Refactor UI layout and add custom tab styling for NHL Pivot Finder

app.py

@@ -28,6 +28,37 @@ team_roo_format = {'Top Score%': '{:.2%}','0 Runs': '{:.2%}', '1 Run': '{:.2%}',
 player_roo_format = {'Top_finish': '{:.2%}','Top_5_finish': '{:.2%}', 'Top_10_finish': '{:.2%}', '20+%': '{:.2%}', '2x%': '{:.2%}', '3x%': '{:.2%}',
                    '4x%': '{:.2%}','GPP%': '{:.2%}'}
 
+st.markdown("""
+<style>
+    /* Tab styling */
+    .stTabs [data-baseweb="tab-list"] {
+        gap: 8px;
+        padding: 4px;
+    }
+
+    .stTabs [data-baseweb="tab"] {
+        height: 50px;
+        white-space: pre-wrap;
+        background-color: #FFD700;
+        color: white;
+        border-radius: 10px;
+        gap: 1px;
+        padding: 10px 20px;
+        font-weight: bold;
+        transition: all 0.3s ease;
+    }
+
+    .stTabs [aria-selected="true"] {
+        background-color: #DAA520;
+        color: white;
+    }
+
+    .stTabs [data-baseweb="tab"]:hover {
+        background-color: #DAA520;
+        cursor: pointer;
+    }
+</style>""", unsafe_allow_html=True)
+
 @st.cache_resource(ttl = 599)
 def player_stat_table():
     collection = db["Player_Level_ROO"] 
@@ -59,271 +90,243 @@ player_stats, dk_roo_raw, fd_roo_raw = player_stat_table()
 opp_dict = dict(zip(dk_roo_raw.Team, dk_roo_raw.Opp))
 t_stamp = f"Last Update: " + str(dk_roo_raw['timestamp'][0]) + f" CST"
 
-tab1, tab2 = st.tabs(['Pivot Finder', 'Uploads and Info'])
-
-with tab1:
-    col1, col2 = st.columns([1, 5])
-    with col1:
-        st.info(t_stamp)
-        if st.button("Load/Reset Data", key='reset1'):
-              st.cache_data.clear()
-              for key in st.session_state.keys():
-                  del st.session_state[key]
-              player_stats, dk_roo_raw, fd_roo_raw = player_stat_table()
-              opp_dict = dict(zip(dk_roo_raw.Team, dk_roo_raw.Opp))
-              t_stamp = f"Last Update: " + str(dk_roo_raw['timestamp'][0]) + f" CST"
-        data_var1 = st.radio("Which data are you loading?", ('Paydirt', 'User'), key='data_var1')
-        site_var1 = st.radio("What site are you working with?", ('Draftkings', 'Fanduel'), key='site_var1')
+st.header("NHL Pivot Finder Tool")
+with st.expander("Info and Filters"):
+    st.info(t_stamp)
+    if st.button("Load/Reset Data", key='reset1'):
+            st.cache_data.clear()
+            for key in st.session_state.keys():
+                del st.session_state[key]
+            player_stats, dk_roo_raw, fd_roo_raw = player_stat_table()
+            opp_dict = dict(zip(dk_roo_raw.Team, dk_roo_raw.Opp))
+            t_stamp = f"Last Update: " + str(dk_roo_raw['timestamp'][0]) + f" CST"
+    site_var1 = st.radio("What site are you working with?", ('Draftkings', 'Fanduel'), key='site_var1')
+    if site_var1 == 'Draftkings':
+        raw_baselines = dk_roo_raw[dk_roo_raw['Slate'] == 'Main Slate']
+        raw_baselines = raw_baselines.sort_values(by='Own', ascending=False)
+    elif site_var1 == 'Fanduel':
+        raw_baselines = fd_roo_raw[fd_roo_raw['Slate'] == 'Main Slate']
+        raw_baselines = raw_baselines.sort_values(by='Own', ascending=False)
+    check_seq = st.radio("Do you want to check a single player or the top 10 in ownership?", ('Single Player', 'Top X Owned'), key='check_seq')
+    if check_seq == 'Single Player':
+        player_check = st.selectbox('Select player to create comps', options = raw_baselines['Player'].unique(), key='dk_player')
+    elif check_seq == 'Top X Owned':
+        top_x_var = st.number_input('How many players would you like to check?', min_value = 1, max_value = 10, value = 5, step = 1)
+    Salary_var = st.number_input('Acceptable +/- Salary range', min_value = 0, max_value = 1000, value = 300, step = 100)
+    Median_var = st.number_input('Acceptable +/- Median range', min_value = 0, max_value = 10, value = 3, step = 1)
+    pos_var1 = st.radio("Compare to all positions or specific positions?", ('All Positions', 'Specific Positions'), key='pos_var1')
+    if pos_var1 == 'Specific Positions':
+        pos_var_list = st.multiselect('Which positions would you like to include?', options = raw_baselines['Position'].unique(), key='pos_var_list')
+    elif pos_var1 == 'All Positions':
+        pos_var_list = raw_baselines.Position.values.tolist()
+    split_var1 = st.radio("Are you running the full slate or certain games?", ('Full Slate Run', 'Specific Games'), key='split_var1')
+    if split_var1 == 'Specific Games':
+        team_var1 = st.multiselect('Which teams would you like to include?', options = raw_baselines['Team'].unique(), key='team_var1')
+    elif split_var1 == 'Full Slate Run':
