数据分析编程:SQL,Python or SPL?

 

Talk is cheap. Let’s show the code

1. 计算用户会话次数

用户行为数据表

userid action_type action_time
U1059 login 2023-12-01 18:00:10
U1092 login 2023-12-01 18:00:17
U1069 login 2023-12-01 18:00:22

10 分钟没有任何动作或退出后 5 分钟没有登录则认为会话结束,计算各用户的会话次数。

SPL

A
1 =file(“session_data.csv”).import@tc()
2 =A1.group(userid;~.group@i((action_type[-1]==“exit”&&interval@s(action_time[-1],action_time)>300)||(interval@s(action_time[-1],action_time)>600)).len():session_num)

SQL

WITH login_data AS (
    SELECT userid, action_type, action_time,
        LAG(action_time) OVER (PARTITION BY userid ORDER BY action_time) AS prev_time,
        LAG(action_type) OVER (PARTITION BY userid ORDER BY action_time) AS prev_action
    FROM session_data)
SELECT userid, COUNT(*) AS session_count
FROM (
    SELECT userid, action_type, action_time, prev_time, prev_action,
        CASE
            WHEN prev_time IS NULL OR (action_time - prev_time) > 600
                OR (prev_action = 'exit' AND (action_time - prev_time) > 300)
            THEN 1
            ELSE 0
        END AS is_new_session
    FROM login_data)
WHERE is_new_session = 1
GROUP BY userid;

Python

login_data = pd.read_csv("session_data.csv")
login_data['action_time'] = pd.to_datetime(login_data['action_time'])
grouped = login_data.groupby("userid")
session_count = {}
for uid, sub_df in grouped:
    session_count[uid] = 0
    start_index = 0
    for i in range(1, len(sub_df)):
        current = sub_df.iloc[i]
        last = sub_df.iloc[start_index]
        last_action = last['action_type']
        if (current["action_time"] - last["action_time"]).seconds > 600 or \
            (last_action=="exit" and (current["action_time"] - last["action_time"]).seconds > 300):
            session_count[uid] += 1
        start_index = i
    session_count[uid] += 1
session_cnt = pd.DataFrame(list(session_count.items()), columns=['UID', 'session_count'])

2. 1 分钟内连续得分 3 次的球员

球赛得分表

team player play_time score
A A3 2023-12-31 09:00:09 2
B B1 2023-12-31 09:00:24 3
A A5 2023-12-31 09:00:57 2

SPL

A
1 =file(“ball_game.csv”).import@tc()
2 =A1.group@o(player).select(~.len()>2&&(~.pselect(#>2&&interval@s(play_time[-2],play_time)<60))).(player)

A2:group@o(),@o 选项是按顺序把相同球员分成一组,球员不同开始新的分组,然后筛选其中连续得分次数大于等于 3 次且有任意一个连续三次得分时间间隔小于 60 的分组,最后取出球员。

SQL

WITH numbered_scores AS (
    SELECT team, player, play_time, score,
        ROW_NUMBER() OVER (ORDER BY play_time) AS rn
    FROM ball_game)
SELECT DISTINCT s1.player
FROM numbered_scores s1
    JOIN numbered_scores s2 ON s1.player = s2.player AND s1.rn = s2.rn - 1
    JOIN numbered_scores s3 ON s1.player = s3.player AND s1.rn = s3.rn - 2
WHERE (s3.play_time - s1.play_time) < 60 ;

Python

df = pd.read_csv("ball_game.csv")
df["play_time"] = pd.to_datetime(df["play_time"])
result_players = []
player = None
start_index = 0
consecutive_scores = 0
for i in range(len(df)-2):
    current = df.iloc[i]
    if player != current["player"]:
        player = current["player"]
        consecutive_scores = 1
    else:
        consecutive_scores += 1
    last2 = df.iloc[i-2] if i >=2 else None
    if consecutive_scores >= 3 and (current['play_time'] - last2['play_time']).seconds < 60:
        result_players.append(player)
result_players = list(set(result_players))

3. 每 7 天中连续三天活跃的用户数

用户登录表

id userid ts
1 466 2017-01-07 18:24:55
2 458 2017-01-07 18:25:18
3 458 2017-01-07 18:26:21

