Exploring and understanding Python through surprising snippets.
-
-
Translations: [Chinese 中文](https://github.com/leisurelicht/wtfpython-cn) | [Vietnamese Tiếng Việt](https://github.com/vuduclyunitn/wtfptyhon-vi) | [Spanish Español](https://web.archive.org/web/20220511161045/https://github.com/JoseDeFreitas/wtfpython-es) | [Korean 한국어](https://github.com/buttercrab/wtfpython-ko) | [Russian Русский](https://github.com/satwikkansal/wtfpython/tree/master/translations/ru-russian) | [German Deutsch](https://github.com/BenSt099/wtfpython) | [Add translation](https://github.com/satwikkansal/wtfpython/issues/new?title=Add%20translation%20for%20[LANGUAGE]&body=Expected%20time%20to%20finish:%20[X]%20weeks.%20I%27ll%20start%20working%20on%20it%20from%20[Y].)
Other modes: [Interactive Website](https://wtfpython-interactive.vercel.app) | [Interactive Notebook](https://colab.research.google.com/github/satwikkansal/wtfpython/blob/master/irrelevant/wtf.ipynb)
@@ -22,7 +20,7 @@ While some of the examples you see below may not be WTFs in the truest sense, bu
If you're an experienced Python programmer, you can take it as a challenge to get most of them right in the first attempt. You may have already experienced some of them before, and I might be able to revive sweet old memories of yours! :sweat_smile:
-PS: If you're a returning reader, you can learn about the new modifications [here](https://github.com/satwikkansal/wtfpython/releases/) (the examples marked with asterisk are the ones added in the latest major revision).
+PS: If you're a returning reader, you can learn about the new modifications [here](https://github.com/satwikkansal/wtfpython/releases/) (the examples marked with asterisk are the ones added in the latest major revision).
So, here we go...
@@ -33,83 +31,83 @@ So, here we go...
- [Structure of the Examples](#structure-of-the-examples)
- + [▶ Some fancy Title](#-some-fancy-title)
+ - [▶ Some fancy Title](#-some-fancy-title)
- [Usage](#usage)
- [👀 Examples](#-examples)
- * [Section: Strain your brain!](#section-strain-your-brain)
- + [▶ First things first! *](#-first-things-first-)
- + [▶ Strings can be tricky sometimes](#-strings-can-be-tricky-sometimes)
- + [▶ Be careful with chained operations](#-be-careful-with-chained-operations)
- + [▶ How not to use `is` operator](#-how-not-to-use-is-operator)
- + [▶ Hash brownies](#-hash-brownies)
- + [▶ Deep down, we're all the same.](#-deep-down-were-all-the-same)
- + [▶ Disorder within order *](#-disorder-within-order-)
- + [▶ Keep trying... *](#-keep-trying-)
- + [▶ For what?](#-for-what)
- + [▶ Evaluation time discrepancy](#-evaluation-time-discrepancy)
- + [▶ `is not ...` is not `is (not ...)`](#-is-not--is-not-is-not-)
- + [▶ A tic-tac-toe where X wins in the first attempt!](#-a-tic-tac-toe-where-x-wins-in-the-first-attempt)
- + [▶ Schrödinger's variable](#-schrödingers-variable-)
- + [▶ The chicken-egg problem *](#-the-chicken-egg-problem-)
- + [▶ Subclass relationships](#-subclass-relationships)
- + [▶ Methods equality and identity](#-methods-equality-and-identity)
- + [▶ All-true-ation *](#-all-true-ation-)
- + [▶ The surprising comma](#-the-surprising-comma)
- + [▶ Strings and the backslashes](#-strings-and-the-backslashes)
- + [▶ not knot!](#-not-knot)
- + [▶ Half triple-quoted strings](#-half-triple-quoted-strings)
- + [▶ What's wrong with booleans?](#-whats-wrong-with-booleans)
- + [▶ Class attributes and instance attributes](#-class-attributes-and-instance-attributes)
- + [▶ yielding None](#-yielding-none)
- + [▶ Yielding from... return! *](#-yielding-from-return-)
- + [▶ Nan-reflexivity *](#-nan-reflexivity-)
- + [▶ Mutating the immutable!](#-mutating-the-immutable)
- + [▶ The disappearing variable from outer scope](#-the-disappearing-variable-from-outer-scope)
- + [▶ The mysterious key type conversion](#-the-mysterious-key-type-conversion)
- + [▶ Let's see if you can guess this?](#-lets-see-if-you-can-guess-this)
- + [▶ Exceeds the limit for integer string conversion](#-exceeds-the-limit-for-integer-string-conversion)
- * [Section: Slippery Slopes](#section-slippery-slopes)
- + [▶ Modifying a dictionary while iterating over it](#-modifying-a-dictionary-while-iterating-over-it)
- + [▶ Stubborn `del` operation](#-stubborn-del-operation)
- + [▶ The out of scope variable](#-the-out-of-scope-variable)
- + [▶ Deleting a list item while iterating](#-deleting-a-list-item-while-iterating)
- + [▶ Lossy zip of iterators *](#-lossy-zip-of-iterators-)
- + [▶ Loop variables leaking out!](#-loop-variables-leaking-out)
- + [▶ Beware of default mutable arguments!](#-beware-of-default-mutable-arguments)
- + [▶ Catching the Exceptions](#-catching-the-exceptions)
- + [▶ Same operands, different story!](#-same-operands-different-story)
- + [▶ Name resolution ignoring class scope](#-name-resolution-ignoring-class-scope)
- + [▶ Rounding like a banker *](#-rounding-like-a-banker-)
- + [▶ Needles in a Haystack *](#-needles-in-a-haystack-)
- + [▶ Splitsies *](#-splitsies-)
- + [▶ Wild imports *](#-wild-imports-)
- + [▶ All sorted? *](#-all-sorted-)
- + [▶ Midnight time doesn't exist?](#-midnight-time-doesnt-exist)
- * [Section: The Hidden treasures!](#section-the-hidden-treasures)
- + [▶ Okay Python, Can you make me fly?](#-okay-python-can-you-make-me-fly)
- + [▶ `goto`, but why?](#-goto-but-why)
- + [▶ Brace yourself!](#-brace-yourself)
- + [▶ Let's meet Friendly Language Uncle For Life](#-lets-meet-friendly-language-uncle-for-life)
- + [▶ Even Python understands that love is complicated](#-even-python-understands-that-love-is-complicated)
- + [▶ Yes, it exists!](#-yes-it-exists)
- + [▶ Ellipsis *](#-ellipsis-)
- + [▶ Inpinity](#-inpinity)
- + [▶ Let's mangle](#-lets-mangle)
- * [Section: Appearances are deceptive!](#section-appearances-are-deceptive)
- + [▶ Skipping lines?](#-skipping-lines)
- + [▶ Teleportation](#-teleportation)
- + [▶ Well, something is fishy...](#-well-something-is-fishy)
- * [Section: Miscellaneous](#section-miscellaneous)
- + [▶ `+=` is faster](#--is-faster)
- + [▶ Let's make a giant string!](#-lets-make-a-giant-string)
- + [▶ Slowing down `dict` lookups *](#-slowing-down-dict-lookups-)
- + [▶ Bloating instance `dict`s *](#-bloating-instance-dicts-)
- + [▶ Minor Ones *](#-minor-ones-)
+ - [Section: Strain your brain!](#section-strain-your-brain)
+ - [▶ First things first! *](#-first-things-first-)
+ - [▶ Strings can be tricky sometimes](#-strings-can-be-tricky-sometimes)
+ - [▶ Be careful with chained operations](#-be-careful-with-chained-operations)
+ - [▶ How not to use `is` operator](#-how-not-to-use-is-operator)
+ - [▶ Hash brownies](#-hash-brownies)
+ - [▶ Deep down, we're all the same.](#-deep-down-were-all-the-same)
+ - [▶ Disorder within order *](#-disorder-within-order-)
+ - [▶ Keep trying... *](#-keep-trying-)
+ - [▶ For what?](#-for-what)
+ - [▶ Evaluation time discrepancy](#-evaluation-time-discrepancy)
+ - [▶ `is not ...` is not `is (not ...)`](#-is-not--is-not-is-not-)
+ - [▶ A tic-tac-toe where X wins in the first attempt!](#-a-tic-tac-toe-where-x-wins-in-the-first-attempt)
+ - [▶ Schrödinger's variable](#-schrödingers-variable-)
+ - [▶ The chicken-egg problem *](#-the-chicken-egg-problem-)
+ - [▶ Subclass relationships](#-subclass-relationships)
+ - [▶ Methods equality and identity](#-methods-equality-and-identity)
+ - [▶ All-true-ation *](#-all-true-ation-)
+ - [▶ The surprising comma](#-the-surprising-comma)
+ - [▶ Strings and the backslashes](#-strings-and-the-backslashes)
+ - [▶ not knot!](#-not-knot)
+ - [▶ Half triple-quoted strings](#-half-triple-quoted-strings)
+ - [▶ What's wrong with booleans?](#-whats-wrong-with-booleans)
+ - [▶ Class attributes and instance attributes](#-class-attributes-and-instance-attributes)
+ - [▶ yielding None](#-yielding-none)
+ - [▶ Yielding from... return! *](#-yielding-from-return-)
+ - [▶ Nan-reflexivity *](#-nan-reflexivity-)
+ - [▶ Mutating the immutable!](#-mutating-the-immutable)
+ - [▶ The disappearing variable from outer scope](#-the-disappearing-variable-from-outer-scope)
+ - [▶ The mysterious key type conversion](#-the-mysterious-key-type-conversion)
+ - [▶ Let's see if you can guess this?](#-lets-see-if-you-can-guess-this)
+ - [▶ Exceeds the limit for integer string conversion](#-exceeds-the-limit-for-integer-string-conversion)
+ - [Section: Slippery Slopes](#section-slippery-slopes)
+ - [▶ Modifying a dictionary while iterating over it](#-modifying-a-dictionary-while-iterating-over-it)
+ - [▶ Stubborn `del` operation](#-stubborn-del-operation)
+ - [▶ The out of scope variable](#-the-out-of-scope-variable)
+ - [▶ Deleting a list item while iterating](#-deleting-a-list-item-while-iterating)
+ - [▶ Lossy zip of iterators *](#-lossy-zip-of-iterators-)
+ - [▶ Loop variables leaking out!](#-loop-variables-leaking-out)
+ - [▶ Beware of default mutable arguments!](#-beware-of-default-mutable-arguments)
+ - [▶ Catching the Exceptions](#-catching-the-exceptions)
+ - [▶ Same operands, different story!](#-same-operands-different-story)
+ - [▶ Name resolution ignoring class scope](#-name-resolution-ignoring-class-scope)
+ - [▶ Rounding like a banker *](#-rounding-like-a-banker-)
+ - [▶ Needles in a Haystack *](#-needles-in-a-haystack-)
+ - [▶ Splitsies *](#-splitsies-)
+ - [▶ Wild imports *](#-wild-imports-)
+ - [▶ All sorted? *](#-all-sorted-)
+ - [▶ Midnight time doesn't exist?](#-midnight-time-doesnt-exist)
+ - [Section: The Hidden treasures!](#section-the-hidden-treasures)
+ - [▶ Okay Python, Can you make me fly?](#-okay-python-can-you-make-me-fly)
+ - [▶ `goto`, but why?](#-goto-but-why)
+ - [▶ Brace yourself!](#-brace-yourself)
+ - [▶ Let's meet Friendly Language Uncle For Life](#-lets-meet-friendly-language-uncle-for-life)
+ - [▶ Even Python understands that love is complicated](#-even-python-understands-that-love-is-complicated)
+ - [▶ Yes, it exists!](#-yes-it-exists)
+ - [▶ Ellipsis *](#-ellipsis-)
+ - [▶ Inpinity](#-inpinity)
+ - [▶ Let's mangle](#-lets-mangle)
+ - [Section: Appearances are deceptive!](#section-appearances-are-deceptive)
+ - [▶ Skipping lines?](#-skipping-lines)
+ - [▶ Teleportation](#-teleportation)
+ - [▶ Well, something is fishy...](#-well-something-is-fishy)
+ - [Section: Miscellaneous](#section-miscellaneous)
+ - [▶ `+=` is faster](#--is-faster)
+ - [▶ Let's make a giant string!](#-lets-make-a-giant-string)
+ - [▶ Slowing down `dict` lookups *](#-slowing-down-dict-lookups-)
+ - [▶ Bloating instance `dict`s *](#-bloating-instance-dicts-)
+ - [▶ Minor Ones *](#-minor-ones-)
- [Contributing](#contributing)
- [Acknowledgements](#acknowledgements)
- [🎓 License](#-license)
- * [Surprise your friends as well!](#surprise-your-friends-as-well)
- * [More content like this?](#more-content-like-this)
+ - [Surprise your friends as well!](#surprise-your-friends-as-well)
+ - [More content like this?](#more-content-like-this)
@@ -130,16 +128,19 @@ All the examples are structured like below:
> >>> triggering_statement
> Some unexpected output
> ```
+>
> (Optional): One line describing the unexpected output.
>
>
> #### 💡 Explanation:
>
-> * Brief explanation of what's happening and why is it happening.
+> - Brief explanation of what's happening and why is it happening.
+>
> ```py
> # Set up code
> # More examples for further clarification (if necessary)
> ```
+>
> **Output (Python version(s)):**
>
> ```py
@@ -152,10 +153,11 @@ All the examples are structured like below:
# Usage
A nice way to get the most out of these examples, in my opinion, is to read them in sequential order, and for every example:
+
- Carefully read the initial code for setting up the example. If you're an experienced Python programmer, you'll successfully anticipate what's going to happen next most of the time.
- Read the output snippets and,
- + Check if the outputs are the same as you'd expect.
- + Make sure if you know the exact reason behind the output being the way it is.
+ - Check if the outputs are the same as you'd expect.
+ - Make sure if you know the exact reason behind the output being the way it is.
- If the answer is no (which is perfectly okay), take a deep breath, and read the explanation (and if you still don't understand, shout out! and create an issue [here](https://github.com/satwikkansal/wtfpython/issues/new)).
- If yes, give a gentle pat on your back, and you may skip to the next example.
@@ -226,8 +228,6 @@ SyntaxError: invalid syntax
16
```
-
-
#### 💡 Explanation
**Quick walrus operator refresher**
@@ -266,11 +266,11 @@ This saved one line of code, and implicitly prevented invoking `some_func` twice
- Unparenthesized "assignment expression" (use of walrus operator), is restricted at the top level, hence the `SyntaxError` in the `a := "wtf_walrus"` statement of the first snippet. Parenthesizing it worked as expected and assigned `a`.
