def evaluate_model(file_name, date, n_iter, scope, lang, n_eval=5):
#
corpus = Corpus()
corpus.add_files(file_name, encoding='utf8')
#
preproc = TMPreproc(corpus)
dtm_bg = preproc.dtm
#
var_params = [{'n_topics': k} for k in range(5, int(n_eval*10), n_eval)]
#
const_params = {
'n_iter': n_iter,
'random_state': 20200713 # to make results reproducible
}
eval_results = evaluate_topic_models(dtm_bg,
varying_parameters=var_params,
constant_parameters=const_params,
metric=['loglikelihood', 'cao_juan_2009', 'arun_2010']#,
#return_models=True
)
#
eval_results_by_topics = results_by_parameter(eval_results, 'n_topics')
#
name = "evaluate_model_{}_{}iter_{}eval_{}_{}.png".format(date, n_iter, n_eval, scope, lang)
plot_eval_results(eval_results_by_topics, figsize=(8, 6), metric_direction_font_size='x-small', title_fontsize='small', axes_title_fontsize='x-small')
plt.tight_layout()
plt.savefig('out/'+name)
return
def toolkit_cv_plot(self, varying_params,
constant_params,
save_plot=True,
save_dir='results/model_validation',
filename='',
ext='.pdf',
size=(20, 15),
**kwargs):
'''
Using tmtoolkit for parameter tuning based on a wider variety of measures
'''
warnings.filterwarnings("ignore", category = UserWarning)
print('evaluating {} topic models'.format(len(varying_params)))
eval_results = tm_gensim.evaluate_topic_models((self.gensim_dict,
self.bow),
varying_params,
constant_params,
coherence_gensim_texts=self.text,
**kwargs)
results_by_n_topics = results_by_parameter(eval_results, 'num_topics')
plot_eval_results(results_by_n_topics, xaxislabel='num topics',
title='Evaluation results', figsize=size);
if save_plot:
filename = 'tmtoolkit_CV_'
full_path = save_folder_file(save_dir, filename, ext=ext,
optional_folder='convergence_plots')
plt.savefig(full_path)
return(results_by_n_topics)
def test_plot_eval_results(n_param_sets, n_params, n_metrics, plot_specific_metric):
param_names = ['param' + str(i) for i in range(n_params)]
metric_names = ['metric' + str(i) for i in range(n_metrics)]
res = []
for _ in range(n_param_sets):
param_set = dict(zip(param_names, np.random.randint(0, 100, n_params)))
metric_results = dict(zip(metric_names, np.random.uniform(0, 1, n_metrics)))
res.append((param_set, metric_results))
p = random.choice(param_names)
by_param = evaluate.results_by_parameter(res, p)
if not by_param:
with pytest.raises(ValueError):
visualize.plot_eval_results(by_param)
else:
if plot_specific_metric:
metric = random.choice(metric_names)
else:
metric = None
fig, axes = visualize.plot_eval_results(by_param, metric=metric)
plt.close(fig)
import numpy as np
from scipy.sparse import csr_matrix
rows = []
cols = []
data = []
for i in range(0, len(trigram_bow_corpus)):
line = trigram_bow_corpus[i]
for indx, freq in line:
rows.append(i)
cols.append(indx)
data.append(freq)
dtm = csr_matrix((data, (rows, cols)),
shape=(len(trigram_bow_corpus), len(trigram_dictionary)),
dtype=int)
const_params = dict(n_iter=20)
ks = list(range(5, 100,
5)) #+ list(range(50, 200, 50)) + list(range(200, 500, 100))
varying_params = [dict(n_topics=k, alpha=1.0 / k) for k in ks]
eval_results = tm_lda.evaluate_topic_models(
dtm, varying_params, const_params, return_models=True) #,n_max_processes=8
results_by_n_topics = results_by_parameter(eval_results, 'n_topics')
# fig, ax = plt.subplots(figsize=(8, 6))
plot_eval_results(results_by_n_topics)
plt.tight_layout()
# plt.savefig('valid_lda.eps', format='eps', dpi=300)
plt.show()
varying_params = [dict(n_topics=k, alpha=1.0/k) for k in ks]
# this will evaluate all models in parallel using the metrics in tm_lda.DEFAULT_METRICS
# still, this will take some time
print('evaluating %d topic models' % len(varying_params))
models = tm_lda.evaluate_topic_models(dtm, varying_params, const_params,
return_models=True) # retain the calculated models
# save the results as pickle
print('saving results')
pickle_data(models, 'data/lda_evaluation_results.pickle')
# plot the results
print('plotting evaluation results')
results_by_n_topics = results_by_parameter(models, 'n_topics')
plot_eval_results(results_by_n_topics, xaxislabel='num. topics k',
title='Evaluation results for alpha=1/k, beta=0.1', figsize=(8, 6))
plt.savefig('data/lda_evaluation_plot.png')
plt.show()
# the peak seems to be around n_topics == 120
# print the distributions of this model
n_topics_best_model = 120
best_model = dict(results_by_n_topics)[n_topics_best_model]['model']
print('saving final model with n_topics=%d' % n_topics_best_model)
save_ldamodel_to_pickle('data/lda_evaluation_finalmodel.pickle', best_model, vocab, doc_labels, dtm)
print('printing final model')
print_ldamodel_topic_words(best_model.topic_word_, vocab)
print_ldamodel_doc_topics(best_model.doc_topic_, doc_labels)
const_params = dict(
update_every=0,
passes=20,
iterations=400,
alpha='auto',
eta='auto',
)
ks = list(range(10, 140, 10)) + list(range(140, 200, 20))
varying_params = [dict(num_topics=k, alpha=1.0 / k) for k in ks]
print('evaluating %d topic models' % len(varying_params))
eval_results = tm_gensim.evaluate_topic_models(
(gnsm_dict, gnsm_corpus),
varying_params,
const_params,
coherence_gensim_texts=model_lists) # necessary for coherence C_V metric
# save the results as pickle
print('saving results')
pickle_data(eval_results, 'gensim_evaluation_results_entire.pickle')
# plot the results
print('plotting evaluation results')
plt.style.use('ggplot')
results_by_n_topics = results_by_parameter(eval_results, 'num_topics')
plot_eval_results(results_by_n_topics,
xaxislabel='num. topics k',
title='Evaluation results',
figsize=(8, 6))
plt.savefig('gensim_evaluation_plot_entire.png')
plt.show()
print('run script as: %s <tokens preprocessing pipeline> <eta> <alpha factor>' % sys.argv[0])
print('<tokens preprocessing pipeline> must be 0, 1 or 2')
exit(1)
toks = int(sys.argv[1])
eta = float(sys.argv[2])
alpha_mod = float(sys.argv[3])
#%%
picklefile = 'data/tm_eval_results_tok%d_eta_%.2f_alphamod_%.2f.pickle' % (toks, eta, alpha_mod)
print('loading pickle file with evaluation results from `%s`' % picklefile)
eval_results = unpickle_file(picklefile)
eval_results_by_n_topics = results_by_parameter(eval_results, 'n_topics')
n_metrics = len(eval_results_by_n_topics[0][1])
#%%
fig, axes = plot_eval_results(eval_results_by_n_topics,
title='Evaluation results for alpha=%.2f/k, beta=%.2f' % (alpha_mod, eta),
xaxislabel='num. topics (k)')
plot_file_eval_res = 'fig/tm_eval_results_tok%d_eta_%.2f_alphamod_%.2f.png' % (toks, eta, alpha_mod)
print('saving plot to file `%s`' % plot_file_eval_res)
plt.savefig(plot_file_eval_res)
plt.show()
print('done.')
