expression cannot be assignment target python

• SyntaxError: cannot assign to expression here. Maybe you meant '==' instead of '='?

Last updated: Apr 8, 2024 Reading time · 6 min

# Table of Contents

• SyntaxError: cannot assign to literal here (Python)

Note: If you got the error: "SyntaxError: cannot assign to literal here" , click on the second subheading.

# SyntaxError: cannot assign to expression here. Maybe you meant '==' instead of '='?

The Python "SyntaxError: cannot assign to expression here. Maybe you meant '==' instead of '='?" occurs when we have an expression on the left-hand side of an assignment.

To solve the error, specify the variable name on the left and the expression on the right-hand side.

Here is an example of how the error occurs.

# Don't use hyphens in variable names

If this is how you got the error, use an underscore instead of a hyphen.

The name of a variable must start with a letter or an underscore.

A variable name can contain alpha-numeric characters ( a-z , A-Z , 0-9 ) and underscores _ .

Variable names cannot contain any other characters than the aforementioned.

# Don't use expressions on the left-hand side of an assignment

Here is another example of how the error occurs.

We have an expression on the left-hand side which is not allowed.

The variable name has to be specified on the left-hand side, and the expression on the right-hand side.

Now that the division is moved to the right-hand side, the error is resolved.

# Use double equals (==) when comparing values

If you mean to compare two values, use the double equals (==) sign.

Notice that we use double equals == when comparing two values and a single equal = sign for assignment.

Double equals (==) is used for comparison and single equals (=) is used for assignment.

If you use a single equal (=) sign when comparing values, the error is raised.

# Declaring a dictionary

If you get the error when declaring a variable that stores a dictionary, use the following syntax.

Notice that each key and value are separated by a colon and each key-value pair is separated by a comma.

The error is sometimes raised if you have a missing comma between the key-value pairs of a dictionary.

# SyntaxError: cannot assign to literal here (Python)

The Python "SyntaxError: cannot assign to literal here. Maybe you meant '==' instead of '='?" occurs when we try to assign to a literal (e.g. a string or a number).

To solve the error, specify the variable name on the left and the value on the right-hand side of the assignment.

Here are 2 examples of how the error occurs.

Literal values are strings, integers, booleans and floating-point numbers.

# Variable names on the left and values on the right-hand side

When declaring a variable make sure the variable name is on the left-hand side and the value is on the right-hand side of the assignment ( = ).

Notice that variable names should be wrapped in quotes as that is a string literal.

The string "name" is always going to be equal to the string "name" , and the number 100 is always going to be equal to the number 100 , so we cannot assign a value to a literal.

# A variable is a container that stores a specific value

You can think of a variable as a container that stores a specific value.

Variable names should not be wrapped in quotes.

# Declaring multiple variables on the same line

If you got the error while declaring multiple variables on the same line, use the following syntax.

The variable names are still on the left, and the values are on the right-hand side.

You can also use a semicolon to declare multiple variables on the same line.

However, this is uncommon and unnecessary.

# Performing an equality comparison

If you meant to perform an equality comparison, use double equals.

We use double equals == for comparison and single equals = for assignment.

If you need to check if a value is less than or equal to another, use <= .

Similarly, if you need to check if a value is greater than or equal to another, use >= operator.

Make sure you don't use a single equals = sign to compare values because single equals = is used for assignment and not for comparison.

# Assigning to a literal in a for loop

The error also occurs if you try to assign a value to a literal in a for loop by mistake.

Notice that we wrapped the item variable in quotes which makes it a string literal.

Instead, remove the quotes to declare the variable correctly.

Now we declared an item variable that gets set to the current list item on each iteration.

# Using a dictionary

If you meant to declare a dictionary, use curly braces.

A dictionary is a mapping of key-value pairs.

You can use square brackets if you need to add a key-value pair to a dictionary.

If you need to iterate over a dictionary, use a for loop with dict.items() .

The dict.items method returns a new view of the dictionary's items ((key, value) pairs).

# Valid variable names in Python

Note that variable names cannot start with numbers or be wrapped in quotes.

Variable names in Python are case-sensitive.

The 2 variables in the example are completely different and are stored in different locations in memory.

# Additional Resources

You can learn more about the related topics by checking out the following tutorials:

• SyntaxError: cannot assign to function call here in Python

Borislav Hadzhiev

Web Developer

Copyright © 2024 Borislav Hadzhiev

• Fundamentals
• All Articles

[Solved] SyntaxError: cannot assign to expression here in Python

Python raises “SyntaxError: cannot assign to expression here. Maybe you meant ‘==’ instead of ‘=’?” when you assign a value to an expression. On the other hand, this error occurs if an expression is the left-hand side operand in an assignment statement.

Additionally, Python provides you a hint, assuming you meant to use the equality operator ( == ):

Psssst! Do you want to learn web development in 2023?

• How to become a web developer when you have no degree
• How to learn to code without a technical background
• How much do web developers make in the US?

But what's a expression? You may ask. 

🎧 Debugging Jam

Calling all coders in need of a rhythm boost! Tune in to our 24/7 Lofi Coding Radio on YouTube, and let's code to the beat – subscribe for the ultimate coding groove!" Let the bug-hunting begin! 🎵💻🚀

The term "expression" refers to values or combination of values (operands) and operators that result in a value. That said, all the following items are expressions:

• 'someValue'
• 4 * (5 + 2)
• 'someText' + 'anotherText'

Most of the time, the cause of the "SyntaxError: cannot assign to expression here" error is a typo in your code - usually a missing = or invalid identifiers in assignment statements.

How to fix "SyntaxError: cannot assign to expression here"

The long error "SyntaxError: cannot assign to expression here. Maybe you meant '==' instead of '='?" occurs under various scenarios:

• Using an invalid name (identifier) in an assignment statement
• Using = instead of == in a comparison statement

Let's see some examples.

Using an invalid name (identifier) in an assignment statement:  Assignment statements bind names to values. (e.g., total_price = 49.99 )

 Based on Python syntax and semantics , the left-hand side of the assignment operator ( = ) should always be an identifier, not an expression or a literal.

Identifiers (a.k.a names) are arbitrary names you use for definitions in the source code, such as variable names, function names, and class names. For instance, in the statement age = 25 , age is the identifier.

Python identifiers  are based on the  Unicode standard annex UAX-31 , which describes the specifications for using Unicode in identifiers.

That said, you can only use alphanumeric characters and underscores for names. Otherwise, you'll get a SyntaxError. For instance, 2 + 2 = a is a syntax error because the left-hand side operator isn't a valid identifier - it's a Python expression.

A common mistake which results in the "SyntaxError: cannot assign to expression here. Maybe you meant '==' instead of '='?" error is using hyphens ( - ) in your variable names.

Hyphens are only valid in expressions like 45.54 - 12.12 . If you have a '-' in your variable name, Python's interpreter would assume it's an expression:

In the above code, Python's interpreter assumes you're trying to subtract a variable name price from another variable named total .

And since you can't have an expression as a left-hand side operand in an assignment statement, you'll get this SyntaxError.

So if your code looks like the above, you need to replace the hyphen ( - ) with an underscore ( _ ):

That's much better!

Invalid comparison statement :  Another cause of "SyntaxError: cannot assign to expression here" is using an invalid sequence of comparison operators while comparing values .

This one is more of a syntax-related mistake and rarely finds its way to the runtime, but it's worth watching.

Imagine you want to test if a number is an even number. As you probably know, if we divide a number by 2 , and the remainder is 0 , that number is even.

In Python, we use the modulo operator ( % ) to get the remainder of a division:

In the above code, once Python encounters the assignment operator ( = ), it assumes we're trying to assign 0 to x % 2 ! No wonder the response is "SyntaxError: cannot assign to expression here. Maybe you meant '==' instead of '='?".

But once we use the equality operator ( == ), the misconception goes away:

Problem solved!

Alright, I think it does it. I hope this quick guide helped you solve your problem.

Thanks for reading.