+        team_var1 = raw_baselines.Team.values.tolist()
+
+placeholder = st.empty()
+displayholder = st.empty()
+
+if st.button('Simulate appropriate pivots'):
+    with placeholder:
         if site_var1 == 'Draftkings':
-              if data_var1 == 'User':
-                  raw_baselines = proj_dataframe
-              elif data_var1 != 'User':
-                  raw_baselines = dk_roo_raw[dk_roo_raw['Slate'] == 'Main Slate']
-                  raw_baselines = raw_baselines.sort_values(by='Own', ascending=False)
-        elif site_var1 == 'Fanduel':
-              if data_var1 == 'User':
-                  raw_baselines = proj_dataframe
-              elif data_var1 != 'User':
-                  raw_baselines = fd_roo_raw[fd_roo_raw['Slate'] == 'Main Slate']
-                  raw_baselines = raw_baselines.sort_values(by='Own', ascending=False)
-        check_seq = st.radio("Do you want to check a single player or the top 10 in ownership?", ('Single Player', 'Top X Owned'), key='check_seq')
-        if check_seq == 'Single Player':
-            player_check = st.selectbox('Select player to create comps', options = raw_baselines['Player'].unique(), key='dk_player')
-        elif check_seq == 'Top X Owned':
-            top_x_var = st.number_input('How many players would you like to check?', min_value = 1, max_value = 10, value = 5, step = 1)
-        Salary_var = st.number_input('Acceptable +/- Salary range', min_value = 0, max_value = 1000, value = 300, step = 100)
-        Median_var = st.number_input('Acceptable +/- Median range', min_value = 0, max_value = 10, value = 3, step = 1)
-        pos_var1 = st.radio("Compare to all positions or specific positions?", ('All Positions', 'Specific Positions'), key='pos_var1')
-        if pos_var1 == 'Specific Positions':
-            pos_var_list = st.multiselect('Which positions would you like to include?', options = raw_baselines['Position'].unique(), key='pos_var_list')
-        elif pos_var1 == 'All Positions':
-            pos_var_list = raw_baselines.Position.values.tolist()
-        split_var1 = st.radio("Are you running the full slate or certain games?", ('Full Slate Run', 'Specific Games'), key='split_var1')
-        if split_var1 == 'Specific Games':
-            team_var1 = st.multiselect('Which teams would you like to include?', options = raw_baselines['Team'].unique(), key='team_var1')
-        elif split_var1 == 'Full Slate Run':
-            team_var1 = raw_baselines.Team.values.tolist()
-        
-    with col2:
-        placeholder = st.empty()
-        displayholder = st.empty()
-        
-        if st.button('Simulate appropriate pivots'):
-            with placeholder:
-                if site_var1 == 'Draftkings':
-                        working_roo = raw_baselines
-                        working_roo.replace('', 0, inplace=True)
-                if site_var1 == 'Fanduel':
-                        working_roo = raw_baselines
-                        working_roo.replace('', 0, inplace=True)
-                        
-                own_dict = dict(zip(working_roo.Player, working_roo.Own))
-                team_dict = dict(zip(working_roo.Player, working_roo.Team))
-                opp_dict = dict(zip(working_roo.Player, working_roo.Opp))
-                pos_dict = dict(zip(working_roo.Player, working_roo.Position))
-                total_sims = 1000
-
-                if check_seq == 'Single Player':
-                    player_var = working_roo.loc[working_roo['Player'] == player_check]
-                    player_var = player_var.reset_index()
-                    
-                    working_roo = working_roo[working_roo['Position'].isin(pos_var_list)]
-                    working_roo = working_roo[working_roo['Team'].isin(team_var1)]
-                    working_roo = working_roo.loc[(working_roo['Salary'] >= player_var['Salary'][0] - Salary_var) & (working_roo['Salary'] <= player_var['Salary'][0] + Salary_var)]
-                    working_roo = working_roo.loc[(working_roo['Median'] >= player_var['Median'][0] - Median_var) & (working_roo['Median'] <= player_var['Median'][0] + Median_var)]
-    
-                    flex_file = working_roo[['Player', 'Position', 'Salary', 'Median']]
-                    flex_file['Floor_raw'] = flex_file['Median'] * .25
-                    flex_file['Ceiling_raw'] = flex_file['Median'] * 2
-                    flex_file['Floor'] = np.where(flex_file['Position'] == 'G', flex_file['Median'] * .5, flex_file['Floor_raw'])
-                    flex_file['Floor'] = np.where(flex_file['Position'] == 'D', flex_file['Median'] * .1, flex_file['Floor_raw'])
