Is creating a variable in try/except block considered a bad practice? - python

Let's consider this example - code that returns index of the first None value in the list li (if present) or the last element's index if None is not present in li.
I could possibly check for None being in list but using ifs isn't the preferred way - Dive Into Python encourages to use exceptions as they are said to be faster and make code cleaner (see this question). So I came with three approaches:
1.
try:
my_index = li.index(None)
except ValueError:
my_index = len(li) - 1
print my_index
my_index is declared inside try/except block. Less lines, no redundant declaration. Possible problem - different exception type will result in not creating my_index and crashing the script on print.
2.
my_index = None # or anything else
try:
my_index = li.index(None)
except ValueError:
my_index = len(li) - 1
print my_index
my_index is declared before try/except and has a value assigned regardless of what exception happens. Cons - more lines, looks redundant.
3. edit: Won't work - finally is executed regardless of try/except results
try:
my_index = li.index(None)
except ValueError:
my_index = len(li) - 1
finally:
my_index = None # or anything else
print my_index
Pros - always works (or at least I think so). Cons - I have never ever seen anyone using finally for my entire Python experience which must happen for a reason.
Which of these methods is considered the preferred and pythonic way? Maybe there is some better solution?

try:
my_index = li.index(None)
except ValueError:
my_index = len(li) - 1
print my_index
Possible problem - different exception type will result in not creating my_index and crashing the script on print.
Err, no. If any other exception is raised, this entire block of code will be aborted as the exception bubbles up to the caller. So if any other exception type besides ValueError is raised, print will never be executed. Which is a pretty sane behaviour: you handle the errors you expect and can handle, and let other errors cause the entire block to abort, possibly the entire script. This is the sanest and most concise solution for what you want.

The third option won't work. Check out the documentation on finally
(emphasis mine):
A finally clause is always executed before leaving the try statement, whether an exception has occurred or not.
So in the third option, no matter what happens, my_index is always none.
That leaves us with the first and second option. It is worth noting that the second one is what you'll see in most statically typed languages. Python however is a bit more lenient and allows for either option.
Your argument regarding an exception that isn't ValueError is, I think, invalid. Another exception will halt execution and go back to the caller, so the print will never be reached. So the first solution should work just fine.

++ As #deceze noticed already, except ValueError: will catch only errors of this class and not others.
If you really need to process different error cases differently, you may provide more exception clauses:
try:
...
except ValueError:
...
except TypeError:
...
Sequences in except are also supported:
try:
...
except (ValueError, TypeError, ...):
...
+++ You should consider what does your code need to return if empty list was passed: -1? Raise an exception?

I think this is an example where you should not use an exception. While Python employs exception as "usual" programming constructs to reduce complexity, this is I think a case of adding complexity. Your code tells me that my_index has to hold a value after these lines and that you expect li to be an iterable, even under the occurrence of an exception. That this exception is ValueError which is the consequence of None not being in the list, is an added complexity, and one only understandable by convention - moreover, are you sure that its not IndexError that could be thrown? You see, IMHO the construct
if None in li: my_index = li.index(None)
else : my_index = len(li) - 1
will not throw the programmer who comes across this code in half a year, i.e. maybe you yourself, off the track in understanding your program logic, while the version with the exception will cause additional mental work, raising the question if your anticipation of the possible exceptions and reactions was complete and correct. Only if this is a really really performance critical piece of code you should try to evade the double search.

