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oxigraph/python/src/model.rs

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use oxigraph::model::*;
use oxigraph::sparql::Variable;
use pyo3::basic::CompareOp;
use pyo3::exceptions::{PyIndexError, PyNotImplementedError, PyTypeError, PyValueError};
use pyo3::prelude::*;
use pyo3::types::{PyDict, PyTuple};
use pyo3::PyTypeInfo;
use std::collections::hash_map::DefaultHasher;
use std::hash::Hash;
use std::hash::Hasher;
use std::vec::IntoIter;
/// An RDF `node identified by an IRI <https://www.w3.org/TR/rdf11-concepts/#dfn-iri>`_.
///
/// :param value: the IRI as a string.
/// :type value: str
/// :raises ValueError: if the IRI is not valid according to `RFC 3987 <https://tools.ietf.org/rfc/rfc3987>`_.
///
/// The :py:func:`str` function provides a serialization compatible with NTriples, Turtle, and SPARQL:
///
/// >>> str(NamedNode('http://example.com'))
/// '<http://example.com>'
#[pyclass(frozen, name = "NamedNode", module = "pyoxigraph")]
#[derive(Eq, PartialEq, Ord, PartialOrd, Debug, Clone, Hash)]
pub struct PyNamedNode {
inner: NamedNode,
}
impl From<NamedNode> for PyNamedNode {
fn from(inner: NamedNode) -> Self {
Self { inner }
}
}
impl From<PyNamedNode> for NamedNode {
fn from(node: PyNamedNode) -> Self {
node.inner
}
}
impl From<PyNamedNode> for NamedOrBlankNode {
fn from(node: PyNamedNode) -> Self {
node.inner.into()
}
}
impl From<PyNamedNode> for Subject {
fn from(node: PyNamedNode) -> Self {
node.inner.into()
}
}
impl From<PyNamedNode> for Term {
fn from(node: PyNamedNode) -> Self {
node.inner.into()
}
}
impl From<PyNamedNode> for GraphName {
fn from(node: PyNamedNode) -> Self {
node.inner.into()
}
}
#[pymethods]
impl PyNamedNode {
#[new]
fn new(value: String) -> PyResult<Self> {
Ok(NamedNode::new(value)
.map_err(|e| PyValueError::new_err(e.to_string()))?
.into())
}
/// :return: the named node IRI.
/// :rtype: str
///
/// >>> NamedNode("http://example.com").value
/// 'http://example.com'
#[getter]
fn value(&self) -> &str {
self.inner.as_str()
}
fn __str__(&self) -> String {
self.inner.to_string()
}
fn __repr__(&self) -> String {
let mut buffer = String::new();
named_node_repr(self.inner.as_ref(), &mut buffer);
buffer
}
fn __hash__(&self) -> u64 {
hash(&self.inner)
}
fn __richcmp__(&self, other: &PyAny, op: CompareOp) -> PyResult<bool> {
if let Ok(other) = other.extract::<PyRef<Self>>() {
Ok(op.matches(self.cmp(&other)))
} else if PyBlankNode::is_type_of(other)
|| PyLiteral::is_type_of(other)
|| PyDefaultGraph::is_type_of(other)
{
eq_compare_other_type(op)
} else {
Err(PyTypeError::new_err(
"NamedNode could only be compared with RDF terms",
))
}
}
/// :rtype: typing.Any
fn __getnewargs__(&self) -> (&str,) {
(self.value(),)
}
/// :rtype: NamedNode
fn __copy__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
/// :type memo: typing.Any
/// :rtype: NamedNode
#[allow(unused_variables)]
fn __deepcopy__<'a>(slf: PyRef<'a, Self>, memo: &'_ PyAny) -> PyRef<'a, Self> {
slf
}
#[classattr]
fn __match_args__() -> (&'static str,) {
("value",)
}
}
/// An RDF `blank node <https://www.w3.org/TR/rdf11-concepts/#dfn-blank-node>`_.
///
/// :param value: the `blank node ID <https://www.w3.org/TR/rdf11-concepts/#dfn-blank-node-identifier>`_ (if not present, a random blank node ID is automatically generated).
/// :type value: str or None, optional
/// :raises ValueError: if the blank node ID is invalid according to NTriples, Turtle, and SPARQL grammars.
///
/// The :py:func:`str` function provides a serialization compatible with NTriples, Turtle, and SPARQL:
///
/// >>> str(BlankNode('ex'))
/// '_:ex'
#[pyclass(frozen, name = "BlankNode", module = "pyoxigraph")]
#[derive(Eq, PartialEq, Debug, Clone, Hash)]
pub struct PyBlankNode {
inner: BlankNode,
}
impl From<BlankNode> for PyBlankNode {
fn from(inner: BlankNode) -> Self {
Self { inner }
}
}
impl From<PyBlankNode> for BlankNode {
fn from(node: PyBlankNode) -> Self {
node.inner
}
}
impl From<PyBlankNode> for NamedOrBlankNode {
fn from(node: PyBlankNode) -> Self {
node.inner.into()
}
}
impl From<PyBlankNode> for Subject {
fn from(node: PyBlankNode) -> Self {
node.inner.into()
}
}
impl From<PyBlankNode> for Term {
fn from(node: PyBlankNode) -> Self {
node.inner.into()
}
}
impl From<PyBlankNode> for GraphName {
fn from(node: PyBlankNode) -> Self {
node.inner.into()
}
}
#[pymethods]
impl PyBlankNode {
#[new]
#[pyo3(signature = (value = None))]
fn new(value: Option<String>) -> PyResult<Self> {
Ok(if let Some(value) = value {
BlankNode::new(value).map_err(|e| PyValueError::new_err(e.to_string()))?