-                    flex_file['Ceiling'] = np.where(flex_file['Position'] == 'G', flex_file['Median'] * 1.75, flex_file['Ceiling_raw'])
-                    flex_file['Ceiling'] = np.where(flex_file['Position'] == 'D', flex_file['Median'] * 1.75, flex_file['Ceiling_raw'])
-                    flex_file['STD'] = flex_file['Median'] / 3
-                    flex_file = flex_file[['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD']]
-                    hold_file = flex_file.copy()
-                    overall_file = flex_file.copy()
-                    salary_file = flex_file.copy()
-    
-                    overall_players = overall_file[['Player']]
-
-                    for x in range(0,total_sims):    
-                        salary_file[x] = salary_file['Salary']
-                        overall_file[x] = random.normal(overall_file['Median'],overall_file['STD'])
-
-                    salary_file=salary_file.drop(['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD'], axis=1)
-
-                    salary_file = salary_file.div(1000)
-
-                    overall_file=overall_file.drop(['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD'], axis=1)
-
-                    players_only = hold_file[['Player']]
-                    raw_lineups_file = players_only
+                working_roo = raw_baselines
+                working_roo.replace('', 0, inplace=True)
+        if site_var1 == 'Fanduel':
+                working_roo = raw_baselines
+                working_roo.replace('', 0, inplace=True)
+                
+        own_dict = dict(zip(working_roo.Player, working_roo.Own))
+        team_dict = dict(zip(working_roo.Player, working_roo.Team))
+        opp_dict = dict(zip(working_roo.Player, working_roo.Opp))
+        pos_dict = dict(zip(working_roo.Player, working_roo.Position))
+        total_sims = 1000
 
-                    for x in range(0,total_sims):
-                        maps_dict = {'proj_map':dict(zip(hold_file.Player,overall_file[x]))}
-                        raw_lineups_file[x] = sum([raw_lineups_file['Player'].map(maps_dict['proj_map'])])
-                        players_only[x] = raw_lineups_file[x].rank(ascending=False)
+        if check_seq == 'Single Player':
+            player_var = working_roo.loc[working_roo['Player'] == player_check]
+            player_var = player_var.reset_index()
+            
+            working_roo = working_roo[working_roo['Position'].isin(pos_var_list)]
+            working_roo = working_roo[working_roo['Team'].isin(team_var1)]
+            working_roo = working_roo.loc[(working_roo['Salary'] >= player_var['Salary'][0] - Salary_var) & (working_roo['Salary'] <= player_var['Salary'][0] + Salary_var)]
+            working_roo = working_roo.loc[(working_roo['Median'] >= player_var['Median'][0] - Median_var) & (working_roo['Median'] <= player_var['Median'][0] + Median_var)]
+
+            flex_file = working_roo[['Player', 'Position', 'Salary', 'Median']]
+            flex_file['Floor_raw'] = flex_file['Median'] * .25
+            flex_file['Ceiling_raw'] = flex_file['Median'] * 2
+            flex_file['Floor'] = np.where(flex_file['Position'] == 'G', flex_file['Median'] * .5, flex_file['Floor_raw'])
+            flex_file['Floor'] = np.where(flex_file['Position'] == 'D', flex_file['Median'] * .1, flex_file['Floor_raw'])
+            flex_file['Ceiling'] = np.where(flex_file['Position'] == 'G', flex_file['Median'] * 1.75, flex_file['Ceiling_raw'])
+            flex_file['Ceiling'] = np.where(flex_file['Position'] == 'D', flex_file['Median'] * 1.75, flex_file['Ceiling_raw'])
+            flex_file['STD'] = flex_file['Median'] / 3
+            flex_file = flex_file[['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD']]
+            hold_file = flex_file.copy()
+            overall_file = flex_file.copy()
+            salary_file = flex_file.copy()
+
+            overall_players = overall_file[['Player']]
+
+            for x in range(0,total_sims):    
+                salary_file[x] = salary_file['Salary']
+                overall_file[x] = random.normal(overall_file['Median'],overall_file['STD'])
+
+            salary_file=salary_file.drop(['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD'], axis=1)
+
+            salary_file = salary_file.div(1000)
+
+            overall_file=overall_file.drop(['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD'], axis=1)
+
+            players_only = hold_file[['Player']]
+            raw_lineups_file = players_only
+
+            for x in range(0,total_sims):
+                maps_dict = {'proj_map':dict(zip(hold_file.Player,overall_file[x]))}
+                raw_lineups_file[x] = sum([raw_lineups_file['Player'].map(maps_dict['proj_map'])])
