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LOL_Matchups_Model

Sleeping

James McCool

Enhance overall simulation data presentation in app.py. Introduced tabbed layout for displaying player statistics (Kills, Deaths, Assists, CS) to improve user experience. Each tab presents a filtered view of the overall simulation DataFrame, enhancing clarity and readability of performance metrics.

7531a91 about 1 year ago

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	import streamlit as st
	st.set_page_config(layout="wide")
	import numpy as np
	import pandas as pd
	import pymongo
	import time
	from datetime import datetime, timedelta
	from scipy import stats

	@st.cache_resource
	def init_conn():

	uri = st.secrets['mongo_uri']
	client = pymongo.MongoClient(uri, retryWrites=True, serverSelectionTimeoutMS=500000)
	db = client["League_of_Legends_Database"]

	current_date = datetime.now()

	collection = db["gamelogs"]
	max_date = current_date - timedelta(days=1)
	min_date = current_date - timedelta(days=365)
	team_names = collection.distinct("teamname")
	player_names = collection.distinct("playername")

	return db, team_names, player_names, min_date, max_date

	db, team_names, player_names, min_date, max_date = init_conn()

	display_formats = {'wKill%': '{:.2%}', 'wDeath%': '{:.2%}', 'wAssist%': '{:.2%}', 'lKill%': '{:.2%}', 'lDeath%': '{:.2%}', 'lAssist%': '{:.2%}'}

	# Create sidebar container for options
	with st.sidebar:
	st.header("Team Analysis Options")

	# Date filtering options
	st.subheader("Date Range")
	date_filter = st.radio(
	"Select Date Range",
	["Last Year", "Custom Range"]
	)

	if date_filter == "Last Year":
	end_date = max_date
	start_date = (end_date - timedelta(days=365))
	else:
	col1, col2 = st.columns(2)
	with col1:
	start_date = st.date_input(
	"Start Date",
	value=max_date.date() - timedelta(days=30),
	min_value=min_date.date(),
	max_value=max_date.date()
	)
	with col2:
	end_date = st.date_input(
	"End Date",
	value=max_date.date(),
	min_value=min_date.date(),
	max_value=max_date.date()
	)

	col1, col2 = st.columns(2)
	with col1:
	selected_team = st.selectbox(
	"Select Team",
	options=team_names,
	index=team_names.index("T1") if "T1" in team_names else 0
	)
	with col2:
	selected_opponent = st.selectbox(
	"Select Opponent",
	options=team_names,
	index=team_names.index("T1") if "T1" in team_names else 0
	)

	st.subheader("Prediction Settings")
	num_games = st.selectbox(
	"Is the match BO1, BO3, or BO5?",
	options=["BO1", "BO3", "BO5"],
	index=0
	)

	# Convert BO format to number of games
	game_count = int(num_games[2])

	# Create lists to store settings for each game
	win_loss_settings = []
	game_settings_list = []
	kill_predictions = []
	death_predictions = []

	# Create a tab for each game
	game_tabs = st.tabs([f"Game {i+1}" for i in range(game_count)])

	for game_num, game_tab in enumerate(game_tabs, 1):
	with game_tab:

	win_loss_settings.append(st.selectbox(
	f"Game {game_num} Win/Loss",
	options=["Win", "Loss"],
	index=0,
	key=f"win_loss_{game_num}"
	))
	game_setting = st.selectbox(
	f"Game {game_num} Prediction Type",
	options=["Average", "Predict"],
	index=0,
	key=f"game_settings_{game_num}"
	)

	if game_setting == "Average":
	kill_predictions.append(0)
	death_predictions.append(0)
	else:
	col1, col2 = st.columns(2)
	with col1:
	kill_predictions.append(st.number_input(
	f"Game {game_num} Predicted Team Kills",
	min_value=1,
	max_value=100,
	value=20,
	key=f"kills_{game_num}"
	))
	with col2:
	death_predictions.append(st.number_input(
	f"Game {game_num} Predicted Team Deaths",
	min_value=1,
	max_value=100,
	value=5,
	key=f"deaths_{game_num}"
	))

