Exemple #1
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	def spoofing(self, hostname, dns, rawdata, sock):
		fromip = self.client_address[0]
		for ipp,rev in self.server.resolvs:
			if match(ipp, fromip):
				for hnp,ip in rev:
					if match(hnp, hostname):
						return ip
				return self.queryip(hostname)
		return self.queryip(hostname)
Exemple #2
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def test_process():
    from util import read_file_to_list
    from util import match
    rules, rows = read_file_to_list("testinput.txt")

    assert 6 == len(rules)
    assert 5 == len(rows)

    assert True == match(rules, rows[0])
    assert False == match(rules, rows[1])
    assert True == match(rules, rows[2])
    assert False == match(rules, rows[3])
    assert False == match(rules, rows[4])
Exemple #3
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 def check(self, imgSrc) -> bool:
     self.imgSrc = ac.imread(imgSrc)
     res = util.match(self.imgSrc, self.imgSign, 0.9)
     if res != None :
         self.y0 = int(res['rectangle'][3][1] + 80*paras.SCALE)
         return True
     return False
Exemple #4
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 def match(self, text):
  """Personal match."""
  if text in ['i', 'me']:
   return self
  elif text == 'here':
   return self.location
  else:
   return util.match(text, set(self.contents + self.location.contents + [self.location, self]))
Exemple #5
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 def check(self, imgSrc) -> bool:
     self.imgSrc = ac.imread(imgSrc)
     res = util.match(self.imgSrc, self.imgSign)
     # print(res)
     if res != None :
         self.point = [int(res['result'][0]), int(res['result'][1])]
         return True
     return False
Exemple #6
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def test_process():
    from util import read_file_to_list
    from util import match
    rules, rows = read_file_to_list("testinput2.txt")

    valid = 0
    for row in rows:
        if match(rules, row):
            valid += 1
    assert valid == len(rows)
Exemple #7
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def test(task_name, func, subset='train'):
    with open(f'ARC/data/training/{task_name}.json') as f:
        j = json.load(f)

    correct = True
    for i, t in enumerate(j[subset]):
        input_grid = np.array(t['input'])
        pred = func(input_grid)
        # vis(pred)
        target = np.array(t['output'])
        correct &= match(pred, target)

    return correct
Exemple #8
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def processa_paises():

	who_doctors, who_nurses = util.read_pais()

	# remove duplicatas, deixando apenas os dados mais recentes
	util.drop_pais_dupl(who_doctors, "Country")
	util.drop_pais_dupl(who_nurses, "Country")
	
	# cada bloco a seguir cria um atributo da tabela final

	# a lista de paises nao eh igual entre os datasets
	# para igualar, concatenamos e fazemos os ajustes pertinentes
	nome = []
	nome_aux = pd.concat([who_doctors["Country"], who_nurses["Country"]], join='inner', ignore_index=True)
	nome_aux.drop_duplicates(inplace=True)
	nome_series = nome_aux.reset_index() # reseta indices
	nome_series.drop(["index"], axis=1, inplace=True) # remove indices antigos
	for i in range(len(nome_series)):
		nome.append(nome_series["Country"][i])
	nome.sort(key=str.lower) # organiza em ordem alfabetica 

	med_total = util.match(nome, who_doctors, "Medical doctors (number)", "Country")

	med_10k = util.match(nome, who_doctors, "Medical doctors (per 10 000 population)", "Country")

	enf_total = util.match(nome, who_nurses, "Nursing and midwifery personnel  (number)", "Country")

	enf_10k = util.match(nome, who_nurses, "Nursing and midwifery personnel (per 10 000 population)", "Country")

	dados = {'País': nome,
		'Profissionais de enfermagem - Total': enf_total,
		'Profissionais de enfermagem a cada 10k habitantes': enf_10k,
		'Médicos - Total': med_total,
		'Médicos a cada 10k habitantes': med_10k}

	df = pd.DataFrame(data=dados)
	util.write_to_csv(df, "Mundo (OMS)")
	stats.stats_paises(pd.read_csv("../data/processed/Mundo (OMS).csv"))
Exemple #9
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def test_match():
    s = '\n'
    s += str(util.match('abc', 'a'))
    s += '\n'
    s += str(util.match('abc123', 'bc'))
    s += '\n'
    s += str(util.match('abc123', '123'))
    s += '\n'
    s += str(util.match('abc 123', '\s'))
    s += '\n'
    s += str(util.match('abc 123xyz', '\d'))
    s += '\n'
    s += str(util.match('abc123', '^abc'))
    s += '\n'
    s += str(util.match('abc123', '^123'))
    s += '\n'
    s += str(util.match('abc', 'z'))
    return s
Exemple #10
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def test(task_name, func_string, subset='train'):
    with open(f'ARC/data/training/{task_name}.json') as f:
        j = json.load(f)

    prog = parse(func_string)

    correct = True
    for i, t in enumerate(j[subset]):
        input_grid = np.array(t['input'])
        prog_with_input = ['define', 'grid', input_grid, prog]
        pred = eval(prog_with_input)
        #print(pred)
        # vis(pred)
        target = np.array(t['output'])
        correct &= match(pred, target)

    return correct
Exemple #11
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    def answer(self):
        if self.problem is None:
            return

        answer = self.store.find(self.problem)
        if answer is None:
            print("answer not found")
            self.tapAnswer(0)
            self.captureAnswer()
        else:
            res = util.match(self.imgSrc, answer)
            if res is None:
                print("answer not match")
                self.tapAnswer(0)
                self.captureAnswer()
                return
            
