Crates.io | iref |
lib.rs | iref |
version | 3.2.2 |
source | src |
created_at | 2020-03-16 15:06:48.496627 |
updated_at | 2024-07-25 15:01:38.552384 |
description | Uniform & Internationalized Resource Identifiers (URIs/IRIs), borrowed and owned. |
homepage | |
repository | https://github.com/timothee-haudebourg/iref |
max_upload_size | |
id | 219492 |
size | 53,467 |
This crates provides an implementation of Uniform Resource Identifiers (URIs, aka URLs) and Internationalized Resource Identifiers (IRIs) following RFC 3987 and RFC 3986 defined by the Internet Engineering Task Force (IETF) to uniquely identify objects across the web. IRIs are a superclass of URIs accepting international characters defined in the Unicode table.
URI/IRIs are defined as a sequence of characters with distinguishable components: a scheme, an authority, a path, a query and a fragment.
foo://example.com:8042/over/there?name=ferret#nose
\_/ \______________/\_________/ \_________/ \__/
| | | | |
scheme authority path query fragment
This crate provides types to represent borrowed and owned URIs and IRIs
(Uri
, Iri
, UriBuf
, IriBuf
), borrowed and owned URIs and IRIs
references (UriRef
, IriRef
, UriRefBuf
, IriRefBuf
) and similar
types for every part of an URI/IRI. Theses allows the easy access and
manipulation of every components.
It features:
static-iref
crate and its iri
macro; andserde
support (by enabling the serde
feature).You can parse IRI strings by wrapping an Iri
instance around a str
slice.
Note that no memory allocation occurs using Iri
, it only borrows the input data.
Access to each component is done in constant time.
use iref::Iri;
let iri = Iri::new("https://www.rust-lang.org/foo/bar?query#frag")?;
println!("scheme: {}", iri.scheme());
println!("authority: {}", iri.authority().unwrap());
println!("path: {}", iri.path());
println!("query: {}", iri.query().unwrap());
println!("fragment: {}", iri.fragment().unwrap());
IRIs can be created and modified using the IriBuf
type.
With this type, the IRI is held in a single buffer,
modified in-place to reduce memory allocation and optimize memory accesses.
This also allows the conversion from IriBuf
into Iri
.
use iref::IriBuf;
let mut iri = IriBuf::new("https://www.rust-lang.org".to_string())?;
iri.authority_mut().unwrap().set_port(Some("40".try_into()?));
iri.set_path("/foo".try_into()?);
iri.path_mut().push("bar".try_into()?);
iri.set_query(Some("query".try_into()?));
iri.set_fragment(Some("fragment".try_into()?));
assert_eq!(iri, "https://www.rust-lang.org:40/foo/bar?query#fragment");
The try_into
method is used to ensure that each string is syntactically correct with regard to its corresponding component (for instance, it is not possible to replace "query"
with "query?"
since ?
is not a valid query character).
The IRI path is accessed through the path
or path_mut
methods.
It is possible to access the segments of a path using the iterator returned by the segments
method.
for segment in iri.path().segments() {
println!("{}", segment);
}
One can use the normalized_segments
method to iterate over the normalized
version of the path where dot segments (.
and ..
) are removed.
In addition, it is possible to push or pop segments to a path using the
corresponding methods:
let mut iri = IriBuf::new("https://rust-lang.org/a/c".to_string())?;
let mut path = iri.path_mut();
path.pop();
path.push("b".try_into()?);
path.push("c".try_into()?);
path.push("".try_into()?); // the empty segment is valid.
assert_eq!(iri.path(), "/a/b/c/");
This crate provides the two types IriRef
and IriRefBuf
to represent
IRI references. An IRI reference is either an IRI or a relative IRI.
Contrarily to regular IRIs, relative IRI references may have no scheme.
let mut iri_ref = IriRefBuf::default(); // an IRI reference can be empty.
// An IRI reference with a scheme is a valid IRI.
iri_ref.set_scheme(Some("https".try_into()?));
let iri: &Iri = iri_ref.as_iri().unwrap();
// An IRI can be safely converted into an IRI reference.
let iri_ref: &IriRef = iri.into();
Given a base IRI, references can be resolved into a regular IRI using the Reference Resolution Algorithm defined in RFC 3986. This crate provides a strict implementation of this algorithm.
let base_iri = Iri::new("http://a/b/c/d;p?q")?;
let mut iri_ref = IriRefBuf::new("g;x=1/../y".to_string())?;
// non mutating resolution.
assert_eq!(iri_ref.resolved(base_iri), "http://a/b/c/y");
// in-place resolution.
iri_ref.resolve(base_iri);
assert_eq!(iri_ref, "http://a/b/c/y");
This crate implements
Errata 4547 about the
abnormal use of dot segments in relative paths.
This means that for instance, the path a/b/../../../
is normalized into
../
.
Here are the features of the IRI comparison method implemented in this crate.
This implementation does not know anything about existing protocols.
For instance, even if the
HTTP protocol
defines 80
as the default port,
the two IRIs http://example.org
and http://example.org:80
are not equivalent.
/
countsThe path /foo/bar
is not equivalent to /foo/bar/
.
Paths are normalized during comparison by removing dot segments (.
and ..
).
This means for instance that the paths a/b/c
and a/../a/./b/../b/c
are
equivalent.
Note however that this crate implements
Errata 4547 about the
abnormal use of dot segments in relative paths.
This means that for instance, the IRI http:a/b/../../../
is equivalent to
http:../
and not http:
.
Thanks to the pct-str
crate,
percent encoded characters are correctly handled.
The two IRIs http://example.org
and http://exa%6dple.org
are equivalent.