Related

What is the best practice with regards to type consistency for returning a result, error, or warning in Python? [duplicate]

From time to time in Python, I see the block:
try:
try_this(whatever)
except SomeException as exception:
#Handle exception
else:
return something
What is the reason for the try-except-else to exist?
I do not like that kind of programming, as it is using exceptions to perform flow control. However, if it is included in the language, there must be a good reason for it, isn't it?
It is my understanding that exceptions are not errors, and that they should only be used for exceptional conditions (e.g. I try to write a file into disk and there is no more space, or maybe I do not have permission), and not for flow control.
Normally I handle exceptions as:
something = some_default_value
try:
something = try_this(whatever)
except SomeException as exception:
#Handle exception
finally:
return something
Or if I really do not want to return anything if an exception happens, then:
try:
something = try_this(whatever)
return something
except SomeException as exception:
#Handle exception
"I do not know if it is out of ignorance, but I do not like that
kind of programming, as it is using exceptions to perform flow control."
In the Python world, using exceptions for flow control is common and normal.
Even the Python core developers use exceptions for flow-control and that style is heavily baked into the language (i.e. the iterator protocol uses StopIteration to signal loop termination).
In addition, the try-except-style is used to prevent the race-conditions inherent in some of the "look-before-you-leap" constructs. For example, testing os.path.exists results in information that may be out-of-date by the time you use it. Likewise, Queue.full returns information that may be stale. The try-except-else style will produce more reliable code in these cases.
"It my understanding that exceptions are not errors, they should only
be used for exceptional conditions"
In some other languages, that rule reflects their cultural norms as reflected in their libraries. The "rule" is also based in-part on performance considerations for those languages.
The Python cultural norm is somewhat different. In many cases, you must use exceptions for control-flow. Also, the use of exceptions in Python does not slow the surrounding code and calling code as it does in some compiled languages (i.e. CPython already implements code for exception checking at every step, regardless of whether you actually use exceptions or not).
In other words, your understanding that "exceptions are for the exceptional" is a rule that makes sense in some other languages, but not for Python.
"However, if it is included in the language itself, there must be a
good reason for it, isn't it?"
Besides helping to avoid race-conditions, exceptions are also very useful for pulling error-handling outside loops. This is a necessary optimization in interpreted languages which do not tend to have automatic loop invariant code motion.
Also, exceptions can simplify code quite a bit in common situations where the ability to handle an issue is far removed from where the issue arose. For example, it is common to have top level user-interface code calling code for business logic which in turn calls low-level routines. Situations arising in the low-level routines (such as duplicate records for unique keys in database accesses) can only be handled in top-level code (such as asking the user for a new key that doesn't conflict with existing keys). The use of exceptions for this kind of control-flow allows the mid-level routines to completely ignore the issue and be nicely decoupled from that aspect of flow-control.
There is a nice blog post on the indispensibility of exceptions here.
Also, see this Stack Overflow answer: Are exceptions really for exceptional errors?
"What is the reason for the try-except-else to exist?"
The else-clause itself is interesting. It runs when there is no exception but before the finally-clause. That is its primary purpose.
Without the else-clause, the only option to run additional code before finalization would be the clumsy practice of adding the code to the try-clause. That is clumsy because it risks
raising exceptions in code that wasn't intended to be protected by the try-block.
The use-case of running additional unprotected code prior to finalization doesn't arise very often. So, don't expect to see many examples in published code. It is somewhat rare.
Another use-case for the else-clause is to perform actions that must occur when no exception occurs and that do not occur when exceptions are handled. For example:
recip = float('Inf')
try:
recip = 1 / f(x)
except ZeroDivisionError:
logging.info('Infinite result')
else:
logging.info('Finite result')
Another example occurs in unittest runners:
try:
tests_run += 1
run_testcase(case)
except Exception:
tests_failed += 1
logging.exception('Failing test case: %r', case)
print('F', end='')
else:
logging.info('Successful test case: %r', case)
print('.', end='')
Lastly, the most common use of an else-clause in a try-block is for a bit of beautification (aligning the exceptional outcomes and non-exceptional outcomes at the same level of indentation). This use is always optional and isn't strictly necessary.
What is the reason for the try-except-else to exist?
A try block allows you to handle an expected error. The except block should only catch exceptions you are prepared to handle. If you handle an unexpected error, your code may do the wrong thing and hide bugs.
An else clause will execute if there were no errors, and by not executing that code in the try block, you avoid catching an unexpected error. Again, catching an unexpected error can hide bugs.
Example
For example:
try:
try_this(whatever)
except SomeException as the_exception:
handle(the_exception)