-- As usual, parenthesizing of an expression containing `=` operator is not allowed. Hence the syntax error in `(a, b = 6, 9)`.
+- As usual, parenthesizing of an expression containing `=` operator is not allowed. Hence the syntax error in `(a, b = 6, 9)`.
-- The syntax of the Walrus operator is of the form `NAME:= expr`, where `NAME` is a valid identifier, and `expr` is a valid expression. Hence, iterable packing and unpacking are not supported which means,
+- The syntax of the Walrus operator is of the form `NAME:= expr`, where `NAME` is a valid identifier, and `expr` is a valid expression. Hence, iterable packing and unpacking are not supported which means,
- - `(a := 6, 9)` is equivalent to `((a := 6), 9)` and ultimately `(a, 9) ` (where `a`'s value is 6')
+ - `(a := 6, 9)` is equivalent to `((a := 6), 9)` and ultimately `(a, 9)` (where `a`'s value is 6')
```py
>>> (a := 6, 9) == ((a := 6), 9)
@@ -282,7 +282,7 @@ This saved one line of code, and implicitly prevented invoking `some_func` twice
True
```
- - Similarly, `(a, b := 16, 19)` is equivalent to `(a, (b := 16), 19)` which is nothing but a 3-tuple.
+ - Similarly, `(a, b := 16, 19)` is equivalent to `(a, (b := 16), 19)` which is nothing but a 3-tuple.
---
@@ -300,6 +300,7 @@ This saved one line of code, and implicitly prevented invoking `some_func` twice
```
2\.
+
```py
>>> a = "wtf"
>>> b = "wtf"
@@ -348,12 +349,13 @@ False
Makes sense, right?
#### 💡 Explanation:
-+ The behavior in first and second snippets is due to a CPython optimization (called string interning) that tries to use existing immutable objects in some cases rather than creating a new object every time.
-+ After being "interned," many variables may reference the same string object in memory (saving memory thereby).
-+ In the snippets above, strings are implicitly interned. The decision of when to implicitly intern a string is implementation-dependent. There are some rules that can be used to guess if a string will be interned or not:
- * All length 0 and length 1 strings are interned.
- * Strings are interned at compile time (`'wtf'` will be interned but `''.join(['w', 't', 'f'])` will not be interned)
- * Strings that are not composed of ASCII letters, digits or underscores, are not interned. This explains why `'wtf!'` was not interned due to `!`. CPython implementation of this rule can be found [here](https://github.com/python/cpython/blob/3.6/Objects/codeobject.c#L19)
+- The behavior in first and second snippets is due to a CPython optimization (called string interning) that tries to use existing immutable objects in some cases rather than creating a new object every time.
+- After being "interned," many variables may reference the same string object in memory (saving memory thereby).
+- In the snippets above, strings are implicitly interned. The decision of when to implicitly intern a string is implementation-dependent. There are some rules that can be used to guess if a string will be interned or not:
+ - All length 0 and length 1 strings are interned.
+ - Strings are interned at compile time (`'wtf'` will be interned but `''.join(['w', 't', 'f'])` will not be interned)
+ - Strings that are not composed of ASCII letters, digits or underscores, are not interned. This explains why `'wtf!'` was not interned due to `!`. CPython implementation of this rule can be found [here](https://github.com/python/cpython/blob/3.6/Objects/codeobject.c#L19)
+
-+ When `a` and `b` are set to `"wtf!"` in the same line, the Python interpreter creates a new object, then references the second variable at the same time. If you do it on separate lines, it doesn't "know" that there's already `"wtf!"` as an object (because `"wtf!"` is not implicitly interned as per the facts mentioned above). It's a compile-time optimization. This optimization doesn't apply to 3.7.x versions of CPython (check this [issue](https://github.com/satwikkansal/wtfpython/issues/100) for more discussion).
-+ A compile unit in an interactive environment like IPython consists of a single statement, whereas it consists of the entire module in case of modules. `a, b = "wtf!", "wtf!"` is single statement, whereas `a = "wtf!"; b = "wtf!"` are two statements in a single line. This explains why the identities are different in `a = "wtf!"; b = "wtf!"`, and also explain why they are same when invoked in `some_file.py`
-+ The abrupt change in the output of the fourth snippet is due to a [peephole optimization](https://en.wikipedia.org/wiki/Peephole_optimization) technique known as Constant folding. This means the expression `'a'*20` is replaced by `'aaaaaaaaaaaaaaaaaaaa'` during compilation to save a few clock cycles during runtime. Constant folding only occurs for strings having a length of less than 21. (Why? Imagine the size of `.pyc` file generated as a result of the expression `'a'*10**10`). [Here's](https://github.com/python/cpython/blob/3.6/Python/peephole.c#L288) the implementation source for the same.
-+ Note: In Python 3.7, Constant folding was moved out from peephole optimizer to the new AST optimizer with some change in logic as well, so the fourth snippet doesn't work for Python 3.7. You can read more about the change [here](https://bugs.python.org/issue11549).
+- When `a` and `b` are set to `"wtf!"` in the same line, the Python interpreter creates a new object, then references the second variable at the same time. If you do it on separate lines, it doesn't "know" that there's already `"wtf!"` as an object (because `"wtf!"` is not implicitly interned as per the facts mentioned above). It's a compile-time optimization. This optimization doesn't apply to 3.7.x versions of CPython (check this [issue](https://github.com/satwikkansal/wtfpython/issues/100) for more discussion).
+- A compile unit in an interactive environment like IPython consists of a single statement, whereas it consists of the entire module in case of modules. `a, b = "wtf!", "wtf!"` is single statement, whereas `a = "wtf!"; b = "wtf!"` are two statements in a single line. This explains why the identities are different in `a = "wtf!"; b = "wtf!"`, and also explain why they are same when invoked in `some_file.py`
+- The abrupt change in the output of the fourth snippet is due to a [peephole optimization](https://en.wikipedia.org/wiki/Peephole_optimization) technique known as Constant folding. This means the expression `'a'*20` is replaced by `'aaaaaaaaaaaaaaaaaaaa'` during compilation to save a few clock cycles during runtime. Constant folding only occurs for strings having a length of less than 21. (Why? Imagine the size of `.pyc` file generated as a result of the expression `'a'*10**10`). [Here's](https://github.com/python/cpython/blob/3.6/Python/peephole.c#L288) the implementation source for the same.
+- Note: In Python 3.7, Constant folding was moved out from peephole optimizer to the new AST optimizer with some change in logic as well, so the fourth snippet doesn't work for Python 3.7. You can read more about the change [here](https://bugs.python.org/issue11549).
---
-
### ▶ Be careful with chained operations
```py
@@ -401,16 +402,18 @@ As per https://docs.python.org/3/reference/expressions.html#comparisons
While such behavior might seem silly to you in the above examples, it's fantastic with stuff like `a == b == c` and `0 <= x <= 100`.
-* `False is False is False` is equivalent to `(False is False) and (False is False)`
-* `True is False == False` is equivalent to `(True is False) and (False == False)` and since the first part of the statement (`True is False`) evaluates to `False`, the overall expression evaluates to `False`.
-* `1 > 0 < 1` is equivalent to `(1 > 0) and (0 < 1)` which evaluates to `True`.
-* The expression `(1 > 0) < 1` is equivalent to `True < 1` and
+- `False is False is False` is equivalent to `(False is False) and (False is False)`
+- `True is False == False` is equivalent to `(True is False) and (False == False)` and since the first part of the statement (`True is False`) evaluates to `False`, the overall expression evaluates to `False`.
+- `1 > 0 < 1` is equivalent to `(1 > 0) and (0 < 1)` which evaluates to `True`.
+- The expression `(1 > 0) < 1` is equivalent to `True < 1` and
+
```py
>>> int(True)
1
>>> True + 1 #not relevant for this example, but just for fun
2
```
+
So, `1 < 1` evaluates to `False`
---
@@ -468,9 +471,10 @@ False
**The difference between `is` and `==`**
-* `is` operator checks if both the operands refer to the same object (i.e., it checks if the identity of the operands matches or not).
-* `==` operator compares the values of both the operands and checks if they are the same.
-* So `is` is for reference equality and `==` is for value equality. An example to clear things up,
+- `is` operator checks if both the operands refer to the same object (i.e., it checks if the identity of the operands matches or not).
+- `==` operator compares the values of both the operands and checks if they are the same.
+- So `is` is for reference equality and `==` is for value equality. An example to clear things up,
+
```py
>>> class A: pass
>>> A() is A() # These are two empty objects at two different memory locations.
@@ -505,7 +509,7 @@ Quoting from https://docs.python.org/3/c-api/long.html
Here the interpreter isn't smart enough while executing `y = 257` to recognize that we've already created an integer of the value `257,` and so it goes on to create another object in the memory.
-Similar optimization applies to other **immutable** objects like empty tuples as well. Since lists are mutable, that's why `[] is []` will return `False` and `() is ()` will return `True`. This explains our second snippet. Let's move on to the third one,
+Similar optimization applies to other **immutable** objects like empty tuples as well. Since lists are mutable, that's why `[] is []` will return `False` and `() is ()` will return `True`. This explains our second snippet. Let's move on to the third one,
**Both `a` and `b` refer to the same object when initialized with same value in the same line.**
@@ -525,9 +529,9 @@ Similar optimization applies to other **immutable** objects like empty tuples as
140640774013488
```
-* When a and b are set to `257` in the same line, the Python interpreter creates a new object, then references the second variable at the same time. If you do it on separate lines, it doesn't "know" that there's already `257` as an object.
+- When a and b are set to `257` in the same line, the Python interpreter creates a new object, then references the second variable at the same time. If you do it on separate lines, it doesn't "know" that there's already `257` as an object.
-* It's a compiler optimization and specifically applies to the interactive environment. When you enter two lines in a live interpreter, they're compiled separately, therefore optimized separately. If you were to try this example in a `.py` file, you would not see the same behavior, because the file is compiled all at once. This optimization is not limited to integers, it works for other immutable data types like strings (check the "Strings are tricky example") and floats as well,
+- It's a compiler optimization and specifically applies to the interactive environment. When you enter two lines in a live interpreter, they're compiled separately, therefore optimized separately. If you were to try this example in a `.py` file, you would not see the same behavior, because the file is compiled all at once. This optimization is not limited to integers, it works for other immutable data types like strings (check the "Strings are tricky example") and floats as well,
```py
>>> a, b = 257.0, 257.0
@@ -535,14 +539,14 @@ Similar optimization applies to other **immutable** objects like empty tuples as
True
```
-* Why didn't this work for Python 3.7? The abstract reason is because such compiler optimizations are implementation specific (i.e. may change with version, OS, etc). I'm still figuring out what exact implementation change cause the issue, you can check out this [issue](https://github.com/satwikkansal/wtfpython/issues/100) for updates.
+- Why didn't this work for Python 3.7? The abstract reason is because such compiler optimizations are implementation specific (i.e. may change with version, OS, etc). I'm still figuring out what exact implementation change cause the issue, you can check out this [issue](https://github.com/satwikkansal/wtfpython/issues/100) for updates.
---
-
### ▶ Hash brownies
1\.
+
```py
some_dict = {}
some_dict[5.5] = "JavaScript"
@@ -569,10 +573,10 @@ complex
So, why is Python all over the place?
-
#### 💡 Explanation
-* Uniqueness of keys in a Python dictionary is by *equivalence*, not identity. So even though `5`, `5.0`, and `5 + 0j` are distinct objects of different types, since they're equal, they can't both be in the same `dict` (or `set`). As soon as you insert any one of them, attempting to look up any distinct but equivalent key will succeed with the original mapped value (rather than failing with a `KeyError`):
+- Uniqueness of keys in a Python dictionary is by *equivalence*, not identity. So even though `5`, `5.0`, and `5 + 0j` are distinct objects of different types, since they're equal, they can't both be in the same `dict` (or `set`). As soon as you insert any one of them, attempting to look up any distinct but equivalent key will succeed with the original mapped value (rather than failing with a `KeyError`):
+
```py
>>> 5 == 5.0 == 5 + 0j
True
@@ -585,7 +589,8 @@ So, why is Python all over the place?
>>> (5 in some_dict) and (5 + 0j in some_dict)
True
```
-* This applies when setting an item as well. So when you do `some_dict[5] = "Python"`, Python finds the existing item with equivalent key `5.0 -> "Ruby"`, overwrites its value in place, and leaves the original key alone.
+- This applies when setting an item as well. So when you do `some_dict[5] = "Python"`, Python finds the existing item with equivalent key `5.0 -> "Ruby"`, overwrites its value in place, and leaves the original key alone.
+
```py
>>> some_dict
{5.0: 'Ruby'}
@@ -593,15 +598,17 @@ So, why is Python all over the place?
>>> some_dict
{5.0: 'Python'}
```
-* So how can we update the key to `5` (instead of `5.0`)? We can't actually do this update in place, but what we can do is first delete the key (`del some_dict[5.0]`), and then set it (`some_dict[5]`) to get the integer `5` as the key instead of floating `5.0`, though this should be needed in rare cases.
+- So how can we update the key to `5` (instead of `5.0`)? We can't actually do this update in place, but what we can do is first delete the key (`del some_dict[5.0]`), and then set it (`some_dict[5]`) to get the integer `5` as the key instead of floating `5.0`, though this should be needed in rare cases.
+
+- How did Python find `5` in a dictionary containing `5.0`? Python does this in constant time without having to scan through every item by using hash functions. When Python looks up a key `foo` in a dict, it first computes `hash(foo)` (which runs in constant-time). Since in Python it is required that objects that compare equal also have the same hash value ([docs](https://docs.python.org/3/reference/datamodel.html#object.__hash__) here), `5`, `5.0`, and `5 + 0j` have the same hash value.
-* How did Python find `5` in a dictionary containing `5.0`? Python does this in constant time without having to scan through every item by using hash functions. When Python looks up a key `foo` in a dict, it first computes `hash(foo)` (which runs in constant-time). Since in Python it is required that objects that compare equal also have the same hash value ([docs](https://docs.python.org/3/reference/datamodel.html#object.__hash__) here), `5`, `5.0`, and `5 + 0j` have the same hash value.
```py
>>> 5 == 5.0 == 5 + 0j
True
>>> hash(5) == hash(5.0) == hash(5 + 0j)
True
```
+
**Note:** The inverse is not necessarily true: Objects with equal hash values may themselves be unequal. (This causes what's known as a [hash collision](https://en.wikipedia.org/wiki/Collision_(computer_science)), and degrades the constant-time performance that hashing usually provides.)
---
@@ -614,6 +621,7 @@ class WTF:
```
**Output:**
+
```py
>>> WTF() == WTF() # two different instances can't be equal
False
@@ -627,10 +635,11 @@ True
#### 💡 Explanation:
-* When `id` was called, Python created a `WTF` class object and passed it to the `id` function. The `id` function takes its `id` (its memory location), and throws away the object. The object is destroyed.
