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test_ssn.py
1231 lines (997 loc) · 39.5 KB
/
test_ssn.py
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import random
import re
import unittest
from datetime import datetime
from itertools import cycle
from typing import Pattern, Tuple
from unittest import mock
import freezegun
import pytest
from validators.i18n.es import es_cif as is_cif
from validators.i18n.es import es_nie as is_nie
from validators.i18n.es import es_nif as is_nif
from faker import Faker
from faker.providers.ssn.el_GR import tin_checksum as gr_tin_checksum
from faker.providers.ssn.en_CA import checksum as ca_checksum
from faker.providers.ssn.es_CL import rut_check_digit as cl_rut_checksum
from faker.providers.ssn.es_CO import nit_check_digit
from faker.providers.ssn.es_MX import curp_checksum as mx_curp_checksum
from faker.providers.ssn.es_MX import ssn_checksum as mx_ssn_checksum
from faker.providers.ssn.et_EE import checksum as et_checksum
from faker.providers.ssn.fi_FI import Provider as fi_Provider
from faker.providers.ssn.fr_FR import calculate_checksum as fr_calculate_checksum
from faker.providers.ssn.hr_HR import checksum as hr_checksum
from faker.providers.ssn.it_IT import checksum as it_checksum
from faker.providers.ssn.no_NO import Provider as no_Provider
from faker.providers.ssn.no_NO import checksum as no_checksum
from faker.providers.ssn.pl_PL import calculate_month as pl_calculate_mouth
from faker.providers.ssn.pl_PL import checksum as pl_checksum
from faker.providers.ssn.pt_BR import checksum as pt_checksum
from faker.providers.ssn.ro_RO import ssn_checksum as ro_ssn_checksum
from faker.providers.ssn.ro_RO import vat_checksum as ro_vat_checksum
from faker.utils.checksums import luhn_checksum
class TestSvSE(unittest.TestCase):
def setUp(self):
self.fake = Faker("sv_SE")
Faker.seed(0)
def partial_sum(self, number, mult_factor):
quotient, remainder = divmod(number * mult_factor, 10)
return quotient + remainder
def ssn_checksum(self, ssn):
"""Validates the checksum digit and returns a Boolean"""
ssn = ssn.replace("-", "")
if len(ssn) == 12:
ssn = ssn[2:]
if len(ssn) != 10:
return False
mult_factors = cycle([2, 1])
final_sum = sum(self.partial_sum(int(char), mf) for char, mf in zip(ssn[:9], mult_factors))
chksum = -final_sum % 10
return chksum == int(ssn[-1])
def validate_date_string(self, date_str):
date_len = len(date_str)
if date_len == 6:
year_fmt = "%y"
elif date_len == 8:
year_fmt = "%Y"
else:
return False
try:
if date_str != datetime.strptime(date_str, f"{year_fmt}%m%d").strftime(f"{year_fmt}%m%d"):
raise ValueError
return True
except ValueError:
return False
def test_pers_id_short_with_dash(self):
"""Regression case that ensures previous implementations work as-is"""
for _ in range(100):
pers_id = self.fake.ssn()
assert re.search(r"\d{6}-\d{4}", pers_id)
assert self.validate_date_string(pers_id[:6]) is True
assert self.ssn_checksum(pers_id) is True
def test_pers_id_short_no_dash(self):
for _ in range(100):
pers_id = self.fake.ssn(dash=False)
assert re.search(r"\d{10}", pers_id)
assert self.validate_date_string(pers_id[:6]) is True
assert self.ssn_checksum(pers_id) is True
def test_pers_id_long_with_dash(self):
for _ in range(100):
pers_id = self.fake.ssn(long=True)
assert re.search(r"\d{8}-\d{4}", pers_id)
assert self.validate_date_string(pers_id[:8]) is True
assert self.ssn_checksum(pers_id) is True
def test_pers_id_long_no_dash(self):
for _ in range(100):
pers_id = self.fake.ssn(long=True, dash=False)
assert re.search(r"\d{12}", pers_id)