else:
return something
The "try, except" suite has two optional clauses, else and finally. So it's actually try-except-else-finally.
else will evaluate only if there is no exception from the try block. It allows us to simplify the more complicated code below:
no_error = None
try:
try_this(whatever)
no_error = True
except SomeException as the_exception:
handle(the_exception)
if no_error:
return something
so if we compare an else to the alternative (which might create bugs) we see that it reduces the lines of code and we can have a more readable, maintainable, and less buggy code-base.
finally
finally will execute no matter what, even if another line is being evaluated with a return statement.
Broken down with pseudo-code
It might help to break this down, in the smallest possible form that demonstrates all features, with comments. Assume this syntactically correct (but not runnable unless the names are defined) pseudo-code is in a function.
For example:
try:
try_this(whatever)
except SomeException as the_exception:
handle_SomeException(the_exception)
# Handle a instance of SomeException or a subclass of it.
except Exception as the_exception:
generic_handle(the_exception)
# Handle any other exception that inherits from Exception
# - doesn't include GeneratorExit, KeyboardInterrupt, SystemExit
# Avoid bare `except:`
else: # there was no exception whatsoever
return something()
# if no exception, the "something()" gets evaluated,
# but the return will not be executed due to the return in the
# finally block below.
finally:
# this block will execute no matter what, even if no exception,
# after "something" is eval'd but before that value is returned
# but even if there is an exception.
# a return here will hijack the return functionality. e.g.:
return True # hijacks the return in the else clause above
It is true that we could include the code in the else block in the try block instead, where it would run if there were no exceptions, but what if that code itself raises an exception of the kind we're catching? Leaving it in the try block would hide that bug.
We want to minimize lines of code in the try block to avoid catching exceptions we did not expect, under the principle that if our code fails, we want it to fail loudly. This is a best practice.
It is my understanding that exceptions are not errors
In Python, most exceptions are errors.
We can view the exception hierarchy by using pydoc. For example, in Python 2:
$ python -m pydoc exceptions
or Python 3:
$ python -m pydoc builtins
Will give us the hierarchy. We can see that most kinds of Exception are errors, although Python uses some of them for things like ending for loops (StopIteration). This is Python 3's hierarchy:
BaseException
Exception
ArithmeticError
FloatingPointError
OverflowError
ZeroDivisionError
AssertionError
AttributeError
BufferError
EOFError
ImportError
ModuleNotFoundError
LookupError
IndexError
KeyError
MemoryError
NameError
UnboundLocalError
OSError
BlockingIOError
ChildProcessError
ConnectionError
BrokenPipeError
ConnectionAbortedError
ConnectionRefusedError
ConnectionResetError
FileExistsError
FileNotFoundError
InterruptedError
IsADirectoryError
NotADirectoryError
PermissionError
ProcessLookupError
TimeoutError
ReferenceError
RuntimeError
NotImplementedError
RecursionError
StopAsyncIteration
StopIteration
SyntaxError
IndentationError
TabError
SystemError
TypeError
ValueError
UnicodeError
UnicodeDecodeError
UnicodeEncodeError
UnicodeTranslateError
Warning
BytesWarning
DeprecationWarning
FutureWarning
ImportWarning
PendingDeprecationWarning
ResourceWarning
RuntimeWarning
SyntaxWarning
UnicodeWarning
UserWarning
GeneratorExit
KeyboardInterrupt
SystemExit
A commenter asked:
Say you have a method which pings an external API and you want to handle the exception at a class outside the API wrapper, do you simply return e from the method under the except clause where e is the exception object?
No, you don't return the exception, just reraise it with a bare raise to preserve the stacktrace.
try:
try_this(whatever)
except SomeException as the_exception:
handle(the_exception)
raise
Or, in Python 3, you can raise a new exception and preserve the backtrace with exception chaining:
try:
try_this(whatever)
except SomeException as the_exception:
handle(the_exception)
raise DifferentException from the_exception
I elaborate in my answer here.
Python doesn't subscribe to the idea that exceptions should only be used for exceptional cases, in fact the idiom is 'ask for forgiveness, not permission'. This means that using exceptions as a routine part of your flow control is perfectly acceptable, and in fact, encouraged.
This is generally a good thing, as working this way helps avoid some issues (as an obvious example, race conditions are often avoided), and it tends to make code a little more readable.
Imagine you have a situation where you take some user input which needs to be processed, but have a default which is already processed. The try: ... except: ... else: ... structure makes for very readable code:
try:
raw_value = int(input())
except ValueError:
value = some_processed_value
else: # no error occured
value = process_value(raw_value)
Compare to how it might work in other languages:
raw_value = input()
if valid_number(raw_value):
value = process_value(int(raw_value))
else:
value = some_processed_value
Note the advantages. There is no need to check the value is valid and parse it separately, they are done once. The code also follows a more logical progression, the main code path is first, followed by 'if it doesn't work, do this'.
The example is naturally a little contrived, but it shows there are cases for this structure.
See the following example which illustrate everything about try-except-else-finally:
for i in range(3):
try:
y = 1 / i
except ZeroDivisionError:
print(f"\ti = {i}")
print("\tError report: ZeroDivisionError")
