This section defines the correct behavior for evaluation of graph patterns and solution
modifiers, given a query string and an RDF dataset. It does not imply a SPARQL implementation
must use the process defined here.
The outcome of executing a SPARQL query is defined by a series of steps, starting from the
SPARQL query as a string, turning that string into an abstract syntax form, then turning the
abstract syntax into a SPARQL abstract query comprising operators from the SPARQL algebra. This
abstract query is then evaluated on an RDF dataset.
This section defines the process of converting graph patterns and solution modifiers in a
SPARQL query string into a SPARQL algebra expression. The process described converts one
level of query nesting, as formed by subqueries using the nested SELECT syntax and
is applied recursively on subqueries. Each level consists of graph pattern matching and
filtering, followed by the application of solution modifiers.
The SPARQL query string is parsed and the abbreviations for IRIs and triple patterns given
in section 4 are applied. At this point the abstract syntax tree
is composed of:
| Patterns |
Modifiers |
Query Forms |
Other |
| RDF terms |
DISTINCT |
SELECT |
VALUES |
| Property path expression |
REDUCED |
CONSTRUCT |
SERVICE |
| Property path patterns |
Projection |
DESCRIBE |
|
| Groups |
ORDER BY |
ASK |
|
| OPTIONAL |
LIMIT |
|
|
| UNION |
OFFSET |
|
|
| GRAPH |
Select expressions |
|
|
| BIND |
|
|
|
| GROUP BY |
|
|
|
| HAVING |
|
|
|
| MINUS |
|
|
|
| FILTER |
|
|
|
The result of converting such an abstract syntax tree is a SPARQL query that uses the
following symbols in the SPARQL algebra:
| Graph Pattern |
Solution Modifiers |
Property Path |
| BGP |
ToList |
PredicatePath |
| Join |
OrderBy |
InversePath |
| LeftJoin |
Project |
SequencePath |
| Filter |
Distinct |
AlernativePath |
| Union |
Reduced |
ZeroOrMorePath |
| Graph |
Slice |
OneOrMorePath |
| Extend |
ToMultiSet |
ZeroOrOnePath |
| Minus |
|
NegatedPropertySet |
| Group |
|
|
| Aggregation |
|
|
| AggregateJoin |
|
|
Slice is the combination of OFFSET and LIMIT.
ToList is used where conversion from the results of graph pattern matching to
sequences occurs.
ToMultiSet is used where conversion from a solution sequence to a multiset
occurs.
We define a variable to be in-scope if there is a way for a variable to be in the
domain of a solution mapping at that point in the execution of the SPARQL algebra for the
query. The definition below provides a way of determing this from the abstract syntax of a
query.
Note that a subquery with a projection can hide variables; use of a variable in
FILTER, or in MINUS does not cause a variable to be in-scope
outside of those forms.
Let P, P1, P2 be graph patterns and E,
E1,...En be expressions. A variable v is in-scope if:
| Syntax Form |
In-scope variables |
| Basic Graph Pattern (BGP) |
v occurs in the BGP |
| Path |
v occurs in the path |
Group { P1 P2 ... } |
v is in-scope if it is in-scope in one or more of P1, P2, ... |
GRAPH term { P } |
v is term or v is in-scope in P |
{ P1 } UNION { P2 } |
v is in-scope in P1 or in-scope in P2 |
OPTIONAL {P} |
v is in-scope in P |
SERVICE term {P} |
v is term or v is in-scope in P |
BIND (expr AS v) |
v is in-scope |
SELECT .. v .. { P } |
v is in-scope |
SELECT ... (expr AS v) |
v is in-scope |
GROUP BY (expr AS v) |
v is in-scope |
SELECT * { P } |
v is in-scope in P |
VALUES v { values } |
v is in-scope |
VALUES varlist { values } |
v is in-scope if v is in varlist |
The variable v must not be in-scope at the point of the (expr AS
v) form. The scoping for (expr AS v) applies immediately in
SELECT expressions.
In BIND (expr AS v) requires that the variable v is not
in-scope from the preceeding elements in the group graph pattern in which it is used.
In SELECT, the variable v must not be in-scope in the graph
pattern of the SELECT clause, nor used in another select expression earlier in
the clause.
This section describes the process for translating a SPARQL graph pattern into a SPARQL
algebra expression. This process is applied to the group graph pattern (the unit between
{...} delimiters) forming the WHERE clause of a query, and
recursively to each syntactic element within the group graph pattern. The result of the
translation is a SPARQL algebra expression.
In summary, the steps are applied as follows:
We write
translate(graph pattern)
for the algorthm described here to translate graph patterns.
The working group notes that in SPARQL 1.0, the point at which the simplification step is
applied leads to ambiguous transformation of queries involving a doubly nested filter and
pattern in an optional:
OPTIONAL { { ... FILTER ( ... ?x ... ) } }..
This is illustrated by two non-normative test cases:
Applying the simpification step after all the translation of graph patterns is the
preferred reading.
FILTER expressions apply to the whole group graph pattern in which they
appear. The algebra operators to perform filtering are added to the group after
translation of each group element. We collect the filters together here and remove them
from group, then apply them to the whole translated group
graph pattern.
In this step, we also translate graph patterns within FILTER expressions
EXISTS and NOT EXISTS.
Let FS := empty set
For each form FILTER(expr) in the group graph pattern
In expr, replace NOT EXISTS{P} with fn:not(exists(translate(P)))
In expr, replace EXISTS{P} with exists(translate(P))
FS := FS ∪ {expr}
End
The set of filter expressions FS is used
later.
The following table gives the translation of property paths expressions from SPARQL
syntax to terms in the SPARQL algebra. This applies to all elements of a property path
expression recursively.
The next step after this one translates
certain forms to triple patterns, and these are converted later to basic graph patterns
by adjacency (without intervening group pattern delimiters
{ and }) or
other syntax forms. Overall, SPARQL syntax property paths of just an IRI become triple
patterns and these are aggregated into basic graph patterns.
Notes:
- The order of forms IRI and ^IRI in negated property sets is not relevant.
We introduce the following symbols:
- link
- inv
- alt
- seq
- ZeroOrMorePath
- OneOrMorePath
- ZeroOrOnePath
- NPS (for NegatedPropertySet)
| Syntax Form (path) |
Algebra (path) |
iri |
link(iri) |
^path |
inv(path) |
!(:iri1|...|:irin) |
NPS({:iri1 ... :irin}) |
!(^:iri1|...|^:irin) |
inv(NPS({:iri1 ... :irin})) |
!(:iri1|...|:irii|^:irii+1|...|^:irim) |
alt(NPS({:iri1 ...:irii}),
inv(NPS({:irii+1, ..., :irim}))
) |
path1 / path2 |
seq(path1, path2) |
path1 | path2 |
alt(path1, path2) |
path* |
ZeroOrMorePath(path) |
path+ |
OneOrMorePath(path) |
path? |
ZeroOrOnePath(path) |
The previous step translated property path
expressions. This step translates property path
patterns, which are a subject end point, property path expression and object end
point, into triple patterns or wraps in a general algebra operation for path
evaluation.
Notes:
- X and Y are RDF terms or variables.
- ?V is a fresh variable.
- P and Q are path expressions.
- These are only applied to property path patterns, not within property path
expressions.
- Translations earlier in the table are applied in preference to the last
translation.
