// Copyright (c) 2015 Daniel Grunwald // // Permission is hereby granted, free of charge, to any person obtaining a copy of this // software and associated documentation files (the "Software"), to deal in the Software // without restriction, including without limitation the rights to use, copy, modify, merge, // publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons // to whom the Software is furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in all copies or // substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, // INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR // PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE // FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR // OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER // DEALINGS IN THE SOFTWARE. use std; use python::{PythonObject, ToPythonPointer, Python, PythonObjectDowncastError, PythonObjectWithTypeObject, PyClone, PyDrop}; use objects::{PyObject, PyType, exc}; #[cfg(feature="python27-sys")] use objects::oldstyle::PyClass; use ffi; use libc; use std::ptr; use libc::c_char; use conversion::ToPyObject; use std::ffi::CString; /** Defines a new exception type. # Syntax `py_exception!(module, MyError)` * `module` is the name of the containing module. * `MyError` is the name of the new exception type. # Example ``` #[macro_use] extern crate cpython; use cpython::{Python, PyDict}; py_exception!(mymodule, CustomError); fn main() { let gil = Python::acquire_gil(); let py = gil.python(); let ctx = PyDict::new(py); ctx.set_item(py, "CustomError", py.get_type::()).unwrap(); py.run("assert str(CustomError) == \"\"", None, Some(&ctx)).unwrap(); py.run("assert CustomError('oops').args == ('oops',)", None, Some(&ctx)).unwrap(); } ``` */ #[macro_export] macro_rules! py_exception { ($module: ident, $name: ident, $base: ty) => { pub struct $name($crate::PyObject); pyobject_newtype!($name); impl $name { pub fn new<'p, T: $crate::ToPyObject>(py: $crate::Python<'p>, args: T) -> $crate::PyErr { $crate::PyErr::new::<$name, T>(py, args) } } impl $crate::PythonObjectWithCheckedDowncast for $name { #[inline] fn downcast_from<'p>(py: $crate::Python<'p>, obj: $crate::PyObject) -> Result<$name, $crate::PythonObjectDowncastError<'p>> { if <$name as $crate::PythonObjectWithTypeObject>::type_object(py).is_instance(py, &obj) { Ok(unsafe { $crate::PythonObject::unchecked_downcast_from(obj) }) } else { Err($crate::PythonObjectDowncastError(py)) } } #[inline] fn downcast_borrow_from<'a, 'p>(py: $crate::Python<'p>, obj: &'a $crate::PyObject) -> Result<&'a $name, $crate::PythonObjectDowncastError<'p>> { if <$name as $crate::PythonObjectWithTypeObject>::type_object(py).is_instance(py, obj) { Ok(unsafe { $crate::PythonObject::unchecked_downcast_borrow_from(obj) }) } else { Err($crate::PythonObjectDowncastError(py)) } } } impl $crate::PythonObjectWithTypeObject for $name { #[inline] fn type_object(py: $crate::Python) -> $crate::PyType { unsafe { static mut type_object: *mut $crate::_detail::ffi::PyTypeObject = 0 as *mut $crate::_detail::ffi::PyTypeObject; if type_object.is_null() { type_object = $crate::PyErr::new_type( py, concat!(stringify!($module), ".", stringify!($name)), Some($crate::PythonObject::into_object(py.get_type::<$base>())), None).as_type_ptr(); } $crate::PyType::from_type_ptr(py, type_object) } } } }; ($module: ident, $name: ident) => { py_exception!($module, $name, $crate::exc::Exception); } } /// Represents a Python exception that was raised. #[derive(Debug)] pub struct PyErr { /// The type of the exception. This should be either a `PyClass` or a `PyType`. pub ptype : PyObject, /// The value of the exception. /// /// This can be either an instance of `ptype`, /// a tuple of arguments to be passed to `ptype`'s constructor, /// or a single argument to be passed to `ptype`'s constructor. /// Call `PyErr::instance()` to get the exception instance in all cases. pub pvalue : Option, /// The `PyTraceBack` object associated with the error. pub ptraceback : Option } /// Represents the result of a Python call. pub type PyResult = Result; impl PyErr { /// Gets whether an error is present in the Python interpreter's global state. #[inline] pub fn occurred(_ : Python) -> bool { unsafe { !ffi::PyErr_Occurred().is_null() } } /// Creates a new exception type with the given name, which must be of the form /// `.