else:
print(f"\ti = {i}")
print(f"\tNo error report and y equals {y}")
finally:
print("Try block is run.")
Implement it and come by:
i = 0
Error report: ZeroDivisionError
Try block is run.
i = 1
No error report and y equals 1.0
Try block is run.
i = 2
No error report and y equals 0.5
Try block is run.
Is it a good practice to use try-except-else in python?
The answer to this is that it is context dependent. If you do this:
d = dict()
try:
item = d['item']
except KeyError:
item = 'default'
It demonstrates that you don't know Python very well. This functionality is encapsulated in the dict.get method:
item = d.get('item', 'default')
The try/except block is a much more visually cluttered and verbose way of writing what can be efficiently executing in a single line with an atomic method. There are other cases where this is true.
However, that does not mean that we should avoid all exception handling. In some cases it is preferred to avoid race conditions. Don't check if a file exists, just attempt to open it, and catch the appropriate IOError. For the sake of simplicity and readability, try to encapsulate this or factor it out as apropos.
Read the Zen of Python, understanding that there are principles that are in tension, and be wary of dogma that relies too heavily on any one of the statements in it.
You should be careful about using the finally block, as it is not the same thing as using an else block in the try, except. The finally block will be run regardless of the outcome of the try except.
In [10]: dict_ = {"a": 1}
In [11]: try:
....: dict_["b"]
....: except KeyError:
....: pass
....: finally:
....: print "something"
....:
something
As everyone has noted using the else block causes your code to be more readable, and only runs when an exception is not thrown
In [14]: try:
dict_["b"]
except KeyError:
pass
else:
print "something"
....:
Just because no-one else has posted this opinion, I would say
avoid else clauses in try/excepts because they're unfamiliar to most people
Unlike the keywords try, except, and finally, the meaning of the else clause isn't self-evident; it's less readable. Because it's not used very often, it'll cause people that read your code to want to double-check the docs to be sure they understand what's going on.
(I'm writing this answer precisely because I found a try/except/else in my codebase and it caused a wtf moment and forced me to do some googling).
So, wherever I see code like the OP example:
try:
try_this(whatever)
except SomeException as the_exception:
handle(the_exception)
else:
# do some more processing in non-exception case
return something
I would prefer to refactor to
try:
try_this(whatever)
except SomeException as the_exception:
handle(the_exception)
return # <1>
# do some more processing in non-exception case <2>
return something
<1> explicit return, clearly shows that, in the exception case, we are finished working
<2> as a nice minor side-effect, the code that used to be in the else block is dedented by one level.
Whenever you see this:
try:
y = 1 / x
except ZeroDivisionError:
pass
else:
return y
Or even this:
try:
return 1 / x
except ZeroDivisionError:
return None
Consider this instead:
import contextlib
with contextlib.suppress(ZeroDivisionError):
return 1 / x
This is my simple snippet on howto understand try-except-else-finally block in Python:
def div(a, b):
try:
a/b
except ZeroDivisionError:
print("Zero Division Error detected")
else:
print("No Zero Division Error")
finally:
print("Finally the division of %d/%d is done" % (a, b))
Let's try div 1/1:
div(1, 1)
No Zero Division Error
Finally the division of 1/1 is done
Let's try div 1/0
div(1, 0)
Zero Division Error detected
Finally the division of 1/0 is done
I'm attempting to answer this question in a slightly different angle.
There were 2 parts of the OP's question, and I add the 3rd one, too.
What is the reason for the try-except-else to exist?
Does the try-except-else pattern, or the Python in general, encourage using exceptions for flow control?
When to use exceptions, anyway?
Question 1: What is the reason for the try-except-else to exist?
It can be answered from a tactical standpoint. There is of course reason for try...except... to exist. The only new addition here is the else... clause, whose usefulness boils down to its uniqueness:
It runs an extra code block ONLY WHEN there was no exception happened in the try... block.
It runs that extra code block, OUTSIDE of the try... block (meaning any potential exceptions happen inside the else... block would NOT be caught).
It runs that extra code block BEFORE the final... finalization.
db = open(...)
try:
db.insert(something)
except Exception:
db.rollback()
logging.exception('Failing: %s, db is ROLLED BACK', something)
else:
db.commit()
logging.info(
'Successful: %d', # <-- For the sake of demonstration,
# there is a typo %d here to trigger an exception.
# If you move this section into the try... block,
# the flow would unnecessarily go to the rollback path.
something)
finally:
db.close()
In the example above, you can't move that successful log line into behind the finally... block. You can't quite move it into inside the try... block, either, due to the potential exception inside the else... block.
Question 2: does Python encourage using exceptions for flow control?
I found no official written documentation to support that claim. (To readers who would disagree: please leave comments with links to evidences you found.) The only vaguely-relevant paragraph that I found, is this EAFP term:
EAFP
Easier to ask for forgiveness than permission. This common Python coding style assumes the existence of valid keys or attributes and catches exceptions if the assumption proves false. This clean and fast style is characterized by the presence of many try and except statements. The technique contrasts with the LBYL style common to many other languages such as C.
