Yaidom is yet another Scala immutable DOM-like XML API.
Yaidom is yet another Scala immutable DOM-like XML API. The best known Scala immutable DOM-like API is the standard scala.xml API. It:
Yaidom takes a different approach, avoiding XPath-like query support in its query API, and offering good namespace and decent (functional) update support. Yaidom is also characterized by almost mathematical precision and clarity. Still, the API remains practical and pragmatic. In particular, the API user has much configuration control over parsing and serialization, because yaidom exposes the underlying JAXP parsers and serializers, which can be configured by the library user.
Yaidom chooses its battles. For example, given that DTDs do not know about namespaces, yaidom offers good namespace support, but ignores DTDs entirely. Of course the underlying XML parser may still validate XML against a DTD, if so desired. As another example, yaidom tries to leave the handling of the gory details of XML processing (such as whitespace handling) as much as possible to JAXP (and JAXP parser/serializer configuration). As yet another example, yaidom knows nothing about (XML Schema) types of elements and attributes.
As mentioned above, yaidom tries to treat basic XML processing with almost mathematical precision, even if this is "incorrect". At the same time, yaidom tries to be useful in practice. For example, yaidom compromises "correctness" in the following ways:
Yaidom, and in particular the eu.cdevreeze.yaidom.core, eu.cdevreeze.yaidom.queryapi, eu.cdevreeze.yaidom.resolved and eu.cdevreeze.yaidom.simple sub-packages, contains the following layers:
core package)queryapi package)resolved and simple packages)It makes sense to read this documentation, because it helps in getting up-to-speed with yaidom.
In real world XML, elements (and sometimes attributes) tend to have names within a certain namespace. There are 2 kinds of names at play here:
book:Title, and unprefixed names, such as Edition{http://bookstore/book}Title (in James Clark notation),
and not having a namespace, such as EditionThey are represented by immutable classes eu.cdevreeze.yaidom.core.QName and eu.cdevreeze.yaidom.core.EName, respectively.
Qualified names occur in XML, whereas expanded names do not. Yet qualified names have no meaning on their own. They need to be resolved to expanded names, via the in-scope namespaces. Note that the term "qualified name" is often used for what yaidom (and the Namespaces specification) calls "expanded name", and that most XML APIs do not distinguish between the 2 kinds of names. Yaidom has to clearly make this distinction, in order to model namespaces correctly.
To resolve qualified names to expanded names, yaidom distinguishes between:
They are represented by immutable classes eu.cdevreeze.yaidom.core.Declarations and eu.cdevreeze.yaidom.core.Scope, respectively.
Namespace declarations occur in XML, whereas in-scope namespaces do not. The latter are the accumulated effect of the namespace declarations of the element itself, if any, and those in ancestor elements.
Note: in the code examples below, we assume the following import:
import eu.cdevreeze.yaidom.core._To see the resolution of qualified names in action, consider the following sample XML:
<book:Bookstore xmlns:book="http://bookstore/book" xmlns:auth="http://bookstore/author"> <book:Book ISBN="978-0321356680" Price="35" Edition="2"> <book:Title>Effective Java (2nd Edition)</book:Title> <book:Authors> <auth:Author> <auth:First_Name>Joshua</auth:First_Name> <auth:Last_Name>Bloch</auth:Last_Name> </auth:Author> </book:Authors> </book:Book> <book:Book ISBN="978-0981531649" Price="35" Edition="2"> <book:Title>Programming in Scala: A Comprehensive Step-by-Step Guide, 2nd Edition</book:Title> <book:Authors> <auth:Author> <auth:First_Name>Martin</auth:First_Name> <auth:Last_Name>Odersky</auth:Last_Name> </auth:Author> <auth:Author> <auth:First_Name>Lex</auth:First_Name> <auth:Last_Name>Spoon</auth:Last_Name> </auth:Author> <auth:Author> <auth:First_Name>Bill</auth:First_Name> <auth:Last_Name>Venners</auth:Last_Name> </auth:Author> </book:Authors> </book:Book> </book:Bookstore>
Consider the last element with qualified name QName("book:Book"). To resolve this qualified name as expanded name, we need to
know the namespaces in scope at that element. To compute the in-scope namespaces, we need to accumulate the namespace
declarations of the last book:Book element and of its ancestor element(s), starting with the root element.