-* When we do this twice in succession, Python allocates the same memory location to this second object as well. Since (in CPython) `id` uses the memory location as the object id, the id of the two objects is the same.
-* So, the object's id is unique only for the lifetime of the object. After the object is destroyed, or before it is created, something else can have the same id.
-* But why did the `is` operator evaluate to `False`? Let's see with this snippet.
+- When `id` was called, Python created a `WTF` class object and passed it to the `id` function. The `id` function takes its `id` (its memory location), and throws away the object. The object is destroyed.
+- When we do this twice in succession, Python allocates the same memory location to this second object as well. Since (in CPython) `id` uses the memory location as the object id, the id of the two objects is the same.
+- So, the object's id is unique only for the lifetime of the object. After the object is destroyed, or before it is created, something else can have the same id.
+- But why did the `is` operator evaluate to `False`? Let's see with this snippet.
+
```py
class WTF(object):
def __init__(self): print("I")
@@ -638,6 +647,7 @@ True
```
**Output:**
+
```py
>>> WTF() is WTF()
I
@@ -652,6 +662,7 @@ True
D
True
```
+
As you may observe, the order in which the objects are destroyed is what made all the difference here.
---
@@ -684,6 +695,7 @@ class OrderedDictWithHash(OrderedDict):
```
**Output**
+
```py
>>> dictionary == ordered_dict # If a == b
True
@@ -723,6 +735,7 @@ What is going on here?
> Equality tests between OrderedDict objects are order-sensitive and are implemented as `list(od1.items())==list(od2.items())`. Equality tests between `OrderedDict` objects and other Mapping objects are order-insensitive like regular dictionaries.
- The reason for this equality in behavior is that it allows `OrderedDict` objects to be directly substituted anywhere a regular dictionary is used.
- Okay, so why did changing the order affect the length of the generated `set` object? The answer is the lack of intransitive equality only. Since sets are "unordered" collections of unique elements, the order in which elements are inserted shouldn't matter. But in this case, it does matter. Let's break it down a bit,
+
```py
>>> some_set = set()
>>> some_set.add(dictionary) # these are the mapping objects from the snippets above
@@ -750,6 +763,7 @@ What is going on here?
>>> len(another_set)
2
```
+
So the inconsistency is due to `another_ordered_dict in another_set` being `False` because `ordered_dict` was already present in `another_set` and as observed before, `ordered_dict == another_ordered_dict` is `False`.
---
@@ -814,7 +828,6 @@ Iteration 0
---
-
### ▶ For what?
```py
@@ -825,19 +838,23 @@ for i, some_dict[i] in enumerate(some_string):
```
**Output:**
+
```py
>>> some_dict # An indexed dict appears.
{0: 'w', 1: 't', 2: 'f'}
```
-#### 💡 Explanation:
+#### 💡 Explanation:
+
+- A `for` statement is defined in the [Python grammar](https://docs.python.org/3/reference/grammar.html) as:
-* A `for` statement is defined in the [Python grammar](https://docs.python.org/3/reference/grammar.html) as:
```
for_stmt: 'for' exprlist 'in' testlist ':' suite ['else' ':' suite]
```
+
Where `exprlist` is the assignment target. This means that the equivalent of `{exprlist} = {next_value}` is **executed for each item** in the iterable.
An interesting example that illustrates this:
+
```py
for i in range(4):
print(i)
@@ -845,6 +862,7 @@ for i, some_dict[i] in enumerate(some_string):
```
**Output:**
+
```
0
1
@@ -858,7 +876,8 @@ for i, some_dict[i] in enumerate(some_string):
- The assignment statement `i = 10` never affects the iterations of the loop because of the way for loops work in Python. Before the beginning of every iteration, the next item provided by the iterator (`range(4)` in this case) is unpacked and assigned the target list variables (`i` in this case).
-* The `enumerate(some_string)` function yields a new value `i` (a counter going up) and a character from the `some_string` in each iteration. It then sets the (just assigned) `i` key of the dictionary `some_dict` to that character. The unrolling of the loop can be simplified as:
+- The `enumerate(some_string)` function yields a new value `i` (a counter going up) and a character from the `some_string` in each iteration. It then sets the (just assigned) `i` key of the dictionary `some_dict` to that character. The unrolling of the loop can be simplified as:
+
```py
>>> i, some_dict[i] = (0, 'w')
>>> i, some_dict[i] = (1, 't')
@@ -871,6 +890,7 @@ for i, some_dict[i] in enumerate(some_string):
### ▶ Evaluation time discrepancy
1\.
+
```py
array = [1, 8, 15]
# A typical generator expression
@@ -898,6 +918,7 @@ array_2[:] = [1,2,3,4,5]
```
**Output:**
+
```py
>>> print(list(gen_1))
[1, 2, 3, 4]
@@ -918,6 +939,7 @@ array_4 = [400, 500, 600]
```
**Output:**
+
```py
>>> print(list(gen))
[401, 501, 601, 402, 502, 602, 403, 503, 603]
@@ -936,7 +958,6 @@ array_4 = [400, 500, 600]
---
-
### ▶ `is not ...` is not `is (not ...)`
```py
@@ -949,7 +970,7 @@ False
#### 💡 Explanation
- `is not` is a single binary operator, and has behavior different than using `is` and `not` separated.
-- `is not` evaluates to `False` if the variables on either side of the operator point to the same object and `True` otherwise.
+- `is not` evaluates to `False` if the variables on either side of the operator point to the same object and `True` otherwise.
- In the example, `(not None)` evaluates to `True` since the value `None` is `False` in a boolean context, so the expression becomes `'something' is True`.
---
@@ -1016,7 +1037,6 @@ We can avoid this scenario here by not using `row` variable to generate `board`.
### ▶ Schrödinger's variable *
-
```py
funcs = []
results = []
@@ -1030,6 +1050,7 @@ funcs_results = [func() for func in funcs]
```
**Output (Python version):**
+
```py
>>> results
[0, 1, 2, 3, 4, 5, 6]
@@ -1048,12 +1069,14 @@ The values of `x` were different in every iteration prior to appending `some_fun
```
#### 💡 Explanation:
-* When defining a function inside a loop that uses the loop variable in its body, the loop function's closure is bound to the *variable*, not its *value*. The function looks up `x` in the surrounding context, rather than using the value of `x` at the time the function is created. So all of the functions use the latest value assigned to the variable for computation. We can see that it's using the `x` from the surrounding context (i.e. *not* a local variable) with:
+- When defining a function inside a loop that uses the loop variable in its body, the loop function's closure is bound to the *variable*, not its *value*. The function looks up `x` in the surrounding context, rather than using the value of `x` at the time the function is created. So all of the functions use the latest value assigned to the variable for computation. We can see that it's using the `x` from the surrounding context (i.e. *not* a local variable) with:
+
```py
>>> import inspect
>>> inspect.getclosurevars(funcs[0])
ClosureVars(nonlocals={}, globals={'x': 6}, builtins={}, unbound=set())
```
+
Since `x` is a global value, we can change the value that the `funcs` will lookup and return by updating `x`:
```py
@@ -1062,7 +1085,7 @@ Since `x` is a global value, we can change the value that the `funcs` will looku
[42, 42, 42, 42, 42, 42, 42]
```
-* To get the desired behavior you can pass in the loop variable as a named variable to the function. **Why does this work?** Because this will define the variable *inside* the function's scope. It will no longer go to the surrounding (global) scope to look up the variables value but will create a local variable that stores the value of `x` at that point in time.
+- To get the desired behavior you can pass in the loop variable as a named variable to the function. **Why does this work?** Because this will define the variable *inside* the function's scope. It will no longer go to the surrounding (global) scope to look up the variables value but will create a local variable that stores the value of `x` at that point in time.
```py
funcs = []
@@ -1092,6 +1115,7 @@ ClosureVars(nonlocals={}, globals={}, builtins={}, unbound=set())
### ▶ The chicken-egg problem *
1\.
+
```py
>>> isinstance(3, int)
True
@@ -1103,7 +1127,7 @@ True
So which is the "ultimate" base class? There's more to the confusion by the way,
-2\.
+2\.
```py
>>> class A: pass
@@ -1126,15 +1150,14 @@ True
False
```
-
#### 💡 Explanation
- `type` is a [metaclass](https://realpython.com/python-metaclasses/) in Python.
- **Everything** is an `object` in Python, which includes classes as well as their objects (instances).
- class `type` is the metaclass of class `object`, and every class (including `type`) has inherited directly or indirectly from `object`.
- There is no real base class among `object` and `type`. The confusion in the above snippets is arising because we're thinking about these relationships (`issubclass` and `isinstance`) in terms of Python classes. The relationship between `object` and `type` can't be reproduced in pure python. To be more precise the following relationships can't be reproduced in pure Python,
- + class A is an instance of class B, and class B is an instance of class A.
- + class A is an instance of itself.
+ - class A is an instance of class B, and class B is an instance of class A.
+ - class A is an instance of itself.
- These relationships between `object` and `type` (both being instances of each other as well as themselves) exist in Python because of "cheating" at the implementation level.
---
@@ -1142,6 +1165,7 @@ False
### ▶ Subclass relationships
**Output:**
+
```py
>>> from collections.abc import Hashable
>>> issubclass(list, object)
@@ -1152,14 +1176,14 @@ True
False
```
-The Subclass relationships were expected to be transitive, right? (i.e., if `A` is a subclass of `B`, and `B` is a subclass of `C`, the `A` _should_ a subclass of `C`)
+The Subclass relationships were expected to be transitive, right? (i.e., if `A` is a subclass of `B`, and `B` is a subclass of `C`, the `A` *should* a subclass of `C`)
#### 💡 Explanation:
-* Subclass relationships are not necessarily transitive in Python. Anyone is allowed to define their own, arbitrary `__subclasscheck__` in a metaclass.
-* When `issubclass(cls, Hashable)` is called, it simply looks for non-Falsey "`__hash__`" method in `cls` or anything it inherits from.
-* Since `object` is hashable, but `list` is non-hashable, it breaks the transitivity relation.
-* More detailed explanation can be found [here](https://www.naftaliharris.com/blog/python-subclass-intransitivity/).
+- Subclass relationships are not necessarily transitive in Python. Anyone is allowed to define their own, arbitrary `__subclasscheck__` in a metaclass.
+- When `issubclass(cls, Hashable)` is called, it simply looks for non-Falsey "`__hash__`" method in `cls` or anything it inherits from.
+- Since `object` is hashable, but `list` is non-hashable, it breaks the transitivity relation.
+- More detailed explanation can be found [here](https://www.naftaliharris.com/blog/python-subclass-intransitivity/).
---
@@ -1167,6 +1191,7 @@ The Subclass relationships were expected to be transitive, right? (i.e., if `A`
1.
+
```py
class SomeClass:
def method(self):
@@ -1182,6 +1207,7 @@ class SomeClass:
```
**Output:**
+
```py
>>> print(SomeClass.method is SomeClass.method)
True
@@ -1197,12 +1223,14 @@ Accessing `classm` twice, we get an equal object, but not the *same* one? Let's
with instances of `SomeClass`:
2.
+
```py
o1 = SomeClass()
o2 = SomeClass()
```
**Output:**
+
```py
>>> print(o1.method == o2.method)
False
@@ -1221,44 +1249,49 @@ True
Accessing `classm` or `method` twice, creates equal but not *same* objects for the same instance of `SomeClass`.
#### 💡 Explanation
-* Functions are [descriptors](https://docs.python.org/3/howto/descriptor.html). Whenever a function is accessed as an
+- Functions are [descriptors](https://docs.python.org/3/howto/descriptor.html). Whenever a function is accessed as an
attribute, the descriptor is invoked, creating a method object which "binds" the function with the object owning the
attribute. If called, the method calls the function, implicitly passing the bound object as the first argument
(this is how we get `self` as the first argument, despite not passing it explicitly).
+
```py
>>> o1.method
>
```
-* Accessing the attribute multiple times creates a method object every time! Therefore `o1.method is o1.method` is
+- Accessing the attribute multiple times creates a method object every time! Therefore `o1.method is o1.method` is
never truthy. Accessing functions as class attributes (as opposed to instance) does not create methods, however; so
`SomeClass.method is SomeClass.method` is truthy.
+
```py
>>> SomeClass.method
```
-* `classmethod` transforms functions into class methods. Class methods are descriptors that, when accessed, create
+- `classmethod` transforms functions into class methods. Class methods are descriptors that, when accessed, create
a method object which binds the *class* (type) of the object, instead of the object itself.
+
```py
>>> o1.classm
>
```
-* Unlike functions, `classmethod`s will create a method also when accessed as class attributes (in which case they
+- Unlike functions, `classmethod`s will create a method also when accessed as class attributes (in which case they
bind the class, not to the type of it). So `SomeClass.classm is SomeClass.classm` is falsy.
+
```py
>>> SomeClass.classm
>
```
-* A method object compares equal when both the functions are equal, and the bound objects are the same. So
+- A method object compares equal when both the functions are equal, and the bound objects are the same. So
`o1.method == o1.method` is truthy, although not the same object in memory.
-* `staticmethod` transforms functions into a "no-op" descriptor, which returns the function as-is. No method
+- `staticmethod` transforms functions into a "no-op" descriptor, which returns the function as-is. No method
objects are ever created, so comparison with `is` is truthy.
+
```py
>>> o1.staticm
>>> SomeClass.staticm
```
-* Having to create new "method" objects every time Python calls instance methods and having to modify the arguments
+- Having to create new "method" objects every time Python calls instance methods and having to modify the arguments
every time in order to insert `self` affected performance badly.
CPython 3.7 [solved it](https://bugs.python.org/issue26110) by introducing new opcodes that deal with calling methods
without creating the temporary method objects. This is used only when the accessed function is actually called, so the
@@ -1296,7 +1329,7 @@ Why's this True-False alteration?
return True
```
-- `all([])` returns `True` since the iterable is empty.
+- `all([])` returns `True` since the iterable is empty.
- `all([[]])` returns `False` because the passed array has one element, `[]`, and in python, an empty list is falsy.
- `all([[[]]])` and higher recursive variants are always `True`. This is because the passed array's single element (`[[...]]`) is no longer empty, and lists with values are truthy.
@@ -1329,14 +1362,15 @@ SyntaxError: invalid syntax
#### 💡 Explanation:
- Trailing comma is not always legal in formal parameters list of a Python function.
-- In Python, the argument list is defined partially with leading commas and partially with trailing commas. This conflict causes situations where a comma is trapped in the middle, and no rule accepts it.