Such paragraph merely described that, rather than doing this:
def make_some_noise(speaker):
if hasattr(speaker, "quack"):
speaker.quack()
we would prefer this:
def make_some_noise(speaker):
try:
speaker.quack()
except AttributeError:
logger.warning("This speaker is not a duck")
make_some_noise(DonaldDuck()) # This would work
make_some_noise(DonaldTrump()) # This would trigger exception
or potentially even omitting the try...except:
def make_some_noise(duck):
duck.quack()
So, the EAFP encourages duck-typing. But it does not encourage using exceptions for flow control.
Question 3: In what situation you should design your program to emit exceptions?
It is a moot conversation on whether it is anti-pattern to use exception as control flow. Because, once a design decision is made for a given function, its usage pattern would also be determined, and then the caller would have no choice but to use it that way.
So, let's go back to the fundamentals to see when a function would better produce its outcome via returning a value or via emitting exception(s).
What is the difference between the return value and the exception?
Their "blast radius" are different. Return value is only available to the immediate caller; exception can be automatically relayed for unlimited distance until it is caught.
Their distribution patterns are different. Return value is by definition one piece of data (even though you could return a compound data type such as a dictionary or a container object, it is still technically one value).
The exception mechanism, on the contrary, allows multiple values (one at a time) to be returned via their respective dedicate channel. Here, each except FooError: ... and except BarError: ... block is considered as its own dedicate channel.
Therefore, it is up to each different scenario to use one mechanism that fits well.
All normal cases should better be returned via return value, because the callers would most likely need to use that return value immediately. The return-value approach also allows nesting layers of callers in a functional programming style. The exception mechanism's long blast radius and multiple channels do not help here.
For example, it would be unintuitive if any function named get_something(...) produces its happy path result as an exception. (This is not really a contrived example. There is one practice to implement BinaryTree.Search(value) to use exception to ship the value back in the middle of a deep recursion.)
If the caller would likely forget to handle the error sentinel from the return value, it is probably a good idea to use exception's characterist #2 to save caller from its hidden bug. A typical non-example would be the position = find_string(haystack, needle), unfortunately its return value of -1 or null would tend to cause a bug in the caller.
If the error sentinel would collide with a normal value in the result namespace, it is almost certain to use an exception, because you'd have to use a different channel to convey that error.
If the normal channel i.e. the return value is already used in the happy-path, AND the happy-path does NOT have sophisicated flow control, you have no choice but to use exception for flow control. People keep talking about how Python uses StopIteration exception for iteration termination, and use it to kind of justify "using exception for flow control". But IMHO this is only a practical choice in a particular situation, it does not generalize and glorify "using exception for flow control".
At this point, if you already make a sound decision on whether your function get_stock_price() would produce only return-value or also raise exceptions, or if that function is provided by an existing library so that its behavior has long be decided, you do not have much choice in writing its caller calculate_market_trend(). Whether to use get_stock_price()'s exception to control the flow in your calculate_market_trend() is merely a matter of whether your business logic requires you to do so. If yes, do it; otherwise, let the exception bubble up to a higher level (this utilizes the characteristic #1 "long blast radius" of exception).
In particular, if you are implementing a middle-layer library Foo and you happen to be making a dependency on lower-level library Bar, you would probably want to hide your implementation detail, by catching all Bar.ThisError, Bar.ThatError, ..., and map them into Foo.GenericError. In this case, the long blast radius is actually working against us, so you might hope "only if library Bar were returning its errors via return values". But then again, that decision has long been made in Bar, so you can just live with it.
All in all, I think whether to use exception as control flow is a moot point.
OP, YOU ARE CORRECT. The else after try/except in Python is ugly. it leads to another flow-control object where none is needed:
try:
x = blah()
except:
print "failed at blah()"
else:
print "just succeeded with blah"
A totally clear equivalent is:
try:
x = blah()
print "just succeeded with blah"
except:
print "failed at blah()"
This is far clearer than an else clause. The else after try/except is not frequently written, so it takes a moment to figure what the implications are.
Just because you CAN do a thing, doesn't mean you SHOULD do a thing.
Lots of features have been added to languages because someone thought it might come in handy. Trouble is, the more features, the less clear and obvious things are because people don't usually use those bells and whistles.
Just my 5 cents here. I have to come along behind and clean up a lot of code written by 1st-year out of college developers who think they're smart and want to write code in some uber-tight, uber-efficient way when that just makes it a mess to try and read / modify later. I vote for readability every day and twice on Sundays.