	@st.cache_data()
	def simulate_stats(row, num_sims=1000):
	"""Simulate stats using normal distribution"""
	# Using coefficient of variation of 0.3 to generate reasonable standard deviations
	cv = 0.3
	percentiles = [10, 25, 50, 75, 90]

	results = {}
	for stat in ['Kill_Proj', 'Death_Proj', 'Assist_Proj', 'CS_Proj']:
	mean = row[stat]
	std = mean * cv # Using coefficient of variation to determine std
	sims = stats.norm.rvs(loc=mean, scale=std, size=num_sims)
	# Ensure no negative values
	sims = np.maximum(sims, 0)
	results[stat] = np.percentile(sims, percentiles)

	return pd.Series(results)

	@st.cache_data(ttl = 60)
	def init_team_data(team, opponent, win_loss_settings, kill_predictions, death_predictions, start_date, end_date):
	game_count = len(kill_predictions)
	overall_team_data = pd.DataFrame(columns = ['playername', 'teamname', 'position', 'Kill_Proj', 'Death_Proj', 'Assist_Proj', 'CS_Proj'])
	# Convert date objects to datetime strings in the correct format
	start_datetime = datetime.combine(start_date, datetime.min.time()).strftime("%Y-%m-%d %H:%M:%S")
	end_datetime = datetime.combine(end_date, datetime.max.time()).strftime("%Y-%m-%d %H:%M:%S")

	collection = db["gamelogs"]
	cursor = collection.find({"teamname": team, "date": {"$gte": start_datetime, "$lte": end_datetime}})
	raw_display = pd.DataFrame(list(cursor))

	cursor = collection.find({"date": {"$gte": start_datetime, "$lte": end_datetime}})
	raw_opponent = pd.DataFrame(list(cursor))

	tables_to_loop = [raw_display, raw_opponent]

	for loop in range(len(tables_to_loop)):
	tables = tables_to_loop[loop]
	calc_columns = ['kills', 'deaths', 'assists', 'total_cs']
	league_pos_win_stats = {}
	league_pos_loss_stats = {}
	Opponent_pos_win_allowed_stats = {}
	Opponent_pos_loss_allowed_stats = {}
	playername_win_stats = {}
	playername_loss_stats = {}
	teamname_win_stats = {}
	teamname_loss_stats = {}

	if loop == 0:

	for stats in calc_columns:
	playername_win_stats[stats] = tables[tables['result'] == 1].groupby(['playername'])[stats].mean().to_dict()
	playername_loss_stats[stats] = tables[tables['result'] == 0].groupby(['playername'])[stats].mean().to_dict()
	teamname_win_stats[stats] = tables[(tables['result'] == 1) & (tables['position'] == 'team')].groupby(['teamname'])[stats].mean().to_dict()
	teamname_loss_stats[stats] = tables[(tables['result'] == 0) & (tables['position'] == 'team')].groupby(['teamname'])[stats].mean().to_dict()

	for stat in calc_columns:

	column_name = f'playername_avg_{stat}_win'
	tables[column_name] = tables.apply(
	lambda row: playername_win_stats[stat].get(row['playername'], 0),
	axis=1
	)

	column_name = f'playername_avg_{stat}_loss'
	tables[column_name] = tables.apply(
	lambda row: playername_loss_stats[stat].get(row['playername'], 0),
	axis=1
	)

	column_name = f'teamname_avg_{stat}_win'
	tables[column_name] = tables.apply(
	lambda row: teamname_win_stats[stat].get(row['teamname'], 0),
	axis=1
	)

	column_name = f'teamname_avg_{stat}_loss'
	tables[column_name] = tables.apply(
	lambda row: teamname_loss_stats[stat].get(row['teamname'], 0),
	axis=1
	)

	tables['playername_avg_kill_share_win'] = tables['playername_avg_kills_win'] / tables['teamname_avg_kills_win']
	tables['playername_avg_death_share_win'] = tables['playername_avg_deaths_win'] / tables['teamname_avg_deaths_win']
	tables['playername_avg_assist_share_win'] = tables['playername_avg_assists_win'] / tables['teamname_avg_kills_win']
	tables['playername_avg_cs_share_win'] = tables['playername_avg_total_cs_win'] / tables['teamname_avg_total_cs_win']
	tables['playername_avg_kill_share_loss'] = tables['playername_avg_kills_loss'] / tables['teamname_avg_kills_loss']
	tables['playername_avg_death_share_loss'] = tables['playername_avg_deaths_loss'] / tables['teamname_avg_deaths_loss']
	tables['playername_avg_assist_share_loss'] = tables['playername_avg_assists_loss'] / tables['teamname_avg_kills_loss']
	tables['playername_avg_cs_share_loss'] = tables['playername_avg_total_cs_loss'] / tables['teamname_avg_total_cs_loss']
	player_tables = tables

	else:

	for stats in calc_columns:
	league_pos_win_stats[stats] = {
	league: group.groupby('position')[stats].mean().to_dict()
	for league, group in tables[tables['result'] == 1].groupby('league')
	}
	league_pos_loss_stats[stats] = {
	league: group.groupby('position')[stats].mean().to_dict()
	for league, group in tables[tables['result'] == 0].groupby('league')
	}

	Opponent_pos_win_allowed_stats[stats] = {
	opponent: group.groupby('position')[stats].mean().to_dict()
	for opponent, group in tables[tables['result'] == 1].groupby('Opponent')
	}
	Opponent_pos_loss_allowed_stats[stats] = {
	opponent: group.groupby('position')[stats].mean().to_dict()
	for opponent, group in tables[tables['result'] == 0].groupby('Opponent')
	}

	for stat in calc_columns:

	column_name = f'league_pos_avg_{stat}_win'
	tables[column_name] = tables.apply(
	lambda row: league_pos_win_stats[stat].get(row['league'], {}).get(row['position'], 0),
	axis=1
	)

	column_name = f'league_pos_avg_{stat}_loss'
	tables[column_name] = tables.apply(
	lambda row: league_pos_loss_stats[stat].get(row['league'], {}).get(row['position'], 0),
	axis=1
	)

	column_name = f'Opponent_pos_avg_{stat}_allowed_win'
	tables[column_name] = tables.apply(
	lambda row: Opponent_pos_win_allowed_stats[stat].get(row['Opponent'], {}).get(row['position'], 0),
	axis=1
	)

	column_name = f'Opponent_pos_avg_{stat}_allowed_loss'
	tables[column_name] = tables.apply(
	lambda row: Opponent_pos_loss_allowed_stats[stat].get(row['Opponent'], {}).get(row['position'], 0),
	axis=1
	)

	tables = tables[tables['Opponent'] == opponent]

	tables['overall_win_kills_boost_pos'] = tables['Opponent_pos_avg_kills_allowed_win'] / tables['league_pos_avg_kills_win']
	tables['overall_win_deaths_boost_pos'] = tables['Opponent_pos_avg_deaths_allowed_win'] / tables['league_pos_avg_deaths_win']
	tables['overall_win_assists_boost_pos'] = tables['Opponent_pos_avg_assists_allowed_win'] / tables['league_pos_avg_assists_win']
	tables['overall_win_total_cs_boost_pos'] = tables['Opponent_pos_avg_total_cs_allowed_win'] / tables['league_pos_avg_total_cs_win']
	tables['overall_loss_kills_boost_pos'] = tables['Opponent_pos_avg_kills_allowed_loss'] / tables['league_pos_avg_kills_loss']
	tables['overall_loss_deaths_boost_pos'] = tables['Opponent_pos_avg_deaths_allowed_loss'] / tables['league_pos_avg_deaths_loss']
	tables['overall_loss_assists_boost_pos'] = tables['Opponent_pos_avg_assists_allowed_loss'] / tables['league_pos_avg_assists_loss']
	tables['overall_loss_total_cs_boost_pos'] = tables['Opponent_pos_avg_total_cs_allowed_loss'] / tables['league_pos_avg_total_cs_loss']

