use crate ::model ::* ;
use crate ::store_utils ::* ;
use oxigraph ::model ::Term ;
use oxigraph ::sparql ::* ;
use pyo3 ::exceptions ::{ PyRuntimeError , PySyntaxError , PyTypeError , PyValueError } ;
use pyo3 ::prelude ::{
pyclass , pymethods , pyproto , FromPyObject , IntoPy , Py , PyAny , PyCell , PyErr , PyObject , PyRef ,
PyRefMut , PyResult , Python ,
} ;
use pyo3 ::{ PyIterProtocol , PyMappingProtocol , PyObjectProtocol } ;
use std ::vec ::IntoIter ;
pub fn parse_query (
query : & str ,
use_default_graph_as_union : bool ,
default_graph : Option < & PyAny > ,
named_graphs : Option < & PyAny > ,
) -> PyResult < Query > {
let mut query = Query ::parse ( query , None ) . map_err ( | e | map_evaluation_error ( e . into ( ) ) ) ? ;
if use_default_graph_as_union & & default_graph . is_some ( ) {
return Err ( PyValueError ::new_err (
"The query() method use_default_graph_as_union and default_graph arguments should not be set at the same time" ,
) ) ;
}
if use_default_graph_as_union {
query . dataset_mut ( ) . set_default_graph_as_union ( ) ;
}
if let Some ( default_graph ) = default_graph {
if let Ok ( default_graphs ) = default_graph . iter ( ) {
query . dataset_mut ( ) . set_default_graph (
default_graphs
. map ( | graph | Ok ( graph ? . extract ::< PyGraphName > ( ) ? . into ( ) ) )
. collect ::< PyResult < _ > > ( ) ? ,
)
} else if let Ok ( default_graph ) = default_graph . extract ::< PyGraphName > ( ) {
query
. dataset_mut ( )
. set_default_graph ( vec! [ default_graph . into ( ) ] ) ;
} else {
return Err ( PyValueError ::new_err (
format! ( "The query() method default_graph argument should be a NamedNode, a BlankNode, the DefaultGraph or a not empty list of them. {} found" , default_graph . get_type ( )
) ) ) ;
}
}
if let Some ( named_graphs ) = named_graphs {
query . dataset_mut ( ) . set_available_named_graphs (
named_graphs
. iter ( ) ?
. map ( | graph | Ok ( graph ? . extract ::< PyNamedOrBlankNode > ( ) ? . into ( ) ) )
. collect ::< PyResult < _ > > ( ) ? ,
)
}
Ok ( query )
}
pub fn query_results_to_python ( py : Python < ' _ > , results : QueryResults ) -> PyResult < PyObject > {
Ok ( match results {
QueryResults ::Solutions ( inner ) = > PyQuerySolutions { inner } . into_py ( py ) ,
QueryResults ::Graph ( inner ) = > PyQueryTriples { inner } . into_py ( py ) ,
QueryResults ::Boolean ( b ) = > b . into_py ( py ) ,
} )
}
/// Tuple associating variables and terms that are the result of a SPARQL ``SELECT`` query.
///
/// It is the equivalent of a row in SQL.
///
/// It could be indexes by variable name (:py:class:`Variable` or :py:class:`str`) or position in the tuple (:py:class:`int`).
/// Unpacking also works.
///
/// >>> store = SledStore()
/// >>> store.add(Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1')))
/// >>> solution = next(store.query('SELECT ?s ?p ?o WHERE { ?s ?p ?o }'))
/// >>> solution[Variable('s')]
/// <NamedNode value=http://example.com>
/// >>> solution['s']
/// <NamedNode value=http://example.com>
/// >>> solution[0]
/// <NamedNode value=http://example.com>
/// >>> s, p, o = solution
/// >>> s
/// <NamedNode value=http://example.com>
#[ pyclass(unsendable, name = " QuerySolution " , module = " oxigraph " ) ]
pub struct PyQuerySolution {
inner : QuerySolution ,
}
#[ pyproto ]
impl PyObjectProtocol for PyQuerySolution {
fn __repr__ ( & self ) -> String {
let mut buffer = String ::new ( ) ;
buffer . push_str ( "<QuerySolution" ) ;
for ( k , v ) in self . inner . iter ( ) {
buffer . push ( ' ' ) ;
buffer . push_str ( k . as_str ( ) ) ;
buffer . push ( '=' ) ;
term_repr ( v . as_ref ( ) , & mut buffer )
}
buffer . push ( '>' ) ;
buffer
}
}
#[ pyproto ]
impl PyMappingProtocol for PyQuerySolution {
fn __len__ ( & self ) -> usize {
self . inner . len ( )
}