`, as required by `PyErr_NewException`. /// /// `base` can be an existing exception type to subclass, or a tuple of classes /// `dict` specifies an optional dictionary of class variables and methods pub fn new_type(py: Python, name: &str, base: Option, dict: Option) -> PyType { let base: *mut ffi::PyObject = match base { None => ptr::null_mut(), Some(obj) => obj.steal_ptr() }; let dict: *mut ffi::PyObject = match dict { None => ptr::null_mut(), Some(obj) => obj.steal_ptr() }; unsafe { let null_terminated_name = CString::new(name).unwrap(); let ptr: *mut ffi::PyObject = ffi::PyErr_NewException(null_terminated_name.as_ptr() as *mut c_char, base, dict); PyObject::from_borrowed_ptr(py, ptr).unchecked_cast_into::() } } /// Retrieves the current error from the Python interpreter's global state. /// The error is cleared from the Python interpreter. /// If no error is set, returns a `SystemError`. pub fn fetch(py : Python) -> PyErr { unsafe { let mut ptype : *mut ffi::PyObject = std::mem::uninitialized(); let mut pvalue : *mut ffi::PyObject = std::mem::uninitialized(); let mut ptraceback : *mut ffi::PyObject = std::mem::uninitialized(); ffi::PyErr_Fetch(&mut ptype, &mut pvalue, &mut ptraceback); PyErr::new_from_ffi_tuple(py, ptype, pvalue, ptraceback) } } unsafe fn new_from_ffi_tuple(py: Python, ptype: *mut ffi::PyObject, pvalue: *mut ffi::PyObject, ptraceback: *mut ffi::PyObject) -> PyErr { // Note: must not panic to ensure all owned pointers get acquired correctly, // and because we mustn't panic in normalize(). PyErr { ptype: if ptype.is_null() { py.get_type::().into_object() } else { PyObject::from_owned_ptr(py, ptype) }, pvalue: PyObject::from_owned_ptr_opt(py, pvalue), ptraceback: PyObject::from_owned_ptr_opt(py, ptraceback) } } /// Creates a new PyErr of type `T`. /// /// `value` can be: /// * `NoArgs`: the exception instance will be created using python `T()` /// * a tuple: the exception instance will be created using python `T(*tuple)` /// * any other value: the exception instance will be created using python `T(value)` /// /// Panics if `T` is not a python class derived from `BaseException`. pub fn new(py: Python, value: V) -> PyErr where T: PythonObjectWithTypeObject, V: ToPyObject { PyErr::new_helper(py, py.get_type::(), value.to_py_object(py).into_object()) } fn new_helper(_py: Python, ty: PyType, value: PyObject) -> PyErr { assert!(unsafe { ffi::PyExceptionClass_Check(ty.as_object().as_ptr()) } != 0); PyErr { ptype: ty.into_object(), pvalue: Some(value), ptraceback: None } } /// Creates a new PyErr. /// /// `obj` must be an Python exception instance, the PyErr will use that instance. /// If `obj` is a Python exception type object, the PyErr will (lazily) create a new instance of that type. /// Otherwise, a `TypeError` is created instead. pub fn from_instance(py: Python, obj: O) -> PyErr where O: PythonObject { PyErr::from_instance_helper(py, obj.into_object()) } fn from_instance_helper(py: Python, obj: PyObject) -> PyErr { if unsafe { ffi::PyExceptionInstance_Check(obj.as_ptr()) } != 0 { PyErr { ptype: unsafe { PyObject::from_borrowed_ptr(py, ffi::PyExceptionInstance_Class(obj.as_ptr())) }, pvalue: Some(obj), ptraceback: None } } else if unsafe { ffi::PyExceptionClass_Check(obj.as_ptr()) } != 0 { PyErr { ptype: obj, pvalue: None, ptraceback: None } } else { PyErr { ptype: py.get_type::().into_object(), pvalue: Some("exceptions must derive from BaseException".to_py_object(py).into_object()), ptraceback: None } } } /// Construct a new error, with the usual lazy initialization of Python exceptions. /// `exc` is the exception type; usually one of the standard exceptions like `PyExc::runtime_error()`. /// `value` is the exception instance, or a tuple of arguments to pass to the exception constructor. #[inline] pub fn new_lazy_init(exc: PyType, value: Option) -> PyErr { PyErr { ptype: exc.into_object(), pvalue: value, ptraceback: None } } /// Print a standard traceback to sys.stderr. pub fn print(self, py: Python) { self.restore(py); unsafe { ffi::PyErr_PrintEx(0) } } /// Print a standard traceback to sys.stderr. pub fn print_and_set_sys_last_vars(self, py: Python) { self.restore(py); unsafe { ffi::PyErr_PrintEx(1) } } /// Return true if the current exception matches the exception in `exc`. /// If `exc` is a class object, this also returns `true` when `self` is an instance of a subclass. /// If `exc` is a tuple, all exceptions in the tuple (and recursively in subtuples) are searched for a match. pub fn matches(&self, py: Python, exc: T) -> bool where T: ToPyObject { exc.with_borrowed_ptr(py, |exc| unsafe { ffi::PyErr_GivenExceptionMatches(self.ptype.as_ptr(), exc) != 0 }) } /// Normalizes the error. This ensures that the exception value is an instance of the exception type. pub fn normalize(&mut