warnings
— Controle de avisos¶
Código-fonte: Lib/warnings.py
As mensagens de aviso são normalmente emitidas em situações em que é útil alertar o usuário sobre alguma condição em um programa, onde essa condição (normalmente) não garante o levantamento de uma exceção e o encerramento do programa. Por exemplo, pode-se querer emitir um aviso quando um programa usa um módulo obsoleto.
Os programadores Python emitem avisos chamando a função warn()
definida neste módulo. (Os programadores C usam PyErr_WarnEx()
; veja Manipulando Exceções para detalhes).
Mensagens de aviso são normalmente escritas no sys.stderr
, mas sua disposição pode ser alterada de forma flexível, desde ignorar todos os avisos até transformá-los em exceções. A disposição dos avisos pode variar de acordo com categoria de aviso, o texto da mensagem de aviso e o local de origem onde ela é emitida. As repetições de um aviso específico para o mesmo local de origem são normalmente suprimidas.
Existem duas etapas no controle de avisos: primeiro, cada vez que um aviso é emitido, é feita uma determinação se uma mensagem deve ser emitida ou não; a seguir, se uma mensagem deve ser emitida, ela é formatada e impressa usando um gancho configurável pelo usuário.
A determinação de emitir ou não uma mensagem de aviso é controlada pelo filtro de aviso, que é uma sequência de regras e ações correspondentes. As regras podem ser adicionadas ao filtro chamando filterwarnings()
e redefinidas para seu estado padrão chamando resetwarnings()
.
A exibição de mensagens de aviso é feita chamando showwarning()
, que pode ser substituída; a implementação padrão desta função formata a mensagem chamando formatwarning()
, que também está disponível para uso por implementações personalizadas.
Ver também
logging.captureWarnings()
permite que você manipule todos os avisos com a infraestrutura de registro padrão.
Categorias de avisos¶
Existem várias exceções embutidas que representam categorias de aviso. Essa categorização é útil para filtrar grupos de avisos.
Embora sejam tecnicamente exceções embutidas, elas são documentadas aqui, porque conceitualmente pertencem ao mecanismo de avisos.
O código do usuário pode definir categorias de aviso adicionais criando uma subclasse de uma das categorias de aviso padrão. Uma categoria de aviso deve ser sempre uma subclasse da classe Warning
.
As seguintes classes de categorias de avisos estão definidas atualmente:
Classe |
Descrição |
---|---|
Esta é a classe base de todas as classes de categoria de aviso. É uma subclasse de |
|
A categoria padrão para |
|
Categoria base para avisos sobre recursos descontinuados quando esses avisos são destinados a outros desenvolvedores Python (ignorado por padrão, a menos que acionado por código em |
|
Categoria base para avisos sobre recursos sintáticos duvidosos. |
|
Categoria base para avisos sobre recursos duvidosos de tempo de execução. |
|
Categoria base para avisos sobre recursos descontinuados quando esses avisos se destinam a usuários finais de aplicações escritas em Python. |
|
Categoria base para avisos sobre recursos que serão descontinuados no futuro (ignorados por padrão). |
|
Categoria base para avisos acionados durante o processo de importação de um módulo (ignorado por padrão). |
|
Categoria base para avisos relacionados a Unicode. |
|
Categoria base para avisos relacionados a |
|
Base category for warnings related to resource usage (ignored by default). |
Alterado na versão 3.7: Anteriormente, DeprecationWarning
e FutureWarning
eram diferenciadas com base em se um recurso estava sendo removido completamente ou mudando seu comportamento. Elas agora são diferenciadas com base em seu público-alvo e na maneira como são tratadas pelos filtros de avisos padrão.
O filtro de avisos¶
O filtro de avisos controla se os avisos são ignorados, exibidos ou transformados em erros (levantando uma exceção).