-- **Note:** The trailing comma problem is [fixed in Python 3.6](https://bugs.python.org/issue9232). The remarks in [this](https://bugs.python.org/issue9232#msg248399) post discuss in brief different usages of trailing commas in Python.
+- In Python, the argument list is defined partially with leading commas and partially with trailing commas. This conflict causes situations where a comma is trapped in the middle, and no rule accepts it.
+- **Note:** The trailing comma problem is [fixed in Python 3.6](https://bugs.python.org/issue9232). The remarks in [this](https://bugs.python.org/issue9232#msg248399) post discuss in brief different usages of trailing commas in Python.
---
### ▶ Strings and the backslashes
**Output:**
+
```py
>>> print("\"")
"
@@ -1357,11 +1391,14 @@ True
#### 💡 Explanation
- In a usual python string, the backslash is used to escape characters that may have a special meaning (like single-quote, double-quote, and the backslash itself).
+
```py
>>> "wt\"f"
'wt"f'
```
+
- In a raw string literal (as indicated by the prefix `r`), the backslashes pass themselves as is along with the behavior of escaping the following character.
+
```py
>>> r'wt\"f' == 'wt\\"f'
True
@@ -1373,6 +1410,7 @@ True
>>> print(r"\\n")
'\\n'
```
+
- This means when a parser encounters a backslash in a raw string, it expects another character following it. And in our case (`print(r"\")`), the backslash escaped the trailing quote, leaving the parser without a terminating quote (hence the `SyntaxError`). That's why backslashes don't work at the end of a raw string.
---
@@ -1385,6 +1423,7 @@ y = False
```
**Output:**
+
```py
>>> not x == y
True
@@ -1397,16 +1436,17 @@ SyntaxError: invalid syntax
#### 💡 Explanation:
-* Operator precedence affects how an expression is evaluated, and `==` operator has higher precedence than `not` operator in Python.
-* So `not x == y` is equivalent to `not (x == y)` which is equivalent to `not (True == False)` finally evaluating to `True`.
-* But `x == not y` raises a `SyntaxError` because it can be thought of being equivalent to `(x == not) y` and not `x == (not y)` which you might have expected at first sight.
-* The parser expected the `not` token to be a part of the `not in` operator (because both `==` and `not in` operators have the same precedence), but after not being able to find an `in` token following the `not` token, it raises a `SyntaxError`.
+- Operator precedence affects how an expression is evaluated, and `==` operator has higher precedence than `not` operator in Python.
+- So `not x == y` is equivalent to `not (x == y)` which is equivalent to `not (True == False)` finally evaluating to `True`.
+- But `x == not y` raises a `SyntaxError` because it can be thought of being equivalent to `(x == not) y` and not `x == (not y)` which you might have expected at first sight.
+- The parser expected the `not` token to be a part of the `not in` operator (because both `==` and `not in` operators have the same precedence), but after not being able to find an `in` token following the `not` token, it raises a `SyntaxError`.
---
### ▶ Half triple-quoted strings
**Output:**
+
```py
>>> print('wtfpython''')
wtfpython
@@ -1422,14 +1462,15 @@ SyntaxError: EOF while scanning triple-quoted string literal
```
#### 💡 Explanation:
-+ Python supports implicit [string literal concatenation](https://docs.python.org/3/reference/lexical_analysis.html#string-literal-concatenation), Example,
+- Python supports implicit [string literal concatenation](https://docs.python.org/3/reference/lexical_analysis.html#string-literal-concatenation), Example,
+
```
>>> print("wtf" "python")
wtfpython
>>> print("wtf" "") # or "wtf"""
wtf
```
-+ `'''` and `"""` are also string delimiters in Python which causes a SyntaxError because the Python interpreter was expecting a terminating triple quote as delimiter while scanning the currently encountered triple quoted string literal.
+- `'''` and `"""` are also string delimiters in Python which causes a SyntaxError because the Python interpreter was expecting a terminating triple quote as delimiter while scanning the currently encountered triple quoted string literal.
---
@@ -1452,6 +1493,7 @@ for item in mixed_list:
```
**Output:**
+
```py
>>> integers_found_so_far
4
@@ -1459,8 +1501,8 @@ for item in mixed_list:
0
```
-
2\.
+
```py
>>> some_bool = True
>>> "wtf" * some_bool
@@ -1486,20 +1528,19 @@ def tell_truth():
I have lost faith in truth!
```
-
-
#### 💡 Explanation:
-* `bool` is a subclass of `int` in Python
-
+- `bool` is a subclass of `int` in Python
+
```py
>>> issubclass(bool, int)
True
>>> issubclass(int, bool)
False
```
-
-* And thus, `True` and `False` are instances of `int`
+
+- And thus, `True` and `False` are instances of `int`
+
```py
>>> isinstance(True, int)
True
@@ -1507,7 +1548,8 @@ I have lost faith in truth!
True
```
-* The integer value of `True` is `1` and that of `False` is `0`.
+- The integer value of `True` is `1` and that of `False` is `0`.
+
```py
>>> int(True)
1
@@ -1515,17 +1557,18 @@ I have lost faith in truth!
0
```
-* See this StackOverflow [answer](https://stackoverflow.com/a/8169049/4354153) for the rationale behind it.
+- See this StackOverflow [answer](https://stackoverflow.com/a/8169049/4354153) for the rationale behind it.
-* Initially, Python used to have no `bool` type (people used 0 for false and non-zero value like 1 for true). `True`, `False`, and a `bool` type was added in 2.x versions, but, for backward compatibility, `True` and `False` couldn't be made constants. They just were built-in variables, and it was possible to reassign them
+- Initially, Python used to have no `bool` type (people used 0 for false and non-zero value like 1 for true). `True`, `False`, and a `bool` type was added in 2.x versions, but, for backward compatibility, `True` and `False` couldn't be made constants. They just were built-in variables, and it was possible to reassign them
-* Python 3 was backward-incompatible, the issue was finally fixed, and thus the last snippet won't work with Python 3.x!
+- Python 3 was backward-incompatible, the issue was finally fixed, and thus the last snippet won't work with Python 3.x!
---
### ▶ Class attributes and instance attributes
1\.
+
```py
class A:
x = 1
@@ -1538,6 +1581,7 @@ class C(A):
```
**Output:**
+
```py
>>> A.x, B.x, C.x
(1, 1, 1)
@@ -1556,6 +1600,7 @@ class C(A):
```
2\.
+
```py
class SomeClass:
some_var = 15
@@ -1588,8 +1633,8 @@ True
#### 💡 Explanation:
-* Class variables and variables in class instances are internally handled as dictionaries of a class object. If a variable name is not found in the dictionary of the current class, the parent classes are searched for it.
-* The `+=` operator modifies the mutable object in-place without creating a new object. So changing the attribute of one instance affects the other instances and the class attribute as well.
+- Class variables and variables in class instances are internally handled as dictionaries of a class object. If a variable name is not found in the dictionary of the current class, the parent classes are searched for it.
+- The `+=` operator modifies the mutable object in-place without creating a new object. So changing the attribute of one instance affects the other instances and the class attribute as well.
---
@@ -1618,6 +1663,7 @@ def some_func(val):
```
#### 💡 Explanation:
+
- This is a bug in CPython's handling of `yield` in generators and comprehensions.
- Source and explanation can be found here: https://stackoverflow.com/questions/32139885/yield-in-list-comprehensions-and-generator-expressions
- Related bug report: https://bugs.python.org/issue10544
@@ -1625,7 +1671,6 @@ def some_func(val):
---
-
### ▶ Yielding from... return! *
1\.
@@ -1669,13 +1714,13 @@ The same result, this didn't work either.
#### 💡 Explanation:
-+ From Python 3.3 onwards, it became possible to use `return` statement with values inside generators (See [PEP380](https://www.python.org/dev/peps/pep-0380/)). The [official docs](https://www.python.org/dev/peps/pep-0380/#enhancements-to-stopiteration) say that,
+- From Python 3.3 onwards, it became possible to use `return` statement with values inside generators (See [PEP380](https://www.python.org/dev/peps/pep-0380/)). The [official docs](https://www.python.org/dev/peps/pep-0380/#enhancements-to-stopiteration) say that,
> "... `return expr` in a generator causes `StopIteration(expr)` to be raised upon exit from the generator."
-+ In the case of `some_func(3)`, `StopIteration` is raised at the beginning because of `return` statement. The `StopIteration` exception is automatically caught inside the `list(...)` wrapper and the `for` loop. Therefore, the above two snippets result in an empty list.
+- In the case of `some_func(3)`, `StopIteration` is raised at the beginning because of `return` statement. The `StopIteration` exception is automatically caught inside the `list(...)` wrapper and the `for` loop. Therefore, the above two snippets result in an empty list.
-+ To get `["wtf"]` from the generator `some_func` we need to catch the `StopIteration` exception,
+- To get `["wtf"]` from the generator `some_func` we need to catch the `StopIteration` exception,
```py
try:
@@ -1742,13 +1787,11 @@ False
True
```
-
-
#### 💡 Explanation:
- `'inf'` and `'nan'` are special strings (case-insensitive), which, when explicitly typecast-ed to `float` type, are used to represent mathematical "infinity" and "not a number" respectively.
-- Since according to IEEE standards ` NaN != NaN`, obeying this rule breaks the reflexivity assumption of a collection element in Python i.e. if `x` is a part of a collection like `list`, the implementations like comparison are based on the assumption that `x == x`. Because of this assumption, the identity is compared first (since it's faster) while comparing two elements, and the values are compared only when the identities mismatch. The following snippet will make things clearer,
+- Since according to IEEE standards `NaN != NaN`, obeying this rule breaks the reflexivity assumption of a collection element in Python i.e. if `x` is a part of a collection like `list`, the implementations like comparison are based on the assumption that `x == x`. Because of this assumption, the identity is compared first (since it's faster) while comparing two elements, and the values are compared only when the identities mismatch. The following snippet will make things clearer,
```py
>>> x = float('nan')
@@ -1779,6 +1822,7 @@ another_tuple = ([1, 2], [3, 4], [5, 6])
```
**Output:**
+
```py
>>> some_tuple[2] = "change this"
TypeError: 'tuple' object does not support item assignment
@@ -1795,13 +1839,13 @@ But I thought tuples were immutable...
#### 💡 Explanation:
-* Quoting from https://docs.python.org/3/reference/datamodel.html
+- Quoting from https://docs.python.org/3/reference/datamodel.html
> Immutable sequences
An object of an immutable sequence type cannot change once it is created. (If the object contains references to other objects, these other objects may be mutable and may be modified; however, the collection of objects directly referenced by an immutable object cannot change.)
-* `+=` operator changes the list in-place. The item assignment doesn't work, but when the exception occurs, the item has already been changed in place.
-* There's also an explanation in [official Python FAQ](https://docs.python.org/3/faq/programming.html#why-does-a-tuple-i-item-raise-an-exception-when-the-addition-works).
+- `+=` operator changes the list in-place. The item assignment doesn't work, but when the exception occurs, the item has already been changed in place.
+- There's also an explanation in [official Python FAQ](https://docs.python.org/3/faq/programming.html#why-does-a-tuple-i-item-raise-an-exception-when-the-addition-works).
---
@@ -1817,12 +1861,14 @@ except Exception as e:
```
**Output (Python 2.x):**
+
```py
>>> print(e)
# prints nothing
```
**Output (Python 3.x):**
+
```py
>>> print(e)
NameError: name 'e' is not defined
@@ -1830,7 +1876,7 @@ NameError: name 'e' is not defined
#### 💡 Explanation:
-* Source: https://docs.python.org/3/reference/compound_stmts.html#except
+- Source: https://docs.python.org/3/reference/compound_stmts.html#except
When an exception has been assigned using `as` target, it is cleared at the end of the `except` clause. This is as if
@@ -1851,7 +1897,7 @@ NameError: name 'e' is not defined
This means the exception must be assigned to a different name to be able to refer to it after the except clause. Exceptions are cleared because, with the traceback attached to them, they form a reference cycle with the stack frame, keeping all locals in that frame alive until the next garbage collection occurs.
-* The clauses are not scoped in Python. Everything in the example is present in the same scope, and the variable `e` got removed due to the execution of the `except` clause. The same is not the case with functions that have their separate inner-scopes. The example below illustrates this:
+- The clauses are not scoped in Python. Everything in the example is present in the same scope, and the variable `e` got removed due to the execution of the `except` clause. The same is not the case with functions that have their separate inner-scopes. The example below illustrates this:
```py
def f(x):
@@ -1863,6 +1909,7 @@ NameError: name 'e' is not defined
```
**Output:**
+
```py
>>> f(x)
UnboundLocalError: local variable 'x' referenced before assignment
@@ -1874,9 +1921,10 @@ NameError: name 'e' is not defined
[5, 4, 3]
```
-* In Python 2.x, the variable name `e` gets assigned to `Exception()` instance, so when you try to print, it prints nothing.
+- In Python 2.x, the variable name `e` gets assigned to `Exception()` instance, so when you try to print, it prints nothing.
**Output (Python 2.x):**
+
```py
>>> e
Exception()
@@ -1886,7 +1934,6 @@ NameError: name 'e' is not defined
---
-
### ▶ The mysterious key type conversion
```py
@@ -1897,6 +1944,7 @@ some_dict = {'s': 42}
```
**Output:**
+
```py
>>> type(list(some_dict.keys())[0])
str
@@ -1910,10 +1958,11 @@ str
#### 💡 Explanation:
-* Both the object `s` and the string `"s"` hash to the same value because `SomeClass` inherits the `__hash__` method of `str` class.
-* `SomeClass("s") == "s"` evaluates to `True` because `SomeClass` also inherits `__eq__` method from `str` class.
-* Since both the objects hash to the same value and are equal, they are represented by the same key in the dictionary.
-* For the desired behavior, we can redefine the `__eq__` method in `SomeClass`
+- Both the object `s` and the string `"s"` hash to the same value because `SomeClass` inherits the `__hash__` method of `str` class.
+- `SomeClass("s") == "s"` evaluates to `True` because `SomeClass` also inherits `__eq__` method from `str` class.
+- Since both the objects hash to the same value and are equal, they are represented by the same key in the dictionary.
+- For the desired behavior, we can redefine the `__eq__` method in `SomeClass`
+
```py
class SomeClass(str):
def __eq__(self, other):
@@ -1931,6 +1980,7 @@ str
```
**Output:**
+
```py
>>> s = SomeClass('s')
>>> some_dict[s] = 40
@@ -1950,6 +2000,7 @@ a, b = a[b] = {}, 5
```
**Output:**
+
```py
>>> a
{5: ({...}, 5)}
@@ -1957,23 +2008,26 @@ a, b = a[b] = {}, 5
#### 💡 Explanation:
-* According to [Python language reference](https://docs.python.org/3/reference/simple_stmts.html#assignment-statements), assignment statements have the form
+- According to [Python language reference](https://docs.python.org/3/reference/simple_stmts.html#assignment-statements), assignment statements have the form
+
```
(target_list "=")+ (expression_list | yield_expression)
```
+
and
> An assignment statement evaluates the expression list (remember that this can be a single expression or a comma-separated list, the latter yielding a tuple) and assigns the single resulting object to each of the target lists, from left to right.