Reza Lavarian Hey 👋 I'm a software engineer, an author, and an open-source contributor. I enjoy helping people (including myself) decode the complex side of technology. I share my findings on Twitter: @rezalavarian

❤️ You might be also interested in:

• [Solved] SyntaxError: cannot assign to literal here in Python
• SyntaxError: cannot assign to function call here in Python (Solved)
• SyntaxError: invalid decimal literal in Python (Solved)
• How to learn any programming language in a short time
• Your master sword: a programming language

Never miss a guide like this!

Disclaimer: This post may contain affiliate links . I might receive a commission if a purchase is made. However, it doesn’t change the cost you’ll pay.

• Privacy Policy

Python 101 – Assignment Expressions

Assignment expressions were added to Python in version 3.8 . The general idea is that an assignment expression allows you to assign to variables within an expression.

The syntax for doing this is:

This operator has been called the “walrus operator”, although their real name is “assignment expression”. Interestingly, the CPython internals also refer to them as “named expressions”.

You can read all about assignment expressions in PEP 572 . Let’s find out how to use assignment expressions!

Using Assignment Expressions

Assignment expressions are still relatively rare. However, you need to know about assignment expressions because you will probably come across them from time to time. PEP 572 has some good examples of assignment expressions.

In these 3 examples, you are creating a variable in the expression statement itself. The first example creates the variable match by assigning it the result of the regex pattern search. The second example assigns the variable value to the result of calling a function in the while loop’s expression. Finally, you assign the result of calling f(x) to the variable y inside of a list comprehension.

It would probably help to see the difference between code that doesn’t use an assignment expression and one that does. Here’s an example of reading a file in chunks:

This code will open up a file of indeterminate size and process it 1024 bytes at a time. You will find this useful when working with very large files as it prevents you from loading the entire file into memory. If you do, you can run out of memory and cause your application or even the computer to crash.

You can shorten this code up a bit by using an assignment expression:

Here you assign the result of the read() to data within the while loop’s expression. This allows you to then use that variable inside of the while loop’s code block. It also checks that some data was returned so you don’t have to have the if not data: break stanza.

Another good example that is mentioned in PEP 572 is taken from Python’s own site.py . Here’s how the code was originally:

And this is how it could be simplified by using an assignment expression:

You move the assignment into the conditional statement’s expression, which shortens the code up nicely.

Now let’s discover some of the situations where assignment expressions can’t be used.

What You Cannot Do With Assignment Expressions

There are several cases where assignment expressions cannot be used.

One of the most interesting features of assignment expressions is that they can be used in contexts that an assignment statement cannot, such as in a lambda or the previously mentioned comprehension. However, they do NOT support some things that assignment statements can do. For example, you cannot do multiple target assignment:

Another prohibited use case is using an assignment expression at the top level of an expression statement. Here is an example from PEP 572:

There is a detailed list of other cases where assignment expressions are prohibited or discouraged in the PEP. You should check that document out if you plan to use assignment expressions often.

Wrapping Up

Assignment expressions are an elegant way to clean up certain parts of your code. The feature’s syntax is kind of similar to type hinting a variable. Once you have the hang of one, the other should become easier to do as well.

In this article, you saw some real-world examples of using the “walrus operator”. You also learned when assignment expressions shouldn’t be used. This syntax is only available in Python 3.8 or newer, so if you happen to be forced to use an older version of Python, this feature won’t be of much use to you.

Related Reading

This article is based on a chapter from Python 101, 2nd Edition , which you can purchase on Leanpub or Amazon .

If you’d like to learn more Python, then check out these tutorials:

Python 101 – How to Work with Images

Python 101 – Documenting Your Code

Python 101: An Intro to Working with JSON

Python 101 – Creating Multiple Processes

Understanding and Avoiding Syntax Errors in Python Dictionaries

In Python, there are three main types of errors: Syntax errors, Runtime errors, and Logical errors. Syntax errors can include system errors and name errors. System errors occur when the interpreter encounters extraneous tabs and spaces, given that proper indentation is essential for separating blocks of code in Python. Name errors arise when variables are misspelled, and the interpreter can’t find the specified variable within the code’s scope.

Syntax errors are raised when the Python interpreter fails to understand the given commands by the programmer. In other words, when you make any spelling mistake or typos in your code, it will most definitely raise a syntax error.

It can also be raised when defining data types. For example, if you miss the last curly bracket, “}” when defining a dictionary or capitalize the “P” while trying to print an output, it will inevitably raise a syntax error or an exception.

In this article, we will take a look at one of the most common syntax errors. When trying to define dictionaries, there shouldn’t be any assignment operator, i.e., “=” between keys and values. Instead, you should put a colon , “:” between the two.

Let’s look at the root of the above problem followed by it’s solution.

Similar: Syntax Error: EOL while scanning string literal.

Causes of Syntax Errors in Python Dictionaries

Python’s syntax errors can happen for many reasons, like using tabs and spaces incorrectly, spelling variables wrong, using operators the wrong way, or declaring things incorrectly. One common mistake is defining dictionaries wrongly by using “=” instead of “:” between keys and values. Fixing these issues usually means double-checking that everything is spelled right and that you are using things like colons, semicolons, and underscores properly.

There can be numerous reasons why you might encounter a syntax error in python. Some of them are:

• When a keyword is misspelled.
• If there are missing parenthesis when using functions, print statements, or when colons are missing at the end of for or while loops and other characters such as missing underscores(__) from def __innit__() functions.
• Wrong operators that might be present at the wrong place.
• When the variable declared is wrong or misspelled.

Differentiating between ‘=’ and ‘==’ in context of Python Dictionaries

In Python and many other programming languages, the single equals sign “=” denotes assignment, where a variable is given a specific value. In contrast, the double equals sign “==” is used to check for equality between two values or variables.

For example, if there are two variables, namely. ‘a’ and ‘b’ in your code, and you want to assign the integer values of 10 and 20 to each, respectively. In this case, you’ll need to use the assignment operator, that is, a single equal to sign(=) in your code in the following way:

But instead, if we want to check whether the values assigned to ‘a’ and ‘b’ are equal using an “if” statement, we will use the double equal to sign (==) such as,

Syntax Rules for Python Dictionaries

In Python, dictionaries are a unique type of data-storing variables. They are ordered and mutable in nature unlike lists. They are assigned in pairs, in the form of keys and values. Each element in a dictionary is indexed by its’ keys. Each value is accessed by keeping track of its respective key. There should be a colon”:” separating the value from its respective key. They are represented by curly braces ‘{}’. Each key and value pair can be separated from one another with commas ‘,’.

They can be assigned in the following manner:

our_dictionary= {"key1": "value1", "key2":"value2", "key3":"value3",....}

Do check out: [SOLVED] ‘Unexpected Keyword Argument’ TypeError in Python .

Reproducing the Syntax Error: expression cannot contain assignment, perhaps you meant “==”?

In this case, the problem might arise when instead of using a colon “:”, the interpreter encounters an assignment operator. There is a built in function in Python that can explicitly convert data into dictionaries called dict(). But this function might also cause this problem when the identifier is wrong or when there are other syntax mistakes in the code, such as missing parenthesis at the end of a statement.

The error is shown below:

Mitigating Syntax Errors in Python Dictionaries

The only straight forward solution to this problem is making sure you spell the keywords and in built functions correctly and remember to use the identifiers such as colons, semicolons and underscores properly.

Try to avoid using the dict() function for creating dictionaries. Instead, use curly braces as much as possible. If using the function is a necessity, make sure you don’t use the assignment operator incorrectly and use parentheses where necessary.

In the following code, there are no exceptions raised because the syntax is correct and the variable has been assigned correctly.

Nowadays, there are built in syntax detectors in IDEs and editors which can highlight syntax errors like this one. You can also use a debugger if necessary.

