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app.py
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app.py
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import streamlit as st
import pandas as pd
import plotly.express as px
import matplotlib.pyplot as plt
import numpy as np
import plotly.graph_objects as go
st.set_page_config(layout="wide")
def load_csv_data(file_path):
return pd.read_csv(file_path)
def plot_top_n(df, target_column, n=10):
top_n = df.nlargest(n, target_column)
# Initialize the bar plot
fig, ax1 = plt.subplots(figsize=(10, 5))
# Set width for each bar and their positions
width = 0.28
ind = np.arange(len(top_n))
# Plot target_column and MMLU_average on the primary y-axis with adjusted positions
ax1.bar(ind - width, top_n[target_column], width=width, color='blue', label=target_column)
ax1.bar(ind, top_n['MMLU_average'], width=width, color='orange', label='MMLU_average')
# Set the primary y-axis labels and title
ax1.set_title(f'Top {n} performing models on {target_column}')
ax1.set_xlabel('Model')
ax1.set_ylabel('Score')
# Create a secondary y-axis for Parameters
ax2 = ax1.twinx()
# Plot Parameters as bars on the secondary y-axis with adjusted position
ax2.bar(ind + width, top_n['Parameters'], width=width, color='red', label='Parameters')
# Set the secondary y-axis labels
ax2.set_ylabel('Parameters', color='red')
ax2.tick_params(axis='y', labelcolor='red')
# Set the x-ticks and their labels
ax1.set_xticks(ind)
ax1.set_xticklabels(top_n.index, rotation=45, ha="right")
# Adjust the legend
fig.tight_layout()
fig.legend(loc='center left', bbox_to_anchor=(1, 0.5))
# Show the plot
st.pyplot(fig)
# Function to create an unfilled radar chart
def create_radar_chart_unfilled(df, model_names, metrics):
fig = go.Figure()
min_value = df.loc[model_names, metrics].min().min()
max_value = df.loc[model_names, metrics].max().max()
for model_name in model_names:
values_model = df.loc[model_name, metrics]
fig.add_trace(go.Scatterpolar(
r=values_model,
theta=metrics,
name=model_name
))
fig.update_layout(
polar=dict(
radialaxis=dict(
visible=True,
range=[min_value, max_value]
)),
showlegend=True,
width=800, # Change the width as needed
height=600 # Change the height as needed
)
return fig
# Function to create a line chart
def create_line_chart(df, model_names, metrics):
line_data = []
for model_name in model_names:
values_model = df.loc[model_name, metrics]
for metric, value in zip(metrics, values_model):
line_data.append({'Model': model_name, 'Metric': metric, 'Value': value})
line_df = pd.DataFrame(line_data)
fig = px.line(line_df, x='Metric', y='Value', color='Model', title='Comparison of Models', line_dash_sequence=['solid'])
fig.update_layout(showlegend=True)
return fig
def find_top_differences_table(df, target_model, closest_models, num_differences=10, exclude_columns=['Parameters']):
# Calculate the absolute differences for each task between the target model and the closest models
new_df = df.drop(columns=exclude_columns)
differences = new_df.loc[closest_models].sub(new_df.loc[target_model]).abs()
# Unstack the differences and sort by the largest absolute difference
top_differences = differences.unstack().nlargest(num_differences)
# Convert the top differences to a DataFrame for display
top_differences_table = pd.DataFrame({
'Task': [idx[0] for idx in top_differences.index],
'Difference': top_differences.values
})
# Ensure that only unique tasks are returned
unique_top_differences_tasks = list(set(top_differences_table['Task'].tolist()))
return top_differences_table, unique_top_differences_tasks
# st.title('Model Evaluation Results including MMLU by task')
st.title('Interactive Portal for Analyzing Open Source Large Language Models')
st.markdown("""***Last updated March 17th 2024***""")
st.markdown("""**It has not been updated to correctly extract the parameter number from mixture of experts models.**""")
st.markdown("""**As of 04-17-2024, this data was not generated using the chat templates. Smaller models are especially sensative to this and other aspects related to the format of the inputs.**""")
st.markdown("""
This page provides a way to explore the results for individual tasks and compare models across tasks. Data for the benchmarks hellaswag, arc_challenge, and truthfulQA have also been included for comparison.
There are 57 tasks in the MMLU evaluation that cover a wide variety of subjects including Science, Math, Humanities, Social Science, Applied Science, Logic, and Security.