The start Scope is "parent scope" Scope.Empty. Then, in the root element we find namespace declarations:
Declarations.from("book" -> "http://bookstore/book", "auth" -> "http://bookstore/author")
This leads to the following namespaces in scope at the root element:
Scope.Empty.resolve(Declarations.from("book" -> "http://bookstore/book", "auth" -> "http://bookstore/author"))
which is equal to:
Scope.from("book" -> "http://bookstore/book", "auth" -> "http://bookstore/author")
We find no other namespace declarations in the last book:Book element or its ancestor(s), so the computed scope is also the scope
of the last book:Book element.
Then QName("book:Book") is resolved as follows:
Scope.from("book" -> "http://bookstore/book", "auth" -> "http://bookstore/author").resolveQNameOption(QName("book:Book"))
which is equal to:
Some(EName("{http://bookstore/book}Book"))
This namespace support in yaidom has mathematical rigor. The immutable classes QName, EName, Declarations and Scope have
precise definitions, reflected in their implementations, and they obey some interesting properties. For example, if we correctly
define Scope operation relativize (along with resolve), we get:
scope1.resolve(scope1.relativize(scope2)) == scope2
This may not sound like much, but by getting the basics right, yaidom succeeds in offering first-class support for XML namespaces, without the magic and namespace-related bugs often found in other XML libraries.
There are 2 other basic concepts in this package, representing paths to elements:
They are represented by immutable classes eu.cdevreeze.yaidom.core.PathBuilder and eu.cdevreeze.yaidom.core.Path, respectively.
Path builders are like canonical XPath expressions, yet they do not contain the root element itself, and indexing starts with 0 instead of 1.
For example, the last name of the first author of the last book element has path:
Path.from( EName("{http://bookstore/book}Book") -> 1, EName("{http://bookstore/book}Authors") -> 0, EName("{http://bookstore/author}Author") -> 0, EName("{http://bookstore/author}Last_Name") -> 0 )
This path could be written as path builder as follows:
PathBuilder.from(QName("book:Book") -> 1, QName("book:Authors") -> 0, QName("auth:Author") -> 0, QName("auth:Last_Name") -> 0)
Using the Scope mentioned earlier, the latter path builder resolves to the path given before that, by
invoking method PathBuilder.build(scope). In order for this to work, the Scope must be invertible. That is,
there must be a one-to-one correspondence between prefixes ("" for the default namespace) and namespace URIs, because
otherwise the index numbers may differ. Also note that the prefixes book and auth in the path builder are
arbitrary, and need not match with the prefixes used in the XML tree itself.
Yaidom provides a relatively small query API, to query an individual element for collections of child elements, descendant elements or descendant-or-self elements. The resulting collections are immutable Scala collections, that can further be manipulated using the Scala Collections API.
This query API is uniform, in that different element implementations share (most of) the same query API. It is also element-centric (unlike standard Scala XML).
For example, consider the XML example given earlier, as a Scala XML literal named bookstore. We can wrap this Scala
XML Elem into a yaidom wrapper of type ScalaXmlElem, named bookstoreElem. Then we can query
for all books, that is, all descendant-or-self elements with resolved (or expanded) name EName("{http://bookstore/book}Book"),
as follows:
bookstoreElem filterElemsOrSelf (elem => elem.resolvedName == EName("{http://bookstore/book}Book"))
The result would be an immutable IndexedSeq of ScalaXmlElem instances, holding 2 book elements.
We could instead have written:
bookstoreElem.filterElemsOrSelf(EName("{http://bookstore/book}Book"))with the same result, due to an implicit conversion from expanded names to element predicates.
Instead of searching for appropriate descendant-or-self elements, we could have searched for descendant elements only, without altering the result in this case:
bookstoreElem filterElems (elem => elem.resolvedName == EName("{http://bookstore/book}Book"))
or:
bookstoreElem.filterElems(EName("{http://bookstore/book}Book"))We could even have searched for appropriate child elements only, without altering the result in this case:
bookstoreElem filterChildElems (elem => elem.resolvedName == EName("{http://bookstore/book}Book"))
or:
bookstoreElem.filterChildElems(EName("{http://bookstore/book}Book"))or, knowing that all child elements are books:
bookstoreElem.findAllChildElems
We could find all authors of the Scala book as follows:
for { bookElem <- bookstoreElem filterChildElems (elem => elem.resolvedName == EName("{http://bookstore/book}Book")) if bookElem.attributeOption(EName("ISBN")).contains("978-0981531649") authorElem <- bookElem filterElems (elem => elem.resolvedName == EName("{http://bookstore/author}Author")) } yield authorElem
or:
for { bookElem <- bookstoreElem.filterChildElems(EName("{http://bookstore/book}Book")) if bookElem.attributeOption(EName("ISBN")).contains("978-0981531649") authorElem <- bookElem.filterElems(EName("{http://bookstore/author}Author")) } yield authorElem
We could even use operator notation, as follows:
for { bookElem <- bookstoreElem \ (elem => elem.resolvedName == EName("{http://bookstore/book}Book")) if (bookElem \@ EName("ISBN")).contains("978-0981531649") authorElem <- bookElem \\ (elem => elem.resolvedName == EName("{http://bookstore/author}Author")) } yield authorElem
or:
for { bookElem <- bookstoreElem \ EName("{http://bookstore/book}Book") if (bookElem \@ EName("ISBN")).contains("978-0981531649") authorElem <- bookElem \\ EName("{http://bookstore/author}Author") } yield authorElem
where \\ stands for filterElemsOrSelf.