} else {
BlankNode::default()
}
.into())
}
/// :return: the `blank node ID <https://www.w3.org/TR/rdf11-concepts/#dfn-blank-node-identifier>`_.
/// :rtype: str
///
/// >>> BlankNode("ex").value
/// 'ex'
#[getter]
fn value(&self) -> &str {
self.inner.as_str()
}
fn __str__(&self) -> String {
self.inner.to_string()
}
fn __repr__(&self) -> String {
let mut buffer = String::new();
blank_node_repr(self.inner.as_ref(), &mut buffer);
buffer
}
fn __hash__(&self) -> u64 {
hash(&self.inner)
}
fn __richcmp__(&self, other: &PyAny, op: CompareOp) -> PyResult<bool> {
if let Ok(other) = other.extract::<PyRef<Self>>() {
eq_compare(self, &other, op)
} else if PyNamedNode::is_type_of(other)
|| PyLiteral::is_type_of(other)
|| PyDefaultGraph::is_type_of(other)
{
eq_compare_other_type(op)
} else {
Err(PyTypeError::new_err(
"BlankNode could only be compared with RDF terms",
))
}
}
/// :rtype: typing.Any
fn __getnewargs__(&self) -> (&str,) {
(self.value(),)
}
/// :rtype: BlankNode
fn __copy__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
/// :type memo: typing.Any
/// :rtype: BlankNode
#[allow(unused_variables)]
fn __deepcopy__<'a>(slf: PyRef<'a, Self>, memo: &'_ PyAny) -> PyRef<'a, Self> {
slf
}
#[classattr]
fn __match_args__() -> (&'static str,) {
("value",)
}
}
/// An RDF `literal <https://www.w3.org/TR/rdf11-concepts/#dfn-literal>`_.
///
/// :param value: the literal value or `lexical form <https://www.w3.org/TR/rdf11-concepts/#dfn-lexical-form>`_.
/// :type value: str
/// :param datatype: the literal `datatype IRI <https://www.w3.org/TR/rdf11-concepts/#dfn-datatype-iri>`_.
/// :type datatype: NamedNode or None, optional
/// :param language: the literal `language tag <https://www.w3.org/TR/rdf11-concepts/#dfn-language-tag>`_.
/// :type language: str or None, optional
/// :raises ValueError: if the language tag is not valid according to `RFC 5646 <https://tools.ietf.org/rfc/rfc5646>`_ (`BCP 47 <https://tools.ietf.org/rfc/bcp/bcp47>`_).
///
/// The :py:func:`str` function provides a serialization compatible with NTriples, Turtle, and SPARQL:
///
/// >>> str(Literal('example'))
/// '"example"'
/// >>> str(Literal('example', language='en'))
/// '"example"@en'
/// >>> str(Literal('11', datatype=NamedNode('http://www.w3.org/2001/XMLSchema#integer')))
/// '"11"^^<http://www.w3.org/2001/XMLSchema#integer>'
#[pyclass(frozen, name = "Literal", module = "pyoxigraph")]
#[derive(Eq, PartialEq, Debug, Clone, Hash)]
pub struct PyLiteral {
inner: Literal,
}
impl From<Literal> for PyLiteral {
fn from(inner: Literal) -> Self {
Self { inner }
}
}
impl From<PyLiteral> for Literal {
fn from(literal: PyLiteral) -> Self {
literal.inner
}
}
impl From<PyLiteral> for Term {
fn from(node: PyLiteral) -> Self {
node.inner.into()
}
}
#[pymethods]
impl PyLiteral {
#[new]
#[pyo3(signature = (value, *, datatype = None, language = None))]
fn new(
value: String,
datatype: Option<PyNamedNode>,
language: Option<String>,
) -> PyResult<Self> {
Ok(if let Some(language) = language {
if let Some(datatype) = datatype {
if datatype.value() != "http://www.w3.org/1999/02/22-rdf-syntax-ns#langString" {
return Err(PyValueError::new_err(
"The literals with a language tag must use the rdf:langString datatype",
));
}
}
Literal::new_language_tagged_literal(value, language)
.map_err(|e| PyValueError::new_err(e.to_string()))?
} else if let Some(datatype) = datatype {
Literal::new_typed_literal(value, datatype)
} else {
Literal::new_simple_literal(value)
}
.into())
}
/// :return: the literal value or `lexical form <https://www.w3.org/TR/rdf11-concepts/#dfn-lexical-form>`_.
/// :rtype: str
///
/// >>> Literal("example").value
/// 'example'
#[getter]
fn value(&self) -> &str {
self.inner.value()
}
/// :return: the literal `language tag <https://www.w3.org/TR/rdf11-concepts/#dfn-language-tag>`_.
/// :rtype: str or None
///
/// >>> Literal('example', language='en').language
/// 'en'
/// >>> Literal('example').language
///
#[getter]
fn language(&self) -> Option<&str> {
self.inner.language()
}
/// :return: the literal `datatype IRI <https://www.w3.org/TR/rdf11-concepts/#dfn-datatype-iri>`_.