+                players_only[x] = raw_lineups_file[x].rank(ascending=False)
+
+            players_only=players_only.drop(['Player'], axis=1)
+
+            salary_2x_check = (overall_file - (salary_file*2))
+            salary_3x_check = (overall_file - (salary_file*3))
+            salary_4x_check = (overall_file - (salary_file*4))
+
+            players_only['Average_Rank'] = players_only.mean(axis=1)
+            players_only['Top_finish'] = players_only[players_only == 1].count(axis=1)/total_sims
+            players_only['Top_5_finish'] = players_only[players_only <= 5].count(axis=1)/total_sims
+            players_only['Top_10_finish'] = players_only[players_only <= 10].count(axis=1)/total_sims
+            players_only['20+%'] = overall_file[overall_file >= 20].count(axis=1)/float(total_sims)
+            players_only['2x%'] = salary_2x_check[salary_2x_check >= 1].count(axis=1)/float(total_sims)
+            players_only['3x%'] = salary_3x_check[salary_3x_check >= 1].count(axis=1)/float(total_sims)
+            players_only['4x%'] = salary_4x_check[salary_4x_check >= 1].count(axis=1)/float(total_sims)
+
+            players_only['Player'] = hold_file[['Player']]
+
+            final_outcomes = players_only[['Player', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%']]
+
+            final_Proj = pd.merge(hold_file, final_outcomes, on="Player")
+            final_Proj = final_Proj[['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%']]
+            final_Proj['Own'] = final_Proj['Player'].map(own_dict)
+            final_Proj['Team'] = final_Proj['Player'].map(team_dict)
+            final_Proj['Opp'] = final_Proj['Player'].map(opp_dict)
+            final_Proj = final_Proj[['Player', 'Position', 'Team', 'Opp', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%', 'Own']]
+            final_Proj['Projection Rank'] = final_Proj.Median.rank(pct = True)
+            final_Proj['Own Rank'] = final_Proj.Own.rank(pct = True)
+            final_Proj['LevX'] = 0
+            final_Proj['LevX'] = np.where(final_Proj['Position'] == 'C', final_Proj[['Projection Rank', 'Top_5_finish']].mean(axis=1) + final_Proj['20+%'] - final_Proj['Own Rank'], final_Proj['LevX'])
+            final_Proj['LevX'] = np.where(final_Proj['Position'] == 'W', final_Proj[['Projection Rank', 'Top_5_finish']].mean(axis=1) + final_Proj['20+%'] - final_Proj['Own Rank'], final_Proj['LevX'])
+            final_Proj['LevX'] = np.where(final_Proj['Position'] == 'D', final_Proj[['Projection Rank', '2x%']].mean(axis=1) + final_Proj['4x%'] - final_Proj['Own Rank'], final_Proj['LevX'])
+            final_Proj['LevX'] = np.where(final_Proj['Position'] == 'G', final_Proj[['Projection Rank', '2x%']].mean(axis=1) + final_Proj['4x%'] - final_Proj['Own Rank'], final_Proj['LevX'])
+            final_Proj['CPT_Own'] = final_Proj['Own'] / 4
+
+            final_Proj = final_Proj[['Player', 'Position', 'Team', 'Opp', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%', 'Own', 'LevX']]
+            final_Proj = final_Proj.set_index('Player')
+            st.session_state.final_Proj = final_Proj.sort_values(by='Top_finish', ascending=False)
 
-                    players_only=players_only.drop(['Player'], axis=1)
-    
-                    salary_2x_check = (overall_file - (salary_file*2))
-                    salary_3x_check = (overall_file - (salary_file*3))
-                    salary_4x_check = (overall_file - (salary_file*4))
-    
-                    players_only['Average_Rank'] = players_only.mean(axis=1)
-                    players_only['Top_finish'] = players_only[players_only == 1].count(axis=1)/total_sims
-                    players_only['Top_5_finish'] = players_only[players_only <= 5].count(axis=1)/total_sims
-                    players_only['Top_10_finish'] = players_only[players_only <= 10].count(axis=1)/total_sims
-                    players_only['20+%'] = overall_file[overall_file >= 20].count(axis=1)/float(total_sims)
-                    players_only['2x%'] = salary_2x_check[salary_2x_check >= 1].count(axis=1)/float(total_sims)
-                    players_only['3x%'] = salary_3x_check[salary_3x_check >= 1].count(axis=1)/float(total_sims)
-                    players_only['4x%'] = salary_4x_check[salary_4x_check >= 1].count(axis=1)/float(total_sims)
-    
-                    players_only['Player'] = hold_file[['Player']]
-    
-                    final_outcomes = players_only[['Player', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%']]
-    
-                    final_Proj = pd.merge(hold_file, final_outcomes, on="Player")