Key Takeaways: Avoiding Syntax Errors in Python Dictionaries

Having dived into the causes and solutions of Python’s syntax errors, we hope this equips you to write more efficient, error-free code. The intricacies of Python dictionaries need not be a source of worry. With the right practices, you can avoid these errors, optimizing your code and enriching your programming journey.

How will this knowledge influence your approach to using Python dictionaries in future projects?

• Python »
• 3.12.3 Documentation »
• The Python Language Reference »
• 6. Expressions
• Theme Auto Light Dark |

6. Expressions ¶

This chapter explains the meaning of the elements of expressions in Python.

Syntax Notes: In this and the following chapters, extended BNF notation will be used to describe syntax, not lexical analysis. When (one alternative of) a syntax rule has the form

and no semantics are given, the semantics of this form of name are the same as for othername .

6.1. Arithmetic conversions ¶

When a description of an arithmetic operator below uses the phrase “the numeric arguments are converted to a common type”, this means that the operator implementation for built-in types works as follows:

If either argument is a complex number, the other is converted to complex;

otherwise, if either argument is a floating point number, the other is converted to floating point;

otherwise, both must be integers and no conversion is necessary.

Some additional rules apply for certain operators (e.g., a string as a left argument to the ‘%’ operator). Extensions must define their own conversion behavior.

6.2. Atoms ¶

Atoms are the most basic elements of expressions. The simplest atoms are identifiers or literals. Forms enclosed in parentheses, brackets or braces are also categorized syntactically as atoms. The syntax for atoms is:

6.2.1. Identifiers (Names) ¶

An identifier occurring as an atom is a name. See section Identifiers and keywords for lexical definition and section Naming and binding for documentation of naming and binding.

When the name is bound to an object, evaluation of the atom yields that object. When a name is not bound, an attempt to evaluate it raises a NameError exception.

Private name mangling: When an identifier that textually occurs in a class definition begins with two or more underscore characters and does not end in two or more underscores, it is considered a private name of that class. Private names are transformed to a longer form before code is generated for them. The transformation inserts the class name, with leading underscores removed and a single underscore inserted, in front of the name. For example, the identifier __spam occurring in a class named Ham will be transformed to _Ham__spam . This transformation is independent of the syntactical context in which the identifier is used. If the transformed name is extremely long (longer than 255 characters), implementation defined truncation may happen. If the class name consists only of underscores, no transformation is done.

6.2.2. Literals ¶

Python supports string and bytes literals and various numeric literals:

Evaluation of a literal yields an object of the given type (string, bytes, integer, floating point number, complex number) with the given value. The value may be approximated in the case of floating point and imaginary (complex) literals. See section Literals for details.

All literals correspond to immutable data types, and hence the object’s identity is less important than its value. Multiple evaluations of literals with the same value (either the same occurrence in the program text or a different occurrence) may obtain the same object or a different object with the same value.

6.2.3. Parenthesized forms ¶

A parenthesized form is an optional expression list enclosed in parentheses:

A parenthesized expression list yields whatever that expression list yields: if the list contains at least one comma, it yields a tuple; otherwise, it yields the single expression that makes up the expression list.

An empty pair of parentheses yields an empty tuple object. Since tuples are immutable, the same rules as for literals apply (i.e., two occurrences of the empty tuple may or may not yield the same object).

Note that tuples are not formed by the parentheses, but rather by use of the comma. The exception is the empty tuple, for which parentheses are required — allowing unparenthesized “nothing” in expressions would cause ambiguities and allow common typos to pass uncaught.

6.2.4. Displays for lists, sets and dictionaries ¶

For constructing a list, a set or a dictionary Python provides special syntax called “displays”, each of them in two flavors:

either the container contents are listed explicitly, or

they are computed via a set of looping and filtering instructions, called a comprehension .

Common syntax elements for comprehensions are:

The comprehension consists of a single expression followed by at least one for clause and zero or more for or if clauses. In this case, the elements of the new container are those that would be produced by considering each of the for or if clauses a block, nesting from left to right, and evaluating the expression to produce an element each time the innermost block is reached.

However, aside from the iterable expression in the leftmost for clause, the comprehension is executed in a separate implicitly nested scope. This ensures that names assigned to in the target list don’t “leak” into the enclosing scope.

The iterable expression in the leftmost for clause is evaluated directly in the enclosing scope and then passed as an argument to the implicitly nested scope. Subsequent for clauses and any filter condition in the leftmost for clause cannot be evaluated in the enclosing scope as they may depend on the values obtained from the leftmost iterable. For example: [x*y for x in range(10) for y in range(x, x+10)] .

To ensure the comprehension always results in a container of the appropriate type, yield and yield from expressions are prohibited in the implicitly nested scope.

Since Python 3.6, in an async def function, an async for clause may be used to iterate over a asynchronous iterator . A comprehension in an async def function may consist of either a for or async for clause following the leading expression, may contain additional for or async for clauses, and may also use await expressions. If a comprehension contains either async for clauses or await expressions or other asynchronous comprehensions it is called an asynchronous comprehension . An asynchronous comprehension may suspend the execution of the coroutine function in which it appears. See also PEP 530 .

New in version 3.6: Asynchronous comprehensions were introduced.

Changed in version 3.8: yield and yield from prohibited in the implicitly nested scope.

Changed in version 3.11: Asynchronous comprehensions are now allowed inside comprehensions in asynchronous functions. Outer comprehensions implicitly become asynchronous.

6.2.5. List displays ¶

A list display is a possibly empty series of expressions enclosed in square brackets:

A list display yields a new list object, the contents being specified by either a list of expressions or a comprehension. When a comma-separated list of expressions is supplied, its elements are evaluated from left to right and placed into the list object in that order. When a comprehension is supplied, the list is constructed from the elements resulting from the comprehension.

6.2.6. Set displays ¶

A set display is denoted by curly braces and distinguishable from dictionary displays by the lack of colons separating keys and values:

A set display yields a new mutable set object, the contents being specified by either a sequence of expressions or a comprehension. When a comma-separated list of expressions is supplied, its elements are evaluated from left to right and added to the set object. When a comprehension is supplied, the set is constructed from the elements resulting from the comprehension.

An empty set cannot be constructed with {} ; this literal constructs an empty dictionary.

6.2.7. Dictionary displays ¶

A dictionary display is a possibly empty series of dict items (key/value pairs) enclosed in curly braces:

A dictionary display yields a new dictionary object.

If a comma-separated sequence of dict items is given, they are evaluated from left to right to define the entries of the dictionary: each key object is used as a key into the dictionary to store the corresponding value. This means that you can specify the same key multiple times in the dict item list, and the final dictionary’s value for that key will be the last one given.

A double asterisk ** denotes dictionary unpacking . Its operand must be a mapping . Each mapping item is added to the new dictionary. Later values replace values already set by earlier dict items and earlier dictionary unpackings.

New in version 3.5: Unpacking into dictionary displays, originally proposed by PEP 448 .

A dict comprehension, in contrast to list and set comprehensions, needs two expressions separated with a colon followed by the usual “for” and “if” clauses. When the comprehension is run, the resulting key and value elements are inserted in the new dictionary in the order they are produced.

Restrictions on the types of the key values are listed earlier in section The standard type hierarchy . (To summarize, the key type should be hashable , which excludes all mutable objects.) Clashes between duplicate keys are not detected; the last value (textually rightmost in the display) stored for a given key value prevails.

Changed in version 3.8: Prior to Python 3.8, in dict comprehensions, the evaluation order of key and value was not well-defined. In CPython, the value was evaluated before the key. Starting with 3.8, the key is evaluated before the value, as proposed by PEP 572 .

6.2.8. Generator expressions ¶

A generator expression is a compact generator notation in parentheses:

A generator expression yields a new generator object. Its syntax is the same as for comprehensions, except that it is enclosed in parentheses instead of brackets or curly braces.

