trace = self.calib_data[group_key][sim_key]['cc']
ccs_model_agg, ccs_ref_agg = get_cc_model_ref_traces(cc_trace, cluster_id)
# the following code only relevant for rank correlation cc penalty fit
rho = None
p_val = None
if 'rho' in fit_entry:
rho = fit_entry['rho']
if 'p_val' in fit_entry:
p_val = fit_entry['p_val']
const_h = fit_entry['const_h']
x_temp_h = fit_entry['x_temp_h']
itn = fit_entry['itn_level']
drug = fit_entry['drug_cov']
'''
mod_dates, mod_cases = zip(*ccs_model_agg)
ref_dates, ref_cases = zip(*ccs_ref_agg)
'''
marker = self.get_marker(sim_key, count_traces)
if rho and p_val:
#ax.plot(range(0, len(ccs_model_agg)), ccs_model_agg, alpha=0.75, linewidth=0.5, marker = marker, markersize = 0.5*opt_marker_size, label = 'eff. constant=' + str(const_h*x_temp_h) + ', all='+str(x_temp_h) + 'rho=' + str(rho) + ', p-val=' + str(p_val))
#ax.plot(range(0, len(ccs_model_agg)), ccs_model_agg, alpha=0.75, linewidth=0.5, marker = marker, markersize = 0.5*opt_marker_size)
ax.plot(range(0, len(ccs_model_agg)), ccs_model_agg, alpha=0.75, linewidth=0.5)
else:
#ax.plot(range(0, len(ccs_model_agg)), ccs_model_agg, alpha=0.75, linewidth=0.5, marker = marker, markersize = 0.5*opt_marker_size, label = 'eff. constant=' + str(const_h*x_temp_h) + ', all='+str(x_temp_h))
ax.plot(range(0, len(ccs_model_agg)), ccs_model_agg, alpha=0.75, linewidth=0.5)
#ax.plot(range(0, len(ccs_ref_agg)), ccs_ref_agg, alpha=1, linewidth=1.0, c = 'red', label = 'Observed in ' + facility)
count_traces = count_traces + 1
'''
if rho and p_val:
ax.plot(mod_dates, mod_cases, alpha=0.75, linewidth=2.0, marker = marker, label = 'eff. constant=' + str(const_h*x_temp_h) + ', all='+str(x_temp_h) + 'rho=' + str(rho) + ', p-val=' + str(p_val))
else:
ax.plot(mod_dates, mod_cases, alpha=0.75, linewidth=2.0, marker = marker, label = 'eff. constant=' + str(const_h*x_temp_h) + ', all='+str(x_temp_h))
ax.bar(ref_dates, ref_cases, width=12,color='red',edgecolor='red', linewidth=0, label = 'Observed in ' + facility)
'''
plt.xlabel('6-week bins', fontsize=8)
plt.ylabel('Clinical cases', fontsize=8)
legend = plt.legend(loc=1, fontsize=8)
'''
init_font_size = 8
for i,label in enumerate(legend.get_texts()):
if i > 2:
label.set_fontsize(max(init_font_size - i, 5))
'''
plt.title('Clinical cases timeseries', fontsize = 8, fontweight = 'bold', color = 'black')
plt.gca().tick_params(axis='x', labelsize=8)
plt.gca().tick_params(axis='y', labelsize=8)
plt.tight_layout()
output_plot_file_path = os.path.join(self.root_sweep_dir, cc_traces_plots_dir, cc_traces_base_file_name + cluster_id + '.png')
plt.savefig(output_plot_file_path, dpi = 300, format='png')
plt.close()
def plot_calib_err_surfaces(self, err_surface_types):
count = 0
min_residual = self.residuals['min']
max_residual = self.residuals['max']
for cluster_id, cluster_record in self.best_fits.iteritems():
debug_p('Plotting error surface for cluster ' + cluster_id + ' in category ' + self.category)
fig_width = len(err_surface_types)*4.35
fig = plt.figure(cluster_id, figsize=(fig_width, 4), dpi=300, facecolor='white')
#debug_p('error surface types length' + str(len(err_surface_types)))
#debug_p('fig width' + str(fig_width))
gs = gridspec.GridSpec(1, 3)
error_points = {}
title_ITN = 'ITN distribution: '
title_drug_coverage = 'drug coverage: '
opt_fit = {}
opt_sim_key = cluster_record['sim_key']
opt_group_key = cluster_record['group_key']
opt_const_h = cluster_record['habs']['const_h']
opt_x_temp_h = cluster_record['habs']['temp_h']
for err_surface_type in err_surface_types:
opt_fit[err_surface_type] = {}
opt_fit[err_surface_type]['const_h'] = cluster_record[err_surface_type]['const_h']
opt_fit[err_surface_type]['temp_h'] = cluster_record[err_surface_type]['temp_h']
opt_fit[err_surface_type]['value'] = cluster_record[err_surface_type]['value']
if err_surface_type == 'cc_penalty':