-                    final_Proj = final_Proj[['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%']]
-                    final_Proj['Own'] = final_Proj['Player'].map(own_dict)
-                    final_Proj['Team'] = final_Proj['Player'].map(team_dict)
-                    final_Proj['Opp'] = final_Proj['Player'].map(opp_dict)
-                    final_Proj = final_Proj[['Player', 'Position', 'Team', 'Opp', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%', 'Own']]
-                    final_Proj['Projection Rank'] = final_Proj.Median.rank(pct = True)
-                    final_Proj['Own Rank'] = final_Proj.Own.rank(pct = True)
-                    final_Proj['LevX'] = 0
-                    final_Proj['LevX'] = np.where(final_Proj['Position'] == 'C', final_Proj[['Projection Rank', 'Top_5_finish']].mean(axis=1) + final_Proj['20+%'] - final_Proj['Own Rank'], final_Proj['LevX'])
-                    final_Proj['LevX'] = np.where(final_Proj['Position'] == 'W', final_Proj[['Projection Rank', 'Top_5_finish']].mean(axis=1) + final_Proj['20+%'] - final_Proj['Own Rank'], final_Proj['LevX'])
-                    final_Proj['LevX'] = np.where(final_Proj['Position'] == 'D', final_Proj[['Projection Rank', '2x%']].mean(axis=1) + final_Proj['4x%'] - final_Proj['Own Rank'], final_Proj['LevX'])
-                    final_Proj['LevX'] = np.where(final_Proj['Position'] == 'G', final_Proj[['Projection Rank', '2x%']].mean(axis=1) + final_Proj['4x%'] - final_Proj['Own Rank'], final_Proj['LevX'])
-                    final_Proj['CPT_Own'] = final_Proj['Own'] / 4
-    
-                    final_Proj = final_Proj[['Player', 'Position', 'Team', 'Opp', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%', 'Own', 'LevX']]
-                    final_Proj = final_Proj.set_index('Player')
-                    st.session_state.final_Proj = final_Proj.sort_values(by='Top_finish', ascending=False)
-
-                elif check_seq == 'Top X Owned':
-                    if pos_var1 == 'Specific Positions':    
-                        raw_baselines = raw_baselines[raw_baselines['Position'].isin(pos_var_list)]
-                    player_check = raw_baselines['Player'].head(top_x_var).tolist()
-                    final_proj_list = []
-                    for players in player_check:
-                        players_pos = pos_dict[players]
-                        player_var = working_roo.loc[working_roo['Player'] == players]
-                        player_var = player_var.reset_index()
-                        working_roo_temp = working_roo[working_roo['Position'] == players_pos]
-                        working_roo_temp = working_roo_temp[working_roo_temp['Team'].isin(team_var1)]
-                        working_roo_temp = working_roo_temp.loc[(working_roo_temp['Salary'] >= player_var['Salary'][0] - Salary_var) & (working_roo_temp['Salary'] <= player_var['Salary'][0] + Salary_var)]
-                        working_roo_temp = working_roo_temp.loc[(working_roo_temp['Median'] >= player_var['Median'][0] - Median_var) & (working_roo_temp['Median'] <= player_var['Median'][0] + Median_var)]
-                        
-                        flex_file = working_roo_temp[['Player', 'Position', 'Salary', 'Median']]
-                        flex_file['Floor_raw'] = flex_file['Median'] * .25
-                        flex_file['Ceiling_raw'] = flex_file['Median'] * 2
-                        flex_file['Floor'] = np.where(flex_file['Position'] == 'G', flex_file['Median'] * .5, flex_file['Floor_raw'])
-                        flex_file['Floor'] = np.where(flex_file['Position'] == 'D', flex_file['Median'] * .1, flex_file['Floor_raw'])
-                        flex_file['Ceiling'] = np.where(flex_file['Position'] == 'G', flex_file['Median'] * 1.75, flex_file['Ceiling_raw'])
-                        flex_file['Ceiling'] = np.where(flex_file['Position'] == 'D', flex_file['Median'] * 1.75, flex_file['Ceiling_raw'])
-                        flex_file['STD'] = flex_file['Median'] / 3
-                        flex_file = flex_file[['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD']]
-                        hold_file = flex_file.copy()
-                        overall_file = flex_file.copy()
-                        salary_file = flex_file.copy()
-                        
-                        overall_players = overall_file[['Player']]
-
-                        for x in range(0,total_sims):    
-                            salary_file[x] = salary_file['Salary']
-                            overall_file[x] = random.normal(overall_file['Median'],overall_file['STD'])
-
-                        salary_file=salary_file.drop(['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD'], axis=1)
