Two python objects have the same id but "is" operation returns false as shown below:

a = np.arange(12).reshape(2, -1)
c = a.reshape(12, 1)
print("id(c.data)", id(c.data))
print("id(a.data)", id(a.data))

print(c.data is a.data)
print(id(c.data) == id(a.data))

Here is the actual output:

id(c.data) 241233112
id(a.data) 241233112

My question is... why "c.data is a.data" returns false even though they point to the same ID, thus pointing to the same object? I thought that they point to the same object if they have same ID or am I wrong? Thank you!

marked as duplicate by ivan_pozdeev, smci, Community Apr 13 at 6:09

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  • 1
    @C.Nivs They don't even necessarily have different memory addresses (something which Python doesn't expose). Whatever memory was used for the first may have been reused for the second. – chepner Apr 12 at 19:29
  • 3
    @C.Nivs Don't think of it in terms of memory addresses. How memory is managed is completely implementation dependent. All you know for sure is that two objects that overlap in time will not have the same id. – chepner Apr 12 at 19:32
  • 1
    @Aran-Fey, that's okay a good question(though asked before) can sometimes be resurrected for a fruitful discussion – amanb Apr 12 at 19:35
  • 4
    @C.Nivs no, ids do not belong to variables. They belong to objects. Many variables can reference the same object. – juanpa.arrivillaga Apr 12 at 19:55
  • 2
    @juanpa.arrivillaga fair enough. Thanks for the explanation – C.Nivs Apr 12 at 21:19

a.data and c.data both produce a transient object, with no reference to it. As such, both are immediately garbage-collected. The same id can be used for both.

In your first if statement, the objects have to co-exist while is checks if they are identical, which they are not.

In the second if statement, each object is released as soon as id returns its id.

If you save references to both objects, keeping them alive, you can see they are not the same object.

r0 = a.data
r1 = c.data
assert r0 is not r1
  • 5
    what is confusing is the fact that data looks like an attribute, but is probably a property – Jean-François Fabre Apr 12 at 19:27
  • In my tests, the id's are different in the first run, but change to become the same on subsequent runs. – amanb Apr 12 at 19:30
  • @Jean-FrançoisFabre so would that mean that the object itself is only returned when a getter is called, and the property is not actually stored in the class? I'm not quite familiar with the differences between a property vs attribute – C.Nivs Apr 12 at 19:30
  • 6
    a property is a method disguised as an attribute. So it can return a discardable integer, object, whatever. – Jean-François Fabre Apr 12 at 19:31
  • Thank you all! Coming from C/C++, I was just looking for a way to check if two different pointers point to the same object. So I should use "is operator" to compare if check if two pointers point to the same object. id() can return the same string since it can be re-used for transient objects. Thanks – drminix Apr 13 at 6:12
In [62]: a = np.arange(12).reshape(2,-1) 
    ...: c = a.reshape(12,1)                                                    

.data returns a memoryview object. id just gives the id of that object; it's not the value of the object, or any indication of where a databuffer is located.

In [63]: a.data                                                                 
Out[63]: <memory at 0x7f672d1101f8>
In [64]: c.data                                                                 
Out[64]: <memory at 0x7f672d1103a8>
In [65]: type(a.data)                                                           
Out[65]: memoryview


If you want to verify that a and c share a data buffer, I find the __array_interface__ to be a better tool.

In [66]: a.__array_interface__['data']                                          
Out[66]: (50988640, False)
In [67]: c.__array_interface__['data']                                          
Out[67]: (50988640, False)

It even shows the offset produced by slicing - here 24 bytes, 3*8

In [68]: c[3:].__array_interface__['data']                                      
Out[68]: (50988664, False)

I haven't seen much use of a.data. It can be used as the buffer object when creating a new array with ndarray:

In [70]: d = np.ndarray((2,6), dtype=a.dtype, buffer=a.data)                    
In [71]: d                                                                      
array([[ 0,  1,  2,  3,  4,  5],
       [ 6,  7,  8,  9, 10, 11]])
In [72]: d.__array_interface__['data']                                          
Out[72]: (50988640, False)

But normally we create new arrays with shared memory with slicing or np.array (copy=False).

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