-* The `+` in `(target_list "=")+` means there can be **one or more** target lists. In this case, target lists are `a, b` and `a[b]` (note the expression list is exactly one, which in our case is `{}, 5`).
+- The `+` in `(target_list "=")+` means there can be **one or more** target lists. In this case, target lists are `a, b` and `a[b]` (note the expression list is exactly one, which in our case is `{}, 5`).
-* After the expression list is evaluated, its value is unpacked to the target lists from **left to right**. So, in our case, first the `{}, 5` tuple is unpacked to `a, b` and we now have `a = {}` and `b = 5`.
+- After the expression list is evaluated, its value is unpacked to the target lists from **left to right**. So, in our case, first the `{}, 5` tuple is unpacked to `a, b` and we now have `a = {}` and `b = 5`.
-* `a` is now assigned to `{}`, which is a mutable object.
+- `a` is now assigned to `{}`, which is a mutable object.
-* The second target list is `a[b]` (you may expect this to throw an error because both `a` and `b` have not been defined in the statements before. But remember, we just assigned `a` to `{}` and `b` to `5`).
+- The second target list is `a[b]` (you may expect this to throw an error because both `a` and `b` have not been defined in the statements before. But remember, we just assigned `a` to `{}` and `b` to `5`).
+
+- Now, we are setting the key `5` in the dictionary to the tuple `({}, 5)` creating a circular reference (the `{...}` in the output refers to the same object that `a` is already referencing). Another simpler example of circular reference could be
-* Now, we are setting the key `5` in the dictionary to the tuple `({}, 5)` creating a circular reference (the `{...}` in the output refers to the same object that `a` is already referencing). Another simpler example of circular reference could be
```py
>>> some_list = some_list[0] = [0]
>>> some_list
@@ -1985,23 +2039,27 @@ a, b = a[b] = {}, 5
>>> some_list[0][0][0][0][0][0] == some_list
True
```
+
Similar is the case in our example (`a[b][0]` is the same object as `a`)
-* So to sum it up, you can break the example down to
+- So to sum it up, you can break the example down to
+
```py
a, b = {}, 5
a[b] = a, b
```
+
And the circular reference can be justified by the fact that `a[b][0]` is the same object as `a`
+
```py
>>> a[b][0] is a
True
```
-
---
### ▶ Exceeds the limit for integer string conversion
+
```py
>>> # Python 3.10.6
>>> int("2" * 5432)
@@ -2011,6 +2069,7 @@ a, b = a[b] = {}, 5
```
**Output:**
+
```py
>>> # Python 3.10.6
222222222222222222222222222222222222222222222222222222222222222...
@@ -2024,19 +2083,19 @@ ValueError: Exceeds the limit (4300) for integer string conversion:
```
#### 💡 Explanation:
+
This call to `int()` works fine in Python 3.10.6 and raises a ValueError in Python 3.10.8. Note that Python can still work with large integers. The error is only raised when converting between integers and strings.
Fortunately, you can increase the limit for the allowed number of digits when you expect an operation to exceed it. To do this, you can use one of the following:
+
- The -X int_max_str_digits command-line flag
- The set_int_max_str_digits() function from the sys module
- The PYTHONINTMAXSTRDIGITS environment variable
[Check the documentation](https://docs.python.org/3/library/stdtypes.html#int-max-str-digits) for more details on changing the default limit if you expect your code to exceed this value.
-
---
-
## Section: Slippery Slopes
### ▶ Modifying a dictionary while iterating over it
@@ -2067,11 +2126,11 @@ Yes, it runs for exactly **eight** times and stops.
#### 💡 Explanation:
-* Iteration over a dictionary that you edit at the same time is not supported.
-* It runs eight times because that's the point at which the dictionary resizes to hold more keys (we have eight deletion entries, so a resize is needed). This is actually an implementation detail.
-* How deleted keys are handled and when the resize occurs might be different for different Python implementations.
-* So for Python versions other than Python 2.7 - Python 3.5, the count might be different from 8 (but whatever the count is, it's going to be the same every time you run it). You can find some discussion around this [here](https://github.com/satwikkansal/wtfpython/issues/53) or in [this](https://stackoverflow.com/questions/44763802/bug-in-python-dict) StackOverflow thread.
-* Python 3.7.6 onwards, you'll see `RuntimeError: dictionary keys changed during iteration` exception if you try to do this.
+- Iteration over a dictionary that you edit at the same time is not supported.
+- It runs eight times because that's the point at which the dictionary resizes to hold more keys (we have eight deletion entries, so a resize is needed). This is actually an implementation detail.
+- How deleted keys are handled and when the resize occurs might be different for different Python implementations.
+- So for Python versions other than Python 2.7 - Python 3.5, the count might be different from 8 (but whatever the count is, it's going to be the same every time you run it). You can find some discussion around this [here](https://github.com/satwikkansal/wtfpython/issues/53) or in [this](https://stackoverflow.com/questions/44763802/bug-in-python-dict) StackOverflow thread.
+- Python 3.7.6 onwards, you'll see `RuntimeError: dictionary keys changed during iteration` exception if you try to do this.
---
@@ -2087,6 +2146,7 @@ class SomeClass:
**Output:**
1\.
+
```py
>>> x = SomeClass()
>>> y = x
@@ -2098,6 +2158,7 @@ Deleted!
Phew, deleted at last. You might have guessed what saved `__del__` from being called in our first attempt to delete `x`. Let's add more twists to the example.
2\.
+
```py
>>> x = SomeClass()
>>> y = x
@@ -2113,10 +2174,10 @@ Deleted!
Okay, now it's deleted :confused:
#### 💡 Explanation:
-+ `del x` doesn’t directly call `x.__del__()`.
-+ When `del x` is encountered, Python deletes the name `x` from current scope and decrements by 1 the reference count of the object `x` referenced. `__del__()` is called only when the object's reference count reaches zero.
-+ In the second output snippet, `__del__()` was not called because the previous statement (`>>> y`) in the interactive interpreter created another reference to the same object (specifically, the `_` magic variable which references the result value of the last non `None` expression on the REPL), thus preventing the reference count from reaching zero when `del y` was encountered.
-+ Calling `globals` (or really, executing anything that will have a non `None` result) caused `_` to reference the new result, dropping the existing reference. Now the reference count reached 0 and we can see "Deleted!" being printed (finally!).
+- `del x` doesn’t directly call `x.__del__()`.
+- When `del x` is encountered, Python deletes the name `x` from current scope and decrements by 1 the reference count of the object `x` referenced. `__del__()` is called only when the object's reference count reaches zero.
+- In the second output snippet, `__del__()` was not called because the previous statement (`>>> y`) in the interactive interpreter created another reference to the same object (specifically, the `_` magic variable which references the result value of the last non `None` expression on the REPL), thus preventing the reference count from reaching zero when `del y` was encountered.
+- Calling `globals` (or really, executing anything that will have a non `None` result) caused `_` to reference the new result, dropping the existing reference. Now the reference count reached 0 and we can see "Deleted!" being printed (finally!).
---
@@ -2124,6 +2185,7 @@ Okay, now it's deleted :confused:
1\.
+
```py
a = 1
def some_func():
@@ -2135,6 +2197,7 @@ def another_func():
```
2\.
+
```py
def some_closure_func():
a = 1
@@ -2151,6 +2214,7 @@ def another_closure_func():
```
**Output:**
+
```py
>>> some_func()
1
@@ -2164,8 +2228,9 @@ UnboundLocalError: local variable 'a' referenced before assignment
```
#### 💡 Explanation:
-* When you make an assignment to a variable in scope, it becomes local to that scope. So `a` becomes local to the scope of `another_func`, but it has not been initialized previously in the same scope, which throws an error.
-* To modify the outer scope variable `a` in `another_func`, we have to use the `global` keyword.
+- When you make an assignment to a variable in scope, it becomes local to that scope. So `a` becomes local to the scope of `another_func`, but it has not been initialized previously in the same scope, which throws an error.
+- To modify the outer scope variable `a` in `another_func`, we have to use the `global` keyword.
+
```py
def another_func()
global a
@@ -2174,12 +2239,14 @@ UnboundLocalError: local variable 'a' referenced before assignment
```
**Output:**
+
```py
>>> another_func()
2
```
-* In `another_closure_func`, `a` becomes local to the scope of `another_inner_func`, but it has not been initialized previously in the same scope, which is why it throws an error.
-* To modify the outer scope variable `a` in `another_inner_func`, use the `nonlocal` keyword. The nonlocal statement is used to refer to variables defined in the nearest outer (excluding the global) scope.
+- In `another_closure_func`, `a` becomes local to the scope of `another_inner_func`, but it has not been initialized previously in the same scope, which is why it throws an error.
+- To modify the outer scope variable `a` in `another_inner_func`, use the `nonlocal` keyword. The nonlocal statement is used to refer to variables defined in the nearest outer (excluding the global) scope.
+
```py
def another_func():
a = 1
@@ -2191,12 +2258,13 @@ UnboundLocalError: local variable 'a' referenced before assignment
```
**Output:**
+
```py
>>> another_func()
2
```
-* The keywords `global` and `nonlocal` tell the python interpreter to not declare new variables and look them up in the corresponding outer scopes.
-* Read [this](https://sebastianraschka.com/Articles/2014_python_scope_and_namespaces.html) short but an awesome guide to learn more about how namespaces and scope resolution works in Python.
+- The keywords `global` and `nonlocal` tell the python interpreter to not declare new variables and look them up in the corresponding outer scopes.
+- Read [this](https://sebastianraschka.com/Articles/2014_python_scope_and_namespaces.html) short but an awesome guide to learn more about how namespaces and scope resolution works in Python.
---
@@ -2222,6 +2290,7 @@ for idx, item in enumerate(list_4):
```
**Output:**
+
```py
>>> list_1
[1, 2, 3, 4]
@@ -2237,7 +2306,7 @@ Can you guess why the output is `[2, 4]`?
#### 💡 Explanation:
-* It's never a good idea to change the object you're iterating over. The correct way to do so is to iterate over a copy of the object instead, and `list_3[:]` does just that.
+- It's never a good idea to change the object you're iterating over. The correct way to do so is to iterate over a copy of the object instead, and `list_3[:]` does just that.
```py
>>> some_list = [1, 2, 3, 4]
@@ -2248,19 +2317,19 @@ Can you guess why the output is `[2, 4]`?
```
**Difference between `del`, `remove`, and `pop`:**
-* `del var_name` just removes the binding of the `var_name` from the local or global namespace (That's why the `list_1` is unaffected).
-* `remove` removes the first matching value, not a specific index, raises `ValueError` if the value is not found.
-* `pop` removes the element at a specific index and returns it, raises `IndexError` if an invalid index is specified.
+- `del var_name` just removes the binding of the `var_name` from the local or global namespace (That's why the `list_1` is unaffected).
+- `remove` removes the first matching value, not a specific index, raises `ValueError` if the value is not found.
+- `pop` removes the element at a specific index and returns it, raises `IndexError` if an invalid index is specified.
**Why the output is `[2, 4]`?**
+
- The list iteration is done index by index, and when we remove `1` from `list_2` or `list_4`, the contents of the lists are now `[2, 3, 4]`. The remaining elements are shifted down, i.e., `2` is at index 0, and `3` is at index 1. Since the next iteration is going to look at index 1 (which is the `3`), the `2` gets skipped entirely. A similar thing will happen with every alternate element in the list sequence.
-* Refer to this StackOverflow [thread](https://stackoverflow.com/questions/45946228/what-happens-when-you-try-to-delete-a-list-element-while-iterating-over-it) explaining the example
-* See also this nice StackOverflow [thread](https://stackoverflow.com/questions/45877614/how-to-change-all-the-dictionary-keys-in-a-for-loop-with-d-items) for a similar example related to dictionaries in Python.
+- Refer to this StackOverflow [thread](https://stackoverflow.com/questions/45946228/what-happens-when-you-try-to-delete-a-list-element-while-iterating-over-it) explaining the example
+- See also this nice StackOverflow [thread](https://stackoverflow.com/questions/45877614/how-to-change-all-the-dictionary-keys-in-a-for-loop-with-d-items) for a similar example related to dictionaries in Python.
---
-
### ▶ Lossy zip of iterators *
@@ -2278,11 +2347,13 @@ Can you guess why the output is `[2, 4]`?
>>> list(zip(numbers_iter, remaining))
[(4, 3), (5, 4), (6, 5)]
```
+
Where did element `3` go from the `numbers` list?
#### 💡 Explanation:
- From Python [docs](https://docs.python.org/3.3/library/functions.html#zip), here's an approximate implementation of zip function,
+
```py
def zip(*iterables):
sentinel = object()
@@ -2295,9 +2366,11 @@ Where did element `3` go from the `numbers` list?
result.append(elem)
yield tuple(result)
```
-- So the function takes in arbitrary number of iterable objects, adds each of their items to the `result` list by calling the `next` function on them, and stops whenever any of the iterable is exhausted.
+
+- So the function takes in arbitrary number of iterable objects, adds each of their items to the `result` list by calling the `next` function on them, and stops whenever any of the iterable is exhausted.
- The caveat here is when any iterable is exhausted, the existing elements in the `result` list are discarded. That's what happened with `3` in the `numbers_iter`.
- The correct way to do the above using `zip` would be,
+
```py
>>> numbers = list(range(7))
>>> numbers_iter = iter(numbers)
@@ -2306,6 +2379,7 @@ Where did element `3` go from the `numbers` list?
>>> list(zip(remaining, numbers_iter))
[(3, 3), (4, 4), (5, 5), (6, 6)]
```
+
The first argument of zip should be the one with fewest elements.
---
@@ -2313,6 +2387,7 @@ Where did element `3` go from the `numbers` list?
### ▶ Loop variables leaking out!
1\.
+
```py
for x in range(7):
if x == 6:
@@ -2321,6 +2396,7 @@ print(x, ': x in global')
```
**Output:**
+
```py
6 : for x inside loop
6 : x in global
@@ -2329,6 +2405,7 @@ print(x, ': x in global')
But `x` was never defined outside the scope of for loop...
2\.