There is no explicit support for filtering on the "self" element itself. In the example above, we might want to check if the root element has the expected EName, for instance. That is easy to express using a simple idiom, however. The last example then becomes:
for { bookstoreElem <- Vector(bookstoreElem) if bookstoreElem.resolvedName == EName("{http://bookstore/book}Bookstore") bookElem <- bookstoreElem \ EName("{http://bookstore/book}Book") if (bookElem \@ EName("ISBN")).contains("978-0981531649") authorElem <- bookElem \\ EName("{http://bookstore/author}Author") } yield authorElem
Now suppose the same XML is stored in a (org.w3c.dom) DOM tree, wrapped in a DomElem bookstoreElem.
Then the same queries would use exactly the same code as above! The result would be a collection of DomElem instances
instead of ScalaXmlElem instances, however. There are many more element implementations in yaidom, and they share
(most of) the same query API. Therefore this query API is called a uniform query API.
The last example, using operator notation, looks a bit more "XPath-like". It is more verbose than queries in Scala XML, however, partly because in yaidom these operators cannot be chained. Yet this is with good reason. Yaidom does not blur the distinction between elements and element collections, and therefore does not offer any XPath experience. The small price paid in verbosity is made up for by precision. The yaidom query API traits have very precise definitions of their operations, as can be seen in the corresponding documentation.
The uniform query API traits turn minimal APIs into richer APIs, where each richer API is defined very precisely in terms
of the minimal API. The most important (partly concrete) query API trait is eu.cdevreeze.yaidom.queryapi.ElemLike. It needs to be given
a method implementation to query for child elements (not child nodes in general, but just child elements!), and it offers methods to query
for some or all child elements, descendant elements, and descendant-or-self elements. That is, the minimal API consists
of abstract method findAllChildElems, and it offers methods such as filterChildElems, filterElems and filterElemsOrSelf.
This trait has no knowledge about elements at all, other than the fact that elements can have child elements.
Trait eu.cdevreeze.yaidom.queryapi.HasEName needs minimal knowledge about elements themselves, viz. that elements have a
"resolved" (or expanded) name, and "resolved" attributes (mapping attribute expanded names to attribute values). That is,
it needs to be given implementations of abstract methods resolvedName and resolvedAttributes, and then offers methods to
query for individual attributes or the local name of the element.
It is important to note that yaidom does not consider namespace declarations to be attributes themselves. Otherwise, there would have been circular dependencies between both concepts, because attributes with namespaces require in-scope namespaces and therefore namespace declarations for resolving the names of these attributes.
Many traits, such as eu.cdevreeze.yaidom.queryapi.HasEName, are just "capabilities", and need to be combined with trait eu.cdevreeze.yaidom.queryapi.ElemLike in order to offer a useful element querying API.
Note that trait eu.cdevreeze.yaidom.queryapi.ElemLike only knows about elements, not about other kinds of nodes.
Of course the actual element implementations mixing in this query API know about other node types, but that knowledge is outside
the uniform query API. Note that the example queries above only use the minimal element knowledge that traits ElemLike and HasEName
together have about elements. Therefore the query code can be used unchanged for different element implementations.
Trait eu.cdevreeze.yaidom.queryapi.IsNavigable is used to navigate to an element given a Path.
Trait eu.cdevreeze.yaidom.queryapi.UpdatableElemLike (which extends trait IsNavigable) offers functional updates
at given paths. Whereas the traits mentioned above know only about elements, this trait knows that elements have some node
super-type.
Instead of functional updates at given paths, elements can also be "transformed" functionally without specifying any paths. This is offered by trait eu.cdevreeze.yaidom.queryapi.TransformableElemLike. The Scala XML and DOM wrappers above do not mix in this trait.
Above, several individual query API traits were mentioned. There are, however, 3 query API levels which are interesting for those who extend yaidom with new element implementations, but also for most users of the yaidom query API. These levels are represented by "combination traits" that combine several of the query API traits mentioned (or not mentioned) above.