- The final translation simply wraps any remaining property path expression to use a
common form
Path(...).
| Algebra (path) |
Translation |
X link(iri) Y |
X iri Y |
X inv(iri) Y |
Y iri X |
X seq(P, Q) Y |
X P ?V . ?V Q Y |
X P Y |
Path(X, P, Y) |
Examples of the whole path translation process (?_V is a fresh
variable):
?s :p/:q ?o
?s :p ?_V .
?_V :q ?o
?s :p* ?o
Path(?s, ZeroOrMorePath(link(:p)), ?o)
:list rdf:rest*/rdf:first ?member
Path(:list, ZeroOrMorePath(link(rdf:rest)), ?_V) .
?_V rdf:first ?member
After translating property paths, any adjacent triple patterns are collected together
to form a basic graph pattern BGP(triples).
Next, we translate each remaining graph pattern form, recursively applying the
translation process.
If the form is GroupOrUnionGraphPattern
Let A := undefined
For each element G in the GroupOrUnionGraphPattern
If A is undefined
A := Translate(G)
Else
A := Union(A, Translate(G))
End
The result is A
If the form is GraphGraphPattern
If the form is GRAPH IRI GroupGraphPattern
The result is Graph(IRI, Translate(GroupGraphPattern))
If the form is GRAPH Var GroupGraphPattern
The result is Graph(Var, Translate(GroupGraphPattern))
If the form is GroupGraphPattern:
Let FS := the empty set
Let G := the empty pattern, a basic graph pattern which is the empty set.
For each element E in the sequence of elements in the GroupGraphPattern
If E is of the form OPTIONAL{P}
Let A := Translate(P)
If A is of the form Filter(F, A2)
G := LeftJoin(G, A2, F)
Else
G := LeftJoin(G, A, true)
End
End
If E is of the form MINUS{P}
G := Minus(G, Translate(P))
End
If E is of the form BIND(expr AS var)
G := Extend(G, var, expr)
End
If E is any other form
Let A := Translate(E)
G := Join(G, A)
End
End
The result is G.
If the form is InlineData
The result is a multiset of solution mappings 'data'.
data is formed by forming a solution mapping from the variable in the
corresponding position in list of variables (or single variable), omitting a binding
if the DataBlockValue
is the word UNDEF.
If the form is SubSelect
The result is ToMultiset(Translate(SubSelect))
After the group has been translated, the filter expressions are added so they wil
apply to the whole of the rest of the group:
If FS is not empty
Let G := output of preceding step
Let X := Conjunction of expressions in FS
G := Filter(X, G)
End
Some groups of one graph pattern become join(Z, A), where Z is the empty
basic graph pattern (which is the empty set). These can be replaced by A. The empty graph
pattern Z is the identity for join:
Replace join(Z, A) by A
Replace join(A, Z) by A
The second form of a rewrite example is the first with empty group joins removed by the
simplification step.
Example: group with a basic graph pattern consisting of a single triple pattern:
{ ?s ?p ?o }
Join(Z, BGP(?s ?p ?o) )
BGP(?s ?p ?o)
Example: group with a basic graph pattern consisting of two triple patterns:
{ ?s :p1 ?v1 ; :p2 ?v2 }
BGP( ?s :p1 ?v1 . ?s :p2 ?v2 )
Example: group consisting of a union of two basic graph patterns:
{ { ?s :p1 ?v1 } UNION {?s :p2 ?v2 } }
Union(Join(Z, BGP(?s :p1 ?v1)),
Join(Z, BGP(?s :p2 ?v2)) )
Union( BGP(?s :p1 ?v1) , BGP(?s :p2 ?v2) )
Example: group consisting of a union of a union and a basic graph pattern:
{ { ?s :p1 ?v1 } UNION {?s :p2 ?v2 } UNION {?s :p3 ?v3 } }
Union(
Union( Join(Z, BGP(?s :p1 ?v1)),
Join(Z, BGP(?s :p2 ?v2)))
,
Join(Z, BGP(?s :p3 ?v3)) )
Union(
Union( BGP(?s :p1 ?v1) ,
BGP(?s :p2 ?v2),
BGP(?s :p3 ?v3))
Example: group consisting of a basic graph pattern and an optional graph pattern:
{ ?s :p1 ?v1 OPTIONAL {?s :p2 ?v2 } }
LeftJoin(
Join(Z, BGP(?s :p1 ?v1)),
Join(Z, BGP(?s :p2 ?v2)),
true)
LeftJoin(BGP(?s :p1 ?v1), BGP(?s :p2 ?v2), true)
Example: group consisting of a basic graph pattern and two optional graph patterns:
{ ?s :p1 ?v1 OPTIONAL {?s :p2 ?v2 } OPTIONAL { ?s :p3 ?v3 } }
LeftJoin(
LeftJoin(
BGP(?s :p1 ?v1),
BGP(?s :p2 ?v2),
true) ,
BGP(?s :p3 ?v3),
true)
Example: group consisting of a basic graph pattern and an optional graph pattern with a
filter:
{ ?s :p1 ?v1 OPTIONAL {?s :p2 ?v2 FILTER(?v1<3) } }
LeftJoin(
Join(Z, BGP(?s :p1 ?v1)),
Join(Z, BGP(?s :p2 ?v2)),
(?v1<3) )
LeftJoin(
BGP(?s :p1 ?v1) ,
BGP(?s :p2 ?v2) ,
(?v1<3) )
Example: group consisting of a union graph pattern and an optional graph pattern:
{ {?s :p1 ?v1} UNION {?s :p2 ?v2} OPTIONAL {?s :p3 ?v3} }
LeftJoin(
Union(BGP(?s :p1 ?v1),
BGP(?s :p2 ?v2)) ,
BGP(?s :p3 ?v3) ,
true )
Example: group consisting of a basic graph pattern, a filter and an optional graph
pattern:
{ ?s :p1 ?v1 FILTER (?v1 < 3 ) OPTIONAL {?s :p2 ?v2} }
Filter( ?v1 < 3 ,
LeftJoin( BGP(?s :p1 ?v1), BGP(?s :p2 ?v2), true) ,
)
Example: Pattern involving BIND:
{ ?s :p ?v . BIND (2*?v AS ?v2) ?s :p1 ?v2 }
Join(
Extend( BGP(?s :p ?v), ?v2, 2*?v) ,
BGP(?s :p1 ?v2) )
Example: Pattern involving BIND, with a
simplification step:
{ ?s :p ?v . {} BIND (2*?v AS ?v2) }
Extend(
Join(
Join( {}, BGP(?s :p ?v)),
{}),
?v2, 2*?v
)
Extend(
BGP(?s :p ?v) ,
?v2, 2*?v
)
Example: Pattern involving MINUS:
{ ?s :p ?v . MINUS {?s :p1 ?v2 } }
Minus(
BGP(?s :p ?v)
BGP(?s :p1 ?v2)
)
Example: Pattern involving a subquery:
{ ?s :p ?o . {SELECT DISTINCT ?o {?o ?p ?z} } }
Join(
BGP(?s :p ?o) ,
ToMultiSet(
Distinct(
Project( ToList(BGP(?o ?p ?z)), {?o} )
)
)
)
In this step, we process clauses on the query level in the following order:
- Grouping
- Aggregates
- HAVING
- VALUES
- Select expressions
Step: GROUP BY
If the GROUP BY keyword is used, or there is implicit grouping due to the
use of aggregates in the projection, then grouping is performed by the
Group function.
In this case, before grouping, the solution set is converted into a solution
sequence by applying the ToList function.