fn __getitem__ ( & self , input : & PyAny ) -> PyResult < Option < PyTerm > > {
if let Ok ( key ) = usize ::extract ( input ) {
Ok ( self . inner . get ( key ) . map ( | term | PyTerm ::from ( term . clone ( ) ) ) )
} else if let Ok ( key ) = < & str > ::extract ( input ) {
Ok ( self . inner . get ( key ) . map ( | term | PyTerm ::from ( term . clone ( ) ) ) )
} else if let Ok ( key ) = input . downcast ::< PyCell < PyVariable > > ( ) {
let key = & * key . borrow ( ) ;
Ok ( self
. inner
. get ( < & Variable > ::from ( key ) )
. map ( | term | PyTerm ::from ( term . clone ( ) ) ) )
} else {
Err ( PyTypeError ::new_err ( format! (
"{} is not an integer of a string" ,
input . get_type ( ) . name ( ) ? ,
) ) )
}
}
}
#[ pyproto ]
impl PyIterProtocol for PyQuerySolution {
fn __iter__ ( slf : PyRef < Self > ) -> SolutionValueIter {
SolutionValueIter {
inner : slf
. inner
. values ( )
. map ( | v | v . cloned ( ) )
. collect ::< Vec < _ > > ( )
. into_iter ( ) ,
}
}
}
#[ pyclass(module = " oxigraph " ) ]
pub struct SolutionValueIter {
inner : IntoIter < Option < Term > > ,
}
#[ pyproto ]
impl PyIterProtocol for SolutionValueIter {
fn __iter__ ( slf : PyRefMut < Self > ) -> Py < Self > {
slf . into ( )
}
fn __next__ ( mut slf : PyRefMut < Self > ) -> Option < Option < PyTerm > > {
slf . inner . next ( ) . map ( | v | v . map ( PyTerm ::from ) )
}
}
/// An iterator of :py:class:`QuerySolution` returned by a SPARQL ``SELECT`` query
///
/// >>> store = SledStore()
/// >>> store.add(Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1')))
/// >>> list(store.query('SELECT ?s WHERE { ?s ?p ?o }'))
/// [<QuerySolution s=<NamedNode value=http://example.com>>]
#[ pyclass(unsendable, name = " QuerySolutions " , module = " oxigraph " ) ]
pub struct PyQuerySolutions {
inner : QuerySolutionIter ,
}
#[ pymethods ]
impl PyQuerySolutions {
/// :return: the ordered list of all variables that could appear in the query results
/// :rtype: list(Variable)
///
/// >>> store = SledStore()
/// >>> store.query('SELECT ?s WHERE { ?s ?p ?o }').variables
/// [<Variable value=s>]
#[ getter ]
fn variables ( & self ) -> Vec < PyVariable > {
self . inner
. variables ( )
. iter ( )
. map ( | v | v . clone ( ) . into ( ) )
. collect ( )
}
}
#[ pyproto ]
impl PyIterProtocol for PyQuerySolutions {
fn __iter__ ( slf : PyRefMut < Self > ) -> Py < Self > {
slf . into ( )
}
fn __next__ ( mut slf : PyRefMut < Self > ) -> PyResult < Option < PyQuerySolution > > {
Ok ( slf
. inner
. next ( )
. transpose ( )
. map_err ( map_evaluation_error ) ?
. map ( move | inner | PyQuerySolution { inner } ) )
}
}
/// An iterator of :py:class:`Triple` returned by a SPARQL ``CONSTRUCT`` or ``DESCRIBE`` query
///
/// >>> store = MemoryStore()
/// >>> store.add(Quad(NamedNode('http://example.com'), NamedNode('http://example.com/p'), Literal('1')))
/// >>> list(store.query('CONSTRUCT WHERE { ?s ?p ?o }'))
/// [<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>>>]
#[ pyclass(unsendable, name = " QueryTriples " , module = " oxigraph " ) ]
pub struct PyQueryTriples {
inner : QueryTripleIter ,
}
#[ pyproto ]
impl PyIterProtocol for PyQueryTriples {
fn __iter__ ( slf : PyRefMut < Self > ) -> Py < Self > {
slf . into ( )
}
fn __next__ ( mut slf : PyRefMut < Self > ) -> PyResult < Option < PyTriple > > {
Ok ( slf
. inner
. next ( )
. transpose ( )
. map_err ( map_evaluation_error ) ?
. map ( | t | t . into ( ) ) )
}
}
pub fn map_evaluation_error ( error : EvaluationError ) -> PyErr {
match error {
EvaluationError ::Parsing ( error ) = > PySyntaxError ::new_err ( error . to_string ( ) ) ,
EvaluationError ::Io ( error ) = > map_io_err ( error ) ,
EvaluationError ::Query ( error ) = > PyValueError ::new_err ( error . to_string ( ) ) ,
_ = > PyRuntimeError ::new_err ( error . to_string ( ) ) ,
}
}