-
-                        salary_file = salary_file.div(1000)
-
-                        overall_file=overall_file.drop(['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD'], axis=1)
-
-                        players_only = hold_file[['Player']]
-                        raw_lineups_file = players_only
-
-                        for x in range(0,total_sims):
-                            maps_dict = {'proj_map':dict(zip(hold_file.Player,overall_file[x]))}
-                            raw_lineups_file[x] = sum([raw_lineups_file['Player'].map(maps_dict['proj_map'])])
-                            players_only[x] = raw_lineups_file[x].rank(ascending=False)
-
-                        players_only=players_only.drop(['Player'], axis=1)
-        
-                        salary_2x_check = (overall_file - (salary_file*2))
-                        salary_3x_check = (overall_file - (salary_file*3))
-                        salary_4x_check = (overall_file - (salary_file*4))
-        
-                        players_only['Average_Rank'] = players_only.mean(axis=1)
-                        players_only['Top_finish'] = players_only[players_only == 1].count(axis=1)/total_sims
-                        players_only['Top_5_finish'] = players_only[players_only <= 5].count(axis=1)/total_sims
-                        players_only['Top_10_finish'] = players_only[players_only <= 10].count(axis=1)/total_sims
-                        players_only['20+%'] = overall_file[overall_file >= 20].count(axis=1)/float(total_sims)
-                        players_only['2x%'] = salary_2x_check[salary_2x_check >= 1].count(axis=1)/float(total_sims)
-                        players_only['3x%'] = salary_3x_check[salary_3x_check >= 1].count(axis=1)/float(total_sims)
-                        players_only['4x%'] = salary_4x_check[salary_4x_check >= 1].count(axis=1)/float(total_sims)
-        
-                        players_only['Player'] = hold_file[['Player']]
-        
-                        final_outcomes = players_only[['Player', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%']]
-        
-                        final_Proj = pd.merge(hold_file, final_outcomes, on="Player")
-                        final_Proj = final_Proj[['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%']]
-                        final_Proj['Own'] = final_Proj['Player'].map(own_dict)
-                        final_Proj['Team'] = final_Proj['Player'].map(team_dict)
-                        final_Proj['Opp'] = final_Proj['Player'].map(opp_dict)
-                        final_Proj = final_Proj[['Player', 'Position', 'Team', 'Opp', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%', 'Own']]
-                        final_Proj['Projection Rank'] = final_Proj.Median.rank(pct = True)
-                        final_Proj['Own Rank'] = final_Proj.Own.rank(pct = True)
-                        final_Proj['LevX'] = 0
-                        final_Proj['LevX'] = np.where(final_Proj['Position'] == 'C', final_Proj[['Projection Rank', 'Top_5_finish']].mean(axis=1) + final_Proj['20+%'] - final_Proj['Own Rank'], final_Proj['LevX'])
-                        final_Proj['LevX'] = np.where(final_Proj['Position'] == 'W', final_Proj[['Projection Rank', 'Top_5_finish']].mean(axis=1) + final_Proj['20+%'] - final_Proj['Own Rank'], final_Proj['LevX'])
-                        final_Proj['LevX'] = np.where(final_Proj['Position'] == 'D', final_Proj[['Projection Rank', '2x%']].mean(axis=1) + final_Proj['4x%'] - final_Proj['Own Rank'], final_Proj['LevX'])
-                        final_Proj['LevX'] = np.where(final_Proj['Position'] == 'G', final_Proj[['Projection Rank', '2x%']].mean(axis=1) + final_Proj['4x%'] - final_Proj['Own Rank'], final_Proj['LevX'])
-                        final_Proj['CPT_Own'] = final_Proj['Own'] / 4
-                        final_Proj['Pivot_source'] = players
-        
-                        final_Proj = final_Proj[['Player', 'Pivot_source', 'Position', 'Team', 'Opp', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%', 'Own', 'LevX']]
-                        
-                        final_Proj = final_Proj.sort_values(by='Top_finish', ascending=False)
-                        final_proj_list.append(final_Proj)
-                        st.write(f'finished run for {players}')
+        elif check_seq == 'Top X Owned':
+            if pos_var1 == 'Specific Positions':    
+                raw_baselines = raw_baselines[raw_baselines['Position'].isin(pos_var_list)]
+            player_check = raw_baselines['Player'].head(top_x_var).tolist()
+            final_proj_list = []