Variables used in the generator expression are evaluated lazily when the __next__() method is called for the generator object (in the same fashion as normal generators). However, the iterable expression in the leftmost for clause is immediately evaluated, so that an error produced by it will be emitted at the point where the generator expression is defined, rather than at the point where the first value is retrieved. Subsequent for clauses and any filter condition in the leftmost for clause cannot be evaluated in the enclosing scope as they may depend on the values obtained from the leftmost iterable. For example: (x*y for x in range(10) for y in range(x, x+10)) .

The parentheses can be omitted on calls with only one argument. See section Calls for details.

To avoid interfering with the expected operation of the generator expression itself, yield and yield from expressions are prohibited in the implicitly defined generator.

If a generator expression contains either async for clauses or await expressions it is called an asynchronous generator expression . An asynchronous generator expression returns a new asynchronous generator object, which is an asynchronous iterator (see Asynchronous Iterators ).

New in version 3.6: Asynchronous generator expressions were introduced.

Changed in version 3.7: Prior to Python 3.7, asynchronous generator expressions could only appear in async def coroutines. Starting with 3.7, any function can use asynchronous generator expressions.

6.2.9. Yield expressions ¶

The yield expression is used when defining a generator function or an asynchronous generator function and thus can only be used in the body of a function definition. Using a yield expression in a function’s body causes that function to be a generator function, and using it in an async def function’s body causes that coroutine function to be an asynchronous generator function. For example:

Due to their side effects on the containing scope, yield expressions are not permitted as part of the implicitly defined scopes used to implement comprehensions and generator expressions.

Changed in version 3.8: Yield expressions prohibited in the implicitly nested scopes used to implement comprehensions and generator expressions.

Generator functions are described below, while asynchronous generator functions are described separately in section Asynchronous generator functions .

When a generator function is called, it returns an iterator known as a generator. That generator then controls the execution of the generator function. The execution starts when one of the generator’s methods is called. At that time, the execution proceeds to the first yield expression, where it is suspended again, returning the value of expression_list to the generator’s caller, or None if expression_list is omitted. By suspended, we mean that all local state is retained, including the current bindings of local variables, the instruction pointer, the internal evaluation stack, and the state of any exception handling. When the execution is resumed by calling one of the generator’s methods, the function can proceed exactly as if the yield expression were just another external call. The value of the yield expression after resuming depends on the method which resumed the execution. If __next__() is used (typically via either a for or the next() builtin) then the result is None . Otherwise, if send() is used, then the result will be the value passed in to that method.

All of this makes generator functions quite similar to coroutines; they yield multiple times, they have more than one entry point and their execution can be suspended. The only difference is that a generator function cannot control where the execution should continue after it yields; the control is always transferred to the generator’s caller.

Yield expressions are allowed anywhere in a try construct. If the generator is not resumed before it is finalized (by reaching a zero reference count or by being garbage collected), the generator-iterator’s close() method will be called, allowing any pending finally clauses to execute.

When yield from <expr> is used, the supplied expression must be an iterable. The values produced by iterating that iterable are passed directly to the caller of the current generator’s methods. Any values passed in with send() and any exceptions passed in with throw() are passed to the underlying iterator if it has the appropriate methods. If this is not the case, then send() will raise AttributeError or TypeError , while throw() will just raise the passed in exception immediately.

When the underlying iterator is complete, the value attribute of the raised StopIteration instance becomes the value of the yield expression. It can be either set explicitly when raising StopIteration , or automatically when the subiterator is a generator (by returning a value from the subgenerator).

Changed in version 3.3: Added yield from <expr> to delegate control flow to a subiterator.

The parentheses may be omitted when the yield expression is the sole expression on the right hand side of an assignment statement.

The proposal for adding generators and the yield statement to Python.

The proposal to enhance the API and syntax of generators, making them usable as simple coroutines.

The proposal to introduce the yield_from syntax, making delegation to subgenerators easy.

The proposal that expanded on PEP 492 by adding generator capabilities to coroutine functions.

6.2.9.1. Generator-iterator methods ¶

This subsection describes the methods of a generator iterator. They can be used to control the execution of a generator function.

Note that calling any of the generator methods below when the generator is already executing raises a ValueError exception.

Starts the execution of a generator function or resumes it at the last executed yield expression. When a generator function is resumed with a __next__() method, the current yield expression always evaluates to None . The execution then continues to the next yield expression, where the generator is suspended again, and the value of the expression_list is returned to __next__() ’s caller. If the generator exits without yielding another value, a StopIteration exception is raised.

This method is normally called implicitly, e.g. by a for loop, or by the built-in next() function.

Resumes the execution and “sends” a value into the generator function. The value argument becomes the result of the current yield expression. The send() method returns the next value yielded by the generator, or raises StopIteration if the generator exits without yielding another value. When send() is called to start the generator, it must be called with None as the argument, because there is no yield expression that could receive the value.

Raises an exception at the point where the generator was paused, and returns the next value yielded by the generator function. If the generator exits without yielding another value, a StopIteration exception is raised. If the generator function does not catch the passed-in exception, or raises a different exception, then that exception propagates to the caller.

In typical use, this is called with a single exception instance similar to the way the raise keyword is used.

For backwards compatibility, however, the second signature is supported, following a convention from older versions of Python. The type argument should be an exception class, and value should be an exception instance. If the value is not provided, the type constructor is called to get an instance. If traceback is provided, it is set on the exception, otherwise any existing __traceback__ attribute stored in value may be cleared.

Changed in version 3.12: The second signature (type[, value[, traceback]]) is deprecated and may be removed in a future version of Python.

Raises a GeneratorExit at the point where the generator function was paused. If the generator function then exits gracefully, is already closed, or raises GeneratorExit (by not catching the exception), close returns to its caller. If the generator yields a value, a RuntimeError is raised. If the generator raises any other exception, it is propagated to the caller. close() does nothing if the generator has already exited due to an exception or normal exit.

6.2.9.2. Examples ¶

Here is a simple example that demonstrates the behavior of generators and generator functions:

For examples using yield from , see PEP 380: Syntax for Delegating to a Subgenerator in “What’s New in Python.”

6.2.9.3. Asynchronous generator functions ¶

The presence of a yield expression in a function or method defined using async def further defines the function as an asynchronous generator function.

When an asynchronous generator function is called, it returns an asynchronous iterator known as an asynchronous generator object. That object then controls the execution of the generator function. An asynchronous generator object is typically used in an async for statement in a coroutine function analogously to how a generator object would be used in a for statement.

Calling one of the asynchronous generator’s methods returns an awaitable object, and the execution starts when this object is awaited on. At that time, the execution proceeds to the first yield expression, where it is suspended again, returning the value of expression_list to the awaiting coroutine. As with a generator, suspension means that all local state is retained, including the current bindings of local variables, the instruction pointer, the internal evaluation stack, and the state of any exception handling. When the execution is resumed by awaiting on the next object returned by the asynchronous generator’s methods, the function can proceed exactly as if the yield expression were just another external call. The value of the yield expression after resuming depends on the method which resumed the execution. If __anext__() is used then the result is None . Otherwise, if asend() is used, then the result will be the value passed in to that method.

If an asynchronous generator happens to exit early by break , the caller task being cancelled, or other exceptions, the generator’s async cleanup code will run and possibly raise exceptions or access context variables in an unexpected context–perhaps after the lifetime of tasks it depends, or during the event loop shutdown when the async-generator garbage collection hook is called. To prevent this, the caller must explicitly close the async generator by calling aclose() method to finalize the generator and ultimately detach it from the event loop.

In an asynchronous generator function, yield expressions are allowed anywhere in a try construct. However, if an asynchronous generator is not resumed before it is finalized (by reaching a zero reference count or by being garbage collected), then a yield expression within a try construct could result in a failure to execute pending finally clauses. In this case, it is the responsibility of the event loop or scheduler running the asynchronous generator to call the asynchronous generator-iterator’s aclose() method and run the resulting coroutine object, thus allowing any pending finally clauses to execute.