Next, the Group function
divides this solution sequence into groups of one or
more solutions, with the same overall cardinality. In case of implicit grouping, a fixed
constant (1) is used to group all solutions into a single group.
Step: Aggregates
The aggregation step is applied as a transformation on the query level, replacing
aggregate expressions in the query level with Aggregation() algebraic
expressions.
The transformation for query levels that use any aggregates is given
below:
Let A := the empty sequence
Let Q := the query level being evaluated
Let P := the algebra translation of the GroupGraphPattern of the query level
Let E := [], a list of pairs of the form (variable, expression)
If Q contains GROUP BY exprlist
Let Grp := Group(exprlist, ToList(P))
Else If Q contains an aggregate in SELECT, HAVING, ORDER BY
Let Grp := Group((1), ToList(P))
Else
skip the rest of the aggregate step
End
Global i := 1 # Initially 1 for each query processed
For each (X AS Var) in SELECT, each HAVING(X), and each ORDER BY X in Q
For each unaggregated variable V in X
Replace V with Sample(V)
End
For each aggregate R(args ; scalarvals) now in X
# note: scalarvals may be omitted; if so, it's equivalent to the empty function
Ai := Aggregation(args, R, scalarvals, Grp)
Replace R(...) with aggi in Q
i := i + 1
End
End
For each variable V appearing outside of an aggregate
Ai := Aggregation(V, Sample, {}, Grp)
E := E append (V, aggi)
i := i + 1
End
A := Ai, ..., Ai-1
P := AggregateJoin(A)
The HAVING expression is evaluated using the same rules as FILTER().
Note that, due to the logic position in which the HAVING clause is
evaluated, expressions projected by the
SELECT clause are not visible to the HAVING clause.
Let Q := the query level being evaluated
Let P := the algebra translation of the query level so far
For each HAVING(E) in Q
P := Filter(E, P)
End
If the query has a trailing VALUES clause:
Let P := the algebra translation of the query level so far
P := Join(P, ToMultiSet(data))
where data is a solution sequence derived from the VALUES clause
The translatation of the data is the same as for inline
data.
Step: Select expressions
We have two forms of the abstract syntax to consider:
SELECT selItem ... { pattern }
SELECT * { pattern }
Let X := algebra from earlier steps
Let VS := list of all variables visible in the pattern,
so restricted by sub-SELECT projected variables and GROUP BY variables.
Not visible: only in filter, exists/not exists, masked by a subselect,
non-projected GROUP variables, only in the right hand side of MINUS
Let PV := {}, a set of variable names
Note, E is a list of pairs of the form (variable, expression), defined in section 18.2.4.
If "SELECT *"
PV := VS
If "SELECT selItem ..."
For each selItem
If selItem is a variable
PV := PV ∪ { variable }
End
If selItem is (expr AS variable)
variable must not appear in VS nor in PV; if it does then generate a syntax error and stop
PV := PV ∪ { variable }
E := E append (variable, expr)
End
End
For each pair (var, expr) in E
X := Extend(X, var, expr)
End
Result is X
The set PV is used later for projection.
The syntax error arises for use of a variable as the named target of AS (e.g. ... AS
?x) when the variable is used inside the WHERE clause of the SELECT or if already used as
the target of AS in this SELECT expression.
Solution modifiers apply to the processing of a SPARQL query after pattern matching.
Since the solution modifiers operate on sequences
of solution mappings, the query result produced up to this
point is first turned from a multiset of solution mappings
into such a sequence. While there is no implied ordering to
this sequence, and duplicates need not be adjacent, the sequence
is identical to the multiset in terms of the elements that it
contains, and their multiplicities. To apply this conversion
from a multiset into a sequence, the algorithm for capturing
the solution modifiers in the algebra expression begins with
the following step, where Pattern is the algebra
expression produced by the algorithm in the previous section.
Let M := ToList(Pattern)
Now, the solution modifiers are applied in the following order:
- Order by
- Projection
- Distinct
- Reduced
- Offset
- Limit
If the query string has an ORDER BY clause
M := OrderBy(M, list of order comparators)
The set of projection variables, PV, was calculated in the
processing of SELECT expressions.
M := Project(M, PV)
where vars is the set of variables mentioned in the SELECT clause or all named
variables that are in-scope in the query if SELECT *
used.
If the query contains DISTINCT,
M := Distinct(M)
If the query contains REDUCED,
M := Reduced(M)
If the query contains "OFFSET start" or "LIMIT length"
M := Slice(M, start, length)
start defaults to 0
length defaults to (size(M)-start).
The overall abstract query is M.
When matching graph patterns, the possible solutions form a
multiset,
also known as a bag. A multiset is an
unordered collection of elements in which each element may appear more than once. It is
described by a set of elements and a function giving the multiplicity of each of these
elements (i.e., the number of times the element is contained in the multiset).
Write μ for solution mappings.
Write μ0 for the mapping such that dom(μ0) is the empty set.
Write Ω0 for the multiset consisting of exactly the empty mapping
μ0, with multiplicity 1. This is the join identity.
Write μ(x) for the solution mapping variable x to RDF term t : { (x, t) }.
Write Ω(x) for the multiset consisting of exactly μ(?x->t), that is, { { (x, t) } }
with multiplicity 1.
Definition: Compatible Mappings
Two solution mappings μ1 and μ2 are compatible if, for every
variable v in dom(μ1) and in dom(μ2), μ1(v) =
μ2(v).
Here, μ1(v) = μ2(v) means that μ1(v) and μ2(v)
are the same RDF term.
If μ1 and μ2 are compatible then μ1 ∪ μ2 is
also a mapping. Write merge(μ1, μ2) for μ1 ∪
μ2
Definition: Multiplicity
Given a multiset Ω of solution mappings and a solution
mapping μ, we write multiplicity(μ | Ω)
to denote the number of times μ appears in Ω.
Similarly, given a solution sequence Ψ and a solution
mapping μ, we write multiplicity(μ | Ψ)
to denote the number of times μ appears in Ψ.
A basic graph pattern is matched against the active graph for that part of the query.
Basic graph patterns can be instantiated by replacing both variables and blank nodes by
terms, giving two notions of instance. Blank nodes are replaced using an
RDF instance mapping, σ, from blank nodes to RDF terms;
variables are replaced by a solution mapping from query variables to RDF terms.
Definition: Pattern Instance Mapping
A Pattern Instance Mapping, P, is the combination of an RDF instance mapping,
σ, and solution mapping, μ. P(x) = μ(σ(x))
For a BGP 'x', P(x) denotes the result of replacing blank nodes b in x for which σ is
defined with σ(b) and all variables v in x for which μ is defined with μ(v).
Any pattern instance mapping defines a unique solution mapping and a unique RDF instance
mapping obtained by restricting it to query variables and blank nodes respectively.
Definition: Basic Graph Pattern Matching
Let BGP be a basic graph pattern and let G be an RDF graph.
μ is a solution for BGP from G when there is a pattern instance mapping P such
that P(BGP) is a subgraph of G and μ is the restriction of P to the query variables in
BGP.
multiplicity( μ | Ω ) =
number of distinct RDF instance mappings, σ, such that P = μ(σ)
is a pattern instance mapping and P(BGP) is a subgraph of G.
If a basic graph pattern is the empty set, then the solution is Ω0.