opt_fit[err_surface_type]['value'] = opt_fit[err_surface_type]['value']*(math.pow(cc_weight, -1)) # opt_fit of penalties contains the weighted value; hence we reverse the weighting
opt_neigh_fits = []
for sim_key,fit_entry in self.all_fits[cluster_id].iteritems():
if sim_key == 'min_terms' or sim_key == 'max_terms':
continue
x_temp_h = fit_entry['x_temp_h']
const_h = fit_entry['const_h']
fit_val = fit_entry['fit_val']
mse = fit_entry['fit_terms']['mse']
cc_penalty = get_cc_penalty(fit_entry)
itn_level = fit_entry['itn_level']
drug_coverage_level = fit_entry['drug_cov']
group_key = fit_entry['group_key']
if group_key not in error_points:
error_points[group_key] = {
'x_temp_h':[],
'const_h':[],
'fit':[],
'cc_penalty':[],
'mse':[],
'title': title_ITN + itn_level + "; " + title_drug_coverage + str(drug_coverage_level),
'itn_level':itn_level,
'drug_coverage':drug_coverage_level
}
error_points[group_key]['x_temp_h'].append(x_temp_h)
error_points[group_key]['const_h'].append(const_h)
error_points[group_key]['fit'].append(fit_val)
error_points[group_key]['mse'].append(mse)
error_points[group_key]['cc_penalty'].append(cc_penalty)
ymax = 10
scale_int = np.array(range(1,10))
pal = cm = plt.get_cmap('nipy_spectral')
cNorm = colors.Normalize(vmin=0, vmax=ymax)
#scalarMap = cmx.ScalarMappable(norm=cNorm, cmap=pal)
scalarMap = b2mpl.get_map('Spectral', 'Diverging', 5).mpl_colors
lgds = []
for i,(err_surface_type, err_surface_style) in enumerate(err_surface_types.iteritems()):
for j,group_key in enumerate(error_points.keys()):
itn_level = error_points[group_key]['itn_level']
drug_coverage = error_points[group_key]['drug_coverage']
# currently assume opt_group_key is the same for all err_surface_types
if group_key == opt_group_key:
#debug_p('plot at position (0, ' + str(i) + ') in grid')
plt.subplot(gs[0,i])
x = error_points[group_key]['x_temp_h']
y = error_points[group_key]['const_h']
z = error_points[group_key][err_surface_type]
#print len(z)
res = 125
ttl = err_surface_style['title']
min_x = np.min(x)
min_y = np.min(y)
min_z = np.min(z)
max_x = np.max(x)
max_y = np.max(y)
max_z = np.max(z)
#f = interpolate.interp2d(x, y, z)
xi = np.linspace(min_x, max_x , res)
yi = np.linspace(min_y, max_y , res)
zi = griddata(x,y,z,xi,yi)
#xig, yig = np.meshgrid(xi, yi)
#zig = f(xi,yi)
#rbf = Rbf(x, y, z, epsilon=2)
#zig = rbf(xig, yig)
blevels = self.get_colorbar_ticks(min_z, max_z, z)
num_colors = len(blevels)-1
from matplotlib.colors import BoundaryNorm
cmap2 = self.custom_cmap(num_colors, mincol='DarkBlue', midcol='CornflowerBlue', maxcol='w')
cmap2.set_over('0.7') # light gray
bnorm = BoundaryNorm(blevels, ncolors = num_colors, clip = False)
#rmse_pl = plt.contourf(xi,yi,zi,15,cmap=plt.cm.hot)
#rmse_pl = plt.pcolor(xi, yi, zi, cmap=plt.get_cmap('RdYlGn_r'), vmin=0.475, vmax=0.8)
#rmse_pl = plt.pcolor(xi, yi, zi, cmap=plt.get_cmap('RdYlGn_r'))
#rmse_pl = plt.pcolor(xi, yi, zi, cmap=plt.get_cmap('cool'), vmin = min_residual, vmax = max_residual)
#rmse_pl = plt.contourf(xi, yi, zi, cmap=plt.get_cmap('cool'), vmin = min_z, vmax = max_z, levels = blevels, norm = bnorm, extend = 'both')
rmse_pl = plt.contourf(xi, yi, zi, cmap=cmap2, vmin = min_z, vmax = max_z, levels = blevels, norm = bnorm, extend = 'both')
#rmse_pl = plt.contourf(xi,yi,zi,15,cmap=plt.get_cmap('paired'))
#rmse_pl.cmap.set_over('black')
#rmse_pl.cmap.set_under('grey')
max_blevel_in_sample = 0
for blevel in blevels:
if blevel <= satp(z, sample_size_percentile) and blevel > max_blevel_in_sample:
max_blevel_in_sample = blevel
pc = plt.contour(xi,yi,zi, levels=[max_blevel_in_sample], colors='r', linewidth=0, alpha=0.5)
b_per_s = pc.collections[0].get_paths()
count_labels = 0
for per in range(len(b_per_s)):
b_per_s_x = b_per_s[per].vertices[:,0]
b_per_s_y = b_per_s[per].vertices[:,1]
if count_labels == 0:
plt.fill(b_per_s_x,b_per_s_y, 'magenta', linestyle='solid', alpha=0.3, label = 'Opt 5-percentile: ' + err_surface_style['title'])
