Mark Dickinson explained the syntax of what is happening, but the weird examples involving
foo show that the semantics can be counter-intuitive.
= is a right-associative operator which returns as a value the RHS of the assignment so when you write
x = y = 5,
y=5 is first evaluated (assigning 5 to
y in the process) and this value (5) is then assigned to
Before I read this question, I naively assumed that roughly the same thing happens in Python. But, in Python
= isn't an expression (for example,
2 + (x = 5) is a syntax error). So Python must achieve multiple assignments in another way.
We can disassemble rather than guess:
>>> import dis
>>> dis.dis('x = y = 5')
1 0 LOAD_CONST 0 (5)
4 STORE_NAME 0 (x)
7 STORE_NAME 1 (y)
10 LOAD_CONST 1 (None)
See this for a description of the byte code instructions.
The first instruction pushes 5 onto the stack.
The second instruction duplicates it -- so now the top of the stack has two 5s
STORE_NAME(name) "Implements name = TOS" according to the byte code documentation
x = 5 (the 5 on top of the stack), popping that 5 off the stack as it goes, after which
y = 5 with the other 5 on the stack.
The rest of the bytecode isn't directly relevant here.
In the case of
foo = foo =  the byte-code is more complicated because of the lists but has a fundamentally similar structure. The key observation is that once the list
 is created and placed on the stack then the instruction
DUP_TOP doesn't place another copy of
 on the stack, instead it places another reference to the list. In other words, at that stage the top two elements of the stack are aliases for the same list. This can be seen most clearly in the somewhat simpler case:
>>> x = y = 
>>> x = 5
foo = foo =  is executed, the list
 is first assigned to
foo and then an alias of the same list is assigned to
foo. This is why it results in
foo being a circular reference.