// Copyright (c) 2020 lumi // Copyright (c) 2020 Emmanuel Gil Peyrot // Copyright (c) 2020 Bastien Orivel // Copyright (c) 2020 Maxime “pep” Buquet // Copyright (c) 2020 Yue Liu // Copyright (c) 2020 Matt Bilker // Copyright (c) 2020 Xidorn Quan // // This Source Code Form is subject to the terms of the Mozilla Public // License, v. 2.0. If a copy of the MPL was not distributed with this // file, You can obtain one at http://mozilla.org/MPL/2.0/. //! Provides an `Element` type, which represents DOM nodes, and a builder to create them with. use crate::convert::IntoAttributeValue; use crate::error::{Error, Result}; use crate::namespaces::NSChoice; use crate::node::Node; use crate::prefixes::{Namespace, Prefix, Prefixes}; use crate::tree_builder::TreeBuilder; use std::borrow::Cow; use std::collections::{btree_map, BTreeMap}; use std::io::{self, BufRead, Write}; use std::str; use rxml::writer::{Encoder, Item, TrackNamespace}; use rxml::{Namespace as RxmlNamespace, RawReader, XmlVersion}; use std::str::FromStr; use std::slice; fn encode_and_write( item: Item<'_>, enc: &mut Encoder, mut w: W, ) -> io::Result<()> { let mut buf = rxml::bytes::BytesMut::new(); enc.encode_into_bytes(item, &mut buf) .expect("encoder driven incorrectly"); w.write_all(&buf[..])?; Ok(()) } /// Wrapper around a [`std::io::Write`] and an [`rxml::writer::Encoder`], to /// provide a simple function to write an rxml Item to a writer. pub struct CustomItemWriter { writer: W, encoder: Encoder, } impl CustomItemWriter { pub(crate) fn new(writer: W) -> Self { Self { writer, encoder: Encoder::new(), } } } impl CustomItemWriter { pub(crate) fn write(&mut self, item: Item<'_>) -> io::Result<()> { encode_and_write(item, &mut self.encoder, &mut self.writer) } } /// Type alias to simplify the use for the default namespace tracking /// implementation. pub type ItemWriter = CustomItemWriter; /// helper function to escape a `&[u8]` and replace all /// xml special characters (<, >, &, ', ") with their corresponding /// xml escaped value. pub fn escape(raw: &[u8]) -> Cow<[u8]> { let mut escapes: Vec<(usize, &'static [u8])> = Vec::new(); let mut bytes = raw.iter(); fn to_escape(b: u8) -> bool { matches!(b, b'<' | b'>' | b'\'' | b'&' | b'"') } let mut loc = 0; while let Some(i) = bytes.position(|&b| to_escape(b)) { loc += i; match raw[loc] { b'<' => escapes.push((loc, b"<")), b'>' => escapes.push((loc, b">")), b'\'' => escapes.push((loc, b"'")), b'&' => escapes.push((loc, b"&")), b'"' => escapes.push((loc, b""")), _ => unreachable!("Only '<', '>','\', '&' and '\"' are escaped"), } loc += 1; } if escapes.is_empty() { Cow::Borrowed(raw) } else { let len = raw.len(); let mut v = Vec::with_capacity(len); let mut start = 0; for (i, r) in escapes { v.extend_from_slice(&raw[start..i]); v.extend_from_slice(r); start = i + 1; } if start < len { v.extend_from_slice(&raw[start..]); } Cow::Owned(v) } } #[derive(Clone, Eq, Debug)] /// A struct representing a DOM Element. pub struct Element { name: String, namespace: String, /// Namespace declarations pub prefixes: Prefixes, attributes: BTreeMap, children: Vec, } impl<'a> From<&'a Element> for String { fn from(elem: &'a Element) -> String { let mut writer = Vec::new(); elem.write_to(&mut writer).unwrap(); String::from_utf8(writer).unwrap() } } impl FromStr for Element { type Err = Error; fn from_str(s: &str) -> Result { Element::from_reader(s.as_bytes()) } } impl PartialEq for Element { fn eq(&self, other: &Self) -> bool { if self.name() == other.name() && self.ns() == other.ns() && self.attrs().eq(other.attrs()) { if self.nodes().count() != other.nodes().count() { return false; } self.nodes() .zip(other.nodes()) .all(|(node1, node2)| node1 == node2) } else { false } } } impl Element { pub(crate) fn new>( name: String, namespace: String, prefixes: P, attributes: BTreeMap, children: Vec, ) -> Element { Element { name, namespace, prefixes: prefixes.into(), attributes, children, } } /// Return a builder for an `Element` with the given `name`. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let elem = Element::builder("name", "namespace") /// .attr("name", "value") /// .append("inner") /// .build(); /// /// assert_eq!(elem.name(), "name"); /// assert_eq!(elem.ns(), "namespace".to_owned()); /// assert_eq!(elem.attr("name"), Some("value")); /// assert_eq!(elem.attr("inexistent"), None); /// assert_eq!(elem.text(), "inner"); /// ``` pub fn builder, NS: Into>(name: S, namespace: NS) -> ElementBuilder { ElementBuilder { root: Element::new( name.as_ref().to_string(), namespace.into(), None, BTreeMap::new(), Vec::new(), ), } } /// Returns a bare minimum `Element` with this name. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let bare = Element::bare("name", "namespace"); /// /// assert_eq!(bare.name(), "name"); /// assert_eq!(bare.ns(), "namespace"); /// assert_eq!(bare.attr("name"), None); /// assert_eq!(bare.text(), ""); /// ``` pub fn bare, NS: Into>(name: S, namespace: NS) -> Element { Element::new( name.into(), namespace.into(), None, BTreeMap::new(), Vec::new(), ) } /// Returns a reference to the local name of this element (that is, without a possible prefix). pub fn name(&self) -> &str { &self.name } /// Returns a reference to the namespace of this element. pub fn ns(&self) -> String { self.namespace.clone() } /// Returns a reference to the value of the given attribute, if it exists, else `None`. pub fn attr(&self, name: &str) -> Option<&str> { if let Some(value) = self.attributes.get(name) { return Some(value); } None } /// Returns an iterator over the attributes of this element. /// /// # Example /// /// ```rust /// use minidom::Element; /// /// let elm: Element = "".parse().unwrap(); /// /// let mut iter = elm.attrs(); /// /// assert_eq!(iter.next().unwrap(), ("a", "b")); /// assert_eq!(iter.next(), None); /// ``` pub fn attrs(&self) -> Attrs { Attrs { iter: self.attributes.iter(), } } /// Returns an iterator over the attributes of this element, with the value being a mutable /// reference. pub fn attrs_mut(&mut self) -> AttrsMut { AttrsMut { iter: self.attributes.iter_mut(), } } /// Modifies the value of an attribute. pub fn set_attr, V: IntoAttributeValue>(&mut self, name: S, val: V) { let name = name.into(); let val = val.into_attribute_value(); if let Some(value) = self.attributes.get_mut(&name) { *value = val .expect("removing existing value via set_attr, this is not yet supported (TODO)"); // TODO return; } if let Some(val) = val { self.attributes.insert(name, val); } } /// Returns whether the element has the given name and namespace. /// /// # Examples /// /// ```rust /// use minidom::{Element, NSChoice}; /// /// let elem = Element::builder("name", "namespace").build(); /// /// assert_eq!(elem.is("name", "namespace"), true); /// assert_eq!(elem.is("name", "wrong"), false); /// assert_eq!(elem.is("wrong", "namespace"), false); /// assert_eq!(elem.is("wrong", "wrong"), false); /// /// assert_eq!(elem.is("name", NSChoice::OneOf("namespace")), true); /// assert_eq!(elem.is("name", NSChoice::OneOf("foo")), false); /// assert_eq!(elem.is("name", NSChoice::AnyOf(&["foo", "namespace"])), true); /// assert_eq!(elem.is("name", NSChoice::Any), true); /// ``` pub fn is<'a, N: AsRef, NS: Into>>(&self, name: N, namespace: NS) -> bool { self.name == name.as_ref() && namespace.into().compare(self.namespace.as_ref()) } /// Returns whether the element has the given namespace. /// /// # Examples /// /// ```rust /// use minidom::{Element, NSChoice}; /// /// let elem = Element::builder("name", "namespace").build(); /// /// assert_eq!(elem.has_ns("namespace"), true); /// assert_eq!(elem.has_ns("wrong"), false); /// /// assert_eq!