use pyo3::exceptions::{PyIndexError, PyTypeError}; use pyo3::pyclass::CompareOp; use pyo3::types::{PyDict, PyIterator, PyTuple, PyType}; use pyo3::{exceptions::PyKeyError, types::PyMapping, types::PyTupleMethods}; use pyo3::{prelude::*, AsPyPointer, PyTypeInfo}; use rpds::{ HashTrieMap, HashTrieMapSync, HashTrieSet, HashTrieSetSync, List, ListSync, Queue, QueueSync, }; use std::collections::hash_map::DefaultHasher; use std::hash::{Hash, Hasher}; fn hash_shuffle_bits(h: usize) -> usize { ((h ^ 89869747) ^ (h << 16)) * 3644798167 } #[derive(Debug)] struct Key { hash: isize, inner: PyObject, } impl Hash for Key { fn hash(&self, state: &mut H) { state.write_isize(self.hash); } } impl Eq for Key {} impl PartialEq for Key { fn eq(&self, other: &Self) -> bool { Python::with_gil(|py| { self.inner .call_method1(py, "__eq__", (&other.inner,)) .and_then(|value| value.extract(py)) .expect("__eq__ failed!") }) } } impl Key { fn clone_ref(&self, py: Python<'_>) -> Self { Key { hash: self.hash, inner: self.inner.clone_ref(py), } } } impl IntoPy for Key { fn into_py(self, py: Python<'_>) -> PyObject { self.inner.into_py(py) } } unsafe impl AsPyPointer for Key { fn as_ptr(&self) -> *mut pyo3::ffi::PyObject { self.inner.as_ptr() } } impl<'source> FromPyObject<'source> for Key { fn extract_bound(ob: &Bound<'source, PyAny>) -> PyResult { Ok(Key { hash: ob.hash()?, inner: ob.clone().unbind(), }) } } #[repr(transparent)] #[pyclass(name = "HashTrieMap", module = "rpds", frozen, mapping)] struct HashTrieMapPy { inner: HashTrieMapSync, } impl From> for HashTrieMapPy { fn from(map: HashTrieMapSync) -> Self { HashTrieMapPy { inner: map } } } impl<'source> FromPyObject<'source> for HashTrieMapPy { fn extract_bound(ob: &Bound<'source, PyAny>) -> PyResult { let mut ret = HashTrieMap::new_sync(); if let Ok(mapping) = ob.downcast::() { for each in mapping.items()?.iter()? { let (k, v): (Key, PyObject) = each?.extract()?; ret.insert_mut(k, v); } } else { for each in ob.iter()? { let (k, v): (Key, PyObject) = each?.extract()?; ret.insert_mut(k, v); } } Ok(HashTrieMapPy { inner: ret }) } } #[pymethods] impl HashTrieMapPy { #[new] #[pyo3(signature = (value=None, ** kwds))] fn init(value: Option, kwds: Option<&Bound<'_, PyDict>>) -> PyResult { let mut map: HashTrieMapPy; if let Some(value) = value { map = value; } else { map = HashTrieMapPy { inner: HashTrieMap::new_sync(), }; } if let Some(kwds) = kwds { for (k, v) in kwds { map.inner.insert_mut(Key::extract_bound(&k)?, v.into()); } } Ok(map) } fn __contains__(&self, key: Key) -> bool { self.inner.contains_key(&key) } fn __iter__(slf: PyRef<'_, Self>) -> KeysIterator { KeysIterator { inner: slf.inner.clone(), } } fn __getitem__(&self, key: Key, py: Python) -> PyResult { match self.inner.get(&key) { Some(value) => Ok(value.clone_ref(py)), None => Err(PyKeyError::new_err(key)), } } fn __len__(&self) -> usize { self.inner.size() } fn __repr__(&self, py: Python) -> String { let contents = self.inner.into_iter().map(|(k, v)| { format!( "{}: {}", k.inner .call_method0(py, "__repr__") .and_then(|r| r.extract(py)) .unwrap_or("".to_owned()), v.call_method0(py, "__repr__") .and_then(|r| r.extract(py)) .unwrap_or("".to_owned()) ) }); format!