/// :rtype: NamedNode
///
/// >>> Literal('11', datatype=NamedNode('http://www.w3.org/2001/XMLSchema#integer')).datatype
/// <NamedNode value=http://www.w3.org/2001/XMLSchema#integer>
/// >>> Literal('example').datatype
/// <NamedNode value=http://www.w3.org/2001/XMLSchema#string>
/// >>> Literal('example', language='en').datatype
/// <NamedNode value=http://www.w3.org/1999/02/22-rdf-syntax-ns#langString>
#[getter]
fn datatype(&self) -> PyNamedNode {
self.inner.datatype().into_owned().into()
}
fn __str__(&self) -> String {
self.inner.to_string()
}
fn __repr__(&self) -> String {
let mut buffer = String::new();
literal_repr(self.inner.as_ref(), &mut buffer);
buffer
}
fn __hash__(&self) -> u64 {
hash(&self.inner)
}
fn __richcmp__(&self, other: &PyAny, op: CompareOp) -> PyResult<bool> {
if let Ok(other) = other.extract::<PyRef<Self>>() {
eq_compare(self, &other, op)
} else if PyNamedNode::is_type_of(other)
|| PyBlankNode::is_type_of(other)
|| PyDefaultGraph::is_type_of(other)
{
eq_compare_other_type(op)
} else {
Err(PyTypeError::new_err(
"Literal could only be compared with RDF terms",
))
}
}
/// :rtype: typing.Any
fn __getnewargs_ex__<'a>(&'a self, py: Python<'a>) -> PyResult<((&'a str,), &'a PyDict)> {
let kwargs = PyDict::new(py);
if let Some(language) = self.language() {
kwargs.set_item("language", language)?;
} else {
kwargs.set_item("datatype", self.datatype().into_py(py))?;
}
Ok(((self.value(),), kwargs))
}
/// :rtype: Literal
fn __copy__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
/// :type memo: typing.Any
/// :rtype: Literal
#[allow(unused_variables)]
fn __deepcopy__<'a>(slf: PyRef<'a, Self>, memo: &'_ PyAny) -> PyRef<'a, Self> {
slf
}
#[classattr]
fn __match_args__() -> (&'static str,) {
("value",)
}
}
/// The RDF `default graph name <https://www.w3.org/TR/rdf11-concepts/#dfn-default-graph>`_.
#[pyclass(frozen, name = "DefaultGraph", module = "pyoxigraph")]
#[derive(Eq, PartialEq, Debug, Clone, Copy, Hash)]
pub struct PyDefaultGraph {}
impl From<PyDefaultGraph> for GraphName {
fn from(_: PyDefaultGraph) -> Self {
Self::DefaultGraph
}
}
#[pymethods]
impl PyDefaultGraph {
#[new]
fn new() -> Self {
Self {}
}
/// :return: the empty string.
/// :rtype: str
#[getter]
fn value(&self) -> &str {
""
}
fn __str__(&self) -> &str {
"DEFAULT"
}
fn __repr__(&self) -> &str {
"<DefaultGraph>"
}
fn __hash__(&self) -> u64 {
0
}
fn __richcmp__(&self, other: &PyAny, op: CompareOp) -> PyResult<bool> {
if let Ok(other) = other.extract::<PyRef<Self>>() {
eq_compare(self, &other, op)
} else if PyNamedNode::is_type_of(other)
|| PyBlankNode::is_type_of(other)
|| PyLiteral::is_type_of(other)
{
eq_compare_other_type(op)
} else {
Err(PyTypeError::new_err(
"DefaultGraph could only be compared with RDF terms",
))
}
}
/// :rtype: typing.Any
fn __getnewargs__<'a>(&self, py: Python<'a>) -> &'a PyTuple {
PyTuple::empty(py)
}
/// :rtype: DefaultGraph
fn __copy__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
/// :type memo: typing.Any
/// :rtype: DefaultGraph
#[allow(unused_variables)]
fn __deepcopy__<'a>(slf: PyRef<'a, Self>, memo: &'_ PyAny) -> PyRef<'a, Self> {
slf
}
}
#[derive(FromPyObject)]
pub enum PyNamedOrBlankNode {
NamedNode(PyNamedNode),
BlankNode(PyBlankNode),
}
impl From<PyNamedOrBlankNode> for NamedOrBlankNode {
fn from(node: PyNamedOrBlankNode) -> Self {
match node {
PyNamedOrBlankNode::NamedNode(node) => node.into(),
PyNamedOrBlankNode::BlankNode(node) => node.into(),
}
}
}
impl From<NamedOrBlankNode> for PyNamedOrBlankNode {
fn from(node: NamedOrBlankNode) -> Self {
match node {
NamedOrBlankNode::NamedNode(node) => Self::NamedNode(node.into()),
NamedOrBlankNode::BlankNode(node) => Self::BlankNode(node.into()),
}
}
}
impl IntoPy<PyObject> for PyNamedOrBlankNode {
fn into_py(self, py: Python<'_>) -> PyObject {
match self {
Self::NamedNode(node) => node.into_py(py),
Self::BlankNode(node) => node.into_py(py),
}
}
}
#[derive(FromPyObject)]
