Suppose I have a Python function as defined below:
def foo(arg1,arg2):
#do something with args
a = arg1 + arg2
return a
I can get the name of the function using foo.func_name. How can I programmatically get its source code, as I typed above?
If the function is from a source file available on the filesystem, then inspect.getsource(foo) might be of help:
If foo is defined as:
def foo(arg1,arg2):
#do something with args
a = arg1 + arg2
return a
Then:
import inspect
lines = inspect.getsource(foo)
print(lines)
Returns:
def foo(arg1,arg2):
#do something with args
a = arg1 + arg2
return a
But I believe that if the function is compiled from a string, stream or imported from a compiled file, then you cannot retrieve its source code.
len. Where can I find the source code for the len function?
Sep 15, 2016 at 6:06
The inspect module has methods for retrieving source code from python objects. Seemingly it only works if the source is located in a file though. If you had that I guess you wouldn't need to get the source from the object.
The following tests inspect.getsource(foo) using Python 3.6:
import inspect
def foo(arg1,arg2):
#do something with args
a = arg1 + arg2
return a
source_foo = inspect.getsource(foo) # foo is normal function
print(source_foo)
source_max = inspect.getsource(max) # max is a built-in function
print(source_max)
This first prints:
def foo(arg1,arg2):
#do something with args
a = arg1 + arg2
return a
Then fails on inspect.getsource(max) with the following error:
TypeError: <built-in function max> is not a module, class, method, function, traceback, frame, or code object
python 3.5.3 interpreter. import inspect + inspect.getsource(foo) worked fine.
May 7, 2017 at 18:52
Note: this answer only applies to IPython and projects that use it, such as Jupyter.
Just use foo?? or ??foo.
If you are using IPython, then you need to type foo?? or ??foo to see the complete source code. To see only the docstring in the function, use foo? or ?foo. This works in Jupyter notebook as well.
In [19]: foo??
Signature: foo(arg1, arg2)
Source:
def foo(arg1,arg2):
#do something with args
a = arg1 + arg2
return a
File: ~/Desktop/<ipython-input-18-3174e3126506>
Type: function
dir(MyClass), then MyClass.__init__?? and so on.
dis is your friend if the source code is not available:
>>> import dis
>>> def foo(arg1,arg2):
... #do something with args
... a = arg1 + arg2
... return a
...
>>> dis.dis(foo)
3 0 LOAD_FAST 0 (arg1)
3 LOAD_FAST 1 (arg2)
6 BINARY_ADD
7 STORE_FAST 2 (a)
4 10 LOAD_FAST 2 (a)
13 RETURN_VALUE
LOAD_SLOW or LOAD_SLOW_FOR_NO_REASON instead of all these LOAD_FASTs :)
Oct 10, 2022 at 13:28
While I'd generally agree that inspect is a good answer, I'd disagree that you can't get the source code of objects defined in the interpreter. If you use dill.source.getsource from dill, you can get the source of functions and lambdas, even if they are defined interactively.
It also can get the code for from bound or unbound class methods and functions defined in curries... however, you might not be able to compile that code without the enclosing object's code.
>>> from dill.source import getsource
>>>
>>> def add(x,y):
... return x+y
...
>>> squared = lambda x:x**2
>>>
>>> print getsource(add)
def add(x,y):
return x+y
>>> print getsource(squared)
squared = lambda x:x**2
>>>
>>> class Foo(object):
... def bar(self, x):
... return x*x+x
...
>>> f = Foo()
>>>
>>> print getsource(f.bar)
def bar(self, x):
return x*x+x
>>>
dill.source.getsource inspects the interpreter's history for functions, classes, lambdas, etc -- it doesn't inspect the content of strings passed to exec.
Mar 4, 2014 at 3:04
dill to answer this question: stackoverflow.com/questions/13827543/…
Feb 20, 2015 at 16:34
dill.source has functions like getname and importable and getsource that focus on getting the source code (or an importable that yields the object) for any given object. For simple things like an int there is no source, so it doesn't work as expected (i.e. for 'a = 10' it returns '10').
Feb 20, 2015 at 18:08
>>> a = 10; print( [key for key, val in globals().items() if val is a][0] )
Feb 20, 2015 at 18:08
dill, but my answer leaves a bit to be desired (IE, if you have multiple names for the same value, it can't figure out which was used. If you pass in an expression, it can't say what that expression was. Heck, if you pass in an expression that evaluates to the same as a name, it'll give that name instead.) Can dill solve any of those shortcomings of my answer here: stackoverflow.com/a/28634996/901641
Feb 20, 2015 at 18:24
To expand on runeh's answer:
>>> def foo(a):
... x = 2
... return x + a
>>> import inspect
>>> inspect.getsource(foo)
u'def foo(a):\n x = 2\n return x + a\n'
print inspect.getsource(foo)
def foo(a):
x = 2
return x + a
EDIT: As pointed out by @0sh this example works using ipython but not plain python. It should be fine in both, however, when importing code from source files.
getsource(foo).