( "HashTrieMap({{{}}})", contents.collect::>().join(", ") ) } fn __richcmp__(&self, other: &Self, op: CompareOp, py: Python<'_>) -> PyResult { match op { CompareOp::Eq => Ok((self.inner.size() == other.inner.size() && self .inner .iter() .map(|(k1, v1)| (v1, other.inner.get(k1))) .map(|(v1, v2)| v1.bind(py).eq(v2)) .all(|r| r.unwrap_or(false))) .into_py(py)), CompareOp::Ne => Ok((self.inner.size() != other.inner.size() || self .inner .iter() .map(|(k1, v1)| (v1, other.inner.get(k1))) .map(|(v1, v2)| v1.bind(py).ne(v2)) .all(|r| r.unwrap_or(true))) .into_py(py)), _ => Ok(py.NotImplemented()), } } fn __hash__(&self, py: Python) -> PyResult { // modified from https://github.com/python/cpython/blob/d69529d31ccd1510843cfac1ab53bb8cb027541f/Objects/setobject.c#L715 let mut hash_val = self .inner .iter() .map(|(key, val)| { let mut hasher = DefaultHasher::new(); let val_bound = val.bind(py); let key_hash = key.hash; let val_hash = val_bound.hash().map_err(|_| { PyTypeError::new_err(format!( "Unhashable type in HashTrieMap of key {}: {}", key.inner .bind(py) .repr() .and_then(|r| r.extract()) .unwrap_or(" error".to_string()), val_bound .repr() .and_then(|r| r.extract()) .unwrap_or(" error".to_string()) )) })?; hasher.write_isize(key_hash); hasher.write_isize(val_hash); Ok(hasher.finish() as usize) }) .try_fold(0, |acc: usize, x: PyResult| { PyResult::::Ok(acc ^ hash_shuffle_bits(x?)) })?; // factor in the number of entries in the collection hash_val ^= (self.inner.size() + 1) * 1927868237; // dispense patterns in the hash value hash_val ^= (hash_val >> 11) ^ (hash_val >> 25); hash_val = hash_val * 69069 + 907133923; Ok(hash_val as isize) } fn __reduce__(slf: PyRef) -> (Bound<'_, PyType>, (Vec<(Key, PyObject)>,)) { ( HashTrieMapPy::type_object_bound(slf.py()), (slf.inner .iter() .map(|(k, v)| (k.clone_ref(slf.py()), v.clone_ref(slf.py()))) .collect(),), ) } #[classmethod] fn convert( _cls: &Bound<'_, PyType>, value: Bound<'_, PyAny>, py: Python, ) -> PyResult { if value.is_instance_of::() { Ok(value.unbind()) } else { Ok(HashTrieMapPy::extract_bound(&value)?.into_py(py)) } } #[classmethod] #[pyo3(signature = (keys, val=None))] fn fromkeys( _cls: &Bound<'_, PyType>, keys: &Bound<'_, PyAny>, val: Option<&Bound<'_, PyAny>>, py: Python, ) -> PyResult { let mut inner = HashTrieMap::new_sync(); let none = py.None().into_bound(py); let value = val.unwrap_or(&none); for each in keys.iter()? { let key = Key::extract_bound(&each?)?; inner.insert_mut(key, value.clone().unbind()); } Ok(HashTrieMapPy { inner }) } #[pyo3(signature = (key, default=None))] fn get(&self, key: Key, default: Option, py: Python) -> Option { if let Some(value) = self.inner.get(&key) { Some(value.clone_ref(py)) } else { default } } fn keys(&self) -> KeysView { KeysView { inner: self.inner.clone(), } } fn values(&self) -> ValuesView { ValuesView { inner: self.inner.clone(), } } fn items(&self) -> ItemsView { ItemsView { inner: self.inner.clone(), } } fn discard(&self, key: Key) -> PyResult { match self.inner.contains_key(&key) { true => Ok(HashTrieMapPy { inner: self.inner.remove(&key), }), false => Ok(HashTrieMapPy { inner: self.inner.clone(), }), } } fn insert(&self, key: Key, value: Bound<'_, PyAny>) -> HashTrieMapPy { HashTrieMapPy { inner: self.inner.insert(key, value.unbind()), } } fn remove(&self, key: Key) -> PyResult { match self.inner.contains_key(&key) { true => Ok(HashTrieMapPy { inner: self.inner.remove(&key), }), false => Err(PyKeyError::new_err(key)), } } #[pyo3(signature = (*maps, **kwds))] fn update( &self, maps: &Bound<'_, PyTuple>, kwds: Option<&Bound<'_, PyDict>>, ) -> PyResult { let mut inner = self.inner.clone(); for value in maps { let map = HashTrieMapPy::extract_bound(&value)?; for (k, v) in &map.inner { inner.insert_mut(k.clone_ref(value.py()), v.clone_ref(value.py())); } } if let Some(kwds) = kwds { for (k, v) in kwds { inner.insert_mut(Key::extract_bound(&k)?, v.extract()?); } } Ok(HashTrieMapPy { inner }) } } #[pyclass(module = "rpds")] struct KeysIterator { inner: HashTrieMapSync, } #[pymethods] impl KeysIterator { fn __iter__(slf: PyRef<'_, Self>) -> PyRef<'_, Self> { slf } fn __next__(mut slf: PyRefMut<'_, Self>) -> Option { let first = slf.inner.keys().next()?.clone_ref(slf.py()); slf.inner = slf.inner.remove(&first); Some(first) } } #[pyclass(module = "rpds")] struct ValuesIterator { inner: HashTrieMapSync, } #[pymethods] impl ValuesIterator { fn __iter__(slf: PyRef<'_, Self>) -> PyRef<'_, Self> { slf } fn __next__(mut slf: PyRefMut<'_, Self>) -> Option { let kv = slf.inner.iter().next()?; let value = kv.1.clone_ref(slf.py()); slf.inner = slf.inner.remove(kv.0); Some(value) } } #[pyclass(module = "rpds")] struct ItemsIterator { inner: HashTrieMapSync, } #[pymethods] impl ItemsIterator { fn __iter__(slf: PyRef<'_, Self>) -> PyRef<'_, Self> { slf } fn __next__(mut slf: PyRefMut<'_, Self>) -> Option<(Key, PyObject)> { let kv = slf.inner.iter().next()?; let key = kv.0.clone_ref(slf.py()); let value = kv.1.clone_ref(slf.py()); slf.inner = slf.inner.remove(kv.0); Some((key, value)) } } #[pyclass(module = "rpds")] struct KeysView { inner: HashTrieMapSync, } #[pymethods] impl KeysView { fn __contains__(&self, key: Key) -> bool { self.inner.contains_key(&key) } fn __eq__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? != slf.inner.size() { return Ok(false); } for each in other.iter()? { if !slf.inner.contains_key(&Key::extract_bound(&each?)?) { return Ok(false); } } Ok(true) } fn __lt__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? <= slf.inner.size() { return Ok(false); } for each in slf.inner.keys() { if !other.contains(each.inner.clone_ref(slf.py()))? { return Ok(false); } } Ok(true) } fn __le__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? < slf.inner.size() { return Ok(false); } for each in slf.inner.keys() { if !other.contains(each.inner.clone_ref(slf.py()))? { return Ok(false); } } Ok(true) } fn __gt__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? >= slf.inner.size() { return Ok(false); } for each in other.iter()? { if !slf.inner.contains_key(&Key::extract_bound(&each?)?) { return Ok(false); } } Ok(true) } fn __ge__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? > slf.inner.size() { return Ok(false); } for each in other.iter()? { if !slf.inner.contains_key(&Key::extract_bound(&each?)?) { return Ok(false); } } Ok(true) } fn __iter__(slf: PyRef<'_, Self>) -> KeysIterator { KeysIterator { inner: slf.inner.clone(), } } fn __len__(slf: PyRef<'_, Self>) -> usize { slf.inner.size() } fn __and__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>) -> PyResult { KeysView::intersection(slf, other) } fn __or__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { KeysView::union(slf, other, py) } fn __repr__(&self, py: Python) -> String { let contents = self.inner.into_iter().map(|(k, _)| { k.clone_ref(py) .inner .into_py(py) .call_method0(py, "__repr__") .and_then(|r| r.extract(py)) .unwrap_or("".to_owned()) }); format!("keys_view({{{}}})", contents.collect::>().join(", ")) } fn intersection(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>) -> PyResult { // TODO: iterate over the shorter one if it's got a length let mut inner = HashTrieSet::new_sync(); for each in other.iter()? { let key = Key::extract_bound(&each?)