This definition allows the solution mapping to bind a variable in a basic graph pattern,
BGP, to a blank node in G. Since SPARQL treats blank node identifiers in a results format
document (SPARQL Query Results XML Format (Second Edition), SPARQL 1.1 Query Results JSON Format and
SPARQL 1.1 Query Results CSV and TSV Formats) as scoped to the document, they cannot be understood as
identifying nodes in the active graph of the dataset. If DS is the dataset of a query,
pattern solutions are therefore understood to be not from the active graph of DS itself,
but from an RDF graph, called the scoping graph, which is graph-equivalent to the
active graph of DS but shares no blank nodes with DS or with BGP. The same scoping graph is
used for all solutions to a single query. The scoping graph is purely a theoretical
construct; in practice, the effect is obtained simply by the document scope conventions for
blank node identifiers.
Since RDF blank nodes allow infinitely many redundant solutions for many patterns, there
can be infinitely many pattern solutions (obtained by replacing blank nodes by different
blank nodes). It is necessary, therefore, to somehow delimit the solutions for a basic
graph pattern. SPARQL uses the subgraph match criterion to determine the solutions of a
basic graph pattern. There is one solution for each distinct pattern instance mapping from
the basic graph pattern to a subset of the active graph.
This is optimized for ease of computation rather than redundancy elimination. It allows
query results to contain redundancies even when the active graph of the dataset is
lean, and it allows logically equivalent datasets to
yield different query results.
This section defines the evaluation of property path
patterns. A property path pattern is a subject endpoint (an RDF term or a variable), a
property path express and an object endpoint. The
translation of property path expressions converts some
forms to other SPARQL expressions, such as converting property paths of length one to triple
patterns, which in turn are combined into basic graph patterns. This leaves property path
operators ZeroOrOnePath, ZeroOrMorePath, OneOrMorePath and NegatedPropertySets and also path
expressions contained within these operators.
All remaining property path expressions are present in the algebra in the form
Path(X, path, Y) for endpoints X and Y. For example: syntax(:p/:q)*
is a ZeroOrMorePath expression involving a sequence property path becoming the algebra
expession ZeroOrMorePath(seq(link(:p), link(:q))).
Notation
Write
eval(Path(X, PP, Y))
for the evaluation of the property path patterns. This produces a multiset of solution
mappings μ, each solution mapping having a binding for variables used (each of X and Y can
be a variable). Some operators only produce a set of solution mappings.
Write
Var(x1, x2, ..., xn) = { xi | i in 1...n and xi is a variable
}
for the variables in x1, x2, ..., xn.
Write
x:term |
when x is an RDF term |
x:var |
when x is a variable |
x:path |
when x is a path expression |
All evaluation is carried out by matching the active graph
at that point in the overall query evaluation. We omit explicitly including the active graph
in each definition for clarity.
Definition: Evaluation of Predicate Property Path
Let Path(X, link(iri), Y) be an predicate inverse property path pattern, using some IRI
iri.
eval(Path(X, link(iri), Y)) = evaluation of basic graph pattern {X iri Y}
If both X and Y are variables, this is the same as:
eval(Path(X:var, link(iri), Y:var)) = { (X, xn) (Y, yn) | xn and yn are RDF terms and triple (xn iri yn) is in the active graph }
If X is a variable and Y an RDF term:
eval(Path(X:var, link(iri), Y:term)) = { (X, xn) | xn is an RDF term and triple (xn iri Y) is in the active graph
}
If X is an RDF term and Y is a variable:
eval(Path(X:term, link(iri), Y:var)) = { (Y, yn) | yn is an RDF term and triple (X iri yn) is in the active graph
}
If both X and Y are RDF terms:
eval(Path(X:term, link(iri), Y:term))
= { μ0 } if triple (X iri Y) is in the active graph
= { { } } = Ω0
eval(Path(X:term, link(iri), Y:term)) = { } if triple (X iri Y) is not in the active graph
Informally, evaluating a Predicate Property Path is the same as executing a subquery
SELECT * { X P Y } at that point in the query evaluation.
Definition: Evaluation of Inverse Property Path
Let P be a property path expression, then:
eval(Path(X, inv(P), Y)) = eval(Path(Y, P, X))
Definition: Evaluation of Sequence Property Path
Let P and Q be property path expressions. Let V be a fresh variable.
A = Join( eval(Path(X, P, V)), eval(Path(V, Q, Y)) )
eval(Path(X, seq(P,Q), Y)) = Project(A, Var(X,Y))
Informally, this is the same as:
SELECT * { X P _:a . _:a Q Y }
using the fact that a blank node _:a acts like a variable (under simple
entailment) except it does not appear in the results from SELECT *.
Definition: Evaluation of Alternative Property Path
Let P and Q be property path expressions.
eval(Path(X, alt(P,Q), Y)) =
Union(eval(Path(X, P, Y)), eval(Path(X, Q, Y)))
Informally, this is the same as:
SELECT * { { X P Y } UNION { X Q Y } }
Definition: Node set of a graph
The node set of a graph G, nodes(G), is:
nodes(G) = { n | n is an RDF term that is used as a subject or object of a triple of
G}
Definition: Evaluation of ZeroOrOnePath
eval(Path(X:term, ZeroOrOnePath(P), Y:var)) =
{ (Y, yn) | yn = X or {(Y, yn)} in eval(Path(X,P,Y)) }
eval(Path(X:var, ZeroOrOnePath(P), Y:term)) =
{ (X, xn) | xn = Y or {(X, xn)} in eval(Path(X,P,Y)) }
eval(Path(X:term, ZeroOrOnePath(P), Y:term)) =
{ {} } if X = Y or eval(Path(X,P,Y)) is not empty
{ } othewise
eval(Path(X:var, ZeroOrOnePath(P), Y:var)) =
{ (X, xn) (Y, yn) | either (yn in nodes(G) and xn = yn) or {(X,xn), (Y,yn)} in eval(Path(X,P,Y)) }
We define an auxillary function, ALP, used in the definitions of ZeroOrMorePath and
OneOrMorePath. Note that the algorithm given here serves to specify the feature. An
implementation is free to implement evaluation by any method that produces the same results
for the query overall. The ZeroOrMorePath and OneOrMorePath forms return matches based on
distinct nodes connected by the path.
The matching algorithm is based on following all paths, and detecting when a graph node
(subject or object), has been already visited on the path.
Informally, this algorithm attempts to extend the multiset of results by one application
of path at each step, noting which nodes it has visited for this particular path. If
a node has been visited for the path under consideration, it is not a candidate for another
step.
Definition: Function ALP
Let eval(x:term, path) be the evaluation of 'path', starting at RDF term x,
and returning a multiset of RDF terms reached
by repeated matches of path.