pub enum PySubject {
NamedNode(PyNamedNode),
BlankNode(PyBlankNode),
Triple(PyTriple),
}
impl From<PySubject> for Subject {
fn from(node: PySubject) -> Self {
match node {
PySubject::NamedNode(node) => node.into(),
PySubject::BlankNode(node) => node.into(),
PySubject::Triple(triple) => triple.into(),
}
}
}
impl From<Subject> for PySubject {
fn from(node: Subject) -> Self {
match node {
Subject::NamedNode(node) => Self::NamedNode(node.into()),
Subject::BlankNode(node) => Self::BlankNode(node.into()),
Subject::Triple(triple) => Self::Triple(triple.as_ref().clone().into()),
}
}
}
impl IntoPy<PyObject> for PySubject {
fn into_py(self, py: Python<'_>) -> PyObject {
match self {
Self::NamedNode(node) => node.into_py(py),
Self::BlankNode(node) => node.into_py(py),
Self::Triple(triple) => triple.into_py(py),
}
}
}
#[derive(FromPyObject)]
pub enum PyTerm {
NamedNode(PyNamedNode),
BlankNode(PyBlankNode),
Literal(PyLiteral),
Triple(PyTriple),
}
impl From<PyTerm> for Term {
fn from(term: PyTerm) -> Self {
match term {
PyTerm::NamedNode(node) => node.into(),
PyTerm::BlankNode(node) => node.into(),
PyTerm::Literal(literal) => literal.into(),
PyTerm::Triple(triple) => triple.into(),
}
}
}
impl From<Term> for PyTerm {
fn from(term: Term) -> Self {
match term {
Term::NamedNode(node) => Self::NamedNode(node.into()),
Term::BlankNode(node) => Self::BlankNode(node.into()),
Term::Literal(literal) => Self::Literal(literal.into()),
Term::Triple(triple) => Self::Triple(triple.as_ref().clone().into()),
}
}
}
impl IntoPy<PyObject> for PyTerm {
fn into_py(self, py: Python<'_>) -> PyObject {
match self {
Self::NamedNode(node) => node.into_py(py),
Self::BlankNode(node) => node.into_py(py),
Self::Literal(literal) => literal.into_py(py),
Self::Triple(triple) => triple.into_py(py),
}
}
}
/// An RDF `triple <https://www.w3.org/TR/rdf11-concepts/#dfn-rdf-triple>`_.
///
/// :param subject: the triple subject.
/// :type subject: NamedNode or BlankNode or Triple
/// :param predicate: the triple predicate.
/// :type predicate: NamedNode
/// :param object: the triple object.
/// :type object: NamedNode or BlankNode or Literal or Triple
///
/// The :py:func:`str` function provides a serialization compatible with NTriples, Turtle, and SPARQL:
///
/// >>> str(Triple(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1')))
/// '<http://example.com> <http://example.com/p> "1"'
///
/// A triple could also be easily destructed into its components:
///
/// >>> (s, p, o) = Triple(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'))
#[pyclass(frozen, name = "Triple", module = "pyoxigraph")]
#[derive(Eq, PartialEq, Debug, Clone, Hash)]
pub struct PyTriple {
inner: Triple,
}
impl From<Triple> for PyTriple {
fn from(inner: Triple) -> Self {
Self { inner }
}
}
impl From<PyTriple> for Triple {
fn from(triple: PyTriple) -> Self {
triple.inner
}
}
impl<'a> From<&'a PyTriple> for TripleRef<'a> {
fn from(triple: &'a PyTriple) -> Self {
triple.inner.as_ref()
}
}
impl From<PyTriple> for Subject {
fn from(triple: PyTriple) -> Self {
triple.inner.into()
}
}
impl From<PyTriple> for Term {
fn from(triple: PyTriple) -> Self {
triple.inner.into()
}
}
#[pymethods]
impl PyTriple {
#[new]
fn new(subject: PySubject, predicate: PyNamedNode, object: PyTerm) -> Self {
Triple::new(subject, predicate, object).into()
}
/// :return: the triple subject.
/// :rtype: NamedNode or BlankNode or Triple
///
/// >>> Triple(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1')).subject
/// <NamedNode value=http://example.com>
#[getter]
fn subject(&self) -> PySubject {
self.inner.subject.clone().into()
}
/// :return: the triple predicate.
/// :rtype: NamedNode
///
/// >>> Triple(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1')).predicate
/// <NamedNode value=http://example.com/p>
#[getter]
fn predicate(&self) -> PyNamedNode {
self.inner.predicate.clone().into()
}
/// :return: the triple object.