How to target an Exception more accurately?

Consider the (compressed for the sake of example) code below:
import ics
import arrow
import requests
a = min(list(ics.Calendar(requests(get('http://asitewithcalendar.org').text).timeline.on(arrow.now())))
Quite a lot of things are happening here, I am fine with issues (connection, problems with the URL, ...) crashing the code but not with the following error:
ValueError: min() arg is an empty sequence
I would like to catch that specific error: the fact that what is provided to min() is an empty sequence (and pass on it). Even more specifically, I want the other exceptions to crash, including ValueError ones that are not related to the empty sequence fed to min().
A straightforward try catching ValueError would be fine for everything except the last constraint.
Is there a way to say "except ValueError when the error is min() arg is an empty sequence"?
Note: I know that the code in my example is ugly - I wrote it to showcase my question so if the only answer is "impossible - you have to rewrite it to pinpoint the line you want to try" then fine, otherwise I am looking for general solutions
You can do something like:
try:
# Put your code to try here
a = min(list(ics.Calendar(requests(get('http://asitewithcalendar.org').text).timeline.on(arrow.now())))
except ValueError as e:
if str(e) == 'min() arg is an empty sequence':
pass
else:
raise e
This is a case where I would simply check the value before calling min rather than wait for an exception. There is no expression-level way to handle exceptions.
foo = list(ics.Calendar(requests(get('http://asitewithcalendar.org').text).timeline.on(arrow.now()))
if foo:
a = min(foo)
It remains to decide what a should be if foo is empty, but you would have the same problem with a try statement:
foo = list(ics.Calendar(requests(get('http://asitewithcalendar.org').text).timeline.on(arrow.now()))
try:
a = min(foo)
except ValueError:
???
I also wouldn't worry too much about only dealing with empty-sequence errors. Even if it is a different ValueError, a is just as undefined.
how about this.
import numpy
a = min(list(ics.Calendar(requests(get('http://asitewithcalendar.org').text).timeline.on(arrow.now())) + [-np.inf])
when -inf has returned. list has nothing inside it.