ALP(x:term, path) =
Let V = empty set
ALP(x:term, path, V)
return is V
# V is the set of nodes visited
ALP(x:term, path, V:set of RDF terms) =
if ( x in V ) return
add x to V
X = eval(x,path)
For n:term in X
ALP(n, path, V)
End
Definition: Evaluation of
ZeroOrMorePath
eval(Path(X:term, ZeroOrMorePath(path), vy:var)) =
{ { (vy, n) } | n in ALP(X, path) }
eval(Path(vx:var, ZeroOrMorePath(path), vy:var)) =
{ { (vx, t), (vy, n) } | t in nodes(G), (vy, n) in eval(Path(t, ZeroOrMorePath(path), vy)) }
eval(Path(vx:var, ZeroOrMorePath(path), y:term)) =
eval(Path(y:term, ZeroOrMorePath(inv(path)), vx:var))
eval(Path(x:term, ZeroOrMorePath(path), y:term)) =
{ { } } if { (vy:var,y) } in eval(Path(x, ZeroOrMorePath(path) vy)
{ } otherwise
Definition: Evaluation of
OneOrMorePath
eval(Path(X, OneOrMorePath(path), Y))
# For OneOrMorePath, we take one step of the path then start
# recording nodes for results.
eval(Path(x:term, OneOrMorePath(path), vy:var)) =
Let X = eval(x, path)
Let V = the empty multiset
For n in X
ALP(n, path, V)
End
result is V
eval(Path(vx:var, OneOrMorePath(path), vy:var)) =
{ { (vx, t), (vy, n) } | t in nodes(G), (vy, n) in eval(Path(t, OneOrMorePath(path), vy)) }
eval(Path(vx:var, OneOrMorePath(path), y:term)) =
eval(Path(y:term, OneOrMorePath(inv(path)), vx))
eval(Path(x:term, OneOrMorePath(path), y:term)) =
{ { } } if { (vy:var, y) } in eval(Path(x, OneOrMorePath(path), vy))
{ } otherwise
Definition: Evaluation of NegatedPropertySet
Write μ' as the extension of a solution mapping:
μ'(μ,x) = μ(x) if x is a variable
μ'(μ,t) = t if t is a RDF term
Let x and y be variables or RDF terms, and S a set of IRIs:
eval(Path(x, NPS(S), y)) = { μ | ∃ triple(μ'(μ,x), p, μ'(μ,y)) in G, such that the IRI of p ∉ S }
For each remaining symbol in a SPARQL abstract query, we define an operator for
evaluation. The SPARQL algebra operators of the same name are used to evaluate SPARQL
abstract query nodes as described in the section "Evaluation
Semantics". Evaluation of basic graph patterns and property path patterns has been
described above.
Definition: Filter
Let Ω be a multiset of solution mappings and expr be an expression. We define:
Filter(expr, Ω) = { μ | μ in Ω and expr(μ) is an expression that has an
effective boolean value of true }
multiplicity( μ | Filter(expr, Ω) )
= multiplicity( μ | Ω )
Note that evaluating an exists(pattern) expression uses the dataset and
active graph, D(G). See the evaluation of filter.
Definition: Join
Let Ω1 and Ω2 be multisets of solution mappings. We define:
Join(Ω1, Ω2) = { merge(μ1, μ2) |
μ1 in Ω1 and μ2 in Ω2, and μ1 and
μ2 are compatible }
multiplicity( μ | Join(Ω1, Ω2) ) =
for each merge(μ1, μ2), μ1 in
Ω1 and μ2 in Ω2 such that μ = merge(μ1,
μ2),
sum over (μ1, μ2),
multiplicity( μ1 | Ω1 ) * multiplicity( μ2 | Ω2 )
It is possible that a solution mapping μ in a Join can arise in different solution
mappings, μ1 and μ2 in the multisets being joined. The multiplicity
of μ is the sum of the multiplicities from all possibilities.
Definition: Diff
Let Ω1 and Ω2 be multisets of solution mappings and expr be an
expression. We define:
Diff(Ω1, Ω2, expr) = { μ | μ in Ω1 such that ∀ μ′ in
Ω2, either μ and μ′ are not compatible or μ and μ' are compatible and
expr(merge(μ, μ')) does not have an effective boolean value of true }
multiplicity( μ | Diff(Ω1, Ω2, expr) ) =
multiplicity( μ | Ω1 )
The evaluation of expr(merge(μ, μ')) does not have an effective boolean
value of true if it evaluates to false or if it raises an error.
Diff is used internally for the definition of LeftJoin.
Definition: LeftJoin
Let Ω1 and Ω2 be multisets of solution mappings and expr be an
expression. We define:
LeftJoin(Ω1, Ω2, expr) = Filter(expr, Join(Ω1,
Ω2)) ∪ Diff(Ω1, Ω2, expr)
multiplicity( μ | LeftJoin(Ω1, Ω2, expr) ) =
multiplicity( μ | Filter(expr,Join(Ω1, Ω2)) ) +
multiplicity( μ | Diff(Ω1, Ω2,
expr) )
Definition: Union
Let Ω1 and Ω2 be multisets of solution mappings. We define:
Union(Ω1, Ω2) = { μ | μ in Ω1 or μ in Ω2
}
multiplicity( μ | Union(Ω1, Ω2) ) =
multiplicity( μ | Ω1 ) +
multiplicity( μ | Ω2 )
Definition: Minus
Let Ω1 and Ω2 be multisets of solution mappings. We define:
Minus(Ω1, Ω2) = { μ | μ in Ω1 . ∀ μ' in
Ω2, either μ and μ' are not compatible or dom(μ) and dom(μ') are disjoint
}
multiplicity( μ | Minus(Ω1, Ω2) ) =
multiplicity( μ | Ω1 )
The additional restriction on dom(μ) and dom(μ') is added because otherwise if there is
a solution mapping in Ω2 that has no variables in common with the solution
mappings of Ω1, then Minus(Ω1, Ω2) would be empty,
regardless of the rest of Ω2. The empty solution mapping is compatible with
every other solution mapping so P MINUS {} would otherwise be empty for any
pattern P.
Definition: Extend
Let μ be a solution mapping, Ω a multiset of solution mappings, var a variable
and expr be an expression, then we define:
Extend(μ, var, expr) = μ ∪ { (var,value) | var not in dom(μ) and value = expr(μ) }
Extend(μ, var, expr) = μ if var not in dom(μ) and expr(μ) is an error
Extend is undefined when var in dom(μ).
Extend(Ω, var, expr) = { Extend(μ, var, expr) | μ in Ω }
Write [ x | C ] for a sequence of elements where C is a condition on x.
Definition: ToList
Let Ω be a multiset of solution mappings. We define:
ToList(Ω) = a sequence of mappings μ in Ω in any order, with
multiplicity( μ | Ω ) occurrences of
μ
multiplicity( μ | ToList(Ω) ) =
multiplicity( μ | Ω )
Definition: OrderBy
Let Ψ be a sequence of solution mappings. We define:
OrderBy
(Ψ, condition) = [ μ | μ in Ψ and the sequence satisfies the ordering condition]
multiplicity( μ | OrderBy(Ψ, condition) ) =
multiplicity( μ | Ψ )
Definition: Project
Let Ψ be a sequence of solution mappings and PV a set of variables.
For mapping μ, write Proj(μ, PV) to be the restriction of μ to variables in PV.
Project(Ψ, PV) = [ Proj(μ, PV) | μ in Ψ ]
multiplicity( μ | Project(Ψ, PV) ) =
sum( multiplicity( ν | Ψ ) | ν in Ψ such that ν = Proj(μ, PV))
The order of Project(Ψ, PV) must preserve any ordering given by OrderBy.
Definition: Distinct
Let Ψ be a sequence of solution mappings. We define:
Distinct(Ψ) = [ μ | μ in Ψ ]
multiplicity( μ | Distinct(Ψ) ) = 1
for every μ ∈ Distinct(Ψ)
multiplicity( μ | Distinct(Ψ) ) = 0
for every μ ∉ Distinct(Ψ)
The order of Distinct(Ψ) must preserve any ordering given by OrderBy.