Conceitualmente, o filtro de avisos mantém uma lista ordenada de especificações de filtro; qualquer aviso específico é comparado com cada especificação de filtro na lista, por sua vez, até que uma correspondência seja encontrada; o filtro determina a disposição da correspondência. Cada entrada é uma tupla no formato (action, message, category, module, lineno), sendo:
action é uma das seguintes strings:
Valor
Disposição
"default"
exibe a primeira ocorrência de avisos correspondentes para cada local (módulo + número da linha) onde o aviso é emitido
"error"
transforma avisos correspondentes em exceções
"ignore"
nunca exibe avisos correspondentes
"always"
sempre exibe avisos correspondentes
"module"
exibe a primeira ocorrência de avisos correspondentes para cada módulo onde o aviso é emitido (independentemente do número da linha)
"once"
exibe apenas a primeira ocorrência de avisos correspondentes, independentemente da localização
message is a string containing a regular expression that the start of the warning message must match, case-insensitively. In
-W
andPYTHONWARNINGS
, message is a literal string that the start of the warning message must contain (case-insensitively), ignoring any whitespace at the start or end of message.category é uma classe (uma subclasse de
Warning
) da qual a categoria de aviso deve ser uma subclasse para corresponder.module is a string containing a regular expression that the start of the fully qualified module name must match, case-sensitively. In
-W
andPYTHONWARNINGS
, module is a literal string that the fully qualified module name must be equal to (case-sensitively), ignoring any whitespace at the start or end of module.lineno é um número inteiro que deve corresponder ao número da linha onde ocorreu o aviso, ou
0
para corresponder a todos os números de linha.
Como a classe Warning
é derivada da classe embutida Exception
, para transformar um aviso em um erro, simplesmente levantamos category(message)
.
Se um aviso for relatado e não corresponder a nenhum filtro registrado, a ação “padrão” será aplicada (daí seu nome).
Describing Warning Filters¶
The warnings filter is initialized by -W
options passed to the Python
interpreter command line and the PYTHONWARNINGS
environment variable.
The interpreter saves the arguments for all supplied entries without
interpretation in sys.warnoptions
; the warnings
module parses these
when it is first imported (invalid options are ignored, after printing a
message to sys.stderr
).
Individual warnings filters are specified as a sequence of fields separated by colons:
action:message:category:module:line
The meaning of each of these fields is as described in O filtro de avisos.
When listing multiple filters on a single line (as for
PYTHONWARNINGS
), the individual filters are separated by commas and
the filters listed later take precedence over those listed before them (as
they’re applied left-to-right, and the most recently applied filters take
precedence over earlier ones).
Commonly used warning filters apply to either all warnings, warnings in a particular category, or warnings raised by particular modules or packages. Some examples:
default # Show all warnings (even those ignored by default)
ignore # Ignore all warnings
error # Convert all warnings to errors
error::ResourceWarning # Treat ResourceWarning messages as errors
default::DeprecationWarning # Show DeprecationWarning messages
ignore,default:::mymodule # Only report warnings triggered by "mymodule"
error:::mymodule # Convert warnings to errors in "mymodule"
Filtro de avisos padrão¶
By default, Python installs several warning filters, which can be overridden by
the -W
command-line option, the PYTHONWARNINGS
environment
variable and calls to filterwarnings()
.
In regular release builds, the default warning filter has the following entries (in order of precedence):
default::DeprecationWarning:__main__
ignore::DeprecationWarning
ignore::PendingDeprecationWarning
ignore::ImportWarning
ignore::ResourceWarning
In a debug build, the list of default warning filters is empty.
Alterado na versão 3.2: DeprecationWarning
is now ignored by default in addition to
PendingDeprecationWarning
.
Alterado na versão 3.7: DeprecationWarning
is once again shown by default when triggered
directly by code in __main__
.
Alterado na versão 3.7: BytesWarning
no longer appears in the default filter list and is
instead configured via sys.warnoptions
when -b
is specified
twice.