	opp_tables = tables
	opp_pos_kills_boost_win = dict(zip(opp_tables['position'], opp_tables['overall_win_kills_boost_pos']))
	opp_pos_deaths_boost_win = dict(zip(opp_tables['position'], opp_tables['overall_win_deaths_boost_pos']))
	opp_pos_assists_boost_win = dict(zip(opp_tables['position'], opp_tables['overall_win_assists_boost_pos']))
	opp_pos_cs_boost_win = dict(zip(opp_tables['position'], opp_tables['overall_win_total_cs_boost_pos']))
	opp_pos_kills_boost_loss = dict(zip(opp_tables['position'], opp_tables['overall_loss_kills_boost_pos']))
	opp_pos_deaths_boost_loss = dict(zip(opp_tables['position'], opp_tables['overall_loss_deaths_boost_pos']))
	opp_pos_assists_boost_loss = dict(zip(opp_tables['position'], opp_tables['overall_loss_assists_boost_pos']))
	opp_pos_cs_boost_loss = dict(zip(opp_tables['position'], opp_tables['overall_loss_total_cs_boost_pos']))
	opp_boosts = pd.DataFrame({
	'opp_pos_kills_boost_win': opp_pos_kills_boost_win,
	'opp_pos_deaths_boost_win': opp_pos_deaths_boost_win,
	'opp_pos_assists_boost_win': opp_pos_assists_boost_win,
	'opp_pos_cs_boost_win': opp_pos_cs_boost_win,
	'opp_pos_kills_boost_loss': opp_pos_kills_boost_loss,
	'opp_pos_deaths_boost_loss': opp_pos_deaths_boost_loss,
	'opp_pos_assists_boost_loss': opp_pos_assists_boost_loss,
	'opp_pos_cs_boost_loss': opp_pos_cs_boost_loss
	}).set_index(pd.Index(list(opp_pos_kills_boost_win.keys()), name='position'))

	results_dict = {}

	for game in range(game_count):
	if kill_predictions[game] > 0:
	working_tables = player_tables[['playername', 'teamname', 'position', 'playername_avg_kill_share_win', 'playername_avg_death_share_win','playername_avg_assist_share_win',
	'playername_avg_total_cs_win', 'playername_avg_kill_share_loss', 'playername_avg_death_share_loss', 'playername_avg_assist_share_loss', 'playername_avg_total_cs_loss']]
	working_tables = working_tables.rename(columns = {'playername_avg_kill_share_win': 'wKill%', 'playername_avg_death_share_win': 'wDeath%', 'playername_avg_assist_share_win': 'wAssist%',
	'playername_avg_total_cs_win': 'wCS', 'playername_avg_kill_share_loss': 'lKill%', 'playername_avg_death_share_loss': 'lDeath%',
	'playername_avg_assist_share_loss': 'lAssist%', 'playername_avg_total_cs_loss': 'lCS'})
	team_data = working_tables.drop_duplicates(subset = ['playername'])