+            for players in player_check:
+                players_pos = pos_dict[players]
+                player_var = working_roo.loc[working_roo['Player'] == players]
+                player_var = player_var.reset_index()
+                working_roo_temp = working_roo[working_roo['Position'] == players_pos]
+                working_roo_temp = working_roo_temp[working_roo_temp['Team'].isin(team_var1)]
+                working_roo_temp = working_roo_temp.loc[(working_roo_temp['Salary'] >= player_var['Salary'][0] - Salary_var) & (working_roo_temp['Salary'] <= player_var['Salary'][0] + Salary_var)]
+                working_roo_temp = working_roo_temp.loc[(working_roo_temp['Median'] >= player_var['Median'][0] - Median_var) & (working_roo_temp['Median'] <= player_var['Median'][0] + Median_var)]
                 
-                    # Concatenate all the final_Proj dataframes
-                    final_Proj_combined = pd.concat(final_proj_list)
-                    final_Proj_combined = final_Proj_combined.sort_values(by='LevX', ascending=False)
-                    final_Proj_combined = final_Proj_combined[final_Proj_combined['Player'] != final_Proj_combined['Pivot_source']]
-                    st.session_state.final_Proj = final_Proj_combined.reset_index(drop=True)  # Assign the combined dataframe back to final_Proj
-            placeholder.empty()
-
-        with displayholder.container():
-            if 'final_Proj' in st.session_state:
-                st.dataframe(st.session_state.final_Proj.style.background_gradient(axis=0).background_gradient(cmap='RdYlGn').format(player_roo_format, precision=2), use_container_width = True)
-
-                st.download_button(
-                    label="Export Tables",
-                    data=convert_df_to_csv(st.session_state.final_Proj),
-                    file_name='NHL_pivot_export.csv',
-                    mime='text/csv',
-                )
-            else:
-                st.write("Run some pivots my dude/dudette")    
-
-with tab2:
-    st.info("The Projections file can have any columns in any order, but must contain columns explicitly named: 'Player', 'Salary', 'Position', 'Team', 'Opp', 'Median', and 'Own'.")
-    col1, col2 = st.columns([1, 5])
-
-    with col1:
-        proj_file = st.file_uploader("Upload Projections File", key = 'proj_uploader')
-    
-        if proj_file is not None:
-                  try:
-                            proj_dataframe = pd.read_csv(proj_file)
-                  except:
-                            proj_dataframe = pd.read_excel(proj_file)
-    with col2:
-        if proj_file is not None:  
-                  st.dataframe(proj_dataframe.style.background_gradient(axis=0).background_gradient(cmap='RdYlGn').format(precision=2), use_container_width = True)
-        
+                flex_file = working_roo_temp[['Player', 'Position', 'Salary', 'Median']]
+                flex_file['Floor_raw'] = flex_file['Median'] * .25
+                flex_file['Ceiling_raw'] = flex_file['Median'] * 2
+                flex_file['Floor'] = np.where(flex_file['Position'] == 'G', flex_file['Median'] * .5, flex_file['Floor_raw'])
+                flex_file['Floor'] = np.where(flex_file['Position'] == 'D', flex_file['Median'] * .1, flex_file['Floor_raw'])
+                flex_file['Ceiling'] = np.where(flex_file['Position'] == 'G', flex_file['Median'] * 1.75, flex_file['Ceiling_raw'])
+                flex_file['Ceiling'] = np.where(flex_file['Position'] == 'D', flex_file['Median'] * 1.75, flex_file['Ceiling_raw'])
+                flex_file['STD'] = flex_file['Median'] / 3
+                flex_file = flex_file[['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD']]
+                hold_file = flex_file.copy()
+                overall_file = flex_file.copy()
+                salary_file = flex_file.copy()
+                
+                overall_players = overall_file[['Player']]
+
+                for x in range(0,total_sims):    
+                    salary_file[x] = salary_file['Salary']
+                    overall_file[x] = random.normal(overall_file['Median'],overall_file['STD'])
+
+                salary_file=salary_file.drop(['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD'], axis=1)
+
+                salary_file = salary_file.div(1000)
+
+                overall_file=overall_file.drop(['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'STD'], axis=1)
+
+                players_only = hold_file[['Player']]
+                raw_lineups_file = players_only
+
+                for x in range(0,total_sims):
+                    maps_dict = {'proj_map':dict(zip(hold_file.Player,overall_file[x]))}