To take care of finalization upon event loop termination, an event loop should define a finalizer function which takes an asynchronous generator-iterator and presumably calls aclose() and executes the coroutine. This finalizer may be registered by calling sys.set_asyncgen_hooks() . When first iterated over, an asynchronous generator-iterator will store the registered finalizer to be called upon finalization. For a reference example of a finalizer method see the implementation of asyncio.Loop.shutdown_asyncgens in Lib/asyncio/base_events.py .

The expression yield from <expr> is a syntax error when used in an asynchronous generator function.

6.2.9.4. Asynchronous generator-iterator methods ¶

This subsection describes the methods of an asynchronous generator iterator, which are used to control the execution of a generator function.

Returns an awaitable which when run starts to execute the asynchronous generator or resumes it at the last executed yield expression. When an asynchronous generator function is resumed with an __anext__() method, the current yield expression always evaluates to None in the returned awaitable, which when run will continue to the next yield expression. The value of the expression_list of the yield expression is the value of the StopIteration exception raised by the completing coroutine. If the asynchronous generator exits without yielding another value, the awaitable instead raises a StopAsyncIteration exception, signalling that the asynchronous iteration has completed.

This method is normally called implicitly by a async for loop.

Returns an awaitable which when run resumes the execution of the asynchronous generator. As with the send() method for a generator, this “sends” a value into the asynchronous generator function, and the value argument becomes the result of the current yield expression. The awaitable returned by the asend() method will return the next value yielded by the generator as the value of the raised StopIteration , or raises StopAsyncIteration if the asynchronous generator exits without yielding another value. When asend() is called to start the asynchronous generator, it must be called with None as the argument, because there is no yield expression that could receive the value.

Returns an awaitable that raises an exception of type type at the point where the asynchronous generator was paused, and returns the next value yielded by the generator function as the value of the raised StopIteration exception. If the asynchronous generator exits without yielding another value, a StopAsyncIteration exception is raised by the awaitable. If the generator function does not catch the passed-in exception, or raises a different exception, then when the awaitable is run that exception propagates to the caller of the awaitable.

Returns an awaitable that when run will throw a GeneratorExit into the asynchronous generator function at the point where it was paused. If the asynchronous generator function then exits gracefully, is already closed, or raises GeneratorExit (by not catching the exception), then the returned awaitable will raise a StopIteration exception. Any further awaitables returned by subsequent calls to the asynchronous generator will raise a StopAsyncIteration exception. If the asynchronous generator yields a value, a RuntimeError is raised by the awaitable. If the asynchronous generator raises any other exception, it is propagated to the caller of the awaitable. If the asynchronous generator has already exited due to an exception or normal exit, then further calls to aclose() will return an awaitable that does nothing.

6.3. Primaries ¶

Primaries represent the most tightly bound operations of the language. Their syntax is:

6.3.1. Attribute references ¶

An attribute reference is a primary followed by a period and a name:

The primary must evaluate to an object of a type that supports attribute references, which most objects do. This object is then asked to produce the attribute whose name is the identifier. The type and value produced is determined by the object. Multiple evaluations of the same attribute reference may yield different objects.

This production can be customized by overriding the __getattribute__() method or the __getattr__() method. The __getattribute__() method is called first and either returns a value or raises AttributeError if the attribute is not available.

If an AttributeError is raised and the object has a __getattr__() method, that method is called as a fallback.

6.3.2. Subscriptions ¶

The subscription of an instance of a container class will generally select an element from the container. The subscription of a generic class will generally return a GenericAlias object.

When an object is subscripted, the interpreter will evaluate the primary and the expression list.

The primary must evaluate to an object that supports subscription. An object may support subscription through defining one or both of __getitem__() and __class_getitem__() . When the primary is subscripted, the evaluated result of the expression list will be passed to one of these methods. For more details on when __class_getitem__ is called instead of __getitem__ , see __class_getitem__ versus __getitem__ .

If the expression list contains at least one comma, it will evaluate to a tuple containing the items of the expression list. Otherwise, the expression list will evaluate to the value of the list’s sole member.

For built-in objects, there are two types of objects that support subscription via __getitem__() :

Mappings. If the primary is a mapping , the expression list must evaluate to an object whose value is one of the keys of the mapping, and the subscription selects the value in the mapping that corresponds to that key. An example of a builtin mapping class is the dict class.

Sequences. If the primary is a sequence , the expression list must evaluate to an int or a slice (as discussed in the following section). Examples of builtin sequence classes include the str , list and tuple classes.

The formal syntax makes no special provision for negative indices in sequences . However, built-in sequences all provide a __getitem__() method that interprets negative indices by adding the length of the sequence to the index so that, for example, x[-1] selects the last item of x . The resulting value must be a nonnegative integer less than the number of items in the sequence, and the subscription selects the item whose index is that value (counting from zero). Since the support for negative indices and slicing occurs in the object’s __getitem__() method, subclasses overriding this method will need to explicitly add that support.

A string is a special kind of sequence whose items are characters . A character is not a separate data type but a string of exactly one character.

6.3.3. Slicings ¶

A slicing selects a range of items in a sequence object (e.g., a string, tuple or list). Slicings may be used as expressions or as targets in assignment or del statements. The syntax for a slicing:

There is ambiguity in the formal syntax here: anything that looks like an expression list also looks like a slice list, so any subscription can be interpreted as a slicing. Rather than further complicating the syntax, this is disambiguated by defining that in this case the interpretation as a subscription takes priority over the interpretation as a slicing (this is the case if the slice list contains no proper slice).

The semantics for a slicing are as follows. The primary is indexed (using the same __getitem__() method as normal subscription) with a key that is constructed from the slice list, as follows. If the slice list contains at least one comma, the key is a tuple containing the conversion of the slice items; otherwise, the conversion of the lone slice item is the key. The conversion of a slice item that is an expression is that expression. The conversion of a proper slice is a slice object (see section The standard type hierarchy ) whose start , stop and step attributes are the values of the expressions given as lower bound, upper bound and stride, respectively, substituting None for missing expressions.

6.3.4. Calls ¶

A call calls a callable object (e.g., a function ) with a possibly empty series of arguments :

An optional trailing comma may be present after the positional and keyword arguments but does not affect the semantics.

The primary must evaluate to a callable object (user-defined functions, built-in functions, methods of built-in objects, class objects, methods of class instances, and all objects having a __call__() method are callable). All argument expressions are evaluated before the call is attempted. Please refer to section Function definitions for the syntax of formal parameter lists.

If keyword arguments are present, they are first converted to positional arguments, as follows. First, a list of unfilled slots is created for the formal parameters. If there are N positional arguments, they are placed in the first N slots. Next, for each keyword argument, the identifier is used to determine the corresponding slot (if the identifier is the same as the first formal parameter name, the first slot is used, and so on). If the slot is already filled, a TypeError exception is raised. Otherwise, the argument is placed in the slot, filling it (even if the expression is None , it fills the slot). When all arguments have been processed, the slots that are still unfilled are filled with the corresponding default value from the function definition. (Default values are calculated, once, when the function is defined; thus, a mutable object such as a list or dictionary used as default value will be shared by all calls that don’t specify an argument value for the corresponding slot; this should usually be avoided.) If there are any unfilled slots for which no default value is specified, a TypeError exception is raised. Otherwise, the list of filled slots is used as the argument list for the call.

CPython implementation detail: An implementation may provide built-in functions whose positional parameters do not have names, even if they are ‘named’ for the purpose of documentation, and which therefore cannot be supplied by keyword. In CPython, this is the case for functions implemented in C that use PyArg_ParseTuple() to parse their arguments.

If there are more positional arguments than there are formal parameter slots, a TypeError exception is raised, unless a formal parameter using the syntax *identifier is present; in this case, that formal parameter receives a tuple containing the excess positional arguments (or an empty tuple if there were no excess positional arguments).

If any keyword argument does not correspond to a formal parameter name, a TypeError exception is raised, unless a formal parameter using the syntax **identifier is present; in this case, that formal parameter receives a dictionary containing the excess keyword arguments (using the keywords as keys and the argument values as corresponding values), or a (new) empty dictionary if there were no excess keyword arguments.