count_labels = count_labels + 1
else:
plt.fill(b_per_s_x,b_per_s_y, 'magenta', linestyle='solid', alpha=0.3)
cb = plt.colorbar(rmse_pl, ticks = blevels, spacing='uniform')
cb.set_label(ttl + ' residual', fontsize=8)
cb.ax.tick_params(labelsize=8)
#plt.scatter(x, y, 10, z, cmap=cmap2, vmin = min_z, vmax = max_z, norm = bnorm)
level1_opt_neighs_label = False
level2_opt_neighs_label = False
level3_opt_neighs_label = False
# plot all optimal markers on each surface
for (opt_err_surface_type, opt_err_surface_style) in err_surface_types.iteritems():
plt.scatter(opt_fit[opt_err_surface_type]['temp_h'], opt_fit[opt_err_surface_type]['const_h'], c = 'red', marker = opt_err_surface_style['marker'], s = 60, facecolor='none', edgecolor='black', zorder=100, label= opt_err_surface_style['title'] + ' best fit')
'''
for k,fit_val in enumerate(z):
if fit_val < opt_fit[err_surface_type]['value'] + opt_fit[err_surface_type]['value']*subopt_plots_threshold:
if not level1_opt_neighs_label:
label = '< opt + 0.1opt'
level1_opt_neighs_label = True
else:
label = None
#plt.scatter(x[k], y[k], 10, fit_val, marker = 'd', linewidth = 0.75, color = 'green', label = label)
elif fit_val < opt_fit[err_surface_type]['value'] + 2*opt_fit[err_surface_type]['value']*subopt_plots_threshold:
if not level2_opt_neighs_label:
label = '< opt + 0.2opt'
level2_opt_neighs_label = True
else:
label = None
#plt.scatter(x[k], y[k], 10, fit_val, marker = 'o', linewidth = 0.75, color = 'blue', label = label)
elif fit_val < opt_fit[err_surface_type]['value'] + 3*opt_fit[err_surface_type]['value']*subopt_plots_threshold:
if not level3_opt_neighs_label:
label = '< opt + 0.3opt'
level3_opt_neighs_label = True
else:
label = None
#plt.scatter(x[k], y[k], 10, fit_val, marker = 'x', linewidth = 0.75, color = 'red', label = label)
'''
#plt.title(ttl, fontsize = 8, fontweight = 'bold', color = 'white', backgroundcolor = scalarMap.to_rgba(scale_int[itn_levels_2_sbplts[itn_level]]))
plt.title(ttl, fontsize = 8, fontweight = 'bold', color = 'black')
plt.xlabel('All habitats scale', fontsize=8)
plt.ylabel('Constant habitat scale', fontsize=8)
plt.xlim(min_x+0.1, max_x+0.1)
plt.ylim(min_y+0.1, max_y+0.1)
#plt.ylim(0.01, 14)
plt.gca().tick_params(axis='x', labelsize=8)
plt.gca().tick_params(axis='y', labelsize=8)
'''
count_traces = 0
# NEED TO update to new FIT_ENTRY DATA STRUCT IF REUSED
for fit_entry in opt_neigh_fits:
x_temp_h = fit_entry['x_temp_h']
const_h = fit_entry['const_h']
sim_key = fit_entry['sim_key']
marker = self.get_marker(sim_key, count_traces)
plt.scatter(x_temp_h, const_h, c = 'black', marker = marker, s = 20, facecolor='none', zorder=100)
count_traces = count_traces + 1
'''
#plt.subplot(gs[itn_levels_2_sbplts[best_fit_itn_level], 0])
#debug_p('plot optimal at position (0, ' + str(i) + ') in grid')
plt.subplot(gs[0,i])
cluster_record = self.best_fits[cluster_id]
opt_itn = cluster_record['ITN_cov']
opt_drug = cluster_record['MSAT_cov']
#plt.annotate(opt_fit_value, opt_x_temp_h, opt_const_h)
#lgds.append(plt.legend(bbox_to_anchor=(0., 1, 1., .1), loc=2, ncol=1, borderaxespad=0., fontsize=8))
lgds.append(plt.legend(ncol=1,loc='upper center', bbox_to_anchor=(0.,-0.15), borderaxespad=0., fontsize=8, mode='expand'))
plt.tight_layout()
output_plot_file_path = os.path.join(self.root_sweep_dir, err_surfaces_plots_dir, err_surfaces_base_file_name + cluster_id +'.png')
plt.savefig(output_plot_file_path, dpi = 300, format='png', bbox_extra_artists=lgds, bbox_inches='tight')
plt.close()
count = count + 1
def error_loading_fit_terms():
debug_p('Could not load fit terms! Check whether fit terms file at ' + os.path.join(sim_data_dir, fit_terms_file) + ' is accessible.')
raise ValueError('Could not load fit terms! Check whether fit terms file at ' + os.path.join(sim_data_dir, fit_terms_file) + ' is accessible.')
