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	#!/usr/bin/env python
	# coding: utf-8

	# In[1]:
	import numpy as np

	import gradio as gr
	import pandas as pd
	import numpy as np
	import torch
	from torch import nn
	from torch.nn import init, MarginRankingLoss
	from torch.optim import Adam
	from distutils.version import LooseVersion
	from torch.utils.data import Dataset, DataLoader
	from torch.autograd import Variable
	import math
	from transformers import AutoConfig, AutoModel, AutoTokenizer
	import nltk
	import re
	import torch.optim as optim
	from transformers import AutoModelForMaskedLM
	import torch.nn.functional as F
	import random


	# In[2]:


	# eng_dict = []
	# with open('eng_dict.txt', 'r') as file:
	# # Read each line from the file and append it to the list
	# for line in file:
	# # Remove leading and trailing whitespace (e.g., newline characters)
	# cleaned_line = line.strip()
	# eng_dict.append(cleaned_line)


	# In[14]:


	def greet(X, ny):
	global eng_dict
	if ny == 0:
	rand_no = random.random()
	tok_map = {2: 0.4363429005892416,
	1: 0.6672580202327398,
	4: 0.7476060740459144,
	3: 0.9618703668504087,
	6: 0.9701028532809564,
	7: 0.9729244545819342,
	8: 0.9739508754144756,
	5: 0.9994508859743607,
	9: 0.9997507867114407,
	10: 0.9999112969650892,
	11: 0.9999788802297832,
	0: 0.9999831041838266,
	12: 0.9999873281378701,
	22: 0.9999957760459568,
	14: 1.0000000000000002}
	for key in tok_map.keys():
	if rand_no < tok_map[key]:
	num_sub_tokens_label = key
	break
	else:
	num_sub_tokens_label = ny
	tokenizer = AutoTokenizer.from_pretrained("microsoft/graphcodebert-base")
	model = AutoModelForMaskedLM.from_pretrained("microsoft/graphcodebert-base")
	model.load_state_dict(torch.load('model_26_2'))
	model.eval()
	X_init = X
	X_init = X_init.replace("[MASK]", " [MASK] ")
	X_init = X_init.replace("[MASK]", " ".join([tokenizer.mask_token] * num_sub_tokens_label))
	tokens = tokenizer.encode_plus(X_init, add_special_tokens=False,return_tensors='pt')
	input_id_chunki = tokens['input_ids'][0].split(510)
	input_id_chunks = []
	mask_chunks = []
	mask_chunki = tokens['attention_mask'][0].split(510)
	for tensor in input_id_chunki:
	input_id_chunks.append(tensor)
	for tensor in mask_chunki:
	mask_chunks.append(tensor)
	xi = torch.full((1,), fill_value=101)
	yi = torch.full((1,), fill_value=1)
	zi = torch.full((1,), fill_value=102)
	for r in range(len(input_id_chunks)):
	input_id_chunks[r] = torch.cat([xi, input_id_chunks[r]],dim = -1)
	input_id_chunks[r] = torch.cat([input_id_chunks[r],zi],dim=-1)
	mask_chunks[r] = torch.cat([yi, mask_chunks[r]],dim=-1)
	mask_chunks[r] = torch.cat([mask_chunks[r],yi],dim=-1)
	di = torch.full((1,), fill_value=0)
	for i in range(len(input_id_chunks)):
	pad_len = 512 - input_id_chunks[i].shape[0]
	if pad_len > 0:
	for p in range(pad_len):
	input_id_chunks[i] = torch.cat([input_id_chunks[i],di],dim=-1)
	mask_chunks[i] = torch.cat([mask_chunks[i],di],dim=-1)
	vb = torch.ones_like(input_id_chunks[0])
	fg = torch.zeros_like(input_id_chunks[0])
	maski = []
	for l in range(len(input_id_chunks)):
	masked_pos = []
	for i in range(len(input_id_chunks[l])):
	if input_id_chunks[l][i] == tokenizer.mask_token_id: #103
	if i != 0 and input_id_chunks[l][i-1] == tokenizer.mask_token_id:
	continue
	masked_pos.append(i)
	maski.append(masked_pos)
	input_ids = torch.stack(input_id_chunks)
	att_mask = torch.stack(mask_chunks)
	outputs = model(input_ids, attention_mask = att_mask)
	last_hidden_state = outputs[0].squeeze()
	l_o_l_sa = []
	sum_state = []
	for t in range(num_sub_tokens_label):
	c = []
	l_o_l_sa.append(c)
	if len(maski) == 1:
	masked_pos = maski[0]
	for k in masked_pos:
	for t in range(num_sub_tokens_label):
	l_o_l_sa[t].append(last_hidden_state[k+t])
	else:
	for p in range(len(maski)):
	masked_pos = maski[p]
	for k in masked_pos:
	for t in range(num_sub_tokens_label):
	if (k+t) >= len(last_hidden_state[p]):
	l_o_l_sa[t].append(last_hidden_state[p+1][k+t-len(last_hidden_state[p])])
	continue
	l_o_l_sa[t].append(last_hidden_state[p][k+t])
	for t in range(num_sub_tokens_label):
	sum_state.append(l_o_l_sa[t][0])
	for i in range(len(l_o_l_sa[0])):
	if i == 0:
	continue
	for t in range(num_sub_tokens_label):
	sum_state[t] = sum_state[t] + l_o_l_sa[t][i]
	yip = len(l_o_l_sa[0])
	# qw = []
	er = ""
	val = 0.0
	for t in range(num_sub_tokens_label):
	sum_state[t] /= yip
	idx = torch.topk(sum_state[t], k=5, dim=0)[1]
	probs = F.softmax(sum_state[t], dim=0)
	wor = [tokenizer.decode(i.item()).strip() for i in idx]
	cnt = 0
	for kl in wor:
	if all(char.isalpha() for char in kl):
	# qw.append(kl.lower())
	er+=kl
	break
	cnt+=1
	val = val - torch.log(probs[idx[cnt]])
	val = val/num_sub_tokens_label
	vali = round(val.item(), 2)