            point = int(res['result'][0]), int(res['result'][1])
            #idx = util.findImg(self.answers, answer)
            #print("=====Find Answer!=====", idx)
            #self.tapAnswer(idx)
            print("======find answer======", point[0], point[1])
            self.tapPosition(point[0], point[1])
            time.sleep(1) #skip the middle status: right answer but wrong sign
Exemple #12
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def matchfind():
    surveyname = request.args.get('surveyname', '') #write JS method for this
    username = session['user']
    print surveyname, username
    return json.dumps(util.match(surveyname, username))
Exemple #13
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            noise = Variable(noise, volatile=True)  # total freeze netG
            y = Variable(netG(noise).data)

            f_enc_Y_D, f_dec_Y_D = netD(y)

            # compute biased MMD2 and use ReLU to prevent negative value
            mmd2_D = mix_rbf_mmd2(f_enc_X_D, f_enc_Y_D, sigma_list)
            mmd2_D = F.relu(mmd2_D)

            # compute rank hinge loss
            #print('f_enc_X_D:', f_enc_X_D.size())
            #print('f_enc_Y_D:', f_enc_Y_D.size())
            one_side_errD = one_sided(f_enc_X_D.mean(0) - f_enc_Y_D.mean(0))

            # compute L2-loss of AE
            L2_AE_X_D = util.match(x.view(batch_size, -1), f_dec_X_D, 'L2')
            L2_AE_Y_D = util.match(y.view(batch_size, -1), f_dec_Y_D, 'L2')

            errD = torch.sqrt(
                mmd2_D
            ) + lambda_rg * one_side_errD - lambda_AE_X * L2_AE_X_D - lambda_AE_Y * L2_AE_Y_D
            errD.backward(mone)
            optimizerD.step()

        # ---------------------------
        #        Optimize over NetG
        # ---------------------------
        for p in netD.parameters():
            p.requires_grad = False

        for j in range(Giters):
Exemple #14
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def matchfind():
    surveyname = request.args.get("surveyname", "")  # write JS method for this
    username = session["user"]
    print surveyname, username
    return json.dumps(util.match(surveyname, username))
Exemple #15
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 def button4Click(self):
     self.error = match(self.cfeats,self.rfm)
     self.button4["background"] = "lightgreen"
Exemple #16
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	def match_headers(self,headers,hijackheaders):
		for k,v in hijackheaders.items():
			if not k in headers or not match(v,headers[k]):
				return False
		return True
Exemple #17
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#   Lam [[Char]] expr
#   Word [Char]
#   Number Num
#   Character Char
App = lambda es: lambda app,lam,word,number,character:app(es)
Lam = lambda w,e: lambda app,lam,word,number,character:lam(w,e)
Word = lambda n: lambda app,lam,word,number,character:word(n)
Number = lambda d: lambda app,lam,word,number,character:number(d)
Character = lambda c: lambda app,lam,word,number,character:character(c)

getChildren = lambda n:n(Const([]),lambda _,la: la)
getName = lambda l: l(lambda t:t.d,lambda _,__:'')
toExprST = Y(lambda f: lambda tr:tr(
    lambda t:match(t.n)([
        ('T_word',lambda w: Word(t.d)),
        ('T_number',lambda d: Number(int(t.d))),
        ('T_char',lambda c: Character(t.d))
    ])(lambda a:Const(a)(print(a))),
    lambda b,la: match(b)([
        ('P_expr',lambda _: let(list(map(f,la)),lambda la:
            # fold(App)(la[0])(la[1:])
            App(la)
        )),
        ('P_abst',lambda _: let(list(map(getName,getChildren(la[0]))),lambda largs:
            Lam(largs,f(la[1]))
        ))
    ])(lambda a:Const(a)(print(a)))
))

# toListOfExprs as RoseTree Tok [Char] -> Maybe [([Char],expr)]
toListOfExprs  = lambda tr: (
Exemple #18
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                one_side_errD_thinned = one_sided(
                    f_enc_X_D.mean(0) - thinned_f_enc_Y_D.mean(0))
            except Exception as e:
                print('D: Thinning f_enc_Y: Error: {}'.format(e))
                pdb.set_trace()
            # Unthinned hinge loss.
            one_side_errD_unthinned = one_sided(
                f_enc_X_D.mean(0) - f_enc_Y_D.mean(0))
            # Choose which hinge loss you want.
            if not weighted:
                one_side_errD = one_side_errD_unthinned
            else:
                one_side_errD = one_side_errD_thinned

            # compute L2-loss of AE
            L2_AE_X_D = util.match(x.view(batch_size, -1), f_dec_X_D, 'L2')
            L2_AE_Y_D = util.match(y.view(batch_size, -1), f_dec_Y_D, 'L2')
            # Also compute AE loss on subsets of zeros and ones.
            try:
                if len(x_eval_1s) or len(x_eval_dec_1s):
                    L2_AE_X1_D = util.match(x_eval_1s.view(len(x_eval_1s), -1),
                                            x_eval_dec_1s, 'L2')
                else:
                    L2_AE_X1_D = Variable(
                        torch.from_numpy(np.array([0
                                                   ])).type(torch.FloatTensor))
            except Exception as e:
                print('D: Computing x1 ae error. Error: {}'.format(e))
                pdb.set_trace()
            try:
                if len(x_eval_0s) or len(x_eval_dec_0s):