[Preliminary analysis of MMLU-by-Task data](https://coreymorrisdata.medium.com/preliminary-analysis-of-mmlu-evaluation-data-insights-from-500-open-source-models-e67885aa364b)
""")
# Load the data into memory
data_path = "processed_data_2024-04-16.csv"
data_df = load_csv_data(data_path)
# drop the column Unnamed: 0
data_df.rename(columns={'Unnamed: 0': "Model Name"}, inplace=True)
data_df.set_index("Model Name", inplace=True)
filtered_data = data_df
# sort the table by the MMLU_average column
filtered_data = filtered_data.sort_values(by=['MMLU_average'], ascending=False)
# Select box for filtering by Parameters
parameter_threshold = st.selectbox(
'Filter by Parameters (Less Than or Equal To):',
options=[3, 7, 13, 35, 'No threshold'],
index=4, # Set the default selected option to 'No threshold'
format_func=lambda x: f"{x}" if isinstance(x, int) else x
)
if isinstance(parameter_threshold, int):
filtered_data = filtered_data[filtered_data['Parameters'] <= parameter_threshold]
# model name filtering
search_queries = st.text_input("Filter by Model Name:", "").replace(" ", "").split(',')
if search_queries:
filtered_data = filtered_data[filtered_data.index.str.contains('|'.join(search_queries), case=False)]
# column name filtering
column_search_query = st.text_input("Filter by Column/Task Name:", "").replace(" ", "").split(',')
matching_columns = [col for col in filtered_data.columns if any(query.lower() in col.lower() for query in column_search_query)]
filtered_data = filtered_data[matching_columns]
# Display the DataFrame with only the matching columns
st.markdown("## Sortable Results")
st.dataframe(
filtered_data[matching_columns],
column_config={
"URL": st.column_config.LinkColumn( # Only current way to make url a clickable link with streamlit without removing the interactivity of the table
width="small"
)
},
hide_index=True,
)
# CSV download
filtered_data.index.name = "Model Name"
csv = filtered_data.to_csv(index=True)
st.download_button(
label="Download data as CSV",
data=csv,
file_name="model_evaluation_results.csv",
mime="text/csv",
)
def create_plot(df, x_values, y_values, models=None, title=None):
if models is not None:
df = df[df.index.isin(models)]
# remove rows with NaN values
df = df.dropna(subset=[x_values, y_values])
#remove label rows URL, full_model_name
df = df.drop(columns=['URL', 'full_model_name'])
plot_data = pd.DataFrame({
'Model': df.index,
x_values: df[x_values],
y_values: df[y_values],
})
plot_data['color'] = 'purple'
fig = px.scatter(plot_data, x=x_values, y=y_values, color='color', hover_data=['Model'], trendline="ols")
# If title is not provided, use x_values vs. y_values as the default title
if title is None:
title = x_values + " vs. " + y_values
layout_args = dict(
showlegend=False,
xaxis_title=x_values,
yaxis_title=y_values,
xaxis=dict(),
yaxis=dict(),
title=title,
height=500,
width=1000,
)
fig.update_layout(**layout_args)
# Add a dashed line at 0.25 for the y_values
x_min = df[x_values].min()
x_max = df[x_values].max()
y_min = df[y_values].min()
y_max = df[y_values].max()
if x_values.startswith('MMLU'):
fig.add_shape(
type='line',
x0=0.25, x1=0.25,
y0=y_min, y1=y_max,
line=dict(
color='red',
width=2,
dash='dash'
)
)
if y_values.startswith('MMLU'):
fig.add_shape(
type='line',
x0=x_min, x1=x_max,
y0=0.25, y1=0.25,
line=dict(
color='red',
width=2,
dash='dash'
)
)
return fig
# Custom scatter plots
st.header('Custom scatter plots')
st.write("""
The scatter plot is useful to identify models that outperform or underperform on a particular task in relation to their size or overall performance.
Identifying these models is a first step to better understand what training strategies result in better performance on a particular task.
""")
st.markdown("***The dashed red line indicates random chance accuracy of 0.25 as the MMLU evaluation is multiple choice with 4 response options.***")
# add a line separating the writing
st.markdown("***")
st.write("As expected, there is a strong positive relationship between the number of parameters and average performance on the MMLU evaluation.")
column_list_for_plotting = filtered_data.columns.tolist()
if 'URL' in column_list_for_plotting:
column_list_for_plotting.remove('URL')
if 'full_model_name' in column_list_for_plotting:
column_list_for_plotting.remove('full_model_name')
selected_x_column = st.selectbox('Select x-axis', column_list_for_plotting, index=0)
selected_y_column = st.selectbox('Select y-axis', column_list_for_plotting, index=1)
if selected_x_column != selected_y_column: # Avoid creating a plot with the same column on both axes
fig = create_plot(filtered_data, selected_x_column, selected_y_column)
st.plotly_chart(fig)
else:
st.write("Please select different columns for the x and y axes.")