Can exceptions be caught from both a try and except block with one except statement? [duplicate]

I have some code in a Python except clause that is intended to do some logging, but the logging code might itself cause an exception. In my case, I'd like to just ignore any second exception that might occur, and raise the original exception. Here is a very simplified example:
try:
a = this_variable_doesnt_exist
except:
try:
1/0
except:
pass
raise
Running the above code, I hope to get:
NameError: name 'this_variable_doesnt_exist' is not defined
but instead, in Python 2.x, I get:
ZeroDivisionError: integer division or modulo by zero
I've discovered that in Python 3.x, it does what I want.
I couldn't find much commentary on this in the Python 2.x docs (unless I missed it). Can I achieve this in 2.x?
I believe what you're seeing is the result of exception chaining, which is a change in Python 3.
From the Motivation section of the PEP:
During the handling of one exception (exception A), it is possible that another exception (exception B) may occur. In today's Python (version 2.4), if this happens, exception B is propagated outward and exception A is lost. In order to debug the problem, it is useful to know about both exceptions. The __context__ attribute retains this information automatically.
The PEP then goes on to describe the new exception chaining (which is implemented in Py3k) in detail—it's an interesting read. I learned something new today.
With abstraction:
def log_it():
try:
1 / 0
except:
pass
try:
this = that
except:
log_it()
raise
Does what you want in Python 2.5
Another way to do it is to store the exception in a variable, then re-raise it explicitly:
try:
this = that
except NameError, e: # or NameError as e for Python 2.6
try:
1 / 0
except:
pass
raise e
Note that you probably shouldn't just be using a bare except to catch everything that might come - it's usually best to catch the specific exceptions you expect to occur in case a drastic and fatal exception (like being out of memory) occurs.
In my CausedException class I take care of that for Python 2.x (and for Python 3 as well, in case you want to pass cause trees instead of simple cause chains). Maybe it can help you.