Overriding the default filter¶
Developers of applications written in Python may wish to hide all Python level
warnings from their users by default, and only display them when running tests
or otherwise working on the application. The sys.warnoptions
attribute
used to pass filter configurations to the interpreter can be used as a marker to
indicate whether or not warnings should be disabled:
import sys
if not sys.warnoptions:
import warnings
warnings.simplefilter("ignore")
Developers of test runners for Python code are advised to instead ensure that all warnings are displayed by default for the code under test, using code like:
import sys
if not sys.warnoptions:
import os, warnings
warnings.simplefilter("default") # Change the filter in this process
os.environ["PYTHONWARNINGS"] = "default" # Also affect subprocesses
Finally, developers of interactive shells that run user code in a namespace
other than __main__
are advised to ensure that DeprecationWarning
messages are made visible by default, using code like the following (where
user_ns
is the module used to execute code entered interactively):
import warnings
warnings.filterwarnings("default", category=DeprecationWarning,
module=user_ns.get("__name__"))
Temporarily Suppressing Warnings¶
If you are using code that you know will raise a warning, such as a deprecated
function, but do not want to see the warning (even when warnings have been
explicitly configured via the command line), then it is possible to suppress
the warning using the catch_warnings
context manager:
import warnings
def fxn():
warnings.warn("deprecated", DeprecationWarning)
with warnings.catch_warnings():
warnings.simplefilter("ignore")
fxn()
While within the context manager all warnings will simply be ignored. This
allows you to use known-deprecated code without having to see the warning while
not suppressing the warning for other code that might not be aware of its use
of deprecated code. Note: this can only be guaranteed in a single-threaded
application. If two or more threads use the catch_warnings
context
manager at the same time, the behavior is undefined.
Testing Warnings¶
To test warnings raised by code, use the catch_warnings
context
manager. With it you can temporarily mutate the warnings filter to facilitate
your testing. For instance, do the following to capture all raised warnings to
check:
import warnings
def fxn():
warnings.warn("deprecated", DeprecationWarning)
with warnings.catch_warnings(record=True) as w:
# Cause all warnings to always be triggered.
warnings.simplefilter("always")
# Trigger a warning.
fxn()
# Verify some things
assert len(w) == 1
assert issubclass(w[-1].category, DeprecationWarning)
assert "deprecated" in str(w[-1].message)
One can also cause all warnings to be exceptions by using error
instead of
always
. One thing to be aware of is that if a warning has already been
raised because of a once
/default
rule, then no matter what filters are
set the warning will not be seen again unless the warnings registry related to
the warning has been cleared.
Once the context manager exits, the warnings filter is restored to its state
when the context was entered. This prevents tests from changing the warnings
filter in unexpected ways between tests and leading to indeterminate test
results. The showwarning()
function in the module is also restored to
its original value. Note: this can only be guaranteed in a single-threaded
application. If two or more threads use the catch_warnings
context
manager at the same time, the behavior is undefined.
When testing multiple operations that raise the same kind of warning, it is important to test them in a manner that confirms each operation is raising a new warning (e.g. set warnings to be raised as exceptions and check the operations raise exceptions, check that the length of the warning list continues to increase after each operation, or else delete the previous entries from the warnings list before each new operation).
Updating Code For New Versions of Dependencies¶
Warning categories that are primarily of interest to Python developers (rather than end users of applications written in Python) are ignored by default.
Notably, this “ignored by default” list includes DeprecationWarning
(for every module except __main__
), which means developers should make sure
to test their code with typically ignored warnings made visible in order to
receive timely notifications of future breaking API changes (whether in the
standard library or third party packages).
In the ideal case, the code will have a suitable test suite, and the test runner
will take care of implicitly enabling all warnings when running tests
(the test runner provided by the unittest
module does this).
In less ideal cases, applications can be checked for use of deprecated
interfaces by passing -Wd
to the Python interpreter (this is
shorthand for -W default
) or setting PYTHONWARNINGS=default
in
the environment. This enables default handling for all warnings, including those
that are ignored by default. To change what action is taken for encountered
warnings you can change what argument is passed to -W
(e.g.
-W error
). See the -W
flag for more details on what is
possible.