The most basic level is eu.cdevreeze.yaidom.queryapi.ClarkNodes.Elem. It combines traits such as
eu.cdevreeze.yaidom.queryapi.ElemApi and eu.cdevreeze.yaidom.queryapi.HasENameApi. Object
eu.cdevreeze.yaidom.queryapi.ClarkNodes also contains types for non-element nodes. All element
implementations that extend trait ClarkNodes.Elem should have a node hierarchy with all its kinds of
nodes extending the appropriate ClarkNodes member type.
All element implementation directly or indirectly implement the ClarkNodes.Elem trait. The part of
the yaidom query API that knows about ElemApi querying and about ENames is the ClarkNodes query
API level. It does not know about QNames, in-scope namespaces, ancestor elements, base URIs, etc.
The next level is eu.cdevreeze.yaidom.queryapi.ScopedNodes.Elem. It extends the ClarkNodes.Elem
trait, but offers knowledge about QNames and in-scope namespaces as well. Many element implementations
offer at least this query API level. The remarks about non-element nodes above also apply here, and apply below.
The third level is eu.cdevreeze.yaidom.queryapi.BackingNodes.Elem. It extends the ScopedNodes.Elem
trait, but offers knowledge about ancestor elements and document/base URIs as well. This is the level
typically used for "backing elements" in "yaidom dialects", thus allowing for multiple "XML backends"
to be used behind "yaidom dialects". Yaidom dialects are specific "XML dialect" type-safe yaidom query APIs,
mixing in and leveraging trait eu.cdevreeze.yaidom.queryapi.SubtypeAwareElemApi (often in combination
with eu.cdevreeze.yaidom.queryapi.ScopedNodes.Elem).
To get to know the yaidom query API and its 3 levels, it pays off to study the API documentation of traits eu.cdevreeze.yaidom.queryapi.ClarkNodes.Elem, eu.cdevreeze.yaidom.queryapi.ScopedNodes.Elem and eu.cdevreeze.yaidom.queryapi.BackingNodes.Elem.
In package simple there are 2 immutable element implementations, eu.cdevreeze.yaidom.simple.ElemBuilder
and eu.cdevreeze.yaidom.simple.Elem. Arguably, ElemBuilder is not an element implementation. Indeed,
it does not even offer the ClarkNodes.Elem query API.
Class eu.cdevreeze.yaidom.simple.Elem is the default element implementation of yaidom. It extends class eu.cdevreeze.yaidom.simple.Node.
The latter also has sub-classes for text nodes, comments, entity references and processing instructions. Class eu.cdevreeze.yaidom.simple.Document
contains a document Elem, but is not a Node sub-class itself. This node hierarchy offers the ScopedNodes query API,
so simple elements offer the ScopedNodes.Elem query API.
The eu.cdevreeze.yaidom.simple.Elem class has the following characteristics:
Scope, but no Declarationsparse and print offer DocumentParser and DocumentPrinter classes for parsing/serializing these default
Elem (and Document) instancesCreating such Elem trees by hand is a bit cumbersome, partly because scopes have to be passed to each Elem in the tree.
The latter is not needed if we use class eu.cdevreeze.yaidom.simple.ElemBuilder to create element trees by hand. When the tree
has been fully created as ElemBuilder, invoke method ElemBuilder.build(parentScope) to turn it into an Elem.
Like their super-classes Node and NodeBuilder, classes Elem and ElemBuilder have very much in common. Both are immutable,
easy to compose (ElemBuilder instances even more so), equality is reference equality, etc. The most important differences
are as follows:
Scope, an ElemBuilder contains a DeclarationsElemBuilder easier to compose than an Elem, because no Scope needs to be passed around throughout the treeElemBuilder uses a minimal query API, mixing in almost only traits ElemLike and TransformableElemLikeElemBuilder neither keeps nor knows about Scopes, so does not know about resolved element/attribute namesThe Effective Java book element in the XML example above could have been written as ElemBuilder (without the inter-element whitespace) as follows:
import NodeBuilder._ elem( qname = QName("book:Book"), attributes = Vector(QName("ISBN") -> "978-0321356680", QName("Price") -> "35", QName("Edition") -> "2"), children = Vector( elem( qname = QName("book:Title"), children = Vector( text("Effective Java (2nd Edition)") ) ), elem( qname = QName("book:Authors"), children = Vector( elem( qname = QName("auth:Author"), children = Vector( elem( qname = QName("auth:First_Name"), children = Vector( text("Joshua") ) ), elem( qname = QName("auth:Last_Name"), children = Vector( text("Bloch") ) ) ) ) ) ) ) )
This ElemBuilder (say, eb) lacks namespace declarations for prefixes book and auth. So, the following returns false:
eb.canBuild(Scope.Empty)
while the following returns true:
eb.canBuild(Scope.from("book" -> "http://bookstore/book", "auth" -> "http://bookstore/author"))
Indeed,
eb.build(Scope.from("book" -> "http://bookstore/book", "auth" -> "http://bookstore/author"))
returns the element tree as Elem.
