Both lambda
and def
create the same kind of function – they have the same kind of metadata and capabilities. Their technical difference is syntactical:
- A
lambda
is an expression producing a function.
- A
def
is a statement producing a function.
This is everything that dictates how they can be used. Other apparent differences simply come from the information lambda
/def
can capture.
>>> def def_func(): pass
>>> lambda_func = lambda: None
>>> type(def_func) == type(lambda_func)
True
Usage: Expression vs. Statement
A lambda
is more flexible as expressions can be part of more language constructs.
# v--------------v arguments must be expressions
sort(values, key=lambda x: abs(x))
In contrast, a def
is more powerful as it can consist of more language constructs.
def encode(num, base):
while num: # statements must be inside statements
num, bit = divmod(num, base)
yield bit
These differences derive directly from one being an expression and the other being a statement. Python has no special rules to decide where a lambda
/def
may be used.
Where the wild <lambda>
s grow
The primary reason to assume lambda
and def
correspond to different kinds of function is metadata: lambda
is often referred to as an "anonymous function" and miraculously it always produces a function <lambda>
. Other quirks include "lambda functions can't be pickled", and recently typing also does "not work" for lambda
.
That is because compared to def
syntax, the lambda
syntax has no way of specifying name, type annotations and similar. As such, Python simply fills in sane defaults for either: the name becomes <lambda>
and annotations are left empty.
>>> identity = lambda a: a
>>> identity.__qualname__
'<lambda>'
>>> identity.__annotations__
{}
Since <lambda>
is not a valid identifier, everything using this metadata to find the function – most prominently pickle
– fails.
However, that does not make the function an "anonymous function" type. The metadata can be patched up to insert what def
would provide:
>>> identity.__qualname__ = identity.__name__ = 'identity'
>>> identity
<function __main__.identity(a)>
Of course at that one point one can just use def
…