assert self.validate_date_string(pers_id[:8]) is True
assert self.ssn_checksum(pers_id) is True
def test_org_id_short_with_dash(self):
for _ in range(100):
org_id = self.fake.org_id()
assert re.search(r"\d{6}-\d{4}", org_id)
assert int(org_id[2:4]) >= 20
assert self.ssn_checksum(org_id) is True
def test_org_id_short_no_dash(self):
for _ in range(100):
org_id = self.fake.org_id(dash=False)
assert re.search(r"\d{10}", org_id)
assert int(org_id[2:4]) >= 20
assert self.ssn_checksum(org_id) is True
def test_org_id_long_with_dash(self):
for _ in range(100):
org_id = self.fake.org_id(long=True)
assert re.search(r"\d{8}-\d{4}", org_id)
assert int(org_id[4:6]) >= 20
assert self.ssn_checksum(org_id) is True
def test_org_id_long_no_dash(self):
for _ in range(100):
org_id = self.fake.org_id(long=True, dash=False)
assert re.search(r"\d{12}", org_id)
assert int(org_id[4:6]) >= 20
assert self.ssn_checksum(org_id) is True
def test_vat_id(self):
for _ in range(100):
vat_id = self.fake.vat_id()
assert re.search(r"SE\d{12}", vat_id)
assert int(vat_id[2]) in (1, 2, 3, 5, 6, 7, 8, 9)
assert int(vat_id[6:8]) >= 20
def test_org_and_vat_id(self):
for _ in range(100):
oid, vid = self.fake.org_and_vat_id()
assert oid.replace("-", "")[-10:] == vid[4:-2]
assert re.search(r"SE\d{12}", vid)
class TestBgBG(unittest.TestCase):
def setUp(self):
self.fake = Faker("bg_BG")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^BG\d{9,10}$", self.fake.vat_id())
class TestCsCZ(unittest.TestCase):
def setUp(self):
self.fake = Faker("cs_CZ")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^CZ\d{8,10}$", self.fake.vat_id())
def test_birth_number(self):
for _ in range(100):
birth_number = self.fake.birth_number()
assert len(birth_number) in [10, 11]
assert birth_number[6] == "/"
assert int(birth_number.replace("/", "")) % 11 == 0
class TestSkSK(unittest.TestCase):
def setUp(self):
self.fake = Faker("sk_SK")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^SK\d{10}$", self.fake.vat_id())
def test_birth_number(self):
for _ in range(100):
birth_number = self.fake.birth_number()
assert len(birth_number) in [10, 11]
assert birth_number[6] == "/"
assert int(birth_number.replace("/", "")) % 11 == 0
class TestDeAT(unittest.TestCase):
def setUp(self):
self.fake = Faker("de_AT")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^ATU\d{8}$", self.fake.vat_id())
class TestElCY(unittest.TestCase):
def setUp(self):
self.fake = Faker("el_CY")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^CY\d{9}\w$", self.fake.vat_id())
class TestElGr(unittest.TestCase):
def setUp(self):
self.fake = Faker("el_GR")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
prefix = random.choice([True, False])
vat_id = self.fake.vat_id(prefix=prefix)
assert re.search(r"^(EL)?\d{9}$", vat_id)
assert vat_id[2 if prefix else 0] in ("7", "8", "9", "0")
assert str(gr_tin_checksum(vat_id[2:-1] if prefix else vat_id[:-1])) == vat_id[-1]
def test_tin(self):
for _ in range(100):
tin = self.fake.tin()
assert re.search(r"^\d{9}$", tin)
assert tin[0] in ("1", "2", "3", "4")
assert str(gr_tin_checksum(tin[:-1])) == tin[-1]
def test_ssn(self):
for _ in range(100):
ssn = self.fake.ssn()
assert re.search(r"^\d{11}$", ssn)
assert datetime.strptime(ssn[:6], "%d%m%y")
assert luhn_checksum(ssn) == 0
def test_police_id(self):
for _ in range(100):
assert re.search(r"^[ΑΒΕΖΗΙΚΜΝΟΡΤΥΧ]{1,2}\d{6}$", self.fake.police_id())
class TestEnCA(unittest.TestCase):
def setUp(self):
self.fake = Faker("en_CA")
Faker.seed(0)
def test_ssn(self):
for _ in range(100):
sin = self.fake.ssn()