	if win_loss_settings[game] == "Win":
	team_data['Kill_Proj'] = team_data.apply(lambda row: row['wKill%'] * opp_pos_kills_boost_win.get(row['position'], 1), axis=1) * kill_predictions[game]
	team_data['Death_Proj'] = team_data.apply(lambda row: row['wDeath%'] * opp_pos_deaths_boost_win.get(row['position'], 1), axis=1) * death_predictions[game]
	team_data['Assist_Proj'] = team_data.apply(lambda row: row['wAssist%'] * opp_pos_assists_boost_win.get(row['position'], 1), axis=1) * kill_predictions[game]
	team_data['CS_Proj'] = team_data.apply(lambda row: row['wCS'] * opp_pos_cs_boost_win.get(row['position'], 1), axis=1)
	team_data = team_data[['playername', 'teamname', 'position', 'Kill_Proj', 'Death_Proj', 'Assist_Proj', 'CS_Proj']]
	else:
	team_data['Kill_Proj'] = team_data.apply(lambda row: row['lKill%'] * opp_pos_kills_boost_loss.get(row['position'], 1), axis=1) * kill_predictions[game]
	team_data['Death_Proj'] = team_data.apply(lambda row: row['lDeath%'] * opp_pos_deaths_boost_loss.get(row['position'], 1), axis=1) * death_predictions[game]
	team_data['Assist_Proj'] = team_data.apply(lambda row: row['lAssist%'] * opp_pos_assists_boost_loss.get(row['position'], 1), axis=1) * kill_predictions[game]
	team_data['CS_Proj'] = team_data.apply(lambda row: row['lCS'] * opp_pos_cs_boost_loss.get(row['position'], 1), axis=1)
	team_data = team_data[['playername', 'teamname', 'position', 'Kill_Proj', 'Death_Proj', 'Assist_Proj', 'CS_Proj']]
	else:
	working_tables = player_tables[['playername', 'teamname', 'position', 'playername_avg_kills_win', 'playername_avg_deaths_win', 'playername_avg_assists_win', 'playername_avg_total_cs_win',
	'playername_avg_kills_loss', 'playername_avg_deaths_loss', 'playername_avg_assists_loss', 'playername_avg_total_cs_loss']]
	working_tables = working_tables.rename(columns = {'playername_avg_kills_win': 'wKill%', 'playername_avg_deaths_win': 'wDeath%', 'playername_avg_assists_win': 'wAssist%',
	'playername_avg_total_cs_win': 'wCS', 'playername_avg_kills_loss': 'lKill%', 'playername_avg_deaths_loss': 'lDeath%',
	'playername_avg_assists_loss': 'lAssist%', 'playername_avg_total_cs_loss': 'lCS'})
	team_data = working_tables.drop_duplicates(subset = ['playername'])

	if win_loss_settings[game] == "Win":
	team_data['Kill_Proj'] = team_data.apply(lambda row: row['wKill%'] * opp_pos_kills_boost_win.get(row['position'], 1), axis=1)
	team_data['Death_Proj'] = team_data.apply(lambda row: row['wDeath%'] * opp_pos_deaths_boost_win.get(row['position'], 1), axis=1)
	team_data['Assist_Proj'] = team_data.apply(lambda row: row['wAssist%'] * opp_pos_assists_boost_win.get(row['position'], 1), axis=1)
	team_data['CS_Proj'] = team_data.apply(lambda row: row['wCS'] * opp_pos_cs_boost_win.get(row['position'], 1), axis=1)
	team_data = team_data[['playername', 'teamname', 'position', 'Kill_Proj', 'Death_Proj', 'Assist_Proj', 'CS_Proj']]
	else:
	team_data['Kill_Proj'] = team_data.apply(lambda row: row['lKill%'] * opp_pos_kills_boost_loss.get(row['position'], 1), axis=1)
	team_data['Death_Proj'] = team_data.apply(lambda row: row['lDeath%'] * opp_pos_deaths_boost_loss.get(row['position'], 1), axis=1)
	team_data['Assist_Proj'] = team_data.apply(lambda row: row['lAssist%'] * opp_pos_assists_boost_loss.get(row['position'], 1), axis=1)
	team_data['CS_Proj'] = team_data.apply(lambda row: row['lCS'] * opp_pos_cs_boost_loss.get(row['position'], 1), axis=1)
	team_data = team_data[['playername', 'teamname', 'position', 'Kill_Proj', 'Death_Proj', 'Assist_Proj', 'CS_Proj']]

	results_dict[f'game {game + 1}'] = team_data.dropna()
	team_data['playername'] = team_data['playername'] + f' game {game + 1}'

	overall_team_data = pd.concat([overall_team_data, team_data])

	return overall_team_data.dropna().set_index('playername'), opp_boosts, results_dict

	if st.button("Run"):
	team_data, opp_boost, results_dict = init_team_data(selected_team, selected_opponent, win_loss_settings, kill_predictions, death_predictions, start_date, end_date)

	player_summary = pd.DataFrame()
	for game_num, game_df in results_dict.items():
	# Remove 'game X' from playernames if present
	clean_df = game_df.copy()
	clean_df['playername'] = clean_df['playername'].str.split(' game ').str[0]

	if player_summary.empty:
	player_summary = clean_df
	else:
	# Add the stats to existing players
	player_summary.update(clean_df) # Update teamname and position if needed
	for col in ['Kill_Proj', 'Death_Proj', 'Assist_Proj', 'CS_Proj']:
	player_summary[col] += clean_df[col]
	player_summary = player_summary.set_index('playername')