/// :rtype: NamedNode or BlankNode or Literal or Triple
///
/// >>> Triple(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1')).object
/// <Literal value=1 datatype=<NamedNode value=http://www.w3.org/2001/XMLSchema#string>>
#[getter]
fn object(&self) -> PyTerm {
self.inner.object.clone().into()
}
fn __str__(&self) -> String {
self.inner.to_string()
}
fn __repr__(&self) -> String {
let mut buffer = String::new();
triple_repr(self.inner.as_ref(), &mut buffer);
buffer
}
fn __hash__(&self) -> u64 {
hash(&self.inner)
}
fn __richcmp__(&self, other: &Self, op: CompareOp) -> PyResult<bool> {
eq_compare(self, other, op)
}
fn __len__(&self) -> usize {
3
}
fn __getitem__(&self, input: usize) -> PyResult<PyTerm> {
match input {
0 => Ok(Term::from(self.inner.subject.clone()).into()),
1 => Ok(Term::from(self.inner.predicate.clone()).into()),
2 => Ok(self.inner.object.clone().into()),
_ => Err(PyIndexError::new_err("A triple has only 3 elements")),
}
}
fn __iter__(&self) -> TripleComponentsIter {
TripleComponentsIter {
inner: vec![
self.inner.subject.clone().into(),
self.inner.predicate.clone().into(),
self.inner.object.clone(),
]
.into_iter(),
}
}
/// :rtype: typing.Any
fn __getnewargs__(&self) -> (PySubject, PyNamedNode, PyTerm) {
(self.subject(), self.predicate(), self.object())
}
/// :rtype: Triple
fn __copy__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
/// :type memo: typing.Any
/// :rtype: Triple
#[allow(unused_variables)]
fn __deepcopy__<'a>(slf: PyRef<'a, Self>, memo: &'_ PyAny) -> PyRef<'a, Self> {
slf
}
#[classattr]
fn __match_args__() -> (&'static str, &'static str, &'static str) {
("subject", "predicate", "object")
}
}
#[derive(FromPyObject)]
pub enum PyGraphName {
NamedNode(PyNamedNode),
BlankNode(PyBlankNode),
DefaultGraph(PyDefaultGraph),
}
impl From<PyGraphName> for GraphName {
fn from(graph_name: PyGraphName) -> Self {
match graph_name {
PyGraphName::NamedNode(node) => node.into(),
PyGraphName::BlankNode(node) => node.into(),
PyGraphName::DefaultGraph(default_graph) => default_graph.into(),
}
}
}
impl From<GraphName> for PyGraphName {
fn from(graph_name: GraphName) -> Self {
match graph_name {
GraphName::NamedNode(node) => Self::NamedNode(node.into()),
GraphName::BlankNode(node) => Self::BlankNode(node.into()),
GraphName::DefaultGraph => Self::DefaultGraph(PyDefaultGraph::new()),
}
}
}
impl IntoPy<PyObject> for PyGraphName {
fn into_py(self, py: Python<'_>) -> PyObject {
match self {
Self::NamedNode(node) => node.into_py(py),
Self::BlankNode(node) => node.into_py(py),
Self::DefaultGraph(node) => node.into_py(py),
}
}
}
/// An RDF `triple <https://www.w3.org/TR/rdf11-concepts/#dfn-rdf-triple>`_.
/// in a `RDF dataset <https://www.w3.org/TR/rdf11-concepts/#dfn-rdf-dataset>`_.
///
/// :param subject: the quad subject.
/// :type subject: NamedNode or BlankNode or Triple
/// :param predicate: the quad predicate.
/// :type predicate: NamedNode
/// :param object: the quad object.
/// :type object: NamedNode or BlankNode or Literal or Triple
/// :param graph_name: the quad graph name. If not present, the default graph is assumed.
/// :type graph_name: NamedNode or BlankNode or DefaultGraph or None, optional
///
/// The :py:func:`str` function provides a serialization compatible with NTriples, Turtle, and SPARQL:
///
/// >>> str(Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'), NamedNode('http://example.com/g')))
/// '<http://example.com> <http://example.com/p> "1" <http://example.com/g>'
///
/// >>> str(Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'), DefaultGraph()))
/// '<http://example.com> <http://example.com/p> "1"'
///
/// A quad could also be easily destructed into its components:
///
/// >>> (s, p, o, g) = Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'), NamedNode('http://example.com/g'))
#[pyclass(frozen, name = "Quad", module = "pyoxigraph")]
#[derive(Eq, PartialEq, Debug, Clone, Hash)]
pub struct PyQuad {
inner: Quad,
}
impl From<Quad> for PyQuad {
fn from(inner: Quad) -> Self {
Self { inner }
}
}
impl From<PyQuad> for Quad {
fn from(node: PyQuad) -> Self {
node.inner
}
}
impl<'a> From<&'a PyQuad> for QuadRef<'a> {
fn from(node: &'a PyQuad) -> Self {
node.inner.as_ref()
}
}
#[pymethods]
impl PyQuad {
#[new]
#[pyo3(signature = (subject, predicate, object, graph_name = None))]
fn new(
subject: PySubject,
predicate: PyNamedNode,
object: PyTerm,
graph_name: Option<PyGraphName>,
) -> Self {
Quad::new(
subject,
predicate,
object,
graph_name.unwrap_or(PyGraphName::DefaultGraph(PyDefaultGraph {})),
)
.into()
}
/// :return: the quad subject.
/// :rtype: NamedNode or BlankNode or Triple
///
/// >>> Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'), NamedNode('http://example.com/g')).subject
/// <NamedNode value=http://example.com>
#[getter]
fn subject(&self) -> PySubject {
self.inner.subject.clone().into()
}
/// :return: the quad predicate.
/// :rtype: NamedNode
///
/// >>> Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'), NamedNode('http://example.com/g')).predicate
/// <NamedNode value=http://example.com/p>
#[getter]
fn predicate(&self) -> PyNamedNode {
self.inner.predicate.clone().into()
}
/// :return: the quad object.