+
```py
# This time let's initialize x first
x = -1
@@ -2339,6 +2416,7 @@ print(x, ': x in global')
```
**Output:**
+
```py
6 : for x inside loop
6 : x in global
@@ -2347,6 +2425,7 @@ print(x, ': x in global')
3\.
**Output (Python 2.x):**
+
```py
>>> x = 1
>>> print([x for x in range(5)])
@@ -2356,6 +2435,7 @@ print(x, ': x in global')
```
**Output (Python 3.x):**
+
```py
>>> x = 1
>>> print([x for x in range(5)])
@@ -2384,6 +2464,7 @@ def some_func(default_arg=[]):
```
**Output:**
+
```py
>>> some_func()
['some_string']
@@ -2406,6 +2487,7 @@ def some_func(default_arg=[]):
```
**Output:**
+
```py
>>> some_func.__defaults__ #This will show the default argument values for the function
([],)
@@ -2450,6 +2532,7 @@ except IndexError, ValueError:
```
**Output (Python 2.x):**
+
```py
Caught!
@@ -2457,6 +2540,7 @@ ValueError: list.remove(x): x not in list
```
**Output (Python 3.x):**
+
```py
File "", line 3
except IndexError, ValueError:
@@ -2466,7 +2550,8 @@ SyntaxError: invalid syntax
#### 💡 Explanation
-* To add multiple Exceptions to the except clause, you need to pass them as parenthesized tuple as the first argument. The second argument is an optional name, which when supplied will bind the Exception instance that has been raised. Example,
+- To add multiple Exceptions to the except clause, you need to pass them as parenthesized tuple as the first argument. The second argument is an optional name, which when supplied will bind the Exception instance that has been raised. Example,
+
```py
some_list = [1, 2, 3]
try:
@@ -2476,12 +2561,16 @@ SyntaxError: invalid syntax
print("Caught again!")
print(e)
```
+
**Output (Python 2.x):**
+
```
Caught again!
list.remove(x): x not in list
```
+
**Output (Python 3.x):**
+
```py
File "", line 4
except (IndexError, ValueError), e:
@@ -2489,7 +2578,8 @@ SyntaxError: invalid syntax
IndentationError: unindent does not match any outer indentation level
```
-* Separating the exception from the variable with a comma is deprecated and does not work in Python 3; the correct way is to use `as`. Example,
+- Separating the exception from the variable with a comma is deprecated and does not work in Python 3; the correct way is to use `as`. Example,
+
```py
some_list = [1, 2, 3]
try:
@@ -2499,7 +2589,9 @@ SyntaxError: invalid syntax
print("Caught again!")
print(e)
```
+
**Output:**
+
```
Caught again!
list.remove(x): x not in list
@@ -2510,6 +2602,7 @@ SyntaxError: invalid syntax
### ▶ Same operands, different story!
1\.
+
```py
a = [1, 2, 3, 4]
b = a
@@ -2517,6 +2610,7 @@ a = a + [5, 6, 7, 8]
```
**Output:**
+
```py
>>> a
[1, 2, 3, 4, 5, 6, 7, 8]
@@ -2525,6 +2619,7 @@ a = a + [5, 6, 7, 8]
```
2\.
+
```py
a = [1, 2, 3, 4]
b = a
@@ -2532,6 +2627,7 @@ a += [5, 6, 7, 8]
```
**Output:**
+
```py
>>> a
[1, 2, 3, 4, 5, 6, 7, 8]
@@ -2541,17 +2637,18 @@ a += [5, 6, 7, 8]
#### 💡 Explanation:
-* `a += b` doesn't always behave the same way as `a = a + b`. Classes *may* implement the *`op=`* operators differently, and lists do this.
+- `a += b` doesn't always behave the same way as `a = a + b`. Classes *may* implement the *`op=`* operators differently, and lists do this.
-* The expression `a = a + [5,6,7,8]` generates a new list and sets `a`'s reference to that new list, leaving `b` unchanged.
+- The expression `a = a + [5,6,7,8]` generates a new list and sets `a`'s reference to that new list, leaving `b` unchanged.
-* The expression `a += [5,6,7,8]` is actually mapped to an "extend" function that operates on the list such that `a` and `b` still point to the same list that has been modified in-place.
+- The expression `a += [5,6,7,8]` is actually mapped to an "extend" function that operates on the list such that `a` and `b` still point to the same list that has been modified in-place.
---
### ▶ Name resolution ignoring class scope
1\.
+
```py
x = 5
class SomeClass:
@@ -2560,12 +2657,14 @@ class SomeClass:
```
**Output:**
+
```py
>>> list(SomeClass.y)[0]
5
```
2\.
+
```py
x = 5
class SomeClass:
@@ -2574,18 +2673,21 @@ class SomeClass:
```
**Output (Python 2.x):**
+
```py
>>> SomeClass.y[0]
17
```
**Output (Python 3.x):**
+
```py
>>> SomeClass.y[0]
5
```
#### 💡 Explanation
+
- Scopes nested inside class definition ignore names bound at the class level.
- A generator expression has its own scope.
- Starting from Python 3.X, list comprehensions also have their own scope.
@@ -2595,6 +2697,7 @@ class SomeClass:
### ▶ Rounding like a banker *
Let's implement a naive function to get the middle element of a list:
+
```py
def get_middle(some_list):
mid_index = round(len(some_list) / 2)
@@ -2602,6 +2705,7 @@ def get_middle(some_list):
```
**Python 3.x:**
+
```py
>>> get_middle([1]) # looks good
1
@@ -2614,6 +2718,7 @@ def get_middle(some_list):
>>> round(len([1,2,3,4,5]) / 2) # why?
2
```
+
It seems as though Python rounded 2.5 to 2.
#### 💡 Explanation:
@@ -2636,7 +2741,7 @@ It seems as though Python rounded 2.5 to 2.
2.0
```
-- This is the recommended way to round .5 fractions as described in [IEEE 754](https://en.wikipedia.org/wiki/IEEE_754#Rounding_rules). However, the other way (round away from zero) is taught in school most of the time, so banker's rounding is likely not that well known. Furthermore, some of the most popular programming languages (for example: JavaScript, Java, C/C++, Ruby, Rust) do not use banker's rounding either. Therefore, this is still quite special to Python and may result in confusion when rounding fractions.
+- This is the recommended way to round .5 fractions as described in [IEEE 754](https://en.wikipedia.org/wiki/IEEE_754#Rounding_rules). However, the other way (round away from zero) is taught in school most of the time, so banker's rounding is likely not that well known. Furthermore, some of the most popular programming languages (for example: JavaScript, Java, C/C++, Ruby, Rust) do not use banker's rounding either. Therefore, this is still quite special to Python and may result in confusion when rounding fractions.
- See the [round() docs](https://docs.python.org/3/library/functions.html#round) or [this stackoverflow thread](https://stackoverflow.com/questions/10825926/python-3-x-rounding-behavior) for more information.
- Note that `get_middle([1])` only returned 1 because the index was `round(0.5) - 1 = 0 - 1 = -1`, returning the last element in the list.
@@ -2778,20 +2883,20 @@ def similar_recursive_func(a):
#### 💡 Explanation:
-* For 1, the correct statement for expected behavior is `x, y = (0, 1) if True else (None, None)`.
+- For 1, the correct statement for expected behavior is `x, y = (0, 1) if True else (None, None)`.
-* For 2, the correct statement for expected behavior is `t = ('one',)` or `t = 'one',` (missing comma) otherwise the interpreter considers `t` to be a `str` and iterates over it character by character.
+- For 2, the correct statement for expected behavior is `t = ('one',)` or `t = 'one',` (missing comma) otherwise the interpreter considers `t` to be a `str` and iterates over it character by character.
-* `()` is a special token and denotes empty `tuple`.
+- `()` is a special token and denotes empty `tuple`.
-* In 3, as you might have already figured out, there's a missing comma after 5th element (`"that"`) in the list. So by implicit string literal concatenation,
+- In 3, as you might have already figured out, there's a missing comma after 5th element (`"that"`) in the list. So by implicit string literal concatenation,
```py
>>> ten_words_list
['some', 'very', 'big', 'list', 'thatconsists', 'of', 'exactly', 'ten', 'words']
```
-* No `AssertionError` was raised in 4th snippet because instead of asserting the individual expression `a == b`, we're asserting entire tuple. The following snippet will clear things up,
+- No `AssertionError` was raised in 4th snippet because instead of asserting the individual expression `a == b`, we're asserting entire tuple. The following snippet will clear things up,
```py
>>> a = "python"
@@ -2810,15 +2915,14 @@ def similar_recursive_func(a):
AssertionError: Values are not equal
```
-* As for the fifth snippet, most methods that modify the items of sequence/mapping objects like `list.append`, `dict.update`, `list.sort`, etc. modify the objects in-place and return `None`. The rationale behind this is to improve performance by avoiding making a copy of the object if the operation can be done in-place (Referred from [here](https://docs.python.org/3/faq/design.html#why-doesn-t-list-sort-return-the-sorted-list)).
+- As for the fifth snippet, most methods that modify the items of sequence/mapping objects like `list.append`, `dict.update`, `list.sort`, etc. modify the objects in-place and return `None`. The rationale behind this is to improve performance by avoiding making a copy of the object if the operation can be done in-place (Referred from [here](https://docs.python.org/3/faq/design.html#why-doesn-t-list-sort-return-the-sorted-list)).
-* Last one should be fairly obvious, mutable object (like `list`) can be altered in the function, and the reassignment of an immutable (`a -= 1`) is not an alteration of the value.
+- Last one should be fairly obvious, mutable object (like `list`) can be altered in the function, and the reassignment of an immutable (`a -= 1`) is not an alteration of the value.
-* Being aware of these nitpicks can save you hours of debugging effort in the long run.
+- Being aware of these nitpicks can save you hours of debugging effort in the long run.
---
-
### ▶ Splitsies *
```py
@@ -2841,9 +2945,10 @@ def similar_recursive_func(a):
#### 💡 Explanation:
- It might appear at first that the default separator for split is a single space `' '`, but as per the [docs](https://docs.python.org/3/library/stdtypes.html#str.split)
- > If sep is not specified or is `None`, a different splitting algorithm is applied: runs of consecutive whitespace are regarded as a single separator, and the result will contain no empty strings at the start or end if the string has leading or trailing whitespace. Consequently, splitting an empty string or a string consisting of just whitespace with a None separator returns `[]`.
+ > If sep is not specified or is `None`, a different splitting algorithm is applied: runs of consecutive whitespace are regarded as a single separator, and the result will contain no empty strings at the start or end if the string has leading or trailing whitespace. Consequently, splitting an empty string or a string consisting of just whitespace with a None separator returns `[]`.
> If sep is given, consecutive delimiters are not grouped together and are deemed to delimit empty strings (for example, `'1,,2'.split(',')` returns `['1', '', '2']`). Splitting an empty string with a specified separator returns `['']`.
- Noticing how the leading and trailing whitespaces are handled in the following snippet will make things clear,
+
```py
>>> ' a '.split(' ')
['', 'a', '']
@@ -2886,12 +2991,15 @@ NameError: name '_another_weird_name_func' is not defined
- It is often advisable to not use wildcard imports. The first obvious reason for this is, in wildcard imports, the names with a leading underscore don't get imported. This may lead to errors during runtime.
- Had we used `from ... import a, b, c` syntax, the above `NameError` wouldn't have occurred.
+
```py
>>> from module import some_weird_name_func_, _another_weird_name_func
>>> _another_weird_name_func()
works!
```
+
- If you really want to use wildcard imports, then you'd have to define the list `__all__` in your module that will contain a list of public objects that'll be available when we do wildcard imports.
+
```py
__all__ = ['_another_weird_name_func']
@@ -2901,6 +3009,7 @@ NameError: name '_another_weird_name_func' is not defined
def _another_weird_name_func():
print("works!")
```
+
**Output**
```py
@@ -2932,7 +3041,7 @@ False
#### 💡 Explanation:
-- The `sorted` method always returns a list, and comparing lists and tuples always returns `False` in Python.
+- The `sorted` method always returns a list, and comparing lists and tuples always returns `False` in Python.
- ```py
>>> [] == tuple()
@@ -2978,6 +3087,7 @@ if noon_time:
```py
('Time at noon is', datetime.time(12, 0))
```
+
The midnight time is not printed.
#### 💡 Explanation:
@@ -2987,8 +3097,6 @@ Before Python 3.5, the boolean value for `datetime.time` object was considered t
---
---
-
-
## Section: The Hidden treasures!
This section contains a few lesser-known and interesting things about Python that most beginners like me are unaware of (well, not anymore).
@@ -3005,9 +3113,9 @@ import antigravity
Sshh... It's a super-secret.
#### 💡 Explanation:
-+ `antigravity` module is one of the few easter eggs released by Python developers.
-+ `import antigravity` opens up a web browser pointing to the [classic XKCD comic](https://xkcd.com/353/) about Python.
-+ Well, there's more to it. There's **another easter egg inside the easter egg**. If you look at the [code](https://github.com/python/cpython/blob/master/Lib/antigravity.py#L7-L17), there's a function defined that purports to implement the [XKCD's geohashing algorithm](https://xkcd.com/426/).
+- `antigravity` module is one of the few easter eggs released by Python developers.
+- `import antigravity` opens up a web browser pointing to the [classic XKCD comic](https://xkcd.com/353/) about Python.
+- Well, there's more to it. There's **another easter egg inside the easter egg**. If you look at the [code](https://github.com/python/cpython/blob/master/Lib/antigravity.py#L7-L17), there's a function defined that purports to implement the [XKCD's geohashing algorithm](https://xkcd.com/426/).
---
@@ -3027,6 +3135,7 @@ print("Freedom!")
```
**Output (Python 2.3):**
+
```py
I am trapped, please rescue!
I am trapped, please rescue!
@@ -3034,6 +3143,7 @@ Freedom!
```
#### 💡 Explanation:
+
- A working version of `goto` in Python was [announced](https://mail.python.org/pipermail/python-announce-list/2004-April/002982.html) as an April Fool's joke on 1st April 2004.
- Current versions of Python do not have this module.
- Although it works, but please don't use it. Here's the [reason](https://docs.python.org/3/faq/design.html#why-is-there-no-goto) to why `goto` is not present in Python.
@@ -3049,6 +3159,7 @@ from __future__ import braces
```
**Output:**
+
```py
File "some_file.py", line 1
from __future__ import braces
@@ -3058,16 +3169,17 @@ SyntaxError: not a chance
Braces? No way! If you think that's disappointing, use Java. Okay, another surprising thing, can you find where's the `SyntaxError` raised in `__future__` module [code](https://github.com/python/cpython/blob/master/Lib/__future__.py)?
#### 💡 Explanation:
-+ The `__future__` module is normally used to provide features from future versions of Python. The "future" in this specific context is however, ironic.