	# Create simulated percentiles
	individual_sim_results = []
	for idx, row in team_data.iterrows():
	percentiles = simulate_stats(row)
	individual_sim_results.append({
	'Player': idx,
	'Position': row['position'],
	'Stat': 'Kills',
	'10%': percentiles['Kill_Proj'][0],
	'25%': percentiles['Kill_Proj'][1],
	'50%': percentiles['Kill_Proj'][2],
	'75%': percentiles['Kill_Proj'][3],
	'90%': percentiles['Kill_Proj'][4]
	})
	# Repeat for other stats
	for stat, name in [('Death_Proj', 'Deaths'), ('Assist_Proj', 'Assists'), ('CS_Proj', 'CS')]:
	individual_sim_results.append({
	'Player': idx,
	'Position': row['position'],
	'Stat': name,
	'10%': percentiles[stat][0],
	'25%': percentiles[stat][1],
	'50%': percentiles[stat][2],
	'75%': percentiles[stat][3],
	'90%': percentiles[stat][4]
	})

	sim_df = pd.DataFrame(individual_sim_results)

	# Create simulated percentiles
	overall_sim_results = []
	for idx, row in player_summary.iterrows():
	percentiles = simulate_stats(row)
	overall_sim_results.append({
	'Player': idx,
	'Position': row['position'],
	'Stat': 'Kills',
	'10%': percentiles['Kill_Proj'][0],
	'25%': percentiles['Kill_Proj'][1],
	'50%': percentiles['Kill_Proj'][2],
	'75%': percentiles['Kill_Proj'][3],
	'90%': percentiles['Kill_Proj'][4]
	})
	# Repeat for other stats
	for stat, name in [('Death_Proj', 'Deaths'), ('Assist_Proj', 'Assists'), ('CS_Proj', 'CS')]:
	overall_sim_results.append({
	'Player': idx,
	'Position': row['position'],
	'Stat': name,
	'10%': percentiles[stat][0],
	'25%': percentiles[stat][1],
	'50%': percentiles[stat][2],
	'75%': percentiles[stat][3],
	'90%': percentiles[stat][4]
	})

	overall_sim_df = pd.DataFrame(overall_sim_results)
	overall_sim_df = overall_sim_df.drop_duplicates(subset = ['Player', 'Stat'])

	tab1, tab2 = st.tabs(["Team Data", "Opponent Data"])
	with tab1:
	st.subheader("Full Match Data")
	st.dataframe(player_summary.style.background_gradient(axis=0).background_gradient(cmap='RdYlGn').format(display_formats, precision=2), use_container_width = True)
	st.subheader("Individual Game Data")
	st.dataframe(team_data.style.background_gradient(axis=0).background_gradient(cmap='RdYlGn').format(display_formats, precision=2), use_container_width = True)
	with tab2:
	st.dataframe(opp_boost.style.background_gradient(axis=0).background_gradient(cmap='RdYlGn').format(precision=2), use_container_width = True)

	st.subheader("Individual Game Simulations")
	unique_players = sim_df['Player'].unique().tolist()
	player_tabs = st.tabs(unique_players)

	for player, tab in zip(unique_players, player_tabs):
	with tab:
	player_data = sim_df[sim_df['Player'] == player]
	player_data = player_data.set_index('Stat')
	st.dataframe(
	player_data[['10%', '25%', '50%', '75%', '90%']]
	.style.format(precision=2),
	use_container_width=True
	)

	st.subheader("Overall Simulations")
	stat_tabs = st.tabs(["Kills", "Deaths", "Assists", "CS"])

	for stat, tab in zip(["Kills", "Deaths", "Assists", "CS"], stat_tabs):
	with tab:
	stat_data = overall_sim_df[overall_sim_df['Stat'] == stat].copy()
	stat_data = stat_data.set_index('Player')[['Position', '10%', '25%', '50%', '75%', '90%']]
	st.dataframe(
	stat_data.style.format(precision=2).background_gradient(axis=0),
	use_container_width=True
	)