/// :rtype: NamedNode or BlankNode or Literal or Triple
///
/// >>> Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'), NamedNode('http://example.com/g')).object
/// <Literal value=1 datatype=<NamedNode value=http://www.w3.org/2001/XMLSchema#string>>
#[getter]
fn object(&self) -> PyTerm {
self.inner.object.clone().into()
}
/// :return: the quad graph name.
/// :rtype: NamedNode or BlankNode or DefaultGraph
///
/// >>> Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'), NamedNode('http://example.com/g')).graph_name
/// <NamedNode value=http://example.com/g>
#[getter]
fn graph_name(&self) -> PyGraphName {
self.inner.graph_name.clone().into()
}
/// :return: the quad underlying triple.
/// :rtype: Triple
///
/// >>> Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1'), NamedNode('http://example.com/g')).triple
/// <Triple subject=<NamedNode value=http://example.com> predicate=<NamedNode value=http://example.com/p> object=<Literal value=1 datatype=<NamedNode value=http://www.w3.org/2001/XMLSchema#string>>>
#[getter]
fn triple(&self) -> PyTriple {
Triple::from(self.inner.clone()).into()
}
fn __str__(&self) -> String {
self.inner.to_string()
}
fn __repr__(&self) -> String {
let mut buffer = String::new();
buffer.push_str("<Quad subject=");
term_repr(self.inner.subject.as_ref().into(), &mut buffer);
buffer.push_str(" predicate=");
named_node_repr(self.inner.predicate.as_ref(), &mut buffer);
buffer.push_str(" object=");
term_repr(self.inner.object.as_ref(), &mut buffer);
buffer.push_str(" graph_name=");
graph_name_repr(self.inner.graph_name.as_ref(), &mut buffer);
buffer.push('>');
buffer
}
fn __hash__(&self) -> u64 {
hash(&self.inner)
}
fn __richcmp__(&self, other: &Self, op: CompareOp) -> PyResult<bool> {
eq_compare(self, other, op)
}
fn __len__(&self) -> usize {
4
}
fn __getitem__(&self, input: usize, py: Python<'_>) -> PyResult<PyObject> {
match input {
0 => Ok(PySubject::from(self.inner.subject.clone()).into_py(py)),
1 => Ok(PyNamedNode::from(self.inner.predicate.clone()).into_py(py)),
2 => Ok(PyTerm::from(self.inner.object.clone()).into_py(py)),
3 => Ok(PyGraphName::from(self.inner.graph_name.clone()).into_py(py)),
_ => Err(PyIndexError::new_err("A quad has only 4 elements")),
}
}
fn __iter__(&self) -> QuadComponentsIter {
QuadComponentsIter {
inner: vec![
Some(self.inner.subject.clone().into()),
Some(self.inner.predicate.clone().into()),
Some(self.inner.object.clone()),
match self.inner.graph_name.clone() {
GraphName::NamedNode(node) => Some(node.into()),
GraphName::BlankNode(node) => Some(node.into()),
GraphName::DefaultGraph => None,
},
]
.into_iter(),
}
}
/// :rtype: typing.Any
fn __getnewargs__(&self) -> (PySubject, PyNamedNode, PyTerm, PyGraphName) {
(
self.subject(),
self.predicate(),
self.object(),
self.graph_name(),
)
}
/// :rtype: Quad
fn __copy__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
/// :type memo: typing.Any
/// :rtype: Quad
#[allow(unused_variables)]
fn __deepcopy__<'a>(slf: PyRef<'a, Self>, memo: &'_ PyAny) -> PyRef<'a, Self> {
slf
}
#[classattr]
fn __match_args__() -> (&'static str, &'static str, &'static str, &'static str) {
("subject", "predicate", "object", "graph_name")
}
}
/// A SPARQL query variable.
///
/// :param value: the variable name as a string.
/// :type value: str
/// :raises ValueError: if the variable name is invalid according to the SPARQL grammar.
///
/// The :py:func:`str` function provides a serialization compatible with SPARQL:
///
/// >>> str(Variable('foo'))
/// '?foo'
#[pyclass(frozen, name = "Variable", module = "pyoxigraph")]
#[derive(Eq, PartialEq, Debug, Clone, Hash)]
pub struct PyVariable {
inner: Variable,
}
impl From<Variable> for PyVariable {
fn from(inner: Variable) -> Self {
Self { inner }
}
}
impl From<PyVariable> for Variable {
fn from(variable: PyVariable) -> Self {
variable.inner
}
}
impl<'a> From<&'a PyVariable> for &'a Variable {
fn from(variable: &'a PyVariable) -> Self {
&variable.inner
}
}
#[pymethods]
impl PyVariable {
#[new]
fn new(value: String) -> PyResult<Self> {
Ok(Variable::new(value)
.map_err(|e| PyValueError::new_err(e.to_string()))?
.into())
}
/// :return: the variable name.
