My understanding was that Python strings are immutable.

I tried the following code:

a = "Dog"
b = "eats"
c = "treats"

print a, b, c
# Dog eats treats

print a + " " + b + " " + c
# Dog eats treats

print a
# Dog

a = a + " " + b + " " + c
print a
# Dog eats treats
# !!!

Shouldn't Python have prevented the assignment? I am probably missing something.

Any idea?

  • 58
    The string itself is immutable but the label can change. – mitch Feb 1 '12 at 14:58
  • 7
    Assigning a new value to an existing variable is perfectly valid. Python does not have constants. This is independent from data type mutability. – Felix Kling Feb 1 '12 at 15:00
  • 16
    You may want to take a look at the id() function. a will have a different id before and after the assignment, indicating that it is pointing at different objects. Likewise with code like b = a you'll find that a and b will have the same id, indicating they're referencing the same object. – DRH Feb 1 '12 at 15:03
  • 2
    See python.net/~goodger/projects/pycon/2007/idiomatic/… – user395760 Feb 1 '12 at 15:33
  • The link from delnan is exactly what I was refering to. – mitch Feb 1 '12 at 16:47

22 Answers 22


First a pointed to the string "Dog". Then you changed the variable a to point at a new string "Dog eats treats". You didn't actually mutate the string "Dog". Strings are immutable, variables can point at whatever they want.


The string objects themselves are immutable.

The variable, a, which points to the string, is mutable.


a = "Foo"
# a now points to "Foo"
b = a
# b points to the same "Foo" that a points to
a = a + a
# a points to the new string "FooFoo", but b still points to the old "Foo"

print a
print b
# Outputs:

# FooFoo
# Foo

# Observe that b hasn't changed, even though a has.
  • @jason try the same kind of operations with lists (that are mutable) to see the difference a.append(3) corresponds to a = a + "Foo" – jimifiki Feb 1 '12 at 15:20
  • 1
    @jimifiki a.append(3) is not the same as a = a + 3. It's not even a += 3 (inplace addition is equivalent to .extend, not to .append). – user395760 Feb 1 '12 at 15:34
  • @delnan and so, what? For the sake of showing that strings and lists behave differently you can assume that a = a+"Foo" is the same as a.append(something). In any case it's not the same. Obviously. Were you happier reading a.extend([something]) instead of a.append(something)? I don't see that big difference in this context. But probably I'm missing something. Thruth depends on context – jimifiki Feb 1 '12 at 16:24
  • @jimifiki: What are you talking about? + behaves the same for lists and strings - it concatenates by creates a new copy and not mutating either operand. – user395760 Feb 1 '12 at 16:25
  • 6
    The truly important point to take away from all this is that strings don't have an append function because they're immutable. – Lily Chung Oct 16 '14 at 21:02

The variable a is pointing at the object "Dog". It's best to think of the variable in Python as a tag. You can move the tag to different objects which is what you did when you changed a = "dog" to a = "dog eats treats".

However, immutability refers to the object, not the tag.

If you tried a[1] = 'z' to make "dog" into "dzg", you would get the error:

TypeError: 'str' object does not support item assignment" 

because strings don't support item assignment, thus they are immutable.


Something is mutable only when we are able to change the values held in the memory location without changing the memory location itself.

The trick is: If you find that the memory location before and after the change are the same, it is mutable.

For example, list is mutable. How?

>> a = ['hello']
>> id(a)

# Now let's modify
>> a[0] = "hello new"
>> a
['hello new']
Now that we have changed "a", let's see the location of a
>> id(a)
so it is the same as before. So we mutated a. So list is mutable.

A string is immutable. How do we prove it?

> a = "hello"
> a[0]
# Now let's modify it
> a[0] = 'n'

we get

TypeError: 'str' object does not support item assignment

So we failed mutating the string. It means a string is immutable.

In you reassigning, you change the variable to point to a new location itself. Here you have not mutated the string, but mutating the variable itself. The following is what you are doing.

>> a = "hello"
>> id(a)
>> a ="world"
>> id(a)

id before and after reassignment is different, so it this proves that you are actually not mutating, but pointing the variable to new location. Which is not mutating that string, but mutating that variable.


A variable is just a label pointing to an object. The object is immutable, but you can make the label point to a completely different object if you want to.



>>> a='asdf'
>>> a.__repr__
<method-wrapper '__repr__' of str object at 0x1091aab90>
>>> a='asdf'
>>> a.__repr__
<method-wrapper '__repr__' of str object at 0x1091aab90>
>>> a='qwer'
>>> a.__repr__
<method-wrapper '__repr__' of str object at 0x109198490>

Notice that the hex memory location did not change when I stored the same value in the variable twice. It did change when I stored a different value. The string is immutable. Not because of zealotry, but because you pay the performance penalty of creating a new object in memory. The variable a is just a label pointing to that memory address. It can be altered to point to anything.