Available Functions¶
-
warnings.
warn
(message, category=None, stacklevel=1, source=None)¶ Issue a warning, or maybe ignore it or raise an exception. The category argument, if given, must be a warning category class; it defaults to
UserWarning
. Alternatively, message can be aWarning
instance, in which case category will be ignored andmessage.__class__
will be used. In this case, the message text will bestr(message)
. This function raises an exception if the particular warning issued is changed into an error by the warnings filter. The stacklevel argument can be used by wrapper functions written in Python, like this:def deprecation(message): warnings.warn(message, DeprecationWarning, stacklevel=2)
This makes the warning refer to
deprecation()
’s caller, rather than to the source ofdeprecation()
itself (since the latter would defeat the purpose of the warning message).source, if supplied, is the destroyed object which emitted a
ResourceWarning
.Alterado na versão 3.6: Added source parameter.
-
warnings.
warn_explicit
(message, category, filename, lineno, module=None, registry=None, module_globals=None, source=None)¶ This is a low-level interface to the functionality of
warn()
, passing in explicitly the message, category, filename and line number, and optionally the module name and the registry (which should be the__warningregistry__
dictionary of the module). The module name defaults to the filename with.py
stripped; if no registry is passed, the warning is never suppressed. message must be a string and category a subclass ofWarning
or message may be aWarning
instance, in which case category will be ignored.module_globals, if supplied, should be the global namespace in use by the code for which the warning is issued. (This argument is used to support displaying source for modules found in zipfiles or other non-filesystem import sources).
source, if supplied, is the destroyed object which emitted a
ResourceWarning
.Alterado na versão 3.6: Add the source parameter.
-
warnings.
showwarning
(message, category, filename, lineno, file=None, line=None)¶ Write a warning to a file. The default implementation calls
formatwarning(message, category, filename, lineno, line)
and writes the resulting string to file, which defaults tosys.stderr
. You may replace this function with any callable by assigning towarnings.showwarning
. line is a line of source code to be included in the warning message; if line is not supplied,showwarning()
will try to read the line specified by filename and lineno.
-
warnings.
formatwarning
(message, category, filename, lineno, line=None)¶ Format a warning the standard way. This returns a string which may contain embedded newlines and ends in a newline. line is a line of source code to be included in the warning message; if line is not supplied,
formatwarning()
will try to read the line specified by filename and lineno.
-
warnings.
filterwarnings
(action, message='', category=Warning, module='', lineno=0, append=False)¶ Insert an entry into the list of warnings filter specifications. The entry is inserted at the front by default; if append is true, it is inserted at the end. This checks the types of the arguments, compiles the message and module regular expressions, and inserts them as a tuple in the list of warnings filters. Entries closer to the front of the list override entries later in the list, if both match a particular warning. Omitted arguments default to a value that matches everything.
-
warnings.
simplefilter
(action, category=Warning, lineno=0, append=False)¶ Insert a simple entry into the list of warnings filter specifications. The meaning of the function parameters is as for
filterwarnings()
, but regular expressions are not needed as the filter inserted always matches any message in any module as long as the category and line number match.
-
warnings.
resetwarnings
()¶ Reset the warnings filter. This discards the effect of all previous calls to
filterwarnings()
, including that of the-W
command line options and calls tosimplefilter()
.
Available Context Managers¶
-
class
warnings.
catch_warnings
(*, record=False, module=None)¶ A context manager that copies and, upon exit, restores the warnings filter and the
showwarning()
function. If the record argument isFalse
(the default) the context manager returnsNone
on entry. If record isTrue
, a list is returned that is progressively populated with objects as seen by a customshowwarning()
function (which also suppresses output tosys.stdout
). Each object in the list has attributes with the same names as the arguments toshowwarning()
.The module argument takes a module that will be used instead of the module returned when you import
warnings
whose filter will be protected. This argument exists primarily for testing thewarnings
module itself.Nota
The
catch_warnings
manager works by replacing and then later restoring the module’sshowwarning()
function and internal list of filter specifications. This means the context manager is modifying global state and therefore is not thread-safe.