?; if slf.inner.contains_key(&key) { inner.insert_mut(key); } } Ok(HashTrieSetPy { inner }) } fn union(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { // There doesn't seem to be a low-effort way to get a HashTrieSet out of a map, // so we just keep our map and add values we'll ignore. let mut inner = slf.inner.clone(); for each in other.iter()? { inner.insert_mut(Key::extract_bound(&each?)?, py.None()); } Ok(KeysView { inner }) } } #[pyclass(module = "rpds")] struct ValuesView { inner: HashTrieMapSync, } #[pymethods] impl ValuesView { fn __iter__(slf: PyRef<'_, Self>) -> ValuesIterator { ValuesIterator { inner: slf.inner.clone(), } } fn __len__(slf: PyRef<'_, Self>) -> usize { slf.inner.size() } fn __repr__(&self, py: Python) -> String { let contents = self.inner.into_iter().map(|(_, v)| { v.into_py(py) .call_method0(py, "__repr__") .and_then(|r| r.extract(py)) .unwrap_or("".to_owned()) }); format!("values_view([{}])", contents.collect::>().join(", ")) } } #[pyclass(module = "rpds")] struct ItemsView { inner: HashTrieMapSync, } #[derive(FromPyObject)] struct ItemViewQuery(Key, PyObject); #[pymethods] impl ItemsView { fn __contains__(slf: PyRef<'_, Self>, item: ItemViewQuery) -> PyResult { if let Some(value) = slf.inner.get(&item.0) { return item.1.bind(slf.py()).eq(value); } Ok(false) } fn __iter__(slf: PyRef<'_, Self>) -> ItemsIterator { ItemsIterator { inner: slf.inner.clone(), } } fn __len__(slf: PyRef<'_, Self>) -> usize { slf.inner.size() } fn __eq__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? != slf.inner.size() { return Ok(false); } for (k, v) in slf.inner.iter() { if !other.contains((k.inner.clone_ref(slf.py()), v))? { return Ok(false); } } Ok(true) } fn __repr__(&self, py: Python) -> String { let contents = self.inner.into_iter().map(|(k, v)| { let tuple = PyTuple::new_bound(py, [k.inner.clone_ref(py), v.clone_ref(py)]); format!("{:?}", tuple) }); format!("items_view([{}])", contents.collect::>().join(", ")) } fn __lt__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? <= slf.inner.size() { return Ok(false); } for (k, v) in slf.inner.iter() { let pair = PyTuple::new_bound(py, [k.inner.clone_ref(py), v.clone_ref(py)]); // FIXME: needs to compare if !other.contains(pair)? { return Ok(false); } } Ok(true) } fn __le__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? < slf.inner.size() { return Ok(false); } for (k, v) in slf.inner.iter() { let pair = PyTuple::new_bound(py, [k.inner.clone_ref(py), v.clone_ref(py)]); // FIXME: needs to compare if !other.contains(pair)? { return Ok(false); } } Ok(true) } fn __gt__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? >= slf.inner.size() { return Ok(false); } for each in other.iter()? { let kv = each?; let k = kv.get_item(0)?; match slf.inner.get(&Key::extract_bound(&k)?) { Some(value) => { let pair = PyTuple::new_bound(py, [k, value.bind(py).clone()]); if !pair.eq(kv)? { return Ok(false); } } None => return Ok(false), } } Ok(true) } fn __ge__(slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? > slf.inner.size() { return Ok(false); } for each in other.iter()? { let kv = each?; let k = kv.get_item(0)?; match slf.inner.get(&Key::extract_bound(&k)?) { Some(value) => { let pair = PyTuple::new_bound(py, [k, value.bind(py).clone()]); if !pair.eq(kv)? { return Ok(false); } } None => return Ok(false), } } Ok(true) } fn __and__( slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python, ) -> PyResult { ItemsView::intersection(slf, other, py) } fn __or__( slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python, ) -> PyResult { ItemsView::union(slf, other, py) } fn intersection( slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python, ) -> PyResult { // TODO: iterate over the shorter one if it's got a length let mut inner = HashTrieSet::new_sync(); for each in other.iter()? { let kv = each?; let k = kv.get_item(0)?; if let Some(value) = slf.inner.get(&Key::extract_bound(&k)?) { let pair = PyTuple::new_bound(py, [k, value.bind(py).clone()]); if pair.eq(kv)? { inner.insert_mut(Key::extract_bound(&pair)?); } } } Ok(HashTrieSetPy { inner }) } fn union( slf: PyRef<'_, Self>, other: &Bound<'_, PyAny>, py: Python, ) -> PyResult { // TODO: this is very inefficient, but again can't seem to get a HashTrieSet out of ourself let mut inner = HashTrieSet::new_sync(); for (k, v) in slf.inner.iter() { let pair = PyTuple::new_bound(py, [k.inner.clone_ref(py), v.clone_ref(py)]); inner.insert_mut(Key::extract_bound(&pair)?); } for each in other.iter()? { inner.insert_mut(Key::extract_bound(&each?)?); } Ok(HashTrieSetPy { inner }) } } #[repr(transparent)] #[pyclass(name = "HashTrieSet", module = "rpds", frozen)] struct HashTrieSetPy { inner: HashTrieSetSync, } impl<'source> FromPyObject<'source> for HashTrieSetPy { fn extract_bound(ob: &Bound<'source, PyAny>) -> PyResult { let mut ret = HashTrieSet::new_sync(); for each in ob.iter()? { let k: Key = each?.extract()?; ret.insert_mut(k); } Ok(HashTrieSetPy { inner: ret }) } } #[pymethods] impl HashTrieSetPy { #[new] #[pyo3(signature = (value=None))] fn init(value: Option) -> Self { if let Some(value) = value { value } else { HashTrieSetPy { inner: HashTrieSet::new_sync(), } } } fn __contains__(&self, key: Key) -> bool { self.inner.contains(&key) } fn __and__(&self, other: &Self, py: Python) -> Self { self.intersection(other, py) } fn __or__(&self, other: &Self, py: Python) -> Self { self.union(other, py) } fn __sub__(&self, other: &Self) -> Self { self.difference(other) } fn __xor__(&self, other: &Self, py: Python) -> Self { self.symmetric_difference(other, py) } fn __iter__(slf: PyRef<'_, Self>) -> SetIterator { SetIterator { inner: slf.inner.clone(), } } fn __len__(&self) -> usize { self.inner.size() } fn __repr__(&self, py: Python) -> String { let contents = self.inner.into_iter().map(|k| { k.clone_ref(py) .into_py(py) .call_method0(py, "__repr__") .and_then(|r| r.extract(py)) .unwrap_or("".to_owned()) }); format!( "HashTrieSet({{{}}})", contents.collect::>().join(", ") ) } fn __eq__(slf: PyRef<'_, Self>, other: Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? != slf.inner.size() { return Ok(false); } for each in other.iter()? { if !slf.inner.contains(&Key::extract_bound(&each?)?) { return Ok(false); } } Ok(true) } fn __hash__(&self) -> PyResult { // modified from https://github.com/python/cpython/blob/d69529d31ccd1510843cfac1ab53bb8cb027541f/Objects/setobject.c#L715 let mut hash_val = self .inner .iter() .map(|k| k.hash as usize) .fold(0, |acc: usize, x: usize| acc ^ hash_shuffle_bits(x)); // factor in the number of entries in the collection hash_val ^= (self.inner.size() + 1) * 1927868237; // dispense patterns in the hash value hash_val ^= (hash_val >> 11) ^ (hash_val >> 25); hash_val = hash_val * 69069 + 907133923; Ok(hash_val as isize) } fn __lt__(slf: PyRef<'_, Self>, other: Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? <= slf.inner.size() { return Ok(false); } for each in slf.inner.iter() { if !other.contains(each.inner.clone_ref(py))? { return Ok(false); } } Ok(true) } fn __le__(slf: PyRef<'_, Self>, other: Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? < slf.inner.size() { return Ok(false); } for each in slf.inner.iter() { if !other.contains(each.inner.clone_ref(slf.py()))? { return Ok(false); } } Ok(true) } fn __gt__(slf: PyRef<'_, Self>, other: Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? >= slf.inner.size() { return Ok(false); } for each in other.iter()? { if !slf.inner.contains(&Key::extract_bound(&each?)