147 lines
4.6 KiB
Markdown
147 lines
4.6 KiB
Markdown
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---
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title: Python Integers
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---
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The theoretical domain for integers in python is negative infinity to infinity. In practice, integer values are limited by the amount of available memory.
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In Python 2, there was a distinction between **`int`**, numbers that fit in a 32 or 64 bit _C long_, and **`long`**, numbers limited by available memory. Python 3 unified the two types into just **`int`**, more info in <a href='https://www.python.org/dev/peps/pep-0237/' target='_blank' rel='nofollow'>PEP 237</a>.
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**`int` creation using integer literals**
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<a href='https://docs.python.org/3/reference/lexical_analysis.html#integer-literals' target='_blank' rel='nofollow'>Integer Literals</a>
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_Integer objects_ can be created using using integer literals. Unadorned numbers without decimals are integer literals:
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>>> 1234567890 # Unadorned numbers are integer literals
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1234567890
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>>> type(1234567890)
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<class 'int'>
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Numeric literals do not contain a sign, however creating negative _integer objects_ is possible by prefixing with a unary `-` (minus) operator with no space before the literal:
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>>> -1234567890
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-1234567890
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>>> type(-1234567890)
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<class 'int'>
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Likewise, positive integer objects can be created by prefixing a unary `+` (plus) operator with no space before the digits. Usually `+` is ommited:
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>>> +1234
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1234
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Binary (base 2, prefix: `0b` or `0B`), octal (base 8, prefix: `0o` or `0O`), and hexadecimal (base 16, prefix: `0x` or `0X`) integers can also be created using integer literals:
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>>> 0b1, 0b10, 0b11
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(1, 2, 3)
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>>> 0o1, 0o10, 0o11
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(1, 8, 9)
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>>> 0x1, 0x10, 0x11
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(1, 16, 17)
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Note that leading 0's for non-zero integer literals are **not allowed**:
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>>> 0 # Zero by itself is okay.
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0
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>>> 01 # Leading zero(s) cause SyntaxError.
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File "<stdin>", line 1
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01
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^
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SyntaxError: invalid token
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The `int` <a href='https://docs.python.org/3/library/functions.html#int' target='_blank' rel='nofollow'>constructor</a> is another way to create _integer objects_.
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class int(x=0)
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class int(x, base=10)
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Creating _integer objects_ with integer literals is preferred when possible:
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>>> a = 1 # Prefer integer literal when possible.
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>>> type(a)
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<class 'int'>
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>>> b = int(1) # Works but unnecessary.
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>>> type(b)
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<class 'int'>
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However, the constructor allows for creating _integer objects_ from other number types:
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>>> a = 1.123
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>>> type(a)
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<class 'float'>
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>>> print(a)
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1.123
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>>> b = int(1.123)
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>>> type(b)
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<class 'int'>
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>>> print(b)
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1
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Using the `int` constructor for floating point numbers will truncate the number towards zero:
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>>> int(-1.23)
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-1
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>>> int(1.23)
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1
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The built-in `boolean` constants are instances of the `bool` class, and are subclasses of the `int` class, making them a kind of numeric type:
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>>> type(True)
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<class 'bool'>
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>>> issubclass(bool, int)
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True
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If that doesn't make sense to you, don't worry. For now just remember that calling the int constructor with `boolean` objects will return _integer objects_:
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>>> int(True)
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1
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>>> int(False)
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0
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The `int` constructor will also make _integer objects_ from strings:
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>>> a = "10"
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>>> type(a)
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<class 'str'>
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>>> b = int("10")
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>>> type(b)
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<class 'int'>
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_Strings_ for the `int` constructor must represent an integer literal:
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The second parameter of the `int` constructor is to specify a base (default: 10). Valid bases are 0 and 2-36.
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If an explicit base is provided the first argument must be a string.
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>>> int("111", 2)
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7
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>>> int(111, 2)
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Traceback (most recent call last):
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File "<stdin>", line 1, in <module>
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TypeError: int() can't convert non-string with explicit base
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The string used for the `int` constructor with an explicit base must be a valid integer literal for that base:
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>>> int('11', 2)
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3
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>>> int('12', 2)
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Traceback (most recent call last):
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File "<stdin>", line 1, in <module>
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ValueError: invalid literal for int() with base 2: '12'
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Both prefixed and non-prefixed strings of integer literals can be used, however, if used, the prefix must match the provided base.
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>>> int('1101', 2)
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13
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>>> int('0b1101', 2)
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13
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>>> int('0x1101', 2)
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Traceback (most recent call last):
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File "<stdin>", line 1, in <module>
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ValueError: invalid literal for int() with base 2: '0x1101'
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If a prefixed string and base 0 is used, the created integer object will use the base specified by the prefix. If no prefix is used, then the base is assumed 10
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>>> int('100', 0)
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100
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>>> int('0b100', 0)
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4
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>>> int('0o100', 0)
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64
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