Definition: Reduced
Let Ψ be a sequence of solution mappings. We define:
Reduced(Ψ) = [ μ | μ in Ψ ]
multiplicity( μ | Reduced(Ψ) ) is
between 1 and multiplicity( μ | Ψ )
for every μ ∈ Reduced(Ψ)
multiplicity( μ | Reduced(Ψ) ) = 0
for every μ ∉ Reduced(Ψ)
The order of Reduced(Ψ) must preserve any ordering given by OrderBy.
The Reduced solution sequence modifier does not guarantee a defined multiplicity.
Definition: Slice
Let Ψ be a sequence of solution mappings. We define:
Slice
(Ψ, start, length)[i] = Ψ[start+i] for i = 0 to (length-1)
Definition: ToMultiSet
Let Ψ be a solution sequence. We define:
ToMultiSet(Ψ) = { μ | μ in Ψ }
multiplicity( μ | ToMultiSet(Ψ) ) =
multiplicity( μ | Ψ )
Definition: ToMultiset
ToMultiset turns a sequence into a multiset with the same elements and multiplicities as
the sequence. The order of the sequence has no effect on the resulting multiset, and
duplicates are preserved.
Definition: Exists
exists(pattern) is a function that returns true if the pattern
evaluates to a non-empty solution sequence, given the current
solution mapping and active graph at the time of evaluation; otherwise it returns
false.
Group is a function which groups a solution sequence into multiple solutions, based on
some attribute of the solutions.
Definition: Group
Group evaluates a list of expressions against a solution sequence Ψ, producing a
partial function from keys to solution sequences.
Group(exprlist, Ψ) = {
ListEval(exprlist, μ)
→ [ μ' | μ' in Ψ such that
ListEval(exprlist, μ') and
ListEval(exprlist, μ)
are the same ] | μ in Ψ },
where two lists L and L' (as produced by
the ListEval function) are considered
the same iff they have the same number of elements and, for every
position k within the two lists, either of the
following two conditions is true:
- the element at the k-th position of
L is an RDF term; the element at the k-th
position of L' is also an RDF term; and these two
RDF terms are the same term
- the element at the k-th position of L
is an error, and the element at the k-th position of
L' is also an error
Definition: ListEval
ListEval((expr1, ..., exprn), μ) returns a list
(e1, ..., en), where ei = expri(μ) or
error.
ListEval retains errors resulting from the evaluation of the list elements.
Note that, although the result of ListEval
may contain errors, and errors may be used
to group, solutions containing error values are removed at the
end of evaluating the group and any aggregation functions.
Note also that the result of ListEval((unbound), μ)
is the list (error), as the evaluation of an unbound expression is an
error.
Aggregation, a function which calculates a scalar value as an output of the aggregate
expression. It is used in the SELECT clause, the HAVING evaluation process, and in ORDER
BY (where required). Aggregation calculates aggregated values over groups of solutions,
using set functions.
Definition: Aggregation
Let exprlist be a list of expressions or *; func, a set function;
scalarvals, a partial function (possibly with an empty domain) passed from the aggregate
in the query; and { key1→Ψ1, ...,
keym→Ψm }, a partial function from keys to
solution sequences as produced by the grouping step.
Aggregation applies the set function func to the given set and produces a
single value for each key and a group of solutions for that key.
Aggregation(exprlist, func, scalarvals, { key1→Ψ1, ...,
keym→Ψm } )
= { (key, F(Ψ)) | key → Ψ in { key1→Ψ1, ...,
keym→Ψm } }
where
M(Ψ) = [ ListEval(exprlist, μ) | μ in Ψ ]
F(Ψ) = func(M(Ψ), scalarvals), for non-DISTINCT
F(Ψ) = func(Dedup(M(Ψ)), scalarvals), for DISTINCT
with Dedup(M(Ψ)) being an order-preserving, duplicate-free version of the sequence M(Ψ); that is, Dedup(M(Ψ)) is a sequence of lists that has the following four properties
(where each such list in this sequence may contain RDF terms and
errors, as it is produced by the ListEval function).
- For every list L in M(Ψ) there exists a
list L' in Dedup(M(Ψ)) such that L
and L' are the same,
where two lists L and L' from M(Ψ) are
considered the same as specified in the definition of the
Group operator.
- For every list L in Dedup(M(Ψ)) there exists
a list L' in M(Ψ) such that L and
L' are the same.
- Dedup(M(Ψ)) is free of duplicates. That is, the list at the i-th position in Dedup(M(Ψ)) is not the same list as the list at the j-th position in Dedup(M(Ψ)) for every two natural numbers i and j such that i ≠ j.
- For any two lists L1 and L2 in Dedup(M(Ψ)), the relative order of their first occurrences in M(Ψ) is preserved in Dedup(M(Ψ)). That is, if i1 < i2, then j1 < j2, where
- i1 is the smallest natural number such that L1 is at the i1-th position in M(Ψ),
- i2 is the smallest natural number such that L2 is at the i2-th position in M(Ψ),
- j1 is the position of L1 in Dedup(M(Ψ)), and
- j2 is the position of L2 in Dedup(M(Ψ)).
Special Case: when COUNT is used with the expression
*, then F(Ψ) is the cardinality of the group solution sequence,
i.e., F(Ψ) = Card(Ψ),
or F(Ψ) = Card(Distinct(Ψ))
if the DISTINCT keyword is present.
scalarvals are used to pass values to the underlying set function, bypassing
the mechanics of the grouping. For example, the aggregate expression
GROUP_CONCAT(?x ; separator="|") has a scalarvals argument of { "separator"
→ "|" }.
All aggregates may have the DISTINCT keyword as the first token in their
argument list. If this keyword is present, then first argument to func is Dedup(M(Ψ)).
Example
Given a solution sequence Ψ with the following values:
| solution |
?x |
?y |
?z |
| μ1 |
1 |
2 |
3 |
| μ2 |
1 |
3 |
4 |
| μ3 |
2 |
5 |
6 |
And the query expression SELECT (ex:agg(?y, ?z) AS ?agg) WHERE { ?x ?y ?z } GROUP BY
?x.
We produce G = Group((?x), Ψ) = { (1) → [μ1, μ2], (2) →
[μ3] }
And so Aggregation((?y, ?z), ex:agg, {}, G) =
{ ((1), eg:agg([(2, 3), (3, 4)], {})), ((2), eg:agg([(5, 6)], {})) }.
Definition: AggregateJoin
Let S1, ..., Sn be a list of sets, where each set
Si contains key to (aggregated) value maps as produced by Aggregate.
Let K = { key | key in dom(Sj) for some 1 ≤ j ≤ n } be the set of
keys, then
AggregateJoin(S1, ..., Sn) = { agg1→val1,
..., aggn→valn | key in K and key→vali in
Si for each 1 ≤ i ≤ n }
The set functions which underlie SPARQL aggregates all have a common signature:
SetFunc(S), or SetFunc(S, scalarvals) where S is a sequence of lists, and scalarvals is
one or more scalar values that are passed to the set function indirectly via the ( ...
; key=value ) syntax for aggregates in the SPARQL grammar. The only use of this that is
supported by the built-in aggregates in SPARQL Query 1.1 is GROUP_CONCAT,
as in GROUP_CONCAT(?x ; separator=", ").
Note that the name "Set Function" is somewhat historical — the arguments to set
functions are in fact sequences. The name is retained due to the commonality with SQL
Set Functions, which operate over multisets.