python3 ValueError value

I am trying to write a function using python3, with exception handling.
I thought ValueError is the right tool to check if the value is in given range, as given here in python3 doc which says:
function receives an argument that has the right type but an inappropriate value
So, in this my tiny snippet, I am expecting to use ValueError to check range(0-1) which is not doing:
while True:
try:
imode = int(input("Generate for EOS(0) or S2(1)"))
except (ValueError):
print("Mode not recognised! Retry")
continue
else:
break
print(imode)
which yeilds:
Generate for EOS(0) or S2(1)3
3
Sure, I can do the value checking as:
if (imode < 0 or imode > 1):
print("Mode not recogised. RETRY!")
continue
else:
break
but the ValueError seems do do this thing.
There are several question on ValueError here, but none of them checking "inappropriate value, e.g. this
I am a novice and python is not my main language.
Kindly give me some insight.
I think you misunderstand what ValueError (and in general, an Exception) is.
Exceptions are a way for a method to signal to its caller that some critical error condition has been encountered that would prevent that method from executing as intended. Python's try-except-finally control structure provides a way for the caller to detect those error conditions and react accordingly.
ValueError is a standard Exception raised by various methods that perform range-checking of some kind to signal that a value provided to the method fell outside the valid range. In other words, it's a universal way of signaling that error condition. ValueError by itself doesn't do any kind of checking. There are many other standard Exceptions like this; KeyError signifies that you tried to access a key in a mapping structure (like a dict or set) that didn't exist, IndexError means you tried to index into a list-like structure to an invalid location, etc. None of them actually do anything special in and of themselves, they're simply a way of directly specifying exactly what kind of problem was encountered by the called method.
Exceptions go hand in hand with the idiom in python that it is generally considered 'easier to ask forgiveness than permission'. Many languages support exceptions of course, but Python is one of the few where you will very frequently see code where the Exception case is actually a commonly-followed code path rather than one that only happens when something has gone really wrong.
Here is an example of the correct use of a ValueError:
def gen(selection):
if imode == 0:
# do EOS stuff here
elif imode == 1:
# do S2 stuff here
else:
raise ValueError("Please Select An Option Between 0-1")
def selector():
while True:
try:
gen(int(input("Generate for EOS(0) or S2(1)")))
break
except ValueError as e: # This will actually satisfy two cases; If the user entered not a number, in which case int() raises, or if they entered a number out of bounds, in which chase gen() raises.
print(e)
Note there are probably much more direct ways to do what you want, but this is just serving as an example of how to correctly use a ValueError.

Is it correct to use a return statement within a try and except statement?

If I have such code in the end of function:
try:
return map(float, result)
except ValueError, e:
print "error", e
Is it correct to use try / except in return part of method?
Is there a wiser way to solve this?
Keep it simple: no try block
It took me a while to learn, that in Python it is natural, that functions throw exceptions up. I have spent too much effort on handling these problems in the place the problem occurred.
The code can become much simpler and also easier to maintain if you simply let the exception bubble up. This allows for detecting problems on the level, where it is appropriate.
One option is:
try:
return map(float, result)
except ValueError, e:
print "error", e
raise
but this introduces print from within some deep function. The same can be provided by raise which let upper level code to do what is appropriate.
With this context, my preferred solution looks:
return map(float, result)
No need to dance around, do, what is expected to be done, and throw an exception up, if there is a problem.
If you surround the code block containing a return statement with an try/except clause, you should definitely spend some thoughts of what should be returned, if an exception actually occurs:
In you example, the function will simply return None. If it's that what you want, I would suggest to explicitely add a return None like
except ValueError, e:
print "error", e
return None
in your except block to make that fact clear.
Other possibilities would be to return a "default value" (empty map in this case) or to "reraise" the exception using
except ValueError, e:
print "error", e
raise
It depends on how the function is used, under what circumstances you expect exceptions and on your general design which option you want to choose.
As is often the case in languages with exceptions, programmers assume that printing an error message "handles" it.
Printing an error message doesn't handle anything; you might as well have put pass there instead. This causes problems because the the code was expecting the try block to accomplish something and that something has not happened.
In Python, you should:
figure out where the error can actually be handled in the sense that the fault is actually rectified, or
let the exception unwind to the top and abort the program
Having a program abort with an exception is infinitely better than having it run and yield inaccurate results.
So unless you know that your code can accept an empty list, you shouldn't return anything that you thought deserved a try block.

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