The statement a = a + " " + b + " " + c can be broken down based upon pointers.

a + " " says give me what a points to, which can't be changed, and add " " to my current working set.


working_set = "Dog "
a = "Dog" 
b = "eats"
c = "treats"

+ b says give me what b points to, which can't be changed, and add it to current working set.


working_set = "Dog eats"
a = "Dog" 
b = "eats"
c = "treats"

+ " " + c says add " " to the current set. Then give me what c points to, which can't be changed, and add it to current working set. memory:

working_set = "Dog eats treats"
a = "Dog" 
b = "eats"
c = "treats"

Finally, a = says set my pointer to point to the resulting set.


a = "Dog eats treats"
b = "eats"
c = "treats"

"Dog" is reclaimed, because no more pointers connect to it's chunk of memory. We never modified the memory section "Dog" resided in, which is what is meant by immutable. However, we can change which labels, if any, point to that section of memory.

l = [1,2,3]
print id(l)
print id(l) #object l is the same

a = "dog"
print id(a)
a = "cat"
print id(a) #object a is a new object, previous one is deleted

There is a difference between data and the label it is associated with. For example when you do

a = "dog"

the data "dog" is created and put under the label a. The label can change but what is in the memory won't. The data "dog" will still exist in memory (until the garbage collector deletes it) after you do

a = "cat"

In your programm a now ^points to^ "cat" but the string "dog" hasn't changed.


Python strings are immutable. However, a is not a string: it is a variable with a string value. You can't mutate the string, but can change what value of the variable to a new string.


Variables can point to anywhere they want.. An error will be thrown if you do the following:

a = "dog"
print a                   #dog
a[1] = "g"                #ERROR!!!!!! STRINGS ARE IMMUTABLE

Python string objects are immutable. Example:

>>> a = 'tanim'
>>> 'Address of a is:{}'.format(id(a))
'Address of a is:64281536'
>>> a = 'ahmed'
>>> 'Address of a is:{}'.format(id(a))
'Address of a is:64281600'

In this example we can see that when we assign different value in a it doesn't modify.A new object is created.
And it can't be modified. Example:

  >>> a[0] = 'c'
    Traceback (most recent call last):
      File "<stdin>", line 1, in <module>
    **TypeError**: 'str' object does not support item assignment

A error occurs.


'mutable' means that we can change the content of the string, 'immutable' means that we can't add an extra string.

click for photo proof


>>> a = 'dogs'

>>> a.replace('dogs', 'dogs eat treats')

'dogs eat treats'

>>> print a


Immutable, isn't it?!

The variable change part has already been discussed.

  • 1
    This isn't proving or disproving the mutability of python strings, just that the replace() method returns a new string. – Brent Hronik Apr 19 '16 at 0:34

Consider this addition to your example

 a = "Dog"
 b = "eats"
 c = "treats"
 print (a,b,c)
 #Dog eats treats
 d = a + " " + b + " " + c
 print (a)
 print (d)
 #Dog eats treats

One of the more precise explanations I found in a blog is:

In Python, (almost) everything is an object. What we commonly refer to as "variables" in Python are more properly called names. Likewise, "assignment" is really the binding of a name to an object. Each binding has a scope that defines its visibility, usually the block in which the name originates.


some_guy = 'Fred'
# ...
some_guy = 'George'

When we later say some_guy = 'George', the string object containing 'Fred' is unaffected. We've just changed the binding of the name some_guy. We haven't, however, changed either the 'Fred' or 'George' string objects. As far as we're concerned, they may live on indefinitely.

Link to blog: https://jeffknupp.com/blog/2012/11/13/is-python-callbyvalue-or-callbyreference-neither/


Adding a bit more to above-mentioned answers.

id of a variable changes upon reassignment.

>>> a = 'initial_string'
>>> id(a)
>>> a = 'new_string'
>>> id(a)

Which means that we have mutated the variable a to point to a new string. Now there exist two string(str) objects:

'initial_string' with id = 139982120425648


'new_string' with id = 139982120425776

Consider the below code:

>>> b = 'intitial_string'
>>> id(b)

Now, b points to the 'initial_string' and has the same id as a had before reassignment.

Thus, the 'intial_string' has not been mutated.



a = 3
b = a
a = 3+2
print b
# 5

Not immutable:

a = 'OOP'
b = a
a = 'p'+a
print b


a = [1,2,3]
b = range(len(a))
for i in range(len(a)):
    b[i] = a[i]+1

This is an error in Python 3 because it is immutable. And not an error in Python 2 because clearly it is not immutable.


The built-in function id() returns the identity of an object as an integer. This integer usually corresponds to the object’s location in memory.





Initially, 'a' is stored in 139831803293008 memory location, as the string object is immutable in python if you try to modify and reassign the reference will be removed and will be a pointer to a new memory location(139831803293120).

a = 'dog'
address = id(a)

a = a + 'cat'
print(id(a))      #Address changes

import ctypes
ctypes.cast(address, ctypes.py_object).value    #value at old address is intact
  • 3
    While this code may resolve the OP's issue, it is best to include an explanation as to how your code addresses the OP's issue. In this way, future visitors can learn from your post, and apply it to their own code. SO is not a coding service, but a resource for knowledge. Also, high quality, complete answers are more likely to be upvoted. These features, along with the requirement that all posts are self-contained, are some of the strengths of SO as a platform, that differentiates it from forums. You can edit to add additional info &/or to supplement your explanations with source documentation – SherylHohman May 16 '20 at 18:50

This image gives the answer. Please read it.

enter image description here


We r just concatenate the two string values. We never change the value of (a). Just now (a) represent another memory block that has "dogdog" value. Because in the backend, one variable never represent two memory blocks at same time. The value of (a) before concatenation was "dog". But after that (a) represent the "dogdog", because now (a) in backend rep. the block that has "dogdog" value. And "dog" is rep. by (b) and "dog" isn't counted as garbage value until (b) represent the "dog".

The confusion is we represent the memory blocks(that contain data or info.) in backend with same variable name.


You can make a numpy array immutable and use the first element:

numpyarrayname[0] = "write once"




numpyarrayname.flags.writeable = False

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