The set functions defined in this document are Count, Sum, Min, Max, Avg,
GroupConcat, and Sample — corresponding to the aggregates COUNT,
SUM, MIN, MAX, AVG,
GROUP_CONCAT, and SAMPLE. Definitions may be found in the
following sections. Systems may choose to expand this set using local extensions, using
the same notation as for functions and casts. Note that, unless the ; separator is used
this requires the parser to know whether some IRI refers to a function, cast, or
aggregate before it can determine if there are any errors in a query where aggregates
are used.
The definitions of the set functions in the following sections
are based on two functions, Flatten
and Card, which are defined as follows.
Flatten is a function which is
used to collapse a sequence of lists into a single list.
For example, [(1, 2), (3, 4)] becomes (1, 2, 3, 4).
Definition: Flatten
Let S be a sequence of lists,
i.e., S =
[L1,
L2, ...,
Lm]
where, for every i ∈ {1, ..., m},
Li is a list.
Flatten(S) is the list
( x | L in S and
x in L ).
Card is a function that returns the
cardinality of a sequence or a list of elements (which may be
solution mappings or other types of elements, depending on the
context).
Definition: Card
Given a sequence or a list L, Card(L) is the cardinality of L.
Count is a SPARQL set function which counts the number of times a given expression
has a bound, non-error value within the aggregate group.
Definition: Count
xsd:integer Count(sequence S)
Count(S) = Card(L'),
where L' is the list L = Flatten(S)
with all error elements removed.
Sum is a SPARQL set function that returns the numeric value obtained by summing
the values within the aggregate group. Type promotion happens as per the op:numeric-add
function, applied transitively, (see definition below) so the value of SUM(?x), in an
aggregate group where ?x has values 1 (integer), 2.0e0 (float), and 3.0 (decimal) will
be 6.0 (float).
Definition: Sum
numeric Sum(sequence S)
Sum(S) = SumList(L),
where L = Flatten(S) and
SumList(L) is defined recursively as follows.
Note that L1 is the first element in
L, and L2..n is L
without its first element.
In this way, Sum( [(1), (2), (3)] ) = SumList( (1, 2, 3) ) =
op:numeric-add(1, op:numeric-add(2, op:numeric-add(3, 0))).
The Avg set function calculates the
average value for an expression over a group. It is defined in terms of Sum and Count.
Definition: Avg
numeric Avg(sequence S)
If Count(S) = 0,
then Avg(S) = "0"^^xsd:integer.
If Count(S) > 0,
then Avg(S) =
Sum(S) /
Count(S).
For example, Avg([(1), (2), (3)]) =
Sum([(1), (2), (3)])/Count([(1), (2), (3)])
= 6/3 = 2.
Min is a SPARQL set function that returns the minimum value from a group
respectively.
It makes use of the SPARQL ORDER BY ordering definition, to allow ordering over
arbitrarily typed expressions.
Definition: Min
term Min(sequence S)
Min(S) = MinList(L),
where L is the list of values obtained by
Flatten(S)
and then ordered as per the ORDER BY ASC clause,
and MinList(L) is defined as follows.
- If Card(L) = 0, then
MinList(L) = error.
- If Card(L) > 0, then
MinList(L) = L1,
where L1 is the first element in
L.
Max is a SPARQL set function that returns the maximum value from a group
respectively.
It makes use of the SPARQL ORDER BY ordering definition, to allow ordering over
arbitrarily typed expressions.
Definition: Max
term Max(sequence S)
Max(S) = MaxList(L),
where L is the list of values obtained by
Flatten(S)
and then ordered as per the ORDER BY DESC clause,
and MaxList(L) is defined as follows.
- If Card(L) = 0, then
MaxList(L) = error.
- If Card(L) > 0, then
MaxList(L) = L1,
where L1 is the first element in
L.
GroupConcat is a set function which performs a string concatenation across the
values of an expression with a group. The order of the strings is not specified. The
separator character used in the concatenation may be given with the scalar argument
SEPARATOR.
Definition: GroupConcat
literal GroupConcat(sequence S, function scalarvals)
If the scalarvals argument is absent from GROUP_CONCAT,
then scalarvals is taken to be the empty function.
Let sep be a string that is defined as follows.
- If scalarvals is defined for the argument "separator",
then sep = scalarvals("separator").
- If scalarvals is undefined for the argument "separator",
then sep is the "space" character (i.e., unicode codepoint U+0020).
GroupConcat(S, scalarvals) =
GCList(L, sep),
where L = Flatten(S)
and GCList(L, sep)
is defined recursively as follows.
- If Card(L) = 0, then
GCList(L, sep) = "".
- If Card(L) = 1, then
GCList(L, sep) =
CONCAT("", L1).
- If Card(L) > 1, then
GCList(L, sep) =
CONCAT(L1, sep, GCList(L2..n, sep)).
Note that L1 is the first element in
L, and L2..n is L
without its first element.
For example, GroupConcat([("a"), ("b"), ("c")], {"separator" → "."})
= GCList( ("a", "b", "c"), "." )
= "a.b.c".
Sample is a set function which returns an arbitrary value from the sequence passed
to it.
Definition: Sample
RDFTerm Sample(sequence S)
If Card(S) = 0, then
Sample(S) = error.
If Card(S) > 0, then
Sample(S) = v, where v
in Flatten(S).
For example, given Sample([("a"), ("b"), ("c")]), "a", "b", and "c" are all valid return
values. Note that the Sample function is not required to be deterministic for a given input. The
only restriction is that the output value must be present in the input sequence.
We define eval(D(G), algebra expression) as the evaluation of an algebra expression with
respect to a dataset D having active graph G. The active graph is initially the default
graph.
D : a dataset
D(G) : D a dataset with active graph G (the one patterns match against)
D[i] : The graph with IRI i in dataset D
P, P1, P2 : graph patterns
L : a solution sequence
F : an expression
Definition: Evaluation of a Basic Graph Pattern
eval(D(G), BGP) = multiset of solution mappings
See section Basic Graph Patterns
Definition: Evaluation of a Property Path Pattern
eval(D(G), Path(X, path, Y)) = multiset of solution mappings
See section Property Path Expresions
Definition: Evaluation of Filter
eval(D(G), Filter(F, P)) = Filter(F, eval(D(G),P), D(G))
'substitute' is a filter function in support of the evaluation of
EXISTS
and NOT EXISTS forms which were translated to exists.
Definition: Substitute
Let μ be a solution mapping.
substitute(pattern, μ) = the pattern formed by replacing every occurrence of
a variable v in pattern by μ(v) for each v in dom(μ)
Definition: Evaluation of Exists
Let μ be the current solution mapping for a filter and P a graph pattern:
The value exists(P), given D(G) is true if and only if eval(D(G), substitute(P, μ)) is
a non-empty sequence.
Definition: Evaluation of Join
eval(D(G), Join(P1, P2)) = Join(eval(D(G), P1), eval(D(G), P2))
Definition: Evaluation of LeftJoin
eval(D(G), LeftJoin(P1, P2, F)) = LeftJoin(eval(D(G), P1), eval(D(G), P2), F)
Definition: Evaluation of Union
eval(D(G), Union(P1,P2)) = Union(eval(D(G), P1), eval(D(G), P2))
Definition: Evaluation of Graph
if IRI is a graph name in D
eval(D(G), Graph(IRI,P)) = eval(D(D[IRI]), P)
if IRI is not a graph name in D
eval(D(G), Graph(IRI,P)) = the empty multiset
eval(D(G), Graph(var,P)) =
Let R be the empty multiset
foreach IRI i in D
R := Union(R, Join( eval(D(D[i]), P) , Ω(?var->i) ) )
the result is R
The evaluation of graph uses the SPARQL algebra union operator. The multiplicity of a
solution mapping is the sum of the multiplicities of that solution mapping in each join
operation.