?) { return Ok(false); } } Ok(true) } fn __ge__(slf: PyRef<'_, Self>, other: Bound<'_, PyAny>, py: Python) -> PyResult { let abc = PyModule::import_bound(py, "collections.abc")?; if !other.is_instance(&abc.getattr("Set")?)? || other.len()? > slf.inner.size() { return Ok(false); } for each in other.iter()? { if !slf.inner.contains(&Key::extract_bound(&each?)?) { return Ok(false); } } Ok(true) } fn __reduce__(slf: PyRef) -> (Bound<'_, PyType>, (Vec,)) { ( HashTrieSetPy::type_object_bound(slf.py()), (slf.inner.iter().map(|e| e.clone_ref(slf.py())).collect(),), ) } fn insert(&self, value: Key) -> HashTrieSetPy { HashTrieSetPy { inner: self.inner.insert(value), } } fn discard(&self, value: Key) -> PyResult { match self.inner.contains(&value) { true => Ok(HashTrieSetPy { inner: self.inner.remove(&value), }), false => Ok(HashTrieSetPy { inner: self.inner.clone(), }), } } fn remove(&self, value: Key) -> PyResult { match self.inner.contains(&value) { true => Ok(HashTrieSetPy { inner: self.inner.remove(&value), }), false => Err(PyKeyError::new_err(value)), } } fn difference(&self, other: &Self) -> HashTrieSetPy { let mut inner = self.inner.clone(); for value in other.inner.iter() { inner.remove_mut(value); } HashTrieSetPy { inner } } fn intersection(&self, other: &Self, py: Python) -> HashTrieSetPy { let mut inner: HashTrieSetSync = HashTrieSet::new_sync(); let larger: &HashTrieSetSync; let iter; if self.inner.size() > other.inner.size() { larger = &self.inner; iter = other.inner.iter(); } else { larger = &other.inner; iter = self.inner.iter(); } for value in iter { if larger.contains(value) { inner.insert_mut(value.clone_ref(py)); } } HashTrieSetPy { inner } } fn symmetric_difference(&self, other: &Self, py: Python) -> HashTrieSetPy { let mut inner: HashTrieSetSync; let iter; if self.inner.size() > other.inner.size() { inner = self.inner.clone(); iter = other.inner.iter(); } else { inner = other.inner.clone(); iter = self.inner.iter(); } for value in iter { if inner.contains(value) { inner.remove_mut(value); } else { inner.insert_mut(value.clone_ref(py)); } } HashTrieSetPy { inner } } fn union(&self, other: &Self, py: Python) -> HashTrieSetPy { let mut inner: HashTrieSetSync; let iter; if self.inner.size() > other.inner.size() { inner = self.inner.clone(); iter = other.inner.iter(); } else { inner = other.inner.clone(); iter = self.inner.iter(); } for value in iter { inner.insert_mut(value.clone_ref(py)); } HashTrieSetPy { inner } } #[pyo3(signature = (*iterables))] fn update(&self, iterables: Bound<'_, PyTuple>) -> PyResult { let mut inner = self.inner.clone(); for each in iterables { let iter = each.iter()?; for value in iter { inner.insert_mut(Key::extract_bound(&value?)?); } } Ok(HashTrieSetPy { inner }) } } #[pyclass(module = "rpds")] struct SetIterator { inner: HashTrieSetSync, } #[pymethods] impl SetIterator { fn __iter__(slf: PyRef<'_, Self>) -> PyRef<'_, Self> { slf } fn __next__(mut slf: PyRefMut<'_, Self>) -> Option { let first = slf.inner.iter().next()?.clone_ref(slf.py()); slf.inner = slf.inner.remove(&first); Some(first) } } #[repr(transparent)] #[pyclass(name = "List", module = "rpds", frozen, sequence)] struct ListPy { inner: ListSync, } impl From> for ListPy { fn from(elements: ListSync) -> Self { ListPy { inner: elements } } } impl<'source> FromPyObject<'source> for ListPy { fn extract_bound(ob: &Bound<'source, PyAny>) -> PyResult { let mut ret = List::new_sync(); let reversed = PyModule::import_bound(ob.py(), "builtins")?.getattr("reversed")?; let rob: Bound<'_, PyIterator> = reversed.call1((ob,))?.iter()?; for each in rob { ret.push_front_mut(each?.extract()?); } Ok(ListPy { inner: ret }) } } #[pymethods] impl ListPy { #[new] #[pyo3(signature = (*elements))] fn init(elements: &Bound<'_, PyTuple>) -> PyResult { let mut ret: ListPy; if elements.len() == 1 { ret = elements.get_item(0)?.extract()?; } else { ret = ListPy { inner: List::new_sync(), }; if elements.len() > 1 { for each in (0..elements.len()).rev() { ret.inner .push_front_mut(elements.get_item(each)?.extract()?); } } } Ok(ret) } fn __len__(&self) -> usize { self.inner.len() } fn __repr__(&self, py: Python) -> String { let contents = self.inner.into_iter().map(|k| { k.into_py(py) .call_method0(py, "__repr__") .and_then(|r| r.extract(py)) .unwrap_or("".to_owned()) }); format!("List([{}])", contents.collect::>().join(", ")) } fn __richcmp__(&self, other: &Self, op: CompareOp, py: Python<'_>) -> PyResult { match op { CompareOp::Eq => Ok((self.inner.len() == other.inner.len() && self .inner .iter() .zip(other.inner.iter()) .map(|(e1, e2)| e1.bind(py).eq(e2)) .all(|r| r.unwrap_or(false))) .into_py(py)), CompareOp::Ne => Ok((self.inner.len() != other.inner.len() || self .inner .iter() .zip(other.inner.iter()) .map(|(e1, e2)| e1.bind(py).ne(e2)) .any(|r| r.unwrap_or(true))) .into_py(py)), _ => Ok(py.NotImplemented()), } } fn __hash__(&self, py: Python) -> PyResult { let mut hasher = DefaultHasher::new(); self.inner .iter() .enumerate() .try_for_each(|(index, each)| { each.bind(py) .hash() .map_err(|_| { PyTypeError::new_err(format!( "Unhashable type at {} element in List: {}", index, each.bind(py) .repr() .and_then(|r| r.extract()) .unwrap_or(" error".to_string()) )) }) .map(|x| hasher.write_isize(x)) })?; Ok(hasher.finish()) } fn __iter__(slf: PyRef<'_, Self>) -> ListIterator { ListIterator { inner: slf.inner.clone(), } } fn __reversed__(&self) -> ListPy { ListPy { inner: self.inner.reverse(), } } fn __reduce__(slf: PyRef) -> (Bound<'_, PyType>, (Vec,)) { ( ListPy::type_object_bound(slf.py()), (slf.inner.iter().map(|e| e.clone_ref(slf.py())).collect(),), ) } #[getter] fn first(&self) -> PyResult<&PyObject> { self.inner .first() .ok_or_else(|| PyIndexError::new_err("empty list has no first element")) } #[getter] fn rest(&self) -> ListPy { let mut inner = self.inner.clone(); inner.drop_first_mut(); ListPy { inner } } fn push_front(&self, other: PyObject) -> ListPy { ListPy { inner: self.inner.push_front(other), } } fn drop_first(&self) -> PyResult { if let Some(inner) = self.inner.drop_first() { Ok(ListPy { inner }) } else { Err(PyIndexError::new_err("empty list has no first element")) } } } #[pyclass(module = "rpds")] struct ListIterator { inner: ListSync, } #[pymethods] impl ListIterator { fn __iter__(slf: PyRef<'_, Self>) -> PyRef<'_, Self> { slf } fn __next__(mut slf: PyRefMut<'_, Self>) -> Option { let first_op = slf.inner.first()?; let first = first_op.clone_ref(slf.py()); slf.inner = slf.inner.drop_first()?; Some(first) } } #[pyclass(module = "rpds")] struct QueueIterator { inner: QueueSync, } #[pymethods] impl QueueIterator { fn __iter__(slf: PyRef<'_, Self>) -> PyRef<'_, Self> { slf } fn __next__(mut slf: PyRefMut<'_, Self>) -> Option { let first_op = slf.inner.peek()?; let first = first_op.clone_ref(slf.py()); slf.inner = slf.inner.dequeue()?; Some(first) } } #[repr(transparent)] #[pyclass(name = "Queue", module = "rpds", frozen, sequence)] struct QueuePy { inner: QueueSync, } impl From> for QueuePy { fn from(elements: QueueSync) -> Self { QueuePy { inner: elements } } } impl<'source> FromPyObject<'source> for QueuePy { fn extract_bound(ob: &Bound<'source, PyAny>) -> PyResult { let mut ret = Queue::new_sync(); for each in ob.iter()? { ret.enqueue_mut(each?.extract()?); } Ok(QueuePy { inner: ret }) } } #[pymethods] impl QueuePy { #[new] #[pyo3(signature = (*elements))] fn init(elements: &Bound<'_, PyTuple>, py: Python<'_>) -> PyResult { let mut ret: QueuePy; if elements.len() == 1 { ret = elements.get_item(0)?.extract()?; } else { ret = QueuePy { inner: Queue::new_sync(), }; if elements.len() > 1 { for each in elements { ret.inner.enqueue_mut(each.into_py(py)); } } } Ok(ret) } fn __eq__(&self, other: &Self, py: Python<'_>) -> bool { (self.inner.len() == other.inner.len()) && self .inner .iter() .zip(other.inner.iter()) .map(|(e1, e2)| e1.bind(py).eq(e2)) .all(|r| r.unwrap_or(false)) } fn __hash__(&self, py: Python<'_>) -> PyResult { let mut hasher = DefaultHasher::new(); self.inner .iter() .enumerate() .try_for_each(|(index, each)| { each.bind(py) .hash() .map_err(|_| { PyTypeError::new_err(format!( "Unhashable type at {} element in Queue: {}", index, each.bind(py) .repr() .and_then(|r| r.extract()) .unwrap_or(" error".to_string()) )) }) .map(|x| hasher.write_isize(x)) })?; Ok(hasher.finish()) } fn __ne__(&self, other: &Self, py: Python<'_>) -> bool { (self.inner.len() != other.inner.len()) || self .inner .iter() .zip(other.inner.iter()) .map(|(e1, e2)| e1.bind(py).ne(e2)) .any(|r| r.unwrap_or(true)) } fn __iter__(slf: PyRef<'_, Self>) -> QueueIterator { QueueIterator { inner: slf.inner.clone(), } } fn __len__(&self) -> usize { self.inner.len() } fn __repr__(&self, py: Python) -> String { let contents = self.inner.into_iter().map(|k| { k.into_py(py) .call_method0(py, "__repr__") .and_then(|r| r.extract(py)) .unwrap_or("".to_owned()) }); format!("Queue([{}])", contents.collect::>().join(", ")) } #[getter] fn peek(&self, py: Python) -> PyResult { if let Some(peeked) = self.inner.peek() { Ok(peeked.clone_ref(py)) } else { Err(PyIndexError::new_err("peeked an empty queue")) } } #[getter] fn is_empty(&self) -> bool { self.inner.is_empty() } fn enqueue(&self, value: Bound<'_, PyAny>) -> Self { QueuePy { inner: self.inner.enqueue(value.into()), } } fn dequeue(&self) -> PyResult { if let Some(inner) = self.inner.dequeue() { Ok(QueuePy { inner }) } else { Err(PyIndexError::new_err("dequeued an empty queue")) } } } #[pymodule] #[pyo3(name = "rpds")] fn rpds_py(py: Python, m: &Bound<'_, PyModule>) -> PyResult<()> { m.add_class::()?; m.add_class::()?; m.add_class::()?; m.add_class::()?; PyMapping::register::(py)?; let abc = PyModule::import_bound(py, "collections.abc")?; abc.getattr("Set")? .call_method1("register", (HashTrieSetPy::type_object_bound(py),))?; abc.getattr("MappingView")? .call_method1("register", (KeysView::type_object_bound(py),))?; abc.getattr("MappingView")? .call_method1("register", (ValuesView::type_object_bound(py),))?; abc.getattr("MappingView")? .call_method1("register", (ItemsView::type_object_bound(py),))?; abc.getattr("KeysView")? .call_method1("register", (KeysView::type_object_bound(py),))?; abc.getattr("ValuesView")? .call_method1("register", (ValuesView::type_object_bound(py),))?; abc.getattr("ItemsView")? .call_method1("register", (ItemsView::type_object_bound(py),))?; Ok(()) }