If the syntax *expression appears in the function call, expression must evaluate to an iterable . Elements from these iterables are treated as if they were additional positional arguments. For the call f(x1, x2, *y, x3, x4) , if y evaluates to a sequence y1 , …, yM , this is equivalent to a call with M+4 positional arguments x1 , x2 , y1 , …, yM , x3 , x4 .

A consequence of this is that although the *expression syntax may appear after explicit keyword arguments, it is processed before the keyword arguments (and any **expression arguments – see below). So:

It is unusual for both keyword arguments and the *expression syntax to be used in the same call, so in practice this confusion does not often arise.

If the syntax **expression appears in the function call, expression must evaluate to a mapping , the contents of which are treated as additional keyword arguments. If a parameter matching a key has already been given a value (by an explicit keyword argument, or from another unpacking), a TypeError exception is raised.

When **expression is used, each key in this mapping must be a string. Each value from the mapping is assigned to the first formal parameter eligible for keyword assignment whose name is equal to the key. A key need not be a Python identifier (e.g. "max-temp °F" is acceptable, although it will not match any formal parameter that could be declared). If there is no match to a formal parameter the key-value pair is collected by the ** parameter, if there is one, or if there is not, a TypeError exception is raised.

Formal parameters using the syntax *identifier or **identifier cannot be used as positional argument slots or as keyword argument names.

Changed in version 3.5: Function calls accept any number of * and ** unpackings, positional arguments may follow iterable unpackings ( * ), and keyword arguments may follow dictionary unpackings ( ** ). Originally proposed by PEP 448 .

A call always returns some value, possibly None , unless it raises an exception. How this value is computed depends on the type of the callable object.

The code block for the function is executed, passing it the argument list. The first thing the code block will do is bind the formal parameters to the arguments; this is described in section Function definitions . When the code block executes a return statement, this specifies the return value of the function call.

The result is up to the interpreter; see Built-in Functions for the descriptions of built-in functions and methods.

A new instance of that class is returned.

The corresponding user-defined function is called, with an argument list that is one longer than the argument list of the call: the instance becomes the first argument.

The class must define a __call__() method; the effect is then the same as if that method was called.

6.4. Await expression ¶

Suspend the execution of coroutine on an awaitable object. Can only be used inside a coroutine function .

New in version 3.5.

6.5. The power operator ¶

The power operator binds more tightly than unary operators on its left; it binds less tightly than unary operators on its right. The syntax is:

Thus, in an unparenthesized sequence of power and unary operators, the operators are evaluated from right to left (this does not constrain the evaluation order for the operands): -1**2 results in -1 .

The power operator has the same semantics as the built-in pow() function, when called with two arguments: it yields its left argument raised to the power of its right argument. The numeric arguments are first converted to a common type, and the result is of that type.

For int operands, the result has the same type as the operands unless the second argument is negative; in that case, all arguments are converted to float and a float result is delivered. For example, 10**2 returns 100 , but 10**-2 returns 0.01 .

Raising 0.0 to a negative power results in a ZeroDivisionError . Raising a negative number to a fractional power results in a complex number. (In earlier versions it raised a ValueError .)

This operation can be customized using the special __pow__() method.

6.6. Unary arithmetic and bitwise operations ¶

All unary arithmetic and bitwise operations have the same priority:

The unary - (minus) operator yields the negation of its numeric argument; the operation can be overridden with the __neg__() special method.

The unary + (plus) operator yields its numeric argument unchanged; the operation can be overridden with the __pos__() special method.

The unary ~ (invert) operator yields the bitwise inversion of its integer argument. The bitwise inversion of x is defined as -(x+1) . It only applies to integral numbers or to custom objects that override the __invert__() special method.

In all three cases, if the argument does not have the proper type, a TypeError exception is raised.

6.7. Binary arithmetic operations ¶

The binary arithmetic operations have the conventional priority levels. Note that some of these operations also apply to certain non-numeric types. Apart from the power operator, there are only two levels, one for multiplicative operators and one for additive operators:

The * (multiplication) operator yields the product of its arguments. The arguments must either both be numbers, or one argument must be an integer and the other must be a sequence. In the former case, the numbers are converted to a common type and then multiplied together. In the latter case, sequence repetition is performed; a negative repetition factor yields an empty sequence.

This operation can be customized using the special __mul__() and __rmul__() methods.

The @ (at) operator is intended to be used for matrix multiplication. No builtin Python types implement this operator.

The / (division) and // (floor division) operators yield the quotient of their arguments. The numeric arguments are first converted to a common type. Division of integers yields a float, while floor division of integers results in an integer; the result is that of mathematical division with the ‘floor’ function applied to the result. Division by zero raises the ZeroDivisionError exception.

This operation can be customized using the special __truediv__() and __floordiv__() methods.

The % (modulo) operator yields the remainder from the division of the first argument by the second. The numeric arguments are first converted to a common type. A zero right argument raises the ZeroDivisionError exception. The arguments may be floating point numbers, e.g., 3.14%0.7 equals 0.34 (since 3.14 equals 4*0.7 + 0.34 .) The modulo operator always yields a result with the same sign as its second operand (or zero); the absolute value of the result is strictly smaller than the absolute value of the second operand [ 1 ] .

The floor division and modulo operators are connected by the following identity: x == (x//y)*y + (x%y) . Floor division and modulo are also connected with the built-in function divmod() : divmod(x, y) == (x//y, x%y) . [ 2 ] .

In addition to performing the modulo operation on numbers, the % operator is also overloaded by string objects to perform old-style string formatting (also known as interpolation). The syntax for string formatting is described in the Python Library Reference, section printf-style String Formatting .

The modulo operation can be customized using the special __mod__() method.

The floor division operator, the modulo operator, and the divmod() function are not defined for complex numbers. Instead, convert to a floating point number using the abs() function if appropriate.

The + (addition) operator yields the sum of its arguments. The arguments must either both be numbers or both be sequences of the same type. In the former case, the numbers are converted to a common type and then added together. In the latter case, the sequences are concatenated.

This operation can be customized using the special __add__() and __radd__() methods.

The - (subtraction) operator yields the difference of its arguments. The numeric arguments are first converted to a common type.

This operation can be customized using the special __sub__() method.

6.8. Shifting operations ¶

The shifting operations have lower priority than the arithmetic operations:

These operators accept integers as arguments. They shift the first argument to the left or right by the number of bits given by the second argument.

This operation can be customized using the special __lshift__() and __rshift__() methods.

A right shift by n bits is defined as floor division by pow(2,n) . A left shift by n bits is defined as multiplication with pow(2,n) .

6.9. Binary bitwise operations ¶

Each of the three bitwise operations has a different priority level:

The & operator yields the bitwise AND of its arguments, which must be integers or one of them must be a custom object overriding __and__() or __rand__() special methods.

The ^ operator yields the bitwise XOR (exclusive OR) of its arguments, which must be integers or one of them must be a custom object overriding __xor__() or __rxor__() special methods.

The | operator yields the bitwise (inclusive) OR of its arguments, which must be integers or one of them must be a custom object overriding __or__() or __ror__() special methods.

6.10. Comparisons ¶

Unlike C, all comparison operations in Python have the same priority, which is lower than that of any arithmetic, shifting or bitwise operation. Also unlike C, expressions like a < b < c have the interpretation that is conventional in mathematics:

Comparisons yield boolean values: True or False . Custom rich comparison methods may return non-boolean values. In this case Python will call bool() on such value in boolean contexts.

Comparisons can be chained arbitrarily, e.g., x < y <= z is equivalent to x < y and y <= z , except that y is evaluated only once (but in both cases z is not evaluated at all when x < y is found to be false).

Formally, if a , b , c , …, y , z are expressions and op1 , op2 , …, opN are comparison operators, then a op1 b op2 c ... y opN z is equivalent to a op1 b and b op2 c and ... y opN z , except that each expression is evaluated at most once.