# Ensure that generated SINs are 11 characters long
# including spaces, consist of spaces and digits only, and
# satisfy the validation algorithm.
assert len(sin) == 11
assert sin.replace(" ", "").isdigit()
assert ca_checksum(sin) == int(sin[-1])
class TestEnUS(unittest.TestCase):
def setUp(self):
self.fake = Faker("en_US")
Faker.seed(0)
def test_ssn(self):
for _ in range(100):
ssn = self.fake.ssn(taxpayer_identification_number_type="SSN")
# Ensure that generated SINs are 11 characters long
# including dashes, consist of dashes and digits only, and
# satisfy these requirements:
#
# An United States Social Security Number
# (SSN) is a tax processing number issued by the Internal
# Revenue Service with the format "AAA-GG-SSSS". The
# number is divided into three parts: the first three
# digits, known as the area number because they were
# formerly assigned by geographical region; the middle two
# digits, known as the group number; and the final four
# digits, known as the serial number. SSNs with the
# following characteristics are not allocated:
#
# 1) Numbers with all zeros in any digit group
# (000-##-####, ###-00-####, ###-##-0000).
#
# 2) Numbers with 666 or 900-999 in the first digit group.
#
# https://en.wikipedia.org/wiki/Social_Security_number
assert len(ssn) == 11
assert ssn.replace("-", "").isdigit()
[area, group, serial] = ssn.split("-")
assert 1 <= int(area) <= 899 and int(area) != 666
assert 1 <= int(group) <= 99
assert 1 <= int(serial) <= 9999
assert area != "666"
def test_invalid_ssn(self):
# Magic Numbers below generate '666-92-7944', '000-54-2963', '956-GG-9478', '436-00-1386',
# and 134-76-0000 respectively. The "group" (GG) returned for '956-GG-9478 will be a random
# number, and that random number is not in the "itin_group_numbers" List. The random GG occurs
# even when using the same seed_instance() due to using random.choice() for GG to avoid valid
# ITINs being returned as an invalid SSN:
#
# Ensure that generated SSNs are 11 characters long
# including dashes, consist of dashes and digits only, and the tested number
# violates the requirements below, ensuring an INVALID SSN is returned:
#
# A United States Social Security Number
# (SSN) is a tax processing number issued by the Internal
# Revenue Service with the format "AAA-GG-SSSS". The
# number is divided into three parts: the first three
# digits, known as the area number because they were
# formerly assigned by geographical region; the middle two
# digits, known as the group number; and the final four
# digits, known as the serial number. SSNs with the
# following characteristics are not allocated:
#
# 1) Numbers with all zeros in any digit group
# (000-##-####, ###-00-####, ###-##-0000).
#
# 2) Numbers with 666 or 900-999 in the first digit group.
#
# https://en.wikipedia.org/wiki/Social_Security_number
#
# ITIN explained:
# https://www.irs.gov/individuals/international-taxpayers/general-itin-information
itin_group_numbers = [
70,
71,
72,
73,
74,
75,
76,
77,
78,
79,
80,
81,
82,
83,
84,
85,
86,
87,
88,
90,
91,
92,
94,
95,
96,
97,
98,
99,
]
self.fake.seed_instance(2432)
ssn = self.fake.ssn(taxpayer_identification_number_type="INVALID_SSN")
assert len(ssn) == 11
assert ssn.replace("-", "").isdigit()
assert ssn.startswith("666")
self.fake.seed_instance(1514)
ssn = self.fake.ssn(taxpayer_identification_number_type="INVALID_SSN")
assert ssn.startswith("000")
self.fake.seed_instance(2)
ssn = self.fake.ssn(taxpayer_identification_number_type="INVALID_SSN")
[area, group, serial] = ssn.split("-")
assert 900 <= int(area) <= 999 and int(group) not in itin_group_numbers
self.fake.seed_instance(0)
ssn = self.fake.ssn(taxpayer_identification_number_type="INVALID_SSN")
[area, group, serial] = ssn.split("-")
assert int(area) < 900 and int(group) == 0
self.fake.seed_instance(1)
ssn = self.fake.ssn(taxpayer_identification_number_type="INVALID_SSN")
[area, group, serial] = ssn.split("-")
assert int(area) < 900 and int(serial) == 0
def test_prohibited_ssn_value(self):
# 666 is a prohibited value. The magic number selected as a seed
# is one that would (if not specifically checked for) return an
# SSN with an area of '666'.
Faker.seed(19031)
ssn = self.fake.ssn()
[area, group, serial] = ssn.split("-")
assert area != "666"
def test_itin(self):
for _ in range(100):
itin = self.fake.ssn(taxpayer_identification_number_type="ITIN")
# Ensure that generated SINs are 11 characters long
# including dashes, consist of dashes and digits only, and
# satisfy these requirements:
#
# An United States Individual Taxpayer Identification Number
# (ITIN) is a tax processing number issued by the Internal
# Revenue Service. It is a nine-digit number that always begins
# with the number 9 and has a range of 70-88 in the fourth and
# fifth digit. Effective April 12, 2011, the range was extended
# to include 900-70-0000 through 999-88-9999, 900-90-0000
# through 999-92-9999 and 900-94-0000 through 999-99-9999.
# https://www.irs.gov/individuals/international-taxpayers/general-itin-information
assert len(itin) == 11
assert itin.replace("-", "").isdigit()
[area, group, serial] = itin.split("-")
assert 900 <= int(area) <= 999
assert 70 <= int(group) <= 88 or 90 <= int(group) <= 92 or 94 <= int(group) <= 99
assert 0 <= int(serial) <= 9999
def test_ein(self):
ein_prefix_choices = [
"01",
"02",
"03",
"04",
"05",
"06",
"10",
"11",
"12",
"13",
"14",
"15",
"16",
"20",
"21",
"22",
"23",
"24",
"25",
"26",
"27",
"30",
"31",
"32",
"33",
"34",
"35",
"36",
"37",
"38",
"39",
"40",
"41",
"42",
"43",
"44",
"45",
"46",
"47",
"48",
"50",
"51",
"52",
"53",
"54",
"55",
"56",
"57",
"58",
"59",
"60",
"61",
"62",
"63",
"64",
"65",
"66",
"67",
"68",
"71",
"72",
"73",
"74",
"75",
"76",
"77",
"80",
"81",
"82",
"83",
"84",
"85",
"86",
"87",
"88",
"90",
"91",
"92",
"93",
"94",
"95",
"98",
"99",
]
for _ in range(100):
ein = self.fake.ssn(taxpayer_identification_number_type="EIN")
# An United States An Employer Identification Number (EIN) is
# also known as a Federal Tax Identification Number, and is
# used to identify a business entity. EINs follow a format of a
# two-digit prefix followed by a hyphen and a seven-digit sequence.
# https://www.irs.gov/businesses/small-businesses-self-employed/employer-id-numbers
#
# Ensure that generated EINs are 10 characters long
# including a dash, consist of dashes and digits only, and
# satisfy these requirements:
#
# There are only certain EIN Prefix values assigned:
# https://www.irs.gov/businesses/small-businesses-self-employed/how-eins-are-assigned-and-valid-ein-prefixes
assert len(ein) == 10
assert ein.replace("-", "").isdigit()
[prefix, sequence] = ein.split("-")
assert prefix in ein_prefix_choices
assert 0 <= int(sequence) <= 9999999
def test_bad_tin_type(self):
with self.assertRaises(ValueError):
self.fake.ssn(taxpayer_identification_number_type="badValue")
def test_wrong_tin_type_case(self):
with self.assertRaises(ValueError):
self.fake.ssn(taxpayer_identification_number_type="ssn")
class TestEsCO(unittest.TestCase):
def setUp(self):
self._NUIP_REGEX: Pattern = re.compile(r"1[012]\d{8}|[1-9]\d{6,7}")
self._NATURAL_PERSON_NIT_REGEX: Pattern = self._NUIP_REGEX
self._CHECK_DIGIT_REGEX: Pattern = re.compile(r"\d")
self._LEGAL_PERSON_NIT_REGEX: Pattern = re.compile(r"[89]\d{8}")
self.fake = Faker("es_CO")
Faker.seed(0)
def test_nuip(self):
for _ in range(100):
assert self._NUIP_REGEX.fullmatch(self.fake.nuip())
assert self._NUIP_REGEX.fullmatch(self.fake.natural_person_nit())
def test_natural_person_nit_with_check_digit(self):
for _ in range(100):
natural_person_nit, check_digit = self.fake.natural_person_nit_with_check_digit().split("-")
assert self._NATURAL_PERSON_NIT_REGEX.fullmatch(natural_person_nit)
assert self._CHECK_DIGIT_REGEX.fullmatch(check_digit)
assert nit_check_digit(natural_person_nit) == check_digit
def test_legal_person_nit(self):
for _ in range(100):
assert self._LEGAL_PERSON_NIT_REGEX.fullmatch(self.fake.legal_person_nit())
def test_legal_person_nit_with_check_digit(self):
for _ in range(100):
legal_person_nit, check_digit = self.fake.legal_person_nit_with_check_digit().split("-")
assert self._LEGAL_PERSON_NIT_REGEX.fullmatch(legal_person_nit)
assert self._CHECK_DIGIT_REGEX.fullmatch(check_digit)
assert nit_check_digit(legal_person_nit) == check_digit
def test_nit_check_digit(self):
# NITs and check digits of some Colombian state entities.
# Source: <https://www.funcionpublica.gov.co/web/sigep/entidades>
for nit, check_digit in (
("830040256", "0"),
("899999003", "1"),
("892301483", "2"),
("800194600", "3"),
("899999403", "4"),
("860042945", "5"),
("830114475", "6"),
("811000231", "7"),
("899999027", "8"),
("900639630", "9"),
):
with self.subTest(nit=nit, check_digit=check_digit):
assert nit_check_digit(nit) == check_digit
class TestEsES(unittest.TestCase):
def setUp(self):
self.fake = Faker("es_ES")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^ES\w\d{8}$|^ES\d{8}\w$|^ES\w\d{7}\w$", self.fake.vat_id())
def test_nie(self):
for _ in range(100):
assert is_nie(self.fake.nie())
def test_nif(self):
for _ in range(100):
assert is_nif(self.fake.nif())
def test_cif(self):
for _ in range(100):
assert is_cif(self.fake.cif())
def test_doi(self):
assert len(self.fake.doi()) == 9
class TestEsCA(TestEsES):
def setUp(self):
self.fake = Faker("es_CA")
Faker.seed(0)
class TestEsMX(unittest.TestCase):
def setUp(self):
self.fake = Faker("es_MX")
Faker.seed(0)
def test_ssn(self):
for _ in range(100):
ssn = self.fake.ssn()
assert len(ssn) == 11
assert ssn.isnumeric()
assert mx_ssn_checksum(map(int, ssn[:-1])) == int(ssn[-1])
def test_curp(self):
for _ in range(100):
curp = self.fake.curp()
assert len(curp) == 18
assert re.search(r"^[A-Z]{4}\d{6}[A-Z]{6}[0A]\d$", curp)
assert mx_curp_checksum(curp[:-1]) == int(curp[-1])
def test_rfc_natural(self):
for _ in range(100):
rfc = self.fake.rfc()
assert len(rfc) == 13
assert re.search(r"^[A-Z]{4}\d{6}[0-9A-Z]{3}$", rfc)
def test_rfc_legal(self):
for _ in range(100):
rfc = self.fake.rfc(natural=False)
assert len(rfc) == 12
assert re.search(r"^[A-Z]{3}\d{6}[0-9A-Z]{3}$", rfc)
class TestEsCL(unittest.TestCase):
def setUp(self):
self.fake = Faker("es_CL")
Faker.seed(0)
def test_rut(self):
for _ in range(100):
rut = self.fake.rut(min=10000000)
digits, check_digit = self._extract_digits(rut)
assert len(rut) == 12
assert check_digit == cl_rut_checksum(digits)
@staticmethod
def _extract_digits(rut) -> Tuple[int, str]:
"""Extracts the digits and check digit from a formatted RUT."""
char_filter = re.compile(r"[^0-9]")
check_digit = rut[-1]
digits = char_filter.sub("", rut[:-1])
return int(digits), check_digit
class TestEtEE(unittest.TestCase):
"""Tests SSN in the et_EE locale"""
def setUp(self):
self.fake = Faker("et_EE")
Faker.seed(0)
def test_ssn_checksum(self):
assert et_checksum([4, 4, 1, 1, 1, 3, 0, 4, 9, 2]) == 3
assert et_checksum([3, 6, 7, 0, 1, 1, 6, 6, 2, 7]) == 8
assert et_checksum([4, 7, 0, 0, 4, 2, 1, 5, 0, 1]) == 2
assert et_checksum([3, 9, 7, 0, 3, 0, 4, 3, 3, 6]) == 0
@freezegun.freeze_time("2019-03-11")
def test_ssn(self):
self.fake.seed_instance(1)
value = self.fake.ssn()
assert re.search(r"^\d{11}$", value)
assert not value.endswith("0")
self.fake.seed_instance(0)
value = self.fake.ssn()
assert re.search(r"^\d{11}$", value)
assert value.endswith("0")
@freezegun.freeze_time("2002-01-01")
def test_ssn_2000(self):
self.fake.seed_instance(0)
value = self.fake.ssn(min_age=0, max_age=1)
assert re.search(r"^\d{11}$", value)
assert value[0] in ("5", "6")
@freezegun.freeze_time("2101-01-01")
def test_ssn_2100(self):
self.fake.seed_instance(0)
value = self.fake.ssn(min_age=0, max_age=1)
assert re.search(r"^\d{11}$", value)
assert value[0] in ("7", "8")
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^EE\d{9}$", self.fake.vat_id())
class TestFiFI(unittest.TestCase):
"""Tests SSN in the fi_FI locale"""
def setUp(self):
self.fake = Faker("fi_FI")
Faker.seed(0)
self.provider = fi_Provider
def test_century_code(self):
assert self.provider._get_century_code(1900) == "-"
assert self.provider._get_century_code(1999) == "-"
assert self.provider._get_century_code(2000) == "A"
assert self.provider._get_century_code(2999) == "A"
assert self.provider._get_century_code(1800) == "+"
assert self.provider._get_century_code(1899) == "+"
with pytest.raises(ValueError):
self.provider._get_century_code(1799)
with pytest.raises(ValueError):
self.provider._get_century_code(3000)
def test_ssn_sanity(self):
for age in range(100):
self.fake.ssn(min_age=age, max_age=age + 1)
def test_valid_ssn(self):
ssn = self.fake.ssn(artificial=False)
individual_number = int(ssn[7:10])
assert individual_number <= 899
def test_artifical_ssn(self):
ssn = self.fake.ssn(artificial=True)
individual_number = int(ssn[7:10])
assert individual_number >= 900
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^FI\d{8}$", self.fake.vat_id())
class TestFrFR(unittest.TestCase):
def setUp(self):
self.fake = Faker("fr_FR")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^FR[\w\d]{2} \d{9}$", self.fake.vat_id())
def test_ssn(self) -> None:
for _ in range(100):
assert re.search(r"^\d{15}$", self.fake.ssn())
def test_checksum(self) -> None:
assert fr_calculate_checksum(2570533063999) == 3
class TestFrCH:
@pytest.mark.parametrize(
"digits,expected",
[
("22500105", "CHE225001055"),
("60362354", "CHE603623540"),
("36806684", "CHE368066842"),
],
ids=[
"checksum_remainder_11",
"checksum_remainder_10",
"checksum_remainder_other",
],
)
def test_checksum(self, digits, expected):
"""The checksum of the Swiss UID number is calculated correctly
given a certain input of 8 digits."""
fake = Faker("fr_CH")
Faker.seed(0)
with mock.patch(
"faker.providers.ssn.fr_CH.Provider.numerify",
return_value=digits,
autospec=True,
):
result = fake.vat_id()
assert result == expected
class TestEnGB(unittest.TestCase):
def setUp(self):
self.fake = Faker("en_GB")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(
r"^GB\d{3} \d{4} \d{2}(?: \d{3})?$|^GB(?:GD|HA)\d{3}$",
self.fake.vat_id(),
)
class TestHrHR(unittest.TestCase):
"""Tests SSN in the hr_HR locale"""
def setUp(self):
self.fake = Faker("hr_HR")
Faker.seed(0)
def test_ssn_checksum(self):
assert hr_checksum([0, 0, 2, 2, 8, 2, 6, 9, 2, 8]) == 9
assert hr_checksum([5, 8, 9, 3, 6, 9, 5, 1, 2, 5]) == 1
assert hr_checksum([5, 7, 8, 0, 2, 0, 3, 4, 2, 3]) == 7