-+ This is an easter egg concerned with the community's feelings on this issue.
-+ The code is actually present [here](https://github.com/python/cpython/blob/025eb98dc0c1dc27404df6c544fc2944e0fa9f3a/Python/future.c#L49) in `future.c` file.
-+ When the CPython compiler encounters a [future statement](https://docs.python.org/3.3/reference/simple_stmts.html#future-statements), it first runs the appropriate code in `future.c` before treating it as a normal import statement.
+- The `__future__` module is normally used to provide features from future versions of Python. The "future" in this specific context is however, ironic.
+- This is an easter egg concerned with the community's feelings on this issue.
+- The code is actually present [here](https://github.com/python/cpython/blob/025eb98dc0c1dc27404df6c544fc2944e0fa9f3a/Python/future.c#L49) in `future.c` file.
+- When the CPython compiler encounters a [future statement](https://docs.python.org/3.3/reference/simple_stmts.html#future-statements), it first runs the appropriate code in `future.c` before treating it as a normal import statement.
---
### ▶ Let's meet Friendly Language Uncle For Life
**Output (Python 3.x)**
+
```py
>>> from __future__ import barry_as_FLUFL
>>> "Ruby" != "Python" # there's no doubt about it
@@ -3083,12 +3195,14 @@ True
There we go.
#### 💡 Explanation:
+
- This is relevant to [PEP-401](https://www.python.org/dev/peps/pep-0401/) released on April 1, 2009 (now you know, what it means).
- Quoting from the PEP-401
> Recognized that the != inequality operator in Python 3.0 was a horrible, finger-pain inducing mistake, the FLUFL reinstates the <> diamond operator as the sole spelling.
- There were more things that Uncle Barry had to share in the PEP; you can read them [here](https://www.python.org/dev/peps/pep-0401/).
- It works well in an interactive environment, but it will raise a `SyntaxError` when you run via python file (see this [issue](https://github.com/satwikkansal/wtfpython/issues/94)). However, you can wrap the statement inside an `eval` or `compile` to get it working,
+
```py
from __future__ import barry_as_FLUFL
print(eval('"Ruby" <> "Python"'))
@@ -3105,6 +3219,7 @@ import this
Wait, what's **this**? `this` is love :heart:
**Output:**
+
```
The Zen of Python, by Tim Peters
@@ -3147,9 +3262,9 @@ True
#### 💡 Explanation:
-* `this` module in Python is an easter egg for The Zen Of Python ([PEP 20](https://www.python.org/dev/peps/pep-0020)).
-* And if you think that's already interesting enough, check out the implementation of [this.py](https://hg.python.org/cpython/file/c3896275c0f6/Lib/this.py). Interestingly, **the code for the Zen violates itself** (and that's probably the only place where this happens).
-* Regarding the statement `love is not True or False; love is love`, ironic but it's self-explanatory (if not, please see the examples related to `is` and `is not` operators).
+- `this` module in Python is an easter egg for The Zen Of Python ([PEP 20](https://www.python.org/dev/peps/pep-0020)).
+- And if you think that's already interesting enough, check out the implementation of [this.py](https://hg.python.org/cpython/file/c3896275c0f6/Lib/this.py). Interestingly, **the code for the Zen violates itself** (and that's probably the only place where this happens).
+- Regarding the statement `love is not True or False; love is love`, ironic but it's self-explanatory (if not, please see the examples related to `is` and `is not` operators).
---
@@ -3168,6 +3283,7 @@ True
```
**Output:**
+
```py
>>> some_list = [1, 2, 3, 4, 5]
>>> does_exists_num(some_list, 4)
@@ -3188,15 +3304,18 @@ else:
```
**Output:**
+
```py
Try block executed successfully...
```
#### 💡 Explanation:
+
- The `else` clause after a loop is executed only when there's no explicit `break` after all the iterations. You can think of it as a "nobreak" clause.
- `else` clause after a try block is also called "completion clause" as reaching the `else` clause in a `try` statement means that the try block actually completed successfully.
---
+
### ▶ Ellipsis *
```py
@@ -3205,6 +3324,7 @@ def some_func():
```
**Output**
+
```py
>>> some_func()
# No output, No Error
@@ -3219,14 +3339,18 @@ Ellipsis
```
#### 💡 Explanation
+
- In Python, `Ellipsis` is a globally available built-in object which is equivalent to `...`.
+
```py
>>> ...
Ellipsis
```
+
- Ellipsis can be used for several purposes,
- + As a placeholder for code that hasn't been written yet (just like `pass` statement)
- + In slicing syntax to represent the full slices in remaining direction
+ - As a placeholder for code that hasn't been written yet (just like `pass` statement)
+ - In slicing syntax to represent the full slices in remaining direction
+
```py
>>> import numpy as np
>>> three_dimensional_array = np.arange(8).reshape(2, 2, 2)
@@ -3242,7 +3366,9 @@ Ellipsis
]
])
```
+
So our `three_dimensional_array` is an array of array of arrays. Let's say we want to print the second element (index `1`) of all the innermost arrays, we can use Ellipsis to bypass all the preceding dimensions
+
```py
>>> three_dimensional_array[:,:,1]
array([[1, 3],
@@ -3251,9 +3377,10 @@ Ellipsis
array([[1, 3],
[5, 7]])
```
+
Note: this will work for any number of dimensions. You can even select slice in first and last dimension and ignore the middle ones this way (`n_dimensional_array[firs_dim_slice, ..., last_dim_slice]`)
- + In [type hinting](https://docs.python.org/3/library/typing.html) to indicate only a part of the type (like `(Callable[..., int]` or `Tuple[str, ...]`))
- + You may also use Ellipsis as a default function argument (in the cases when you want to differentiate between the "no argument passed" and "None value passed" scenarios).
+ - In [type hinting](https://docs.python.org/3/library/typing.html) to indicate only a part of the type (like `(Callable[..., int]` or `Tuple[str, ...]`))
+ - You may also use Ellipsis as a default function argument (in the cases when you want to differentiate between the "no argument passed" and "None value passed" scenarios).
---
@@ -3262,6 +3389,7 @@ Ellipsis
The spelling is intended. Please, don't submit a patch for this.
**Output (Python 3.x):**
+
```py
>>> infinity = float('infinity')
>>> hash(infinity)
@@ -3271,6 +3399,7 @@ The spelling is intended. Please, don't submit a patch for this.
```
#### 💡 Explanation:
+
- Hash of infinity is 10⁵ x π.
- Interestingly, the hash of `float('-inf')` is "-10⁵ x π" in Python 3, whereas "-10⁵ x e" in Python 2.
@@ -3279,6 +3408,7 @@ The spelling is intended. Please, don't submit a patch for this.
### ▶ Let's mangle
1\.
+
```py
class Yo(object):
def __init__(self):
@@ -3287,6 +3417,7 @@ class Yo(object):
```
**Output:**
+
```py
>>> Yo().bro
True
@@ -3297,6 +3428,7 @@ True
```
2\.
+
```py
class Yo(object):
def __init__(self):
@@ -3306,6 +3438,7 @@ class Yo(object):
```
**Output:**
+
```py
>>> Yo().bro
True
@@ -3329,6 +3462,7 @@ class A(object):
```
**Output:**
+
```py
>>> A().__variable
Traceback (most recent call last):
@@ -3339,15 +3473,14 @@ AttributeError: 'A' object has no attribute '__variable'
'Some value'
```
-
#### 💡 Explanation:
-* [Name Mangling](https://en.wikipedia.org/wiki/Name_mangling) is used to avoid naming collisions between different namespaces.
-* In Python, the interpreter modifies (mangles) the class member names starting with `__` (double underscore a.k.a "dunder") and not ending with more than one trailing underscore by adding `_NameOfTheClass` in front.
-* So, to access `__honey` attribute in the first snippet, we had to append `_Yo` to the front, which would prevent conflicts with the same name attribute defined in any other class.
-* But then why didn't it work in the second snippet? Because name mangling excludes the names ending with double underscores.
-* The third snippet was also a consequence of name mangling. The name `__variable` in the statement `return __variable` was mangled to `_A__variable`, which also happens to be the name of the variable we declared in the outer scope.
-* Also, if the mangled name is longer than 255 characters, truncation will happen.
+- [Name Mangling](https://en.wikipedia.org/wiki/Name_mangling) is used to avoid naming collisions between different namespaces.
+- In Python, the interpreter modifies (mangles) the class member names starting with `__` (double underscore a.k.a "dunder") and not ending with more than one trailing underscore by adding `_NameOfTheClass` in front.
+- So, to access `__honey` attribute in the first snippet, we had to append `_Yo` to the front, which would prevent conflicts with the same name attribute defined in any other class.
+- But then why didn't it work in the second snippet? Because name mangling excludes the names ending with double underscores.
+- The third snippet was also a consequence of name mangling. The name `__variable` in the statement `return __variable` was mangled to `_A__variable`, which also happens to be the name of the variable we declared in the outer scope.
+- Also, if the mangled name is longer than 255 characters, truncation will happen.
---
---
@@ -3357,6 +3490,7 @@ AttributeError: 'A' object has no attribute '__variable'
### ▶ Skipping lines?
**Output:**
+
```py
>>> value = 11
>>> valuе = 32
@@ -3408,6 +3542,7 @@ def energy_receive():
```
**Output:**
+
```py
>>> energy_send(123.456)
>>> energy_receive()
@@ -3418,8 +3553,8 @@ Where's the Nobel Prize?
#### 💡 Explanation:
-* Notice that the numpy array created in the `energy_send` function is not returned, so that memory space is free to reallocate.
-* `numpy.empty()` returns the next free memory slot without reinitializing it. This memory spot just happens to be the same one that was just freed (usually, but not always).
+- Notice that the numpy array created in the `energy_send` function is not returned, so that memory space is free to reallocate.
+- `numpy.empty()` returns the next free memory slot without reinitializing it. This memory spot just happens to be the same one that was just freed (usually, but not always).
---
@@ -3449,14 +3584,15 @@ Shouldn't that be 100?
#### 💡 Explanation
-* **Don't mix tabs and spaces!** The character just preceding return is a "tab", and the code is indented by multiple of "4 spaces" elsewhere in the example.
-* This is how Python handles tabs:
+- **Don't mix tabs and spaces!** The character just preceding return is a "tab", and the code is indented by multiple of "4 spaces" elsewhere in the example.
+- This is how Python handles tabs:
> First, tabs are replaced (from left to right) by one to eight spaces such that the total number of characters up to and including the replacement is a multiple of eight <...>
-* So the "tab" at the last line of `square` function is replaced with eight spaces, and it gets into the loop.
-* Python 3 is kind enough to throw an error for such cases automatically.
+- So the "tab" at the last line of `square` function is replaced with eight spaces, and it gets into the loop.
+- Python 3 is kind enough to throw an error for such cases automatically.
**Output (Python 3.x):**
+
```py
TabError: inconsistent use of tabs and spaces in indentation
```
@@ -3466,7 +3602,6 @@ Shouldn't that be 100?
## Section: Miscellaneous
-
### ▶ `+=` is faster
@@ -3480,7 +3615,7 @@ Shouldn't that be 100?
```
#### 💡 Explanation:
-+ `+=` is faster than `+` for concatenating more than two strings because the first string (example, `s1` for `s1 += s2 + s3`) is not destroyed while calculating the complete string.
+- `+=` is faster than `+` for concatenating more than two strings because the first string (example, `s1` for `s1 += s2 + s3`) is not destroyed while calculating the complete string.
---
@@ -3555,11 +3690,13 @@ Let's increase the number of iterations by a factor of 10.
```
#### 💡 Explanation
+
- You can read more about [timeit](https://docs.python.org/3/library/timeit.html) or [%timeit](https://ipython.org/ipython-doc/dev/interactive/magics.html#magic-timeit) on these links. They are used to measure the execution time of code pieces.
- Don't use `+` for generating long strings — In Python, `str` is immutable, so the left and right strings have to be copied into the new string for every pair of concatenations. If you concatenate four strings of length 10, you'll be copying (10+10) + ((10+10)+10) + (((10+10)+10)+10) = 90 characters instead of just 40 characters. Things get quadratically worse as the number and size of the string increases (justified with the execution times of `add_bytes_with_plus` function)
- Therefore, it's advised to use `.format.` or `%` syntax (however, they are slightly slower than `+` for very short strings).
- Or better, if already you've contents available in the form of an iterable object, then use `''.join(iterable_object)` which is much faster.
- Unlike `add_bytes_with_plus` because of the `+=` optimizations discussed in the previous example, `add_string_with_plus` didn't show a quadratic increase in execution time. Had the statement been `s = s + "x" + "y" + "z"` instead of `s += "xyz"`, the increase would have been quadratic.
+
```py
def add_string_with_plus(iters):
s = ""
@@ -3572,6 +3709,7 @@ Let's increase the number of iterations by a factor of 10.
>>> %timeit -n100 add_string_with_plus(10000) # Quadratic increase in execution time
9 ms ± 298 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
```
+
- So many ways to format and create a giant string are somewhat in contrast to the [Zen of Python](https://www.python.org/dev/peps/pep-0020/), according to which,
> There should be one-- and preferably only one --obvious way to do it.
@@ -3586,6 +3724,7 @@ another_dict = {str(i): 1 for i in range(1_000_000)}
```
**Output:**
+
```py
>>> %timeit some_dict['5']
28.6 ns ± 0.115 ns per loop (mean ± std. dev. of 7 runs, 10000000 loops each)
@@ -3602,14 +3741,14 @@ KeyError: 1
>>> %timeit another_dict['5']
38.5 ns ± 0.0913 ns per loop (mean ± std. dev. of 7 runs, 10000000 loops each)
```
+
Why are same lookups becoming slower?
#### 💡 Explanation:
-+ CPython has a generic dictionary lookup function that handles all types of keys (`str`, `int`, any object ...), and a specialized one for the common case of dictionaries composed of `str`-only keys.
-+ The specialized function (named `lookdict_unicode` in CPython's [source](https://github.com/python/cpython/blob/522691c46e2ae51faaad5bbbce7d959dd61770df/Objects/dictobject.c#L841)) knows all existing keys (including the looked-up key) are strings, and uses the faster & simpler string comparison to compare keys, instead of calling the `__eq__` method.
-+ The first time a `dict` instance is accessed with a non-`str` key, it's modified so future lookups use the generic function.
-+ This process is not reversible for the particular `dict` instance, and the key doesn't even have to exist in the dictionary. That's why attempting a failed lookup has the same effect.
-
+- CPython has a generic dictionary lookup function that handles all types of keys (`str`, `int`, any object ...), and a specialized one for the common case of dictionaries composed of `str`-only keys.
