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from sympy.ntheory import count_digits, digits, is_palindromic |
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from sympy.core.intfunc import num_digits |
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from sympy.testing.pytest import raises |
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def test_num_digits(): |
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assert num_digits(2, 2) == 2 |
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assert num_digits(2**48 - 1, 2) == 48 |
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assert num_digits(1000, 10) == 4 |
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assert num_digits(125, 5) == 4 |
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assert num_digits(100, 16) == 2 |
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assert num_digits(-1000, 10) == 4 |
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for base in range(2, 100): |
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for e in range(1, 100): |
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n = base**e |
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assert num_digits(n, base) == e + 1 |
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assert num_digits(n + 1, base) == e + 1 |
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assert num_digits(n - 1, base) == e |
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def test_digits(): |
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assert all(digits(n, 2)[1:] == [int(d) for d in format(n, 'b')] |
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for n in range(20)) |
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assert all(digits(n, 8)[1:] == [int(d) for d in format(n, 'o')] |
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for n in range(20)) |
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assert all(digits(n, 16)[1:] == [int(d, 16) for d in format(n, 'x')] |
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for n in range(20)) |
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assert digits(2345, 34) == [34, 2, 0, 33] |
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assert digits(384753, 71) == [71, 1, 5, 23, 4] |
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assert digits(93409, 10) == [10, 9, 3, 4, 0, 9] |
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assert digits(-92838, 11) == [-11, 6, 3, 8, 2, 9] |
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assert digits(35, 10) == [10, 3, 5] |
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assert digits(35, 10, 3) == [10, 0, 3, 5] |
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assert digits(-35, 10, 4) == [-10, 0, 0, 3, 5] |
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raises(ValueError, lambda: digits(2, 2, 1)) |
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def test_count_digits(): |
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assert count_digits(55, 2) == {1: 5, 0: 1} |
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assert count_digits(55, 10) == {5: 2} |
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n = count_digits(123) |
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assert n[4] == 0 and type(n[4]) is int |
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def test_is_palindromic(): |
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assert is_palindromic(-11) |
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assert is_palindromic(11) |
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assert is_palindromic(0o121, 8) |
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assert not is_palindromic(123) |
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