	# print(er)
	# astr = ""
	# for j in range(len(qw)):
	# mock = ""
	# mock+= qw[j]
	# if (j+2) < len(qw) and ((mock+qw[j+1]+qw[j+2]) in eng_dict):
	# mock +=qw[j+1]
	# mock +=qw[j+2]
	# j = j+2
	# elif (j+1) < len(qw) and ((mock+qw[j+1]) in eng_dict):
	# mock +=qw[j+1]
	# j = j+1
	# if len(astr) == 0:
	# astr+=mock
	# else:
	# astr+=mock.capitalize()
	er = er+" (with PLL value of: "+str(vali)+")"
	return er, vali

	def meet(X):
	tot_pll = 100.00
	print_str = ""
	fin_out = "The highest confidence prediction is: "
	add_out = ""
	for r in range(6):
	er, pll = greet(X, 6-r)
	print_str+= er
	print_str+='\n'
	if (pll - tot_pll) > 0.1:
	break
	elif pll >= tot_pll:
	continue
	else:
	add_out = er
	tot_pll = pll
	print_str= print_str+fin_out+add_out
	return print_str

	title = "Rename a variable in a Java class"
	description = """This model is a fine-tuned GraphCodeBERT model fine-tuned to output higher-quality variable names for Java classes. Long classes are handled by the
	model. Replace any variable name with a "[MASK]" to get an identifier renaming.
	"""
	ex = [["""import java.io.*;
	public class x {
	public static void main(String[] args) {
	String f = "file.txt";
	BufferedReader [MASK] = null;
	String l;
	try {
	[MASK] = new BufferedReader(new FileReader(f));
	while ((l = [MASK].readLine()) != null) {
	System.out.println(l);
	}
	} catch (IOException e) {
	e.printStackTrace();
	} finally {
	try {
	if ([MASK] != null) [MASK].close();
	} catch (IOException ex) {
	ex.printStackTrace();
	}
	}
	}
	}"""], ["""import java.net.*;
	import java.io.*;

	public class s {
	public static void main(String[] args) throws IOException {
	ServerSocket [MASK] = new ServerSocket(8000);
	try {
	Socket s = [MASK].accept();
	PrintWriter pw = new PrintWriter(s.getOutputStream(), true);
	BufferedReader br = new BufferedReader(new InputStreamReader(s.getInputStream()));
	String i;
	while ((i = br.readLine()) != null) {
	pw.println(i);
	}
	} finally {
	if ([MASK] != null) [MASK].close();
	}
	}
	}"""], ["""import java.io.*;
	import java.util.*;

	public class y {
	public static void main(String[] args) {
	String [MASK] = "data.csv";
	String l = "";
	String cvsSplitBy = ",";
	try (BufferedReader br = new BufferedReader(new FileReader([MASK]))) {
	while ((l = br.readLine()) != null) {
	String[] z = l.split(cvsSplitBy);
	System.out.println("Values [field-1= " + z[0] + " , field-2=" + z[1] + "]");
	}
	} catch (IOException e) {
	e.printStackTrace();
	}
	}
	}"""]]
	# We instantiate the Textbox class
	textbox = gr.Textbox(label="Type Java code snippet:", placeholder="replace variable with [MASK]", lines=10)
	#textbox1 = gr.Textbox(label="Number of tokens in name:", placeholder="0 for randomly sampled number of tokens",lines=1)

	gr.Interface(title = title, description = description, examples = ex, fn=meet, inputs=[
	textbox
	], outputs="text").launch()


	# In[ ]: