analysis.py
import itertools
import random
import numpy as np
import pandas as pd
from lee_et_al_2023.src import base
def center_model(model):
"""Center a model."""
new_model = model.copy()
all_ratings = new_model[base.MONELL_CLASS_LIST].values
bias = np.mean(all_ratings, axis=0)
new_model[base.MONELL_CLASS_LIST] = all_ratings - bias
return new_model
def fast_process(humans, models, f=None, subjects=None, center_fn=center_model,
descriptors=base.MONELL_CLASS_LIST, subgroup_size=1, axis=0):
# humans: Either a dataframe of all the data OR a dict of individual human data in the same shape and style as the model dataframes.
# models: A dict of individual model predictions.
# f: A transformation to apply before computing correlation
if f is None:
f = lambda x: x
if axis == 0:
corr_fn = lambda df1, df2: f(df1).T.corrwith(f(df2).T)
elif axis == 1:
corr_fn = lambda df1, df2: f(df1).corrwith(f(df2))
if subjects is None:
if isinstance(humans, pd.DataFrame):
subjects = humans['SubjectCode'].unique().tolist()
else:
subjects = list(humans.keys())
subject_groups = list(itertools.combinations(subjects, subgroup_size))
random.shuffle(subject_groups)
subject_groups = subject_groups[:100] # For computational reasons...
columns = list(models.keys()) + ['Human']
corrs = []
for subj_group in subject_groups:
for rep in [1, 2]:
# Slice out one subject and a subpanel of the remaining subjects
human = humans[humans['SubjectCode'].isin(subj_group) & (humans['Rep'] == rep)
].groupby('RedJade Code')[descriptors].mean()
panel = humans[~humans['SubjectCode'].isin(subj_group)
].groupby('RedJade Code')[descriptors].mean()
# Align indices and select the subset of molecules that this human rated
panel = panel.loc[human.index]
human[:] = center_fn(human)
panel[:] = center_fn(panel)
_rows = pd.DataFrame({
'SubjectCode' : ', '.join(subj_group),
'Rep': rep,
'Human': corr_fn(human, panel)
})
# Compute correlation for each model with the same subpanel
for model_name, model in models.items():
model_ = model.loc[human.index][descriptors]
model_[:] = center_fn(model_)
_rows[model_name] = corr_fn(model_, panel)
corrs.append(_rows)
corrs = pd.concat(corrs)
corrs = corrs.reset_index().set_index(['RedJade Code' if axis == 0 else 'index', 'SubjectCode', 'Rep'])
return corrs
def model_performance(corrs, model_name):
"""
Reports the performance of `model_name` in matrix `corrs` along
`axis`, which determines aggregation across either descriptors or
across molecules.
Params:
corrs: The output of `fast_corrs`.
model_name: e.g. 'GNN'
Returns:
A pd.Series indexed by molecules or descriptors
and containing win rates.
"""
n_wins = (corrs[model_name] > corrs['Human']).groupby('RedJade Code').sum()
n_ties = (corrs[model_name] == corrs['Human']).groupby('RedJade Code').sum()
n_losses = (corrs[model_name] < corrs['Human']).groupby('RedJade Code').sum()
return (n_wins + 0.5*n_ties) / (n_wins + n_ties + n_losses)
def shuffle_df(df, shuffle):
df_contents = df.to_numpy()
if shuffle == 'descriptors':
# Generate an independent descriptor shuffle for each molecule
shuffle_array = np.argsort(np.random.random(df_contents.shape), axis=1)
df_contents = df_contents[np.arange(df_contents.shape[0])[:, np.newaxis], shuffle_array]
elif shuffle == 'molecules':
df_contents = df_contents[np.random.permutation(df_contents.shape[0])]
else:
raise ValueError('Unsupported shuffle technique: {}'.format(shuffle))
return pd.DataFrame(df_contents, index=df.index, columns=df.columns)