+                    raw_lineups_file[x] = sum([raw_lineups_file['Player'].map(maps_dict['proj_map'])])
+                    players_only[x] = raw_lineups_file[x].rank(ascending=False)
+
+                players_only=players_only.drop(['Player'], axis=1)
+
+                salary_2x_check = (overall_file - (salary_file*2))
+                salary_3x_check = (overall_file - (salary_file*3))
+                salary_4x_check = (overall_file - (salary_file*4))
+
+                players_only['Average_Rank'] = players_only.mean(axis=1)
+                players_only['Top_finish'] = players_only[players_only == 1].count(axis=1)/total_sims
+                players_only['Top_5_finish'] = players_only[players_only <= 5].count(axis=1)/total_sims
+                players_only['Top_10_finish'] = players_only[players_only <= 10].count(axis=1)/total_sims
+                players_only['20+%'] = overall_file[overall_file >= 20].count(axis=1)/float(total_sims)
+                players_only['2x%'] = salary_2x_check[salary_2x_check >= 1].count(axis=1)/float(total_sims)
+                players_only['3x%'] = salary_3x_check[salary_3x_check >= 1].count(axis=1)/float(total_sims)
+                players_only['4x%'] = salary_4x_check[salary_4x_check >= 1].count(axis=1)/float(total_sims)
+
+                players_only['Player'] = hold_file[['Player']]
+
+                final_outcomes = players_only[['Player', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%']]
+
+                final_Proj = pd.merge(hold_file, final_outcomes, on="Player")
+                final_Proj = final_Proj[['Player', 'Position', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%']]
+                final_Proj['Own'] = final_Proj['Player'].map(own_dict)
+                final_Proj['Team'] = final_Proj['Player'].map(team_dict)
+                final_Proj['Opp'] = final_Proj['Player'].map(opp_dict)
+                final_Proj = final_Proj[['Player', 'Position', 'Team', 'Opp', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%', 'Own']]
+                final_Proj['Projection Rank'] = final_Proj.Median.rank(pct = True)
+                final_Proj['Own Rank'] = final_Proj.Own.rank(pct = True)
+                final_Proj['LevX'] = 0
+                final_Proj['LevX'] = np.where(final_Proj['Position'] == 'C', final_Proj[['Projection Rank', 'Top_5_finish']].mean(axis=1) + final_Proj['20+%'] - final_Proj['Own Rank'], final_Proj['LevX'])
+                final_Proj['LevX'] = np.where(final_Proj['Position'] == 'W', final_Proj[['Projection Rank', 'Top_5_finish']].mean(axis=1) + final_Proj['20+%'] - final_Proj['Own Rank'], final_Proj['LevX'])
+                final_Proj['LevX'] = np.where(final_Proj['Position'] == 'D', final_Proj[['Projection Rank', '2x%']].mean(axis=1) + final_Proj['4x%'] - final_Proj['Own Rank'], final_Proj['LevX'])
+                final_Proj['LevX'] = np.where(final_Proj['Position'] == 'G', final_Proj[['Projection Rank', '2x%']].mean(axis=1) + final_Proj['4x%'] - final_Proj['Own Rank'], final_Proj['LevX'])
+                final_Proj['CPT_Own'] = final_Proj['Own'] / 4
+                final_Proj['Pivot_source'] = players
+
+                final_Proj = final_Proj[['Player', 'Pivot_source', 'Position', 'Team', 'Opp', 'Salary', 'Floor', 'Median', 'Ceiling', 'Top_finish', 'Top_5_finish', 'Top_10_finish', '20+%', '2x%', '3x%', '4x%', 'Own', 'LevX']]
+                
+                final_Proj = final_Proj.sort_values(by='Top_finish', ascending=False)
+                final_proj_list.append(final_Proj)
+                st.write(f'finished run for {players}')
+        
+            # Concatenate all the final_Proj dataframes
+            final_Proj_combined = pd.concat(final_proj_list)
+            final_Proj_combined = final_Proj_combined.sort_values(by='LevX', ascending=False)
+            final_Proj_combined = final_Proj_combined[final_Proj_combined['Player'] != final_Proj_combined['Pivot_source']]
+            st.session_state.final_Proj = final_Proj_combined.reset_index(drop=True)  # Assign the combined dataframe back to final_Proj
+    placeholder.empty()
+
+with displayholder.container():
+    if 'final_Proj' in st.session_state:
+        st.dataframe(st.session_state.final_Proj.style.background_gradient(axis=0).background_gradient(cmap='RdYlGn').format(player_roo_format, precision=2), use_container_width = True)
+
+        st.download_button(
+            label="Export Tables",
+            data=convert_df_to_csv(st.session_state.final_Proj),
+            file_name='NHL_pivot_export.csv',
+            mime='text/csv',
+        )
+    else:
+        st.write("Run some pivots my dude/dudette")