Note that the distinction between ElemBuilder and Elem "solves" the mismatch that immutable ("functional") element trees are
constructed in a bottom-up manner, while namespace scoping works in a top-down manner. (See also Anti-XML issue 78, in
https://github.com/djspiewak/anti-xml/issues/78).
There are many more element implementations in yaidom, most of them in sub-packages of this package. Yaidom is extensible in that new element implementations can be invented, for example elements that are better "roundtrippable" (at the expense of "composability"), or yaidom wrappers around other DOM-like APIs (such as XOM or JDOM2). The current element implementations in yaidom are for example:
Elem by hand. See above.ClarkNodes.Elem query API (as well as
update/transformation support).BackingNodes.Elem query API, so knows its ancestry, despite being immutable! This element implementation
is handy for querying XML schemas, for example, because in schemas the ancestry of queried elements typically matters.One yaidom wrapper that is very useful is a Saxon tiny tree yaidom wrapper, namely SaxonElem (JVM-only).
Like "indexed elements", it offers all of the BackingNodes.Elem query API. This element implementation is very efficient,
especially in memory footprint (when using the default tree model, namely tiny trees). It is therefore the most attractive element
implementation to use in "enterprise" production code, but only on the JVM. In combination with Saxon-EE (instead of Saxon-HE) the underlying
Saxon NodeInfo objects can even carry interesting type information.
For ad-hoc element creation, consider using "resolved" elements. They are easy to create, because there is no need to worry about
namespace prefixes. Once created, they can be converted to "simple" elements, given an appropriate Scope (without default namespace).
Yaidom has the following packages, and layering between packages (mentioning the lowest layers first):
core package.core and
queryapi packages.core and queryapi
packages.core, queryapi and simple
packages.convert. It contains conversions between default yaidom nodes on the one hand and DOM,
Scala XML, etc. on the other hand. The convert package depends on the yaidom core, queryapi, resolved and simple packages.eu.cdevreeze.yaidom.saxon, with the Saxon wrapper element implementation described above. It only depends on the core, queryapi
and convert packages.eu.cdevreeze.yaidom.parse and eu.cdevreeze.yaidom.print, for parsing/printing Elems. They depend on
the packages mentioned above, except for indexed and saxon.utils), such as dom and scalaxml. They depend on (some of) the packages mentioned above,
but not on each other.Indeed, all yaidom package dependencies are uni-directional.
Yaidom can be quite memory-hungry. One particular cause of that is the possible creation of very many duplicate EName and QName instances. This can be the case while parsing XML into yaidom documents, or while querying yaidom element trees.
The user of the library can reduce memory consumption to a large extent, and yaidom facilitates that.
As for querying, prefer:
import HasENameApi._ bookstoreElem filterElemsOrSelf withEName("http://bookstore/book", "Book")
to:
bookstoreElem.filterElemsOrSelf(EName("http://bookstore/book", "Book"))
to avoid unnecessary (large scale) EName object creation.
To reduce the memory footprint of parsed XML trees, see eu.cdevreeze.yaidom.core.ENameProvider and eu.cdevreeze.yaidom.core.QNameProvider.
For example, during the startup phase of an application, we could set the global ENameProvider as follows:
ENameProvider.globalENameProvider.become(new ENameProvider.ENameProviderUsingImmutableCache(knownENames))Note that the global ENameProvider or QNameProvider can typically be configured rather late during development, but the memory cost savings can be substantial once configured. Also note that the global ENameProvider or QNameProvider can be used implicitly in application code, by writing:
bookstoreElem filterElemsOrSelf getEName("http://bookstore/book", "Book")
using an implicit ENameProvider, whose members are in scope. Still, for querying the first alternative using withEName is
better, but there are likely many scenarios in yaidom client code where an implicit ENameProvider or QNameProvider makes sense.
The bottom line is that yaidom can be configured to be far less memory-hungry, and that yaidom client code can also take some responsibility in reducing memory usage. Again, the Saxon wrapper implementation is an excellent and efficient choice (but only on the JVM).