Feb 7, 2015 at 18:14
Since this post is marked as the duplicate of this other post, I answer here for the "lambda" case, although the OP is not about lambdas.
So, for lambda functions that are not defined in their own lines: in addition to marko.ristin's answer, you may wish to use mini-lambda or use SymPy as suggested in this answer.
mini-lambda is lighter and supports any kind of operation, but works only for a single variableSymPy is heavier but much more equipped with mathematical/calculus operations. In particular it can simplify your expressions. It also supports several variables in the same expression.Here is how you can do it using mini-lambda:
from mini_lambda import x, is_mini_lambda_expr
import inspect
def get_source_code_str(f):
if is_mini_lambda_expr(f):
return f.to_string()
else:
return inspect.getsource(f)
# test it
def foo(arg1, arg2):
# do something with args
a = arg1 + arg2
return a
print(get_source_code_str(foo))
print(get_source_code_str(x ** 2))
It correctly yields
def foo(arg1, arg2):
# do something with args
a = arg1 + arg2
return a
x ** 2
See mini-lambda documentation for details. I'm the author by the way ;)
You can use inspect module to get full source code for that. You have to use getsource() method for that from the inspect module. For example:
import inspect
def get_my_code():
x = "abcd"
return x
print(inspect.getsource(get_my_code))
You can check it out more options on the below link. retrieve your python code
Please mind that the accepted answers work only if the lambda is given on a separate line. If you pass it in as an argument to a function and would like to retrieve the code of the lambda as object, the problem gets a bit tricky since inspect will give you the whole line.
For example, consider a file test.py:
import inspect
def main():
x, f = 3, lambda a: a + 1
print(inspect.getsource(f))
if __name__ == "__main__":
main()
Executing it gives you (mind the indention!):
x, f = 3, lambda a: a + 1
To retrieve the source code of the lambda, your best bet, in my opinion, is to re-parse the whole source file (by using f.__code__.co_filename) and match the lambda AST node by the line number and its context.
We had to do precisely that in our design-by-contract library icontract since we had to parse the lambda functions we pass in as arguments to decorators. It is too much code to paste here, so have a look at the implementation of this function.
to summarize :
import inspect
print( "".join(inspect.getsourcelines(foo)[0]))
If you're strictly defining the function yourself and it's a relatively short definition, a solution without dependencies would be to define the function in a string and assign the eval() of the expression to your function.
E.g.
funcstring = 'lambda x: x> 5'
func = eval(funcstring)
then optionally to attach the original code to the function:
func.source = funcstring
eval (or it wouldn't be in the spec). The attrs library uses eval to build customized dunder methods for classes. Not eval-ing user input solves the vast majority of relevant security concerns. Still, not something to trifle with.
Rafał Dowgird's answer states:
I believe that if the function is compiled from a string, stream or imported from a compiled file, then you cannot retrieve its source code.
However, it is possible to retrieve the source code of a function compiled from a string, provided that the compiling code also added an entry to the linecache.cache dict:
import linecache
import inspect
script = '''
def add_nums(a, b):
return a + b
'''
bytecode = compile(script, 'unique_filename', 'exec')
tmp = {}
eval(bytecode, {}, tmp)
add_nums = tmp["add_nums"]
linecache.cache['unique_filename'] = (
len(script),
None,
script.splitlines(True),
'unique_filename',
)
print(inspect.getsource(add_nums))
# prints:
# """
# def add_nums(a, b):
# return a + b
# """
This is how the attrs library creates various methods for classes automatically, given a set of attributes that the class expects to be initialized with. See their source code here. As the source explains, this is a feature primarily intended to enable debuggers such as PDB to step through the code.
If all the previous excellent methods fail you are still stuck (!!), you can try to crash your function and use traceback 😂 to get at least some of the code.
In [1]: import traceback
...: def foo(arg1,arg2):
...: #do something with args
...: a = arg1 + arg2
...: return a
...:
In [2]: try:
...: foo(None, None)
...: except Exception as e:
...: print(repr(e))
...: print(traceback.format_exc())
...:
TypeError("unsupported operand type(s) for +: 'NoneType' and 'NoneType'")
Traceback (most recent call last):
File "<ipython-input-2-5e7289999181>", line 2, in <module>
foo(None, None)
File "<ipython-input-1-db29b8b8f18d>", line 4, in foo
a = arg1 + arg2
TypeError: unsupported operand type(s) for +: 'NoneType' and 'NoneType'
Might need to get creative and does not work if the func has no parameters.
from dis import show_code
show_code(XXX)
show_code doesn't actually show the source code of user-defined functions and completely fails for builtin functions.
May 21, 2023 at 3:26
I believe that variable names aren't stored in pyc/pyd/pyo files, so you can not retrieve the exact code lines if you don't have source files.
foo.__name__inspect), clearly explaining the appropriate caveats (e.g. from a file versus interactively defined). One possible solution is a comprehensive yet maximally distilled and well-organized answer. Alternatively or in combination, many of the existing answers could be salvaged if they are clearer on their context.