SPL

A
1 =file(“login_data.csv”).import@tc()
2 =periods(date(A1.ts),date(A1.m(-1).ts))
3 =A1.group(userid).(~.align(A2,date(ts)).(if(#<7,null,(cnt=~[-6:0].group@i(!~).max(count(~)),if(cnt>=3,1,0)))))
4 =msum(A3).~.new(A2(#):dt,int(~):cont3_num).to(7,)

SQL

WITH all_dates AS (
    SELECT DISTINCT TRUNC(ts) AS login_date
    FROM login_data),
user_login_counts AS (
    SELECT userid, TRUNC(ts) AS login_date, 
        (CASE WHEN COUNT(*)>=1 THEN 1 ELSE 0 END) AS login_count
    FROM login_data
    GROUP BY userid, TRUNC(ts)),
whether_login AS (
    SELECT u.userid, ad.login_date, NVL(ulc.login_count, 0) AS login_count
    FROM all_dates ad
    CROSS JOIN (
        SELECT DISTINCT userid
        FROM login_data) u
    LEFT JOIN user_login_counts ulc
    ON u.userid = ulc.userid
    AND ad.login_date = ulc.login_date
    ORDER BY u.userid, ad.login_date),
whether_login_rn AS (
    SELECT userid,login_date,login_count,ROWNUM AS rn 
    FROM whether_login),
whether_eq AS(
    SELECT userid,login_date,login_count,rn,
        (CASE 
            WHEN LAG(login_count,1) OVER (ORDER BY rn)= login_count 
                AND login_count =1 AND LAG(userid,1) OVER (ORDER BY rn)=userid 
            THEN 0 
            ELSE 1 
        END) AS wether_e 
    FROM whether_login_rn
),
numbered_sequence AS (
    SELECT userid,login_date,login_count,rn, wether_e,
        SUM(wether_e) OVER (ORDER BY rn) AS lab
    FROM whether_eq),
consecutive_logins_num AS (
    SELECT userid,login_date,login_count,rn, wether_e,lab,
        (SELECT (CASE WHEN max(COUNT(*))<3 THEN 0 ELSE 1 END)
        FROM numbered_sequence b
        WHERE b.rn BETWEEN a.rn - 6 AND a.rn
        AND b.userid=a.userid
        GROUP BY b. lab) AS cnt
    FROM numbered_sequence a)
SELECT login_date,SUM(cnt) AS cont3_num
FROM consecutive_logins_num
WHERE login_date>=(SELECT MIN(login_date) FROM all_dates)+6
GROUP BY login_date
ORDER BY login_date;

Python

df = pd.read_csv("login_data.csv")
df["ts"] = pd.to_datetime(df["ts"]).dt.date
grouped = df.groupby("userid")
aligned_dates = pd.date_range(start=df["ts"].min(), end=df["ts"].max(), freq='D')
user_date_wether_con3days = []
for uid, group in grouped:
    group = group.drop_duplicates('ts')
    aligned_group = group.set_index("ts").reindex(aligned_dates)
    consecutive_logins = aligned_group.rolling(window=7)
    n = 0
    date_wether_con3days = []
    for r in consecutive_logins:
        n += 1
        if n<7:
            continue
        else:
            ds = r['userid'].isna().cumsum()
            cont_login_times = r.groupby(ds).userid.count().max()
            wether_cont3days = 1 if cont_login_times>=3 else 0
            date_wether_con3days.append(wether_cont3days)
    user_date_wether_con3days.append(date_wether_con3days)
arr = np.array(user_date_wether_con3days)
day7_cont3num = np.sum(arr,axis=0)
result = pd.DataFrame({'dt':aligned_dates[6:],'cont3_num':day7_cont3num})

4. 每天新用户的次日留存率

用户登录表

id userid ts
1 466 2017-01-07 18:24:55
2 458 2017-01-07 18:25:18
3 458 2017-01-07 18:26:21

SPL

A
1 =file(“login_data.csv”).import@tc()
2 =A1.group(userid;fst=date(ts):fst_login,~.(date(ts)).pos(fst+1)>0:wether_sec_login)
3 =A2.groups(fst_login+1:dt;count(wether_sec_login)/count(1):ret_rate)

