// 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 python::{Python, PythonObject, ToPythonPointer, PyDrop}; use err::{self, PyErr, PyResult}; use super::object::PyObject; use super::exc; use ffi::{self, Py_ssize_t}; use conversion::{FromPyObject, ToPyObject}; use std::slice; /// Represents a Python tuple object. pub struct PyTuple(PyObject); pyobject_newtype!(PyTuple, PyTuple_Check, PyTuple_Type); impl PyTuple { /// Construct a new tuple with the given elements. pub fn new(py: Python, elements: &[PyObject]) -> PyTuple { unsafe { let len = elements.len(); let ptr = ffi::PyTuple_New(len as Py_ssize_t); let t = err::result_cast_from_owned_ptr::(py, ptr).unwrap(); for (i, e) in elements.iter().enumerate() { ffi::PyTuple_SetItem(ptr, i as Py_ssize_t, e.steal_ptr(py)); } t } } /// Retrieves the empty tuple. pub fn empty(py: Python) -> PyTuple { unsafe { err::result_cast_from_owned_ptr::(py, ffi::PyTuple_New(0)).unwrap() } } /// Gets the length of the tuple. #[inline] pub fn len(&self, _py: Python) -> usize { unsafe { // non-negative Py_ssize_t should always fit into Rust uint ffi::PyTuple_GET_SIZE(self.0.as_ptr()) as usize } } /// Gets the item at the specified index. /// /// Panics if the index is out of range. pub fn get_item(&self, py: Python, index: usize) -> PyObject { // TODO: reconsider whether we should panic // It's quite inconsistent that this method takes `Python` when `len()` does not. assert!(index < self.len(py)); unsafe { PyObject::from_borrowed_ptr(py, ffi::PyTuple_GET_ITEM(self.0.as_ptr(), index as Py_ssize_t)) } } #[inline] pub fn as_slice<'a>(&'a self, py: Python) -> &'a [PyObject] { // This is safe because PyObject has the same memory layout as *mut ffi::PyObject, // and because tuples are immutable. // (We don't even need a Python token, thanks to immutability) unsafe { let ptr = self.0.as_ptr() as *mut ffi::PyTupleObject; PyObject::borrow_from_owned_ptr_slice( slice::from_raw_parts( (*ptr).ob_item.as_ptr(), self.len(py) )) } } #[inline] pub fn iter(&self, py: Python) -> slice::Iter { self.as_slice(py).iter() } } fn wrong_tuple_length(py: Python, t: &PyTuple, expected_length: usize) -> PyErr { let msg = format!("Expected tuple of length {}, but got tuple of length {}.", expected_length, t.len(py)); PyErr::new_lazy_init(py.get_type::(), Some(msg.to_py_object(py).into_object())) } macro_rules! tuple_conversion ({$length:expr,$(($refN:ident, $n:tt, $T:ident)),+} => { impl <$($T: ToPyObject),+> ToPyObject for ($($T,)+) { type ObjectType = PyTuple; fn to_py_object(&self, py: Python) -> PyTuple { PyTuple::new(py, &[ $(py_coerce_expr!(self.$n.to_py_object(py)).into_object(),)+ ]) } fn into_py_object(self, py: Python) -> PyTuple { PyTuple::new(py, &[ $(py_coerce_expr!(self.$n.into_py_object(py)).into_object(),)+ ]) } } impl <'s, $($T: FromPyObject<'s>),+> FromPyObject<'s> for ($($T,)+) { fn extract(py: Python, obj: &'s PyObject) -> PyResult { let t = try!(obj.cast_as::(py)); let slice = t.as_slice(py); if slice.len() == $length { Ok(( $( try!(slice[$n].extract::<$T>(py)), )+ )) } else { Err(wrong_tuple_length(py, t, $length)) } } } }); tuple_conversion!(1, (ref0, 0, A)); tuple_conversion!(2, (ref0, 0, A), (ref1, 1, B)); tuple_conversion!(3, (ref0, 0, A), (ref1, 1, B), (ref2, 2, C)); tuple_conversion!(4, (ref0, 0, A), (ref1, 1, B), (ref2, 2, C), (ref3, 3, D)); tuple_conversion!(5, (ref0, 0, A), (ref1, 1, B), (ref2, 2, C), (ref3, 3, D), (ref4, 4, E)); tuple_conversion!(6, (ref0, 0, A), (ref1, 1, B), (ref2, 2, C), (ref3, 3, D), (ref4, 4, E), (ref5, 5, F)); tuple_conversion!(7, (ref0, 0, A), (ref1, 1, B), (ref2, 2, C), (ref3, 3, D), (ref4, 4, E), (ref5, 5, F), (ref6, 6, G)); tuple_conversion!(8, (ref0, 0, A), (ref1, 1, B), (ref2, 2, C), (ref3, 3, D), (ref4, 4, E), (ref5, 5, F), (ref6, 6, G), (ref7, 7, H)); tuple_conversion!(9, (ref0, 0, A), (ref1, 1, B), (ref2, 2, C), (ref3, 3, D), (ref4, 4, E), (ref5, 5, F), (ref6, 6, G), (ref7, 7, H), (ref8, 8, I)); // Empty tuple: /// An empty struct that represents the empty argument list. /// Corresponds to the empty tuple `()` in Python. /// /// # Example /// ``` /// let gil_guard = cpython::Python::acquire_gil(); /// let py = gil_guard.python(); /// let os = py.import("os").unwrap(); /// let pid = os.call(py, "get_pid", cpython::NoArgs, None); /// ``` #[derive(Copy, Clone, Debug)] pub struct NoArgs; /// Converts `NoArgs` to an empty Python tuple. impl ToPyObject for NoArgs { type ObjectType = PyTuple; fn to_py_object(&self, py: Python) -> PyTuple { PyTuple::empty(py) } } /// Returns `Ok(NoArgs)` if the input is an empty Python tuple. /// Otherwise, returns an error. extract!(obj to NoArgs; py => { let t = try!(obj.cast_as::(py)); if t.len(py) == 0 { Ok(NoArgs) } else { Err(wrong_tuple_length(py, t, 0)) } }); #[cfg(test)] mod test { use python::{Python, PythonObject}; use conversion::ToPyObject; #[test] fn test_len() { let gil = Python::acquire_gil(); let py = gil.python(); let tuple = (1, 2, 3).to_py_object(py); assert_eq!(3, tuple.len(py)); assert_eq!((1, 2, 3), tuple.into_object().extract(py).unwrap()); } }