# end of custom scatter plots
# # Section to select a model and display radar and line charts
# st.header("Compare a Selected Model to the 5 Models Closest in MMLU Average Performance")
# st.write("""
# This comparison highlights the nuances in model performance across different tasks.
# While the overall MMLU average score provides a general understanding of a model's capabilities,
# examining the closest models reveals variations in performance on individual tasks.
# Such an analysis can uncover specific strengths and weaknesses and guide further exploration and improvement.
# """)
# default_model_name = "GPT-JT-6B-v0"
# default_model_index = filtered_data.index.tolist().index(default_model_name) if default_model_name in filtered_data.index else 0
# selected_model_name = st.selectbox("Select a Model:", filtered_data.index.tolist(), index=default_model_index)
# # Get the closest 5 models with unique indices
# closest_models_diffs = filtered_data['MMLU_average'].sub(filtered_data.loc[selected_model_name, 'MMLU_average']).abs()
# closest_models = closest_models_diffs.nsmallest(5, keep='first').index.drop_duplicates().tolist()
# Find the top 10 tasks with the largest differences and convert to a DataFrame
# top_differences_table, top_differences_tasks = find_top_differences_table(filtered_data, selected_model_name, closest_models)
# Display the DataFrame for the closest models and the top differences tasks
# st.dataframe(filtered_data.loc[closest_models, top_differences_tasks])
# # Display the table in the Streamlit app
# st.markdown("## Top Differences")
# st.dataframe(top_differences_table)
# Create a radar chart for the tasks with the largest differences
# fig_radar_top_differences = create_radar_chart_unfilled(filtered_data, closest_models, top_differences_tasks)
# Display the radar chart
# st.plotly_chart(fig_radar_top_differences)
st.markdown("## Notable findings and plots")
# Moral scenarios plots
st.markdown("### MMLU’s Moral Scenarios Benchmark Doesn’t Measure What You Think it Measures")
def show_random_moral_scenarios_question():
moral_scenarios_data = pd.read_csv('moral_scenarios_questions.csv')
random_question = moral_scenarios_data.sample()
expander = st.expander("Show a random moral scenarios question")
expander.write(random_question['query'].values[0])
st.write("""
After a deeper dive into the moral scenarios task, it appears that benchmark is not a valid measurement of moral judgement.
The challenges these models face are not rooted in understanding each scenario, but rather in the structure of the task itself.
I would recommend using a different benchmark for moral judgement. More details of the analysis can be found here: [MMLU’s Moral Scenarios Benchmark Doesn’t Measure What You Think it Measures ](https://medium.com/p/74fd6e512521)
""")
show_random_moral_scenarios_question()
fig = create_plot(filtered_data, 'Parameters', 'MMLU_moral_scenarios', title="Impact of Parameter Count on Accuracy for Moral Scenarios")
st.plotly_chart(fig)
st.write()
fig = create_plot(filtered_data, 'MMLU_average', 'MMLU_moral_scenarios')
st.plotly_chart(fig)
st.markdown('### Abstract Algebra Performance')
st.write("Small models showed surprisingly strong performance on the abstract algebra task. A 6 Billion parameter model is tied for the best performance on this task and there are a number of other small models in the top 10.")
plot_top_n(filtered_data, 'MMLU_abstract_algebra', 10)
fig = create_plot(filtered_data, 'Parameters', 'MMLU_abstract_algebra')
st.plotly_chart(fig)
st.markdown("***Thank you to hugging face for running the evaluations and supplying the data as well as the original authors of the evaluations.***")
st.markdown("""
# Citation
1. Corey Morris (2023). *Exploring the Characteristics of Large Language Models: An Interactive Portal for Analyzing 700+ Open Source Models Across 57 Diverse Evaluation Tasks*. [link](https://huggingface.co/spaces/CoreyMorris/MMLU-by-task-Leaderboard)
2. Edward Beeching, Clémentine Fourrier, Nathan Habib, Sheon Han, Nathan Lambert, Nazneen Rajani, Omar Sanseviero, Lewis Tunstall, Thomas Wolf. (2023). *Open LLM Leaderboard*. Hugging Face. [link](https://huggingface.co/spaces/HuggingFaceH4/open_llm_leaderboard)
3. Gao, Leo et al. (2021). *A framework for few-shot language model evaluation*. Zenodo. [link](https://doi.org/10.5281/zenodo.5371628)
4. Peter Clark, Isaac Cowhey, Oren Etzioni, Tushar Khot, Ashish Sabharwal, Carissa Schoenick, Oyvind Tafjord. (2018). *Think you have Solved Question Answering? Try ARC, the AI2 Reasoning Challenge*. arXiv. [link](https://arxiv.org/abs/1803.05457)
5. Rowan Zellers, Ari Holtzman, Yonatan Bisk, Ali Farhadi, Yejin Choi. (2019). *HellaSwag: Can a Machine Really Finish Your Sentence?*. arXiv. [link](https://arxiv.org/abs/1905.07830)
6. Dan Hendrycks, Collin Burns, Steven Basart, Andy Zou, Mantas Mazeika, Dawn Song, Jacob Steinhardt. (2021). *Measuring Massive Multitask Language Understanding*. arXiv. [link](https://arxiv.org/abs/2009.03300)
7. Stephanie Lin, Jacob Hilton, Owain Evans. (2022). *TruthfulQA: Measuring How Models Mimic Human Falsehoods*. arXiv. [link](https://arxiv.org/abs/2109.07958)
""")