This section introduces two ways of using Shapes to Shapes (S2S).
Running the release version of S2S requires Java.
- Download the latest universal release.
- Unzip to chosen location.
curl -L0 "https://github.com/softlang/s2s/releases/latest/download/s2s.zip" --output "s2s.zip" && unzip s2s.zip && cd s2sBuilding S2S from source requires the Scala build tool SBT, as well as Java.
- Install the requirements.
- Clone this repository.
- Run
sbt stage.
git clone "https://github.com/softlang/s2s" && cd s2s && sbt stageRun an example, using the included launcher script (replacing s2s with s2s.bat on Windows):
./s2s docs/ex/paper/q1.sparql docs/ex/paper/S1.shaclPlease also consider reading the full tutorial, which includes more intuitive examples for the method itself. The following examples always refer to simply s2s as an executable; see the quick start section for system specific information. Note: On Windows, you may want to set the active code page to UTF-8 via command chcp 65001, if this is not already your default. This enables correct display of unicode symbols in output generated by s2s.
Basic usage is as follows: s2s [OPTIONS] ... [query-file] [shapes-file?]. Full documentation of the command line interface is accessible with s2s --help. The primary input for S2S is a (SCCQ) SPARQL query (query-file) and an optional set of SHACL input shapes (shapes-file). The query is encoded via a (subset) of standard SPARQL syntax, e.g.:
CONSTRUCT {
?y a :E .
?z a :B .
?y :p ?z
} WHERE {
?w :p ?y .
?x :p ?z .
?y a :B .
?z a :E
}Prefix definitions are allowed. By default, the prefix : is defined (for usage in examples) and bound to a S2S specific IRI. Various standard prefixes (e.g., RDF) are predefined. The default prefix can be redefined via --prefix <prefix>, such that : can be rebound for a required domain, without requiring explicit prefix definitions in each query.
Simple SHACL shapes are encoded as description logic axioms (one per line), where the target is the left-hand-side of a subsumption axiom, and the constraint is on the right-hand-side:
:A ⊑ ∃:p.:B
∃:r.⊤ ⊑ :B
:B ⊑ :E
Alternatively, JSON-LD syntax can be used; the equivalent shape specification to the aforementioned axioms is given below. More examples are available. The syntax is determined by file extension, using .json for JSON-LD and .shacl for formal DL notation. Note, that JSON-LD support is still experimental.
{
"@context": {
"s2s": "https://github.com/softlang/s2s/",
"sh": "http://www.w3.org/ns/shacl#"
},
"@graph": [
{
"@id": "s2s:s1",
"@type": "sh:NodeShape",
"sh:targetClass": {
"@id": "s2s:A"
},
"sh:property": {
"sh:path": {
"@id": "s2s:p"
},
"sh:qualifiedValueShape": {
"sh:class": {
"@id": "s2s:B"
}
},
"sh:qualifiedMinCount": 1
}
},
{
"@id": "s2s:s2",
"@type": "sh:NodeShape",
"sh:targetSubjectsOf": {
"@id": "s2s:r"
},
"sh:class": {
"@id": "s2s:B"
}
},
{
"@id": "s2s:s3",
"@type": "sh:NodeShape",
"sh:targetClass": {
"@id": "s2s:B"
},
"sh:class": {
"@id": "s2s:E"
}
}
]
}Another relevant command-line option is --debug. While by default the program outputs only the result shapes, including the --debug option will print detailed information about the internals of the S2S method, including the input, output, vocabulary, all inferred axioms (annotated with the respective step of the method specification in the paper), as well as all generated candidate shapes.
While the CLI application is useful for interacting with the S2S method, S2S can also be accessed through its internal API. Currently, we lack a full documentation or example application for the API, which will be provided in the future. The main entry point for programmatic access to S2S is org.softlang.s2s.infer.Shapes2Shapes, with an usage example (the CLI itself) being available in org.softlang.s2s.main.S2S. Another minimal usage example is given below, using String encoded inputs for query and shapes. Both constructShapes and constructAxioms can be invoked with formal input as well. To this end, consider org.softlang.s2s.infer.AlgorithmInput.
package org.softlang.s2s.example
import org.softlang.s2s.infer.Shapes2Shapes
/** A minimal example for using the s2s API. */
object Example:
val q: String = """
CONSTRUCT {
?x a :Person .
?y a :Agent
} WHERE {
?x a :Person .
?y a :Agent
}
"""
val s: Set[String] = Set(":Person ⊑ :Agent")
// Instantiate shapes 2 shapes with default configuration.
val s2s = Shapes2Shapes()
// Run with side-effects, i.e., printing the results.
s2s.run(q, s)
// Return the set of output shapes (and a log).
val (shapes, log) = s2s.constructShapes(q, s)
// Return the set of constructed axioms (and a log).
val (axioms, log) = s2s.constructAxioms(q, s)
The tutorial, with additional examples and an intuitive description of the underlying method.
The full paper: Philipp Seifer, Daniel Hernández, Ralf Lämmel, and Steffen Staab. 2024. From Shapes to Shapes: Inferring SHACL Shapes for Results of SPARQL CONSTRUCT Queries. In Proceedings of the ACM Web Conference 2024 (WWW ’24). ACM. 10.1145/3589334.3645550.
@inproceedings{SeiferHLS24,
author = {Philipp Seifer and
Daniel Hern{\'{a}}ndez and
Ralf L{\"{a}}mmel and
Steffen Staab},
title = {From Shapes to Shapes: Inferring SHACL Shapes for Results of SPARQL CONSTRUCT Queries},
booktitle = {Proceedings of the {ACM} Web Conference 2024, ({WWW} '24)},
publisher = {{ACM}},
year = {2024},
doi = {10.1145/3589334.3645550},
}An extended version is available on arXiv. For reference, the git repository is available here.