self, py: Python) { // The normalization helper function involves temporarily moving out of the &mut self, // which requires some unsafe trickery: unsafe { std::ptr::write(self, std::ptr::read(self).into_normalized(py)); } // This is safe as long as normalized() doesn't unwind due to a panic. } /// Helper function for normalizing the error by deconstructing and reconstructing the PyErr. /// Must not panic for safety in normalize() fn into_normalized(self, py: Python) -> PyErr { let PyErr { ptype, pvalue, ptraceback } = self; let mut ptype = ptype.steal_ptr(); let mut pvalue = pvalue.steal_ptr(py); let mut ptraceback = ptraceback.steal_ptr(py); unsafe { ffi::PyErr_NormalizeException(&mut ptype, &mut pvalue, &mut ptraceback); PyErr::new_from_ffi_tuple(py, ptype, pvalue, ptraceback) } } /// Retrieves the exception type. /// /// If the exception type is an old-style class, returns `oldstyle::PyClass`. #[cfg(feature="python27-sys")] pub fn get_type(&self, py: Python) -> PyType { match self.ptype.cast_as::(py) { Ok(t) => t.clone_ref(py), Err(_) => match self.ptype.cast_as::(py) { Ok(_) => py.get_type::(), Err(_) => py.None().get_type(py) } } } /// Retrieves the exception type. #[cfg(not(feature="python27-sys"))] pub fn get_type(&self, py: Python) -> PyType { match self.ptype.cast_as::(py) { Ok(t) => t.clone_ref(py), Err(_) => py.None().get_type(py) } } /// Retrieves the exception instance for this error. /// This method takes `&mut self` because the error might need /// to be normalized in order to create the exception instance. pub fn instance(&mut self, py: Python) -> PyObject { self.normalize(py); match self.pvalue { Some(ref instance) => instance.clone_ref(py), None => py.None() } } /// Writes the error back to the Python interpreter's global state. /// This is the opposite of `PyErr::fetch()`. #[inline] pub fn restore(self, py: Python) { let PyErr { ptype, pvalue, ptraceback } = self; unsafe { ffi::PyErr_Restore(ptype.steal_ptr(), pvalue.steal_ptr(py), ptraceback.steal_ptr(py)) } } /// Issue a warning message. /// May return a PyErr if warnings-as-errors is enabled. pub fn warn(py: Python, category: &PyObject, message: &str, stacklevel: i32) -> PyResult<()> { let message = CString::new(message).unwrap(); unsafe { error_on_minusone(py, ffi::PyErr_WarnEx(category.as_ptr(), message.as_ptr(), stacklevel as ffi::Py_ssize_t)) } } } impl PyDrop for PyErr { fn release_ref(self, py: Python) { self.ptype.release_ref(py); self.pvalue.release_ref(py); self.ptraceback.release_ref(py); } } impl PyClone for PyErr { fn clone_ref(&self, py: Python) -> PyErr { PyErr { ptype: self.ptype.clone_ref(py), pvalue: self.pvalue.clone_ref(py), ptraceback: self.ptraceback.clone_ref(py) } } } /// Converts `PythonObjectDowncastError` to Python `TypeError`. impl <'p> std::convert::From> for PyErr { fn from(err: PythonObjectDowncastError<'p>) -> PyErr { PyErr::new_lazy_init(err.0.get_type::(), None) } } /// Construct PyObject from the result of a Python FFI call that returns a new reference (owned pointer). /// Returns `Err(PyErr)` if the pointer is `null`. /// Unsafe because the pointer might be invalid. #[inline] pub unsafe fn result_from_owned_ptr(py : Python, p : *mut ffi::PyObject) -> PyResult { if p.is_null() { Err(PyErr::fetch(py)) } else { Ok(PyObject::from_owned_ptr(py, p)) } } fn panic_after_error(_py: Python) -> ! { unsafe { ffi::PyErr_Print(); } panic!("Python API called failed"); } #[inline] pub unsafe fn from_owned_ptr_or_panic(py : Python, p : *mut ffi::PyObject) -> PyObject { if p.is_null() { panic_after_error(py); } else { PyObject::from_owned_ptr(py, p) } } pub unsafe fn result_cast_from_owned_ptr(py : Python, p : *mut ffi::PyObject) -> PyResult where T: ::python::PythonObjectWithCheckedDowncast { if p.is_null() { Err(PyErr::fetch(py)) } else { Ok(try!(PyObject::from_owned_ptr(py, p).cast_into(py))) } } pub unsafe fn cast_from_owned_ptr_or_panic(py : Python, p : *mut ffi::PyObject) -> T where T: ::python::PythonObjectWithCheckedDowncast { if p.is_null() { panic_after_error(py); } else { PyObject::from_owned_ptr(py, p).cast_into(py).unwrap() } } /// Returns Ok if the error code is not -1. #[inline] pub fn error_on_minusone(py : Python, result : libc::c_int) -> PyResult<()> { if result != -1 { Ok(()) } else { Err(PyErr::fetch(py)) } } #[cfg(test)] mod tests { use {Python, PyErr}; use objects::exc; #[test] fn set_typeerror() { let gil = Python::acquire_gil(); let py = gil.python(); PyErr::new_lazy_init(py.get_type::(), None).restore(py); assert!(PyErr::occurred(py)); drop(PyErr::fetch(py)); } }