A2:按用户分组,记录首次登录日期并查看第二天是否登录
A3:按第二天登录日期统计次日留存率

SQL

WITH first_login AS (
    SELECT userid, MIN(TRUNC(ts)) AS first_login_date
    FROM login_data
    GROUP BY userid),
next_day_login AS (
    SELECT DISTINCT(fl.userid), fl.first_login_date, TRUNC(ld.ts) AS next_day_login_date
    FROM first_login fl
    LEFT JOIN login_data ld ON fl.userid = ld.userid
    WHERE TRUNC(ld.ts) = fl.first_login_date + 1),
day_new_users AS(
    SELECT first_login_date,COUNT(*) AS new_user_num
    FROM first_login
    GROUP BY first_login_date),
next_new_users AS(
    SELECT next_day_login_date, COUNT(*) AS next_user_num
    FROM next_day_login
    GROUP BY next_day_login_date),
all_date AS(
    SELECT DISTINCT(TRUNC(ts)) AS login_date
    FROM login_data)
SELECT all_date.login_date+1 AS dt,dn. new_user_num,nn. next_user_num,
    (CASE 
        WHEN nn. next_day_login_date IS NULL 
        THEN 0 
        ELSE nn.next_user_num 
    END)/dn.new_user_num AS ret_rate
FROM all_date
    JOIN day_new_users dn ON all_date.login_date=dn.first_login_date
    LEFT JOIN next_new_users nn ON dn.first_login_date+1=nn. next_day_login_date
ORDER BY all_date.login_date;

Python

df = pd.read_csv("login_data.csv")
df["ts"] = pd.to_datetime(df["ts"]).dt.date
gp = df.groupby('userid')
row = []
for uid,g in gp:
    fst_dt = g.iloc[0].ts
    sec_dt = fst_dt + pd.Timedelta(days=1)
    all_dt = g.ts.values
    wether_sec_login = sec_dt in all_dt
    row.append([uid,fst_dt,sec_dt,wether_sec_login])
user_wether_ret_df = pd.DataFrame(row,columns=['userid','fst_dt','sec_dt','wether_sec_login'])
result = user_wether_ret_df.groupby('sec_dt').apply(lambda x:x['wether_sec_login'].sum()/len(x))

5. 股价高于前后 5 天时当天的涨幅

股价信息表

STOCKID DATE CLOSING
62 2015-01-05 8.91
62 2015-01-06 8.31
62 2015-01-07 7.6

SPL

A
1 =file(“STOCK.csv”).import@tc()
2 =lth=A1.len(),A1.pselect@a(#>4&&#<=A1.len()-4&&CLOSING>max(CLOSING[-4:-1])&&CLOSING>max(CLOSING[1:4]))
3 =A1.calc(A2,CLOSING/CLOSING[-1]-1)

SQL

SELECT closing/closing_pre-1 AS raise
FROM(
    SELECT dt, closing, ROWNUM AS rn,
        MAX(closing) OVER (
            ORDER BY dt ROWS BETWEEN 5 PRECEDING AND 1 PRECEDING) AS max_pre,
        MAX(closing) OVER (
            ORDER BY dt ROWS BETWEEN 1 FOLLOWING AND 5 FOLLOWING) AS max_suf,
        LAG(closing,1) OVER (ORDER BY dt) AS closing_pre
    FROM stock)
WHERE rn>5 AND rn<=(select count(*) FROM stock)-5
    AND CLOSING>max_pre  AND CLOSING>max_suf;

Python

stock_price_df = pd.read_csv('STOCK.csv')
price_increase_list = []
for i in range(5, len(stock_price_df)-5):
    if stock_price_df['CLOSING'][i] > max(stock_price_df['CLOSING'][i-5:i]) and \
    stock_price_df['CLOSING'][i] > max(stock_price_df['CLOSING'][i+1:i+6]):
        price_increase = stock_price_df['CLOSING'][i] / stock_price_df['CLOSING'][i-1]-1
        price_increase_list.append(price_increase)
result = price_increase_list