assert hr_checksum([4, 3, 3, 3, 1, 4, 6, 7, 6, 2]) == 2
assert hr_checksum([0, 5, 9, 3, 7, 7, 5, 9, 1, 8]) == 7
assert hr_checksum([7, 1, 1, 4, 9, 9, 1, 2, 4, 1]) == 6
def test_ssn(self):
for _ in range(100):
assert re.search(r"^\d{11}$", self.fake.ssn())
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^HR\d{11}$", self.fake.vat_id())
class TestHuHU(unittest.TestCase):
def setUp(self):
self.fake = Faker("hu_HU")
Faker.seed(0)
def test_ssn(self):
for _ in range(100):
ssn = self.fake.ssn()
assert ssn.isdigit()
assert len(ssn) >= 10
assert len(ssn) <= 12
for _ in range(100):
dob_val = (
f"{self.fake.random_int(0, 99):02d}"
f"{self.fake.random_int(1, 12):02d}"
f"{self.fake.random_int(1, 31):02d}"
)
dob = self.fake.random.choice([None, dob_val])
gender = self.fake.random.choice([None, "F", "M", "z"])
try:
ssn = self.fake.ssn(dob=dob, gender=gender)
assert ssn.isdigit()
assert len(ssn) >= 10
assert len(ssn) <= 12
except ValueError:
pass
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^HU\d{8}$", self.fake.vat_id())
class TestItIT(unittest.TestCase):
def setUp(self):
self.fake = Faker("it_IT")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^IT\d{11}$", self.fake.vat_id())
def test_ssn(self):
for _ in range(100):
assert re.search(r"^[A-Z]{6}\d{2}[ABCDEHLMPRST][0-7]\d[A-Z]\d{3}[A-Z]$", self.fake.ssn())
def test_checksum(self) -> None:
assert it_checksum("MDDMRA80L41H501") == "R"
class TestPtBR(unittest.TestCase):
def setUp(self):
self.fake = Faker("pt_BR")
Faker.seed(0)
def test_pt_BR_ssn_checksum(self):
assert pt_checksum([8, 8, 2, 8, 2, 1, 6, 5, 2]) == 2
assert pt_checksum([8, 8, 2, 8, 2, 1, 6, 5, 2, 2]) == 0
def test_pt_BR_ssn(self):
for _ in range(100):
assert re.search(r"^\d{11}$", self.fake.ssn())
def test_pt_BR_cpf(self):
for _ in range(100):
assert re.search(r"\d{3}\.\d{3}\.\d{3}-\d{2}", self.fake.cpf())
def test_pt_BR_rg(self):
for _ in range(100):
to_test = self.fake.rg()
if "X" in to_test:
assert re.search(r"^\d{8}X", to_test)
else:
assert re.search(r"^\d{9}$", to_test)
class TestNlBE(unittest.TestCase):
def setUp(self):
self.fake = Faker("nl_BE")
Faker.seed(0)
def test_ssn(self):
for _ in range(1000):
ssn = self.fake.ssn()
assert len(ssn) == 11
gen_seq = ssn[6:9]
gen_chksum = ssn[9:11]
gen_seq_as_int = int(gen_seq)
gen_chksum_as_int = int(gen_chksum)
# Check that the sequence nr is between 1 inclusive and 998 inclusive
assert gen_seq_as_int > 0
assert gen_seq_as_int <= 998
# validate checksum calculation
# Since the century is not part of ssn, try both below and above year 2000
ssn_below = int(ssn[0:9])
chksum_below = 97 - (ssn_below % 97)
ssn_above = ssn_below + 2000000000
chksum_above = 97 - (ssn_above % 97)
results = [chksum_above, chksum_below]
assert gen_chksum_as_int in results
class TestNlNL(unittest.TestCase):
def setUp(self):
self.fake = Faker("nl_NL")
Faker.seed(0)
def test_vat_id(self):
for _ in range(100):
assert re.search(r"^NL\d{9}B\d{2}$", self.fake.vat_id())
class TestNoNO(unittest.TestCase):
def setUp(self):
self.fake = Faker("no_NO")
Faker.seed(0)
def test_no_NO_ssn_checksum(self):
assert no_checksum([0, 1, 0, 2, 0, 3, 9, 8, 7], no_Provider.scale1) == 6
assert no_checksum([0, 1, 0, 2, 0, 3, 9, 8, 7, 6], no_Provider.scale2) == 7
def test_no_NO_ssn(self):
for _ in range(100):
ssn = self.fake.ssn()
assert ssn.isdigit()
assert len(ssn) == 11
def test_no_NO_ssn_dob_passed(self):
test_data = [("20010203", "030201"), ("19991231", "311299")]
for date_of_birth, expected_dob_part in test_data:
ssn = self.fake.ssn(dob=date_of_birth)
assert ssn[:6] == expected_dob_part
def test_no_NO_ssn_invalid_dob_passed(self):
with pytest.raises(ValueError):
self.fake.ssn(dob="010401")
with pytest.raises(ValueError):
self.fake.ssn(dob="hello_world")
with pytest.raises(ValueError):
self.fake.ssn(dob="001301")
def test_no_NO_ssn_gender_passed(self):