Definition: Evaluation of Group
eval(D(G), Group(exprlist, P)) = Group(exprlist, eval(D(G), P))
Definition: Evaluation of Aggregation
eval(D(G), Aggregation(exprlist, func, scalarvals, Grp)) = Aggregation(exprlist, func,
scalarvals, eval(D(G), Grp))
Definition: Evaluation of AggregateJoin
eval(D(G), AggregateJoin(A1, ..., An)) =
AggregateJoin(eval(D(G), A1), ..., eval(D(G), An))
Note that if eval(D(G), Ai) is an error, it is ignored.
Definition: Evaluation of Extend
eval(D(G), Extend(P, var, expr)) = Extend(eval(D(G), P), var, expr)
Definition: Evaluation of ToList
eval(D(G), ToList(P)) = ToList(eval(D(G), P))
Definition: Evaluation of Distinct
eval(D(G), Distinct(L)) = Distinct(eval(D(G), L))
Definition: Evaluation of Reduced
eval(D(G), Reduced(L)) = Reduced(eval(D(G), L))
Definition: Evaluation of Project
eval(D(G), Project(L, vars)) = Project(eval(D(G), L), vars)
Definition: Evaluation of OrderBy
eval(D(G), OrderBy(L, condition)) = OrderBy(eval(D(G), L), condition)
Definition: Evaluation of ToMultiSet
eval(D(G), ToMultiSet(L)) = ToMultiSet(eval(D), M))
Definition: Evaluation of Slice
eval(D(G), Slice(L, start, length)) = Slice(eval(D(G), L), start, length)
The overall SPARQL design can be used for queries which assume a more elaborate form of
entailment than simple entailment, by re-writing the matching conditions for basic graph
patterns. Since it is an open research problem to state such conditions in a single general
form which applies to all forms of entailment and optimally eliminates needless or
inappropriate redundancy, this document only gives necessary conditions which any such
solution should satisfy. These will need to be extended to full definitions for each
particular case.
Basic graph patterns stand in the same relation to triple patterns that RDF graphs do to
RDF triples, and much of the same terminology can be applied to them. In particular, two
basic graph patterns are said to be equivalent if there is a bijection M between the
terms of the triple patterns that maps blank nodes to blank nodes and maps variables,
literals and IRIs to themselves, such that a triple ( s, p, o ) is in the first pattern if
and only if the triple ( M(s), M(p), M(o) ) is in the second. This definition extends that
for RDF graph equivalence to basic graph patterns by preserving variable names across
equivalent patterns.
An entailment regime specifies
- a subset of RDF graphs called well-formed for the regime
- an entailment relation between subsets of well-formed graphs and well-formed
graphs.
Detailed definitions for querying various entailment regimes can be found in
SPARQL 1.1 Entailment Regimes.
Some entailment regimes can categorize some RDF graphs as inconsistent. For example, the
RDF graph:
_:x rdf:type xsd:string .
_:x rdf:type xsd:decimal .
is D-inconsistent when D contains the XSD datatypes. The effect of a query on an
inconsistent graph is not covered by this specification, but must be specified by the
particular SPARQL extension.
An entailment regime E must provide conditions on basic graph pattern evaluation such
that for any basic graph pattern BGP, any RDF graph G, and any evaluation that satisfies
the conditions, the resulting multiset of solutions is uniquely determined up to RDF graph
equivalence. We denote the multiset of solutions from evaluating BGP over G using E with
Eval-E(G, BGP).
An entailment regime must further satisfy the following conditions:
- For any E-consistent active graph AG, the entailment regime E uniquely specifies a
scoping graph SG that is E-equivalent to AG.
- A set of well-formed graphs for E is specified such that, for any basic graph pattern
BGP, scoping graph SG, and solution mapping μ in Eval-E(SG, BGP), the graph μ(BGP) is
well-formed for E.
- For any basic graph pattern BGP and scoping graph SG, if μ1, ...,
μn in Eval-E(SG, BGP) and BGP1, ..., BGPn are basic
graph patterns all equivalent to BGP but not sharing any blank nodes with each other or
with SG, then
SG E-entails (SG union μ1(BGP1) union ... union
μn(BGPn))
These conditions do not fully determine the set of possible answers, since RDF
allows unlimited amounts of redundancy. In addition, therefore, the following must
hold.
- Entailment regimes should provide conditions to prevent trivial infinite solution
multisets as appropriate to the regime.
(a) SG will often be graph equivalent to AG, but restricting this to E-equivalence
allows some forms of normalization, for example elimination of semantic redundancies, to
be applied to the source documents before querying.
(b) The construction in condition 3 ensures that any blank nodes introduced by the
solution mapping are used in a way which is internally consistent with the way that blank
nodes occur in SG. This ensures that blank node identifiers occur in more than one answer
in an answer set only when the blank nodes so identified are indeed identical in SG. If
the extension does not allow bindings to blank nodes, then this condition can be
simplified to the condition:
SG E-entails μ(BGP) for each solution mapping μ.
(c) These conditions do not impose the SPARQL requirement that SG shares no blank
nodes with AG or BGP. In particular, it allows SG to actually be AG. This allows query
protocols in which blank node identifiers retain their meaning between the query and the
source document, or across multiple queries. Such protocols are not supported by the
current SPARQL protocol specification, however.
(d) Since conditions 1 to 3 are only necessary conditions on answers, condition 4
allows cases where the set of legal answers can be restricted in various ways.
(e) None of these conditions refer explicitly to instance mappings on blank nodes in
BGP. For some entailment regimes, the existential interpretation of blank nodes cannot be
fully captured by the existence of a single instance mapping. These conditions allow such
regimes to give blank nodes in query patterns a 'fully existential' reading.
It is straightforward to show that SPARQL satisfies these conditions for the case
where E is simple entailment, given that the SPARQL condition on SG is that it is
graph-equivalent to AG but shares no blank nodes with AG or BGP (which satisfies the
first condition). The only condition which is nontrivial is (3).
For every solution mapping μi, there is, by definition of basic graph
pattern matching, an RDF instance mapping σi such that
Pi(BGPi) is a subgraph of SG where Pi is the pattern
instance mapping composed of μi and σi. Since BGPi and
SG have no blank nodes in common, the ranges of σi and μi contain
no blank nodes from BGPi; therefore, the solution mapping μi and
the RDF instance mapping σi of Pi commute, so
Pi(BGPi) = σi(μi(BGPi)). So
P1(BGP1) union ... union Pn(BGPn)
= σ1(μ1(BGP1)) union ... union
σn(μn(BGPn))
= [ σ1 + ... + σn]( μ1(BGP1) union ... union
μn(BGPn) )
since the domains of the σi RDF instance mappings are all mutually
exclusive. Since they are also exclusive from SG,
SG union [ σ1 + ... + σn]( μ1(BGP1) union
... union μn(BGPn) )
= [ σ1 + ... + σn](SG union μ1(BGP1) union
... union μn(BGPn) )
i.e.
SG union μ1(BGP1) union ... union
μn(BGPn)
has an instance which is a subgraph of SG, so is simply entailed by SG by the
RDF interpolation lemma [RDF12-SEMANTICS].