+- The specialized function (named `lookdict_unicode` in CPython's [source](https://github.com/python/cpython/blob/522691c46e2ae51faaad5bbbce7d959dd61770df/Objects/dictobject.c#L841)) knows all existing keys (including the looked-up key) are strings, and uses the faster & simpler string comparison to compare keys, instead of calling the `__eq__` method.
+- The first time a `dict` instance is accessed with a non-`str` key, it's modified so future lookups use the generic function.
+- This process is not reversible for the particular `dict` instance, and the key doesn't even have to exist in the dictionary. That's why attempting a failed lookup has the same effect.
### ▶ Bloating instance `dict`s *
@@ -3630,6 +3769,7 @@ def dict_size(o):
```
**Output:** (Python 3.8, other Python 3 versions may vary a little)
+
```py
>>> o1 = SomeClass()
>>> o2 = SomeClass()
@@ -3666,25 +3806,25 @@ Let's try again... In a new interpreter:
What makes those dictionaries become bloated? And why are newly created objects bloated as well?
#### 💡 Explanation:
-+ CPython is able to reuse the same "keys" object in multiple dictionaries. This was added in [PEP 412](https://www.python.org/dev/peps/pep-0412/) with the motivation to reduce memory usage, specifically in dictionaries of instances - where keys (instance attributes) tend to be common to all instances.
-+ This optimization is entirely seamless for instance dictionaries, but it is disabled if certain assumptions are broken.
-+ Key-sharing dictionaries do not support deletion; if an instance attribute is deleted, the dictionary is "unshared", and key-sharing is disabled for all future instances of the same class.
-+ Additionally, if the dictionary keys have been resized (because new keys are inserted), they are kept shared *only* if they are used by a exactly single dictionary (this allows adding many attributes in the `__init__` of the very first created instance, without causing an "unshare"). If multiple instances exist when a resize happens, key-sharing is disabled for all future instances of the same class: CPython can't tell if your instances are using the same set of attributes anymore, and decides to bail out on attempting to share their keys.
-+ A small tip, if you aim to lower your program's memory footprint: don't delete instance attributes, and make sure to initialize all attributes in your `__init__`!
-
+- CPython is able to reuse the same "keys" object in multiple dictionaries. This was added in [PEP 412](https://www.python.org/dev/peps/pep-0412/) with the motivation to reduce memory usage, specifically in dictionaries of instances - where keys (instance attributes) tend to be common to all instances.
+- This optimization is entirely seamless for instance dictionaries, but it is disabled if certain assumptions are broken.
+- Key-sharing dictionaries do not support deletion; if an instance attribute is deleted, the dictionary is "unshared", and key-sharing is disabled for all future instances of the same class.
+- Additionally, if the dictionary keys have been resized (because new keys are inserted), they are kept shared *only* if they are used by a exactly single dictionary (this allows adding many attributes in the `__init__` of the very first created instance, without causing an "unshare"). If multiple instances exist when a resize happens, key-sharing is disabled for all future instances of the same class: CPython can't tell if your instances are using the same set of attributes anymore, and decides to bail out on attempting to share their keys.
+- A small tip, if you aim to lower your program's memory footprint: don't delete instance attributes, and make sure to initialize all attributes in your `__init__`!
### ▶ Minor Ones *
-* `join()` is a string operation instead of list operation. (sort of counter-intuitive at first usage)
+- `join()` is a string operation instead of list operation. (sort of counter-intuitive at first usage)
**💡 Explanation:** If `join()` is a method on a string, then it can operate on any iterable (list, tuple, iterators). If it were a method on a list, it'd have to be implemented separately by every type. Also, it doesn't make much sense to put a string-specific method on a generic `list` object API.
-* Few weird looking but semantically correct statements:
- + `[] = ()` is a semantically correct statement (unpacking an empty `tuple` into an empty `list`)
- + `'a'[0][0][0][0][0]` is also semantically correct, because Python doesn't have a character data type like other languages branched from C. So selecting a single character from a string returns a single-character string.
- + `3 --0-- 5 == 8` and `--5 == 5` are both semantically correct statements and evaluate to `True`.
+- Few weird looking but semantically correct statements:
+ - `[] = ()` is a semantically correct statement (unpacking an empty `tuple` into an empty `list`)
+ - `'a'[0][0][0][0][0]` is also semantically correct, because Python doesn't have a character data type like other languages branched from C. So selecting a single character from a string returns a single-character string.
+ - `3 --0-- 5 == 8` and `--5 == 5` are both semantically correct statements and evaluate to `True`.
+
+- Given that `a` is a number, `++a` and `--a` are both valid Python statements but don't behave the same way as compared with similar statements in languages like C, C++, or Java.
-* Given that `a` is a number, `++a` and `--a` are both valid Python statements but don't behave the same way as compared with similar statements in languages like C, C++, or Java.
```py
>>> a = 5
>>> a
@@ -3696,27 +3836,31 @@ What makes those dictionaries become bloated? And why are newly created objects
```
**💡 Explanation:**
- + There is no `++` operator in Python grammar. It is actually two `+` operators.
- + `++a` parses as `+(+a)` which translates to `a`. Similarly, the output of the statement `--a` can be justified.
- + This StackOverflow [thread](https://stackoverflow.com/questions/3654830/why-are-there-no-and-operators-in-python) discusses the rationale behind the absence of increment and decrement operators in Python.
+ - There is no `++` operator in Python grammar. It is actually two `+` operators.
+ - `++a` parses as `+(+a)` which translates to `a`. Similarly, the output of the statement `--a` can be justified.
+ - This StackOverflow [thread](https://stackoverflow.com/questions/3654830/why-are-there-no-and-operators-in-python) discusses the rationale behind the absence of increment and decrement operators in Python.
+
+- You must be aware of the Walrus operator in Python. But have you ever heard about *the space-invader operator*?
-* You must be aware of the Walrus operator in Python. But have you ever heard about *the space-invader operator*?
```py
>>> a = 42
>>> a -=- 1
>>> a
43
```
+
It is used as an alternative incrementation operator, together with another one
+
```py
>>> a +=+ 1
>>> a
>>> 44
```
+
**💡 Explanation:** This prank comes from [Raymond Hettinger's tweet](https://twitter.com/raymondh/status/1131103570856632321?lang=en). The space invader operator is actually just a malformatted `a -= (-1)`. Which is equivalent to `a = a - (- 1)`. Similar for the `a += (+ 1)` case.
-* Python has an undocumented [converse implication](https://en.wikipedia.org/wiki/Converse_implication) operator.
-
+- Python has an undocumented [converse implication](https://en.wikipedia.org/wiki/Converse_implication) operator.
+
```py
>>> False ** False == True
True
@@ -3729,8 +3873,8 @@ What makes those dictionaries become bloated? And why are newly created objects
```
**💡 Explanation:** If you replace `False` and `True` by 0 and 1 and do the maths, the truth table is equivalent to a converse implication operator. ([Source](https://github.com/cosmologicon/pywat/blob/master/explanation.md#the-undocumented-converse-implication-operator))
-
-* Since we are talking operators, there's also `@` operator for matrix multiplication (don't worry, this time it's for real).
+
+- Since we are talking operators, there's also `@` operator for matrix multiplication (don't worry, this time it's for real).
```py
>>> import numpy as np
@@ -3740,15 +3884,16 @@ What makes those dictionaries become bloated? And why are newly created objects
**💡 Explanation:** The `@` operator was added in Python 3.5 keeping the scientific community in mind. Any object can overload `__matmul__` magic method to define behavior for this operator.
-* From Python 3.8 onwards you can use a typical f-string syntax like `f'{some_var=}` for quick debugging. Example,
+- From Python 3.8 onwards you can use a typical f-string syntax like `f'{some_var=}` for quick debugging. Example,
+
```py
>>> some_string = "wtfpython"
>>> f'{some_string=}'
"some_string='wtfpython'"
- ```
+ ```
+
+- Python uses 2 bytes for local variable storage in functions. In theory, this means that only 65536 variables can be defined in a function. However, python has a handy solution built in that can be used to store more than 2^16 variable names. The following code demonstrates what happens in the stack when more than 65536 local variables are defined (Warning: This code prints around 2^18 lines of text, so be prepared!):
-* Python uses 2 bytes for local variable storage in functions. In theory, this means that only 65536 variables can be defined in a function. However, python has a handy solution built in that can be used to store more than 2^16 variable names. The following code demonstrates what happens in the stack when more than 65536 local variables are defined (Warning: This code prints around 2^18 lines of text, so be prepared!):
-
```py
import dis
exec("""
@@ -3760,10 +3905,10 @@ What makes those dictionaries become bloated? And why are newly created objects
print(dis.dis(f))
```
-
-* Multiple Python threads won't run your *Python code* concurrently (yes, you heard it right!). It may seem intuitive to spawn several threads and let them execute your Python code concurrently, but, because of the [Global Interpreter Lock](https://wiki.python.org/moin/GlobalInterpreterLock) in Python, all you're doing is making your threads execute on the same core turn by turn. Python threads are good for IO-bound tasks, but to achieve actual parallelization in Python for CPU-bound tasks, you might want to use the Python [multiprocessing](https://docs.python.org/3/library/multiprocessing.html) module.
-* Sometimes, the `print` method might not print values immediately. For example,
+- Multiple Python threads won't run your *Python code* concurrently (yes, you heard it right!). It may seem intuitive to spawn several threads and let them execute your Python code concurrently, but, because of the [Global Interpreter Lock](https://wiki.python.org/moin/GlobalInterpreterLock) in Python, all you're doing is making your threads execute on the same core turn by turn. Python threads are good for IO-bound tasks, but to achieve actual parallelization in Python for CPU-bound tasks, you might want to use the Python [multiprocessing](https://docs.python.org/3/library/multiprocessing.html) module.
+
+- Sometimes, the `print` method might not print values immediately. For example,
```py
# File some_file.py
@@ -3775,14 +3920,16 @@ What makes those dictionaries become bloated? And why are newly created objects
This will print the `wtfpython` after 3 seconds due to the `end` argument because the output buffer is flushed either after encountering `\n` or when the program finishes execution. We can force the buffer to flush by passing `flush=True` argument.
-* List slicing with out of the bounds indices throws no errors
+- List slicing with out of the bounds indices throws no errors
+
```py
>>> some_list = [1, 2, 3, 4, 5]
>>> some_list[111:]
[]
```
-* Slicing an iterable not always creates a new object. For example,
+- Slicing an iterable not always creates a new object. For example,
+
```py
>>> some_str = "wtfpython"
>>> some_list = ['w', 't', 'f', 'p', 'y', 't', 'h', 'o', 'n']
@@ -3792,9 +3939,9 @@ What makes those dictionaries become bloated? And why are newly created objects
True
```
-* `int('١٢٣٤٥٦٧٨٩')` returns `123456789` in Python 3. In Python, Decimal characters include digit characters, and all characters that can be used to form decimal-radix numbers, e.g. U+0660, ARABIC-INDIC DIGIT ZERO. Here's an [interesting story](https://chris.improbable.org/2014/8/25/adventures-in-unicode-digits/) related to this behavior of Python.
+- `int('١٢٣٤٥٦٧٨٩')` returns `123456789` in Python 3. In Python, Decimal characters include digit characters, and all characters that can be used to form decimal-radix numbers, e.g. U+0660, ARABIC-INDIC DIGIT ZERO. Here's an [interesting story](https://chris.improbable.org/2014/8/25/adventures-in-unicode-digits/) related to this behavior of Python.
-* You can separate numeric literals with underscores (for better readability) from Python 3 onwards.
+- You can separate numeric literals with underscores (for better readability) from Python 3 onwards.
```py
>>> six_million = 6_000_000
@@ -3805,7 +3952,8 @@ What makes those dictionaries become bloated? And why are newly created objects
4027435774
```
-* `'abc'.count('') == 4`. Here's an approximate implementation of `count` method, which would make the things more clear
+- `'abc'.count('') == 4`. Here's an approximate implementation of `count` method, which would make the things more clear
+
```py
def count(s, sub):
result = 0
@@ -3813,6 +3961,7 @@ What makes those dictionaries become bloated? And why are newly created objects
result += (s[i:i + len(sub)] == sub)
return result
```
+
The behavior is due to the matching of empty substring(`''`) with slices of length 0 in the original string.
---
@@ -3837,15 +3986,15 @@ PS: Please don't reach out with backlinking requests, no links will be added unl
The idea and design for this collection were initially inspired by Denys Dovhan's awesome project [wtfjs](https://github.com/denysdovhan/wtfjs). The overwhelming support by Pythonistas gave it the shape it is in right now.
#### Some nice Links!
-* https://www.youtube.com/watch?v=sH4XF6pKKmk
-* https://www.reddit.com/r/Python/comments/3cu6ej/what_are_some_wtf_things_about_python
-* https://sopython.com/wiki/Common_Gotchas_In_Python
-* https://stackoverflow.com/questions/530530/python-2-x-gotchas-and-landmines
-* https://stackoverflow.com/questions/1011431/common-pitfalls-in-python
-* https://www.python.org/doc/humor/
-* https://github.com/cosmologicon/pywat#the-undocumented-converse-implication-operator
-* https://github.com/wemake-services/wemake-python-styleguide/search?q=wtfpython&type=Issues
-* WFTPython discussion threads on [Hacker News](https://news.ycombinator.com/item?id=21862073) and [Reddit](https://www.reddit.com/r/programming/comments/edsh3q/what_the_fck_python_30_exploring_and/).
+- https://www.youtube.com/watch?v=sH4XF6pKKmk
+- https://www.reddit.com/r/Python/comments/3cu6ej/what_are_some_wtf_things_about_python
+- https://sopython.com/wiki/Common_Gotchas_In_Python
+- https://stackoverflow.com/questions/530530/python-2-x-gotchas-and-landmines
+- https://stackoverflow.com/questions/1011431/common-pitfalls-in-python
+- https://www.python.org/doc/humor/
+- https://github.com/cosmologicon/pywat#the-undocumented-converse-implication-operator
+- https://github.com/wemake-services/wemake-python-styleguide/search?q=wtfpython&type=Issues
+- WFTPython discussion threads on [Hacker News](https://news.ycombinator.com/item?id=21862073) and [Reddit](https://www.reddit.com/r/programming/comments/edsh3q/what_the_fck_python_30_exploring_and/).
# 🎓 License
@@ -3866,5 +4015,4 @@ If you like wtfpython, you can use these quick links to share it with your frien
I've received a few requests for the pdf (and epub) version of wtfpython. You can add your details [here](https://form.jotform.com/221593245656057) to get them as soon as they are finished.
-
**That's all folks!** For upcoming content like this, you can add your email [here](https://form.jotform.com/221593598380062).