# coding: utf-8
# In[71]:
import time
import datetime
import numpy as np
import math
from sklearn.linear_model import LogisticRegression
from sklearn.ensemble import RandomForestClassifier
from sklearn.ensemble import GradientBoostingClassifier
# ############# reading data from files
# In[87]:
#with open('./tianchi_fresh_comp_train_user.csv') as f:
# raw_data = f.read().splitlines()
controlsize = 100000
size = 0
raw_list = []
for line in open("./tianchi_fresh_comp_train_user.csv"):
if(size == 0):
size += 1
continue
raw_list.append(line)
size += 1
if(size == controlsize): break
raw_list = map(lambda line : line.split(","), raw_list)
# In[88]:
############# [Test Code]
raw_list
# In[113]:
train_data = []
train_data28 = []
train_data29 = []
train_data30 = []
test = []
for line in raw_list:
day = line[-1][:10].split('-')
#计算两个日期之间的天数
d1=datetime.datetime(2014,11,18)
d2=datetime.datetime(int(day[0]),int(day[1]),int(day[2]))
diff_days = (d2-d1).days
uid = (int(line[0]), int(line[1]), int(line[2]), int(line[4]), diff_days)
train_data.append(uid)
if(diff_days <= 28): train_data28.append(uid)
elif(diff_days == 29): train_data29.append(uid)
elif(diff_days == 30): train_data30.append(uid)
elif(diff_days > 30): test.append(uid)
train_data = list(set(train_data))
train_data28 = list(set(train_data28))
train_data29 = list(set(train_data29))
train_data30 = list(set(train_data30))
# In[90]:
############# [Test Code]
train_data
# In[114]:
############# [Test Code]
train_data28
# ############# data pre-processing
# In[99]:
def additem(uid, typeid, ui_dict, ui_buy):
if uid in ui_dict[typeid]:
ui_dict[typeid][uid] += 1
else:
ui_dict[typeid][uid] = 1
if typeid == 3:
ui_buy[uid] = 1 #用当天购买或没购买的作用对打标签
return ui_dict, ui_buy
# In[100]:
# for feature
ui_dict = [{} for i in range(4)]
# for label
ui_buy = {}
for line in train_data:
day = line[-1]
if(day < 28): day = 28
uid = (line[0], line[1], day)
typeid = line[2] - 1
ui_dict, ui_buy = additem(uid, typeid, ui_dict, ui_buy)
for newday in range(day+1, 31):
uid = (line[0], line[1], newday)
#print uid,
ui_dict, ui_buy = additem(uid, typeid, ui_dict, ui_buy)
#print ;
# In[101]:
############# [Test Code]
ui_dict
# In[102]:
############# [Test Code]
#print len(train_data),len(ui_dict)
#print len(ui_dict[0]),len(ui_dict[1]),len(ui_dict[2]),len(ui_dict[3])
# In[103]:
############# [Test Code]
ui_buy
# In[135]:
# get train X,Y
x = np.zeros((len(train_data29), 4))
y = np.zeros((len(train_data29), ))
index = 0
for line in train_data29:
uid = (line[0], line[1], line[-1]-1)
for i in range(4):
x[index][i] = math.log1p( ui_dict[i][uid] if uid in ui_dict[i] else 0 )
uid = (line[0], line[1], line[-1])
y[index] = 1 if uid in ui_buy else 0
index += 1
# In[136]:
# get prediction px
px = np.zeros((len(train_data30), 4))
index = 0
for line in train_data30:
uid = (line[0], line[1], line[-1]-1)
for i in range(4):
px[index][i] = math.log1p( ui_dict[i][uid] if uid in ui_dict[i] else 0 )
index += 1
# In[120]:
############# [Test Code]
#print x
#print y
#print px
# ############# training
# In[137]:
model = LogisticRegression()
#model = RandomForestClassifier(n_estimators=100)
#model=GradientBoostingClassifier()
model.fit(x,y)
# ############# predicting
# In[138]:
py = model.predict_proba(px)
npy = []
for item in py:
npy.append(item[1])
py = npy
# In[123]:
############# [Test Code]
py
# In[139]:
# combine and sort by predict score
lx = zip(train_data30, py)
lx = sorted(lx, key = lambda x:x[1], reverse = True)
# In[140]:
############# [Test Code]
lx
# In[130]:
wf = open('ans.csv', 'w')
wf.write('user_id,item_id\n')
for i in range(len(lx)):
item = lx[i]
if(item[1] < 0.5): break #置信区间
wf.write('%s,%s\n' %(item[0][0], item[0][1]))
wf.close()
# ############# 对预测结果进行评估
# In[141]:
size_predictionset = 0
for i in range(len(lx)):
item = lx[i]
if(item[1] >= 0.5): size_predictionset += 1
size_referenceset = 0
for i in range(len(lx)):
item = lx[i]
if(item[0][2] == 4): size_referenceset += 1
size_predictionset_referenceset = 0
for i in range(len(lx)):
item = lx[i]
if(item[0][2] == 4): size_predictionset_referenceset += 1
if(item[1] < 0.5): break
P = 1.0 * size_predictionset_referenceset / size_predictionset * 100
R = 1.0 * size_predictionset_referenceset / size_referenceset * 100
F1 = 2.0 * P * R / ( P + R )
print('precision: %.2f%%' %( P ))
print('recal: %.2f%%' % ( R ))
print('F1: %.2f%%' % ( F1 ))
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