/// :rtype: str
///
/// >>> Variable("foo").value
/// 'foo'
#[getter]
fn value(&self) -> &str {
self.inner.as_str()
}
fn __str__(&self) -> String {
self.inner.to_string()
}
fn __repr__(&self) -> String {
format!("<Variable value={}>", self.inner.as_str())
}
fn __hash__(&self) -> u64 {
hash(&self.inner)
}
fn __richcmp__(&self, other: &Self, op: CompareOp) -> PyResult<bool> {
eq_compare(self, other, op)
}
/// :rtype: typing.Any
fn __getnewargs__(&self) -> (&str,) {
(self.value(),)
}
/// :rtype: Variable
fn __copy__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
/// :type memo: typing.Any
/// :rtype: Variable
#[allow(unused_variables)]
fn __deepcopy__<'a>(slf: PyRef<'a, Self>, memo: &'_ PyAny) -> PyRef<'a, Self> {
slf
}
#[classattr]
fn __match_args__() -> (&'static str,) {
("value",)
}
}
pub struct PyNamedNodeRef<'a>(PyRef<'a, PyNamedNode>);
impl<'a> From<&'a PyNamedNodeRef<'a>> for NamedNodeRef<'a> {
fn from(value: &'a PyNamedNodeRef<'a>) -> Self {
value.0.inner.as_ref()
}
}
impl<'a> TryFrom<&'a PyAny> for PyNamedNodeRef<'a> {
type Error = PyErr;
fn try_from(value: &'a PyAny) -> PyResult<Self> {
if let Ok(node) = value.extract::<PyRef<PyNamedNode>>() {
Ok(Self(node))
} else {
Err(PyTypeError::new_err(format!(
"{} is not an RDF named node",
value.get_type().name()?,
)))
}
}
}
pub enum PyNamedOrBlankNodeRef<'a> {
NamedNode(PyRef<'a, PyNamedNode>),
BlankNode(PyRef<'a, PyBlankNode>),
}
impl<'a> From<&'a PyNamedOrBlankNodeRef<'a>> for NamedOrBlankNodeRef<'a> {
fn from(value: &'a PyNamedOrBlankNodeRef<'a>) -> Self {
match value {
PyNamedOrBlankNodeRef::NamedNode(value) => value.inner.as_ref().into(),
PyNamedOrBlankNodeRef::BlankNode(value) => value.inner.as_ref().into(),
}
}
}
impl<'a> TryFrom<&'a PyAny> for PyNamedOrBlankNodeRef<'a> {
type Error = PyErr;
fn try_from(value: &'a PyAny) -> PyResult<Self> {
if let Ok(node) = value.extract::<PyRef<PyNamedNode>>() {
Ok(Self::NamedNode(node))
} else if let Ok(node) = value.extract::<PyRef<PyBlankNode>>() {
Ok(Self::BlankNode(node))
} else {
Err(PyTypeError::new_err(format!(
"{} is not an RDF named or blank node",
value.get_type().name()?,
)))
}
}
}
pub enum PySubjectRef<'a> {
NamedNode(PyRef<'a, PyNamedNode>),
BlankNode(PyRef<'a, PyBlankNode>),
Triple(PyRef<'a, PyTriple>),
}
impl<'a> From<&'a PySubjectRef<'a>> for SubjectRef<'a> {
fn from(value: &'a PySubjectRef<'a>) -> Self {
match value {
PySubjectRef::NamedNode(value) => value.inner.as_ref().into(),
PySubjectRef::BlankNode(value) => value.inner.as_ref().into(),
PySubjectRef::Triple(value) => (&value.inner).into(),
}
}
}
impl<'a> TryFrom<&'a PyAny> for PySubjectRef<'a> {
type Error = PyErr;
fn try_from(value: &'a PyAny) -> PyResult<Self> {
if let Ok(node) = value.extract::<PyRef<PyNamedNode>>() {
Ok(Self::NamedNode(node))
} else if let Ok(node) = value.extract::<PyRef<PyBlankNode>>() {
Ok(Self::BlankNode(node))
} else if let Ok(node) = value.extract::<PyRef<PyTriple>>() {
Ok(Self::Triple(node))
} else {
Err(PyTypeError::new_err(format!(
"{} is not an RDF named or blank node",
value.get_type().name()?,
)))
}
}
}
pub enum PyTermRef<'a> {
NamedNode(PyRef<'a, PyNamedNode>),
BlankNode(PyRef<'a, PyBlankNode>),
Literal(PyRef<'a, PyLiteral>),
Triple(PyRef<'a, PyTriple>),
}
impl<'a> From<&'a PyTermRef<'a>> for TermRef<'a> {
fn from(value: &'a PyTermRef<'a>) -> Self {
match value {
PyTermRef::NamedNode(value) => value.inner.as_ref().into(),
PyTermRef::BlankNode(value) => value.inner.as_ref().into(),
PyTermRef::Literal(value) => value.inner.as_ref().into(),
PyTermRef::Triple(value) => (&value.inner).into(),
}
}
}
impl<'a> From<&'a PyTermRef<'a>> for Term {
fn from(value: &'a PyTermRef<'a>) -> Self {
TermRef::from(value).into()
}
}
impl<'a> TryFrom<&'a PyAny> for PyTermRef<'a> {
type Error = PyErr;
fn try_from(value: &'a PyAny) -> PyResult<Self> {
if let Ok(node) = value.extract::<PyRef<PyNamedNode>>() {
Ok(Self::NamedNode(node))
} else if let Ok(node) = value.extract::<PyRef<PyBlankNode>>() {
Ok(Self::BlankNode(node))
} else if let Ok(node) = value.extract::<PyRef<PyLiteral>>() {