Note that a op1 b op2 c doesn’t imply any kind of comparison between a and c , so that, e.g., x < y > z is perfectly legal (though perhaps not pretty).

6.10.1. Value comparisons ¶

The operators < , > , == , >= , <= , and != compare the values of two objects. The objects do not need to have the same type.

Chapter Objects, values and types states that objects have a value (in addition to type and identity). The value of an object is a rather abstract notion in Python: For example, there is no canonical access method for an object’s value. Also, there is no requirement that the value of an object should be constructed in a particular way, e.g. comprised of all its data attributes. Comparison operators implement a particular notion of what the value of an object is. One can think of them as defining the value of an object indirectly, by means of their comparison implementation.

Because all types are (direct or indirect) subtypes of object , they inherit the default comparison behavior from object . Types can customize their comparison behavior by implementing rich comparison methods like __lt__() , described in Basic customization .

The default behavior for equality comparison ( == and != ) is based on the identity of the objects. Hence, equality comparison of instances with the same identity results in equality, and equality comparison of instances with different identities results in inequality. A motivation for this default behavior is the desire that all objects should be reflexive (i.e. x is y implies x == y ).

A default order comparison ( < , > , <= , and >= ) is not provided; an attempt raises TypeError . A motivation for this default behavior is the lack of a similar invariant as for equality.

The behavior of the default equality comparison, that instances with different identities are always unequal, may be in contrast to what types will need that have a sensible definition of object value and value-based equality. Such types will need to customize their comparison behavior, and in fact, a number of built-in types have done that.

The following list describes the comparison behavior of the most important built-in types.

Numbers of built-in numeric types ( Numeric Types — int, float, complex ) and of the standard library types fractions.Fraction and decimal.Decimal can be compared within and across their types, with the restriction that complex numbers do not support order comparison. Within the limits of the types involved, they compare mathematically (algorithmically) correct without loss of precision.

The not-a-number values float('NaN') and decimal.Decimal('NaN') are special. Any ordered comparison of a number to a not-a-number value is false. A counter-intuitive implication is that not-a-number values are not equal to themselves. For example, if x = float('NaN') , 3 < x , x < 3 and x == x are all false, while x != x is true. This behavior is compliant with IEEE 754.

None and NotImplemented are singletons. PEP 8 advises that comparisons for singletons should always be done with is or is not , never the equality operators.

Binary sequences (instances of bytes or bytearray ) can be compared within and across their types. They compare lexicographically using the numeric values of their elements.

Strings (instances of str ) compare lexicographically using the numerical Unicode code points (the result of the built-in function ord() ) of their characters. [ 3 ]

Strings and binary sequences cannot be directly compared.

Sequences (instances of tuple , list , or range ) can be compared only within each of their types, with the restriction that ranges do not support order comparison. Equality comparison across these types results in inequality, and ordering comparison across these types raises TypeError .

Sequences compare lexicographically using comparison of corresponding elements. The built-in containers typically assume identical objects are equal to themselves. That lets them bypass equality tests for identical objects to improve performance and to maintain their internal invariants.

Lexicographical comparison between built-in collections works as follows:

For two collections to compare equal, they must be of the same type, have the same length, and each pair of corresponding elements must compare equal (for example, [1,2] == (1,2) is false because the type is not the same).

Collections that support order comparison are ordered the same as their first unequal elements (for example, [1,2,x] <= [1,2,y] has the same value as x <= y ). If a corresponding element does not exist, the shorter collection is ordered first (for example, [1,2] < [1,2,3] is true).

Mappings (instances of dict ) compare equal if and only if they have equal (key, value) pairs. Equality comparison of the keys and values enforces reflexivity.

Order comparisons ( < , > , <= , and >= ) raise TypeError .

Sets (instances of set or frozenset ) can be compared within and across their types.

They define order comparison operators to mean subset and superset tests. Those relations do not define total orderings (for example, the two sets {1,2} and {2,3} are not equal, nor subsets of one another, nor supersets of one another). Accordingly, sets are not appropriate arguments for functions which depend on total ordering (for example, min() , max() , and sorted() produce undefined results given a list of sets as inputs).

Comparison of sets enforces reflexivity of its elements.

Most other built-in types have no comparison methods implemented, so they inherit the default comparison behavior.

User-defined classes that customize their comparison behavior should follow some consistency rules, if possible:

Equality comparison should be reflexive. In other words, identical objects should compare equal:

x is y implies x == y

Comparison should be symmetric. In other words, the following expressions should have the same result:

x == y and y == x x != y and y != x x < y and y > x x <= y and y >= x

Comparison should be transitive. The following (non-exhaustive) examples illustrate that:

x > y and y > z implies x > z x < y and y <= z implies x < z

Inverse comparison should result in the boolean negation. In other words, the following expressions should have the same result:

x == y and not x != y x < y and not x >= y (for total ordering) x > y and not x <= y (for total ordering)

The last two expressions apply to totally ordered collections (e.g. to sequences, but not to sets or mappings). See also the total_ordering() decorator.

The hash() result should be consistent with equality. Objects that are equal should either have the same hash value, or be marked as unhashable.

Python does not enforce these consistency rules. In fact, the not-a-number values are an example for not following these rules.

6.10.2. Membership test operations ¶

The operators in and not in test for membership. x in s evaluates to True if x is a member of s , and False otherwise. x not in s returns the negation of x in s . All built-in sequences and set types support this as well as dictionary, for which in tests whether the dictionary has a given key. For container types such as list, tuple, set, frozenset, dict, or collections.deque, the expression x in y is equivalent to any(x is e or x == e for e in y) .

For the string and bytes types, x in y is True if and only if x is a substring of y . An equivalent test is y.find(x) != -1 . Empty strings are always considered to be a substring of any other string, so "" in "abc" will return True .

For user-defined classes which define the __contains__() method, x in y returns True if y.__contains__(x) returns a true value, and False otherwise.

For user-defined classes which do not define __contains__() but do define __iter__() , x in y is True if some value z , for which the expression x is z or x == z is true, is produced while iterating over y . If an exception is raised during the iteration, it is as if in raised that exception.

Lastly, the old-style iteration protocol is tried: if a class defines __getitem__() , x in y is True if and only if there is a non-negative integer index i such that x is y[i] or x == y[i] , and no lower integer index raises the IndexError exception. (If any other exception is raised, it is as if in raised that exception).

The operator not in is defined to have the inverse truth value of in .

6.10.3. Identity comparisons ¶

The operators is and is not test for an object’s identity: x is y is true if and only if x and y are the same object. An Object’s identity is determined using the id() function. x is not y yields the inverse truth value. [ 4 ]

6.11. Boolean operations ¶

In the context of Boolean operations, and also when expressions are used by control flow statements, the following values are interpreted as false: False , None , numeric zero of all types, and empty strings and containers (including strings, tuples, lists, dictionaries, sets and frozensets). All other values are interpreted as true. User-defined objects can customize their truth value by providing a __bool__() method.

The operator not yields True if its argument is false, False otherwise.

The expression x and y first evaluates x ; if x is false, its value is returned; otherwise, y is evaluated and the resulting value is returned.

The expression x or y first evaluates x ; if x is true, its value is returned; otherwise, y is evaluated and the resulting value is returned.

Note that neither and nor or restrict the value and type they return to False and True , but rather return the last evaluated argument. This is sometimes useful, e.g., if s is a string that should be replaced by a default value if it is empty, the expression s or 'foo' yields the desired value. Because not has to create a new value, it returns a boolean value regardless of the type of its argument (for example, not 'foo' produces False rather than '' .)

6.12. Assignment expressions ¶

An assignment expression (sometimes also called a “named expression” or “walrus”) assigns an expression to an identifier , while also returning the value of the expression .

One common use case is when handling matched regular expressions:

Or, when processing a file stream in chunks:

Assignment expressions must be surrounded by parentheses when used as expression statements and when used as sub-expressions in slicing, conditional, lambda, keyword-argument, and comprehension-if expressions and in assert , with , and assignment statements. In all other places where they can be used, parentheses are not required, including in if and while statements.

New in version 3.8: See PEP 572 for more details about assignment expressions.

6.13. Conditional expressions ¶

Conditional expressions (sometimes called a “ternary operator”) have the lowest priority of all Python operations.

The expression x if C else y first evaluates the condition, C rather than x . If C is true, x is evaluated and its value is returned; otherwise, y is evaluated and its value is returned.

See PEP 308 for more details about conditional expressions.

6.14. Lambdas ¶

Lambda expressions (sometimes called lambda forms) are used to create anonymous functions. The expression lambda parameters: expression yields a function object. The unnamed object behaves like a function object defined with:

See section Function definitions for the syntax of parameter lists. Note that functions created with lambda expressions cannot contain statements or annotations.

6.15. Expression lists ¶

Except when part of a list or set display, an expression list containing at least one comma yields a tuple. The length of the tuple is the number of expressions in the list. The expressions are evaluated from left to right.

An asterisk * denotes iterable unpacking . Its operand must be an iterable . The iterable is expanded into a sequence of items, which are included in the new tuple, list, or set, at the site of the unpacking.

New in version 3.5: Iterable unpacking in expression lists, originally proposed by PEP 448 .

A trailing comma is required only to create a one-item tuple, such as 1, ; it is optional in all other cases. A single expression without a trailing comma doesn’t create a tuple, but rather yields the value of that expression. (To create an empty tuple, use an empty pair of parentheses: () .)

6.16. Evaluation order ¶

Python evaluates expressions from left to right. Notice that while evaluating an assignment, the right-hand side is evaluated before the left-hand side.

In the following lines, expressions will be evaluated in the arithmetic order of their suffixes:

6.17. Operator precedence ¶

The following table summarizes the operator precedence in Python, from highest precedence (most binding) to lowest precedence (least binding). Operators in the same box have the same precedence. Unless the syntax is explicitly given, operators are binary. Operators in the same box group left to right (except for exponentiation and conditional expressions, which group from right to left).

Note that comparisons, membership tests, and identity tests, all have the same precedence and have a left-to-right chaining feature as described in the Comparisons section.

Table of Contents

• 6.1. Arithmetic conversions
• 6.2.1. Identifiers (Names)
• 6.2.2. Literals
• 6.2.3. Parenthesized forms
• 6.2.4. Displays for lists, sets and dictionaries
• 6.2.5. List displays
• 6.2.6. Set displays
• 6.2.7. Dictionary displays
• 6.2.8. Generator expressions
• 6.2.9.1. Generator-iterator methods
• 6.2.9.2. Examples
• 6.2.9.3. Asynchronous generator functions
• 6.2.9.4. Asynchronous generator-iterator methods
• 6.3.1. Attribute references
• 6.3.2. Subscriptions
• 6.3.3. Slicings
• 6.3.4. Calls
• 6.4. Await expression
• 6.5. The power operator
• 6.6. Unary arithmetic and bitwise operations
• 6.7. Binary arithmetic operations
• 6.8. Shifting operations
• 6.9. Binary bitwise operations
• 6.10.1. Value comparisons
• 6.10.2. Membership test operations
• 6.10.3. Identity comparisons
• 6.11. Boolean operations
• 6.12. Assignment expressions
• 6.13. Conditional expressions
• 6.14. Lambdas
• 6.15. Expression lists
• 6.16. Evaluation order
• 6.17. Operator precedence

Previous topic

5. The import system

7. Simple statements

• Report a Bug
• Show Source

How to fix Python SyntaxError: cannot assign to function call

by Nathan Sebhastian

Posted on Jan 15, 2023

Reading time: 2 minutes

Python shows SyntaxError: cannot assign to function call error when you assign a value to the result of a function call.

Here’s an example code that triggers this error:

In the code above, the number 5 is assigned to the result of calling the add() function.

Python responds with the error below:

In Python, a function call is an expression that returns a value. It cannot be used as the target of an assignment.

To fix this error, you need to avoid assigning a value to a function call result.

When you want to declare a variable, you need to specify the variable name on the left side of the operator and the value on the right side of the operator:

You can also assign the function call result to a variable as follows:

If you want to compare the result of a function call to a value, you need to use the equality comparison operator == .

The following code example is valid because it checks whether the result of add() function equals to 5 :

A single equal operator = assigns the right side of the operator to the left side, while double equals == compares if the left side is equal to the right side.

You can even assign the result of the comparison to a variable like this:

Finally, you can also encounter this error when working with Python iterable objects (like a list, dict, or tuple)

You can’t reassign or compare a list element as long as you used the parentheses as shown below:

When you use parentheses with the equality comparison operator, Python responds with TypeError: 'list' object is not callable .

Whether you want to reassign or compare a list element, you need to use the square brackets like this:

And that’s how you fix Python SyntaxError: cannot assign to function call error.

Take your skills to the next level ⚡️

I'm sending out an occasional email with the latest tutorials on programming, web development, and statistics. Drop your email in the box below and I'll send new stuff straight into your inbox!

Hello! This website is dedicated to help you learn tech and data science skills with its step-by-step, beginner-friendly tutorials. Learn statistics, JavaScript and other programming languages using clear examples written for people.

Learn more about this website

Connect with me on Twitter

Or LinkedIn

Type the keyword below and hit enter

Click to see all tutorials tagged with:

Python Enhancement Proposals

• Python »
• PEP Index »

PEP 379 – Adding an Assignment Expression

Motivation and summary, specification, examples from the standard library.

This PEP adds a new assignment expression to the Python language to make it possible to assign the result of an expression in almost any place. The new expression will allow the assignment of the result of an expression at first use (in a comparison for example).

Issue1714448 “if something as x:” [1] describes a feature to allow assignment of the result of an expression in an if statement to a name. It supposed that the as syntax could be borrowed for this purpose. Many times it is not the expression itself that is interesting, rather one of the terms that make up the expression. To be clear, something like this:

seems awfully limited, when this:

is probably the desired result.

See the Examples section near the end.

A new expression is proposed with the (nominal) syntax:

This single expression does the following:

• Evaluate the value of EXPR , an arbitrary expression;
• Assign the result to VAR , a single assignment target; and
• Leave the result of EXPR on the Top of Stack (TOS)

Here -> or ( RARROW ) has been used to illustrate the concept that the result of EXPR is assigned to VAR .

The translation of the proposed syntax is:

The assignment target can be either an attribute, a subscript or name:

This expression should be available anywhere that an expression is currently accepted.

All exceptions that are currently raised during invalid assignments will continue to be raised when using the assignment expression. For example, a NameError will be raised when in example 1 and 2 above if name is not previously defined, or an IndexError if index 0 was out of range.

The following two examples were chosen after a brief search through the standard library, specifically both are from ast.py which happened to be open at the time of the search.

Using assignment expression:

The examples shown below highlight some of the desirable features of the assignment expression, and some of the possible corner cases.

• Assignment in an if statement for use later: def expensive (): import time ; time . sleep ( 1 ) return 'spam' if expensive () -> res in ( 'spam' , 'eggs' ): dosomething ( res )
• Assignment in a while loop clause: while len ( expensive () -> res ) == 4 : dosomething ( res )
• Keep the iterator object from the for loop: for ch in expensive () -> res : sell_on_internet ( res )
• Corner case: for ch -> please_dont in expensive (): pass # who would want to do this? Not I.

This document has been placed in the public domain.

Source: https://github.com/python/peps/blob/main/peps/pep-0379.rst

Last modified: 2023-09-09 17:39:29 GMT

Walrus `SyntaxError: assignment expression cannot be used in a comprehension iterable expression`

What could be the reason that they disabled the use of walrus here also,

gives the error described in the title of this post.

have to instead use,

just found out there is a paragraph for it in the pep. some issue with symbol table analyser.

one can always do something like this,

Related Topics