Ok(Self::Literal(node))
} else if let Ok(node) = value.extract::<PyRef<PyTriple>>() {
Ok(Self::Triple(node))
} else {
Err(PyTypeError::new_err(format!(
"{} is not an RDF term",
value.get_type().name()?,
)))
}
}
}
pub enum PyGraphNameRef<'a> {
NamedNode(PyRef<'a, PyNamedNode>),
BlankNode(PyRef<'a, PyBlankNode>),
DefaultGraph,
}
impl<'a> From<&'a PyGraphNameRef<'a>> for GraphNameRef<'a> {
fn from(value: &'a PyGraphNameRef<'a>) -> Self {
match value {
PyGraphNameRef::NamedNode(value) => value.inner.as_ref().into(),
PyGraphNameRef::BlankNode(value) => value.inner.as_ref().into(),
PyGraphNameRef::DefaultGraph => Self::DefaultGraph,
}
}
}
impl<'a> From<&'a PyGraphNameRef<'a>> for GraphName {
fn from(value: &'a PyGraphNameRef<'a>) -> Self {
GraphNameRef::from(value).into()
}
}
impl<'a> TryFrom<&'a PyAny> for PyGraphNameRef<'a> {
type Error = PyErr;
fn try_from(value: &'a PyAny) -> PyResult<Self> {
if let Ok(node) = value.extract::<PyRef<PyNamedNode>>() {
Ok(Self::NamedNode(node))
} else if let Ok(node) = value.extract::<PyRef<PyBlankNode>>() {
Ok(Self::BlankNode(node))
} else if value.extract::<PyRef<PyDefaultGraph>>().is_ok() {
Ok(Self::DefaultGraph)
} else {
Err(PyTypeError::new_err(format!(
"{} is not an RDF graph name",
value.get_type().name()?,
)))
}
}
}
fn eq_compare<T: Eq>(a: &T, b: &T, op: CompareOp) -> PyResult<bool> {
match op {
CompareOp::Eq => Ok(a == b),
CompareOp::Ne => Ok(a != b),
_ => Err(PyNotImplementedError::new_err(
"Ordering is not implemented",
)),
}
}
fn eq_compare_other_type(op: CompareOp) -> PyResult<bool> {
match op {
CompareOp::Eq => Ok(false),
CompareOp::Ne => Ok(true),
_ => Err(PyNotImplementedError::new_err(
"Ordering is not implemented",
)),
}
}
fn hash(t: &impl Hash) -> u64 {
let mut s = DefaultHasher::new();
t.hash(&mut s);
s.finish()
}
fn named_node_repr(node: NamedNodeRef<'_>, buffer: &mut String) {
buffer.push_str("<NamedNode value=");
buffer.push_str(node.as_str());
buffer.push('>');
}
fn blank_node_repr(node: BlankNodeRef<'_>, buffer: &mut String) {
buffer.push_str("<BlankNode value=");
buffer.push_str(node.as_str());
buffer.push('>');
}
fn literal_repr(literal: LiteralRef<'_>, buffer: &mut String) {
buffer.push_str("<Literal value=");
buffer.push_str(literal.value());
if let Some(language) = literal.language() {
buffer.push_str(" language=");
buffer.push_str(language);
} else {
buffer.push_str(" datatype=");
named_node_repr(literal.datatype(), buffer);
}
buffer.push('>');
}
pub fn term_repr(term: TermRef<'_>, buffer: &mut String) {
match term {
TermRef::NamedNode(node) => named_node_repr(node, buffer),
TermRef::BlankNode(node) => blank_node_repr(node, buffer),
TermRef::Literal(literal) => literal_repr(literal, buffer),
TermRef::Triple(triple) => triple_repr(triple.as_ref(), buffer),
}
}
fn graph_name_repr(term: GraphNameRef<'_>, buffer: &mut String) {
match term {
GraphNameRef::NamedNode(node) => named_node_repr(node, buffer),
GraphNameRef::BlankNode(node) => blank_node_repr(node, buffer),
GraphNameRef::DefaultGraph => buffer.push_str("<DefaultGraph>"),
}
}
fn triple_repr(triple: TripleRef<'_>, buffer: &mut String) {
buffer.push_str("<Triple subject=");
term_repr(triple.subject.into(), buffer);
buffer.push_str(" predicate=");
named_node_repr(triple.predicate, buffer);
buffer.push_str(" object=");
term_repr(triple.object, buffer);
buffer.push('>');
}
#[pyclass(module = "pyoxigraph")]
pub struct TripleComponentsIter {
inner: IntoIter<Term>,
}
#[pymethods]
impl TripleComponentsIter {
fn __iter__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
fn __next__(&mut self) -> Option<PyTerm> {
self.inner.next().map(PyTerm::from)
}
}
#[pyclass(module = "pyoxigraph")]
pub struct QuadComponentsIter {
inner: IntoIter<Option<Term>>,
}
#[pymethods]
impl QuadComponentsIter {
fn __iter__(slf: PyRef<'_, Self>) -> PyRef<Self> {
slf
}
fn __next__(&mut self, py: Python<'_>) -> Option<PyObject> {
self.inner.next().map(move |t| {
if let Some(t) = t {
PyTerm::from(t).into_py(py)
} else {
PyDefaultGraph {}.into_py(py)
}
})
}
}