(elem.has_ns(NSChoice::OneOf("namespace")), true); /// assert_eq!(elem.has_ns(NSChoice::OneOf("foo")), false); /// assert_eq!(elem.has_ns(NSChoice::AnyOf(&["foo", "namespace"])), true); /// assert_eq!(elem.has_ns(NSChoice::Any), true); /// ``` pub fn has_ns<'a, NS: Into>>(&self, namespace: NS) -> bool { namespace.into().compare(self.namespace.as_ref()) } /// Parse a document from a `BufRead`. pub fn from_reader(reader: R) -> Result { let mut tree_builder = TreeBuilder::new(); let mut driver = RawReader::new(reader); while let Some(event) = driver.read()? { tree_builder.process_event(event)?; if let Some(root) = tree_builder.root.take() { return Ok(root); } } Err(Error::EndOfDocument) } /// Parse a document from a `BufRead`, allowing Prefixes to be specified. Useful to provide /// knowledge of namespaces that would have been declared on parent elements not present in the /// reader. pub fn from_reader_with_prefixes>( reader: R, prefixes: P, ) -> Result { let mut tree_builder = TreeBuilder::new().with_prefixes_stack(vec![prefixes.into()]); let mut driver = RawReader::new(reader); while let Some(event) = driver.read()? { tree_builder.process_event(event)?; if let Some(root) = tree_builder.root.take() { return Ok(root); } } Err(Error::EndOfDocument) } /// Output a document to a `Writer`. pub fn write_to(&self, writer: &mut W) -> Result<()> { self.to_writer(&mut ItemWriter::new(writer)) } /// Output a document to a `Writer`. pub fn write_to_decl(&self, writer: &mut W) -> Result<()> { self.to_writer_decl(&mut ItemWriter::new(writer)) } /// Output the document to an `ItemWriter` pub fn to_writer(&self, writer: &mut ItemWriter) -> Result<()> { self.write_to_inner(writer) } /// Output the document to an `ItemWriter` pub fn to_writer_decl(&self, writer: &mut ItemWriter) -> Result<()> { writer .write(Item::XmlDeclaration(XmlVersion::V1_0)) .unwrap(); // TODO: error return self.write_to_inner(writer) } /// Like `write_to()` but without the `` prelude pub fn write_to_inner(&self, writer: &mut ItemWriter) -> Result<()> { for (prefix, namespace) in self.prefixes.declared_prefixes() { assert!(writer.encoder.ns_tracker_mut().declare_fixed( prefix.as_ref().map(|x| (&**x).try_into()).transpose()?, namespace.clone().into(), )); } let namespace: RxmlNamespace = self.namespace.clone().into(); writer.write(Item::ElementHeadStart(&namespace, (*self.name).try_into()?))?; for (key, value) in self.attributes.iter() { let (prefix, name) = <&rxml::NameStr>::try_from(&**key) .unwrap() .split_name() .unwrap(); let namespace = match prefix { Some(prefix) => match writer.encoder.ns_tracker().lookup_prefix(Some(prefix)) { Ok(v) => v, Err(rxml::writer::PrefixError::Undeclared) => return Err(Error::InvalidPrefix), }, None => RxmlNamespace::NONE, }; writer.write(Item::Attribute(&namespace, name, value))?; } if !self.children.is_empty() { writer.write(Item::ElementHeadEnd)?; for child in self.children.iter() { child.write_to_inner(writer)?; } } writer.write(Item::ElementFoot)?; Ok(()) } /// Extracts all children into a collection. pub fn take_nodes(&mut self) -> Vec { self.children.drain(..).collect() } /// Returns an iterator over references to every child node of this element. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let elem: Element = "abc".parse().unwrap(); /// /// let mut iter = elem.nodes(); /// /// assert_eq!(iter.next().unwrap().as_text().unwrap(), "a"); /// assert_eq!(iter.next().unwrap().as_element().unwrap().name(), "c1"); /// assert_eq!(iter.next().unwrap().as_text().unwrap(), "b"); /// assert_eq!(iter.next().unwrap().as_element().unwrap().name(), "c2"); /// assert_eq!(iter.next().unwrap().as_text().unwrap(), "c"); /// assert_eq!(iter.next(), None); /// ``` #[inline] pub fn nodes(&self) -> Nodes { self.children.iter() } /// Returns an iterator over mutable references to every child node of this element. #[inline] pub fn nodes_mut(&mut self) -> NodesMut { self.children.iter_mut() } /// Returns an iterator over references to every child element of this element. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let elem: Element = "hellothisisignored".parse().unwrap(); /// /// let mut iter = elem.children(); /// assert_eq!(iter.next().unwrap().name(), "child1"); /// assert_eq!(iter.next().unwrap().name(), "child2"); /// assert_eq!(iter.next().unwrap().name(), "child3"); /// assert_eq!(iter.next(), None); /// ``` #[inline] pub fn children(&self) -> Children { Children { iter: self.children.iter(), } } /// Returns an iterator over mutable references to every child element of this element. #[inline] pub fn children_mut(&mut self) -> ChildrenMut { ChildrenMut { iter: self.children.iter_mut(), } } /// Returns an iterator over the child Elements, draining the element of /// all its child nodes **including text!** /// /// This is a bit of a footgun, so we make this hidden in the docs (it /// needs to be pub for macro use). Once `extract_if` /// ([rust#43244](https://github.com/rust-lang/rust/issues/43244)) /// is stabilized, we can replace this with a take_children which doesn't /// remove text nodes. #[inline] #[doc(hidden)] pub fn take_contents_as_children(&mut self) -> ContentsAsChildren { ContentsAsChildren { iter: self.children.drain(..), } } /// Returns an iterator over references to every text node of this element. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let elem: Element = "hello world!".parse().unwrap(); /// /// let mut iter = elem.texts(); /// assert_eq!(iter.next().unwrap(), "hello"); /// assert_eq!(iter.next().unwrap(), " world!"); /// assert_eq!(iter.next(), None); /// ``` #[inline] pub fn texts(&self) -> Texts { Texts { iter: self.children.iter(), } } /// Returns an iterator over mutable references to every text node of this element. #[inline] pub fn texts_mut(&mut self) -> TextsMut { TextsMut { iter: self.children.iter_mut(), } } /// Appends a child node to the `Element`, returning the appended node. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let mut elem = Element::bare("root", "ns1"); /// /// assert_eq!(elem.children().count(), 0); /// /// elem.append_child(Element::bare("child", "ns1")); /// /// { /// let mut iter = elem.children(); /// assert_eq!(iter.next().unwrap().name(), "child"); /// assert_eq!(iter.next(), None); /// } /// /// let child = elem.append_child(Element::bare("new", "ns1")); /// /// assert_eq!(child.name(), "new"); /// ``` pub fn append_child(&mut self, child: Element) -> &mut Element { self.children.push(Node::Element(child)); if let Node::Element(ref mut cld) = *self.children.last_mut().unwrap() { cld } else { unreachable!() } } /// Appends a text node to an `Element`. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let mut elem = Element::bare("node", "ns1"); /// /// assert_eq!(elem.text(), ""); /// /// elem.append_text_node("text"); /// /// assert_eq!(elem.text(), "text"); /// ``` pub fn append_text_node>(&mut self, child: S) { self.children.push(Node::Text(child.into())); } /// Appends a string as plain text to an `Element`. /// /// If the last child node of the element is a text node, the string will be appended to it. /// Otherwise, a new text node will be created. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let mut elem = Element::bare("node", "ns1"); /// /// assert_eq!(elem.text(), ""); /// /// elem.append_text_node("text"); /// /// elem.append_text(" and more text"); /// /// assert_eq!(elem.nodes().count(), 1); /// ``` pub fn append_text>(&mut self, text: S) { if let Some(Node::Text(ref mut child)) = self.children.last_mut() { child.push_str(&text.into()); } else { self.append_text_node(text); } } /// Appends a node to an `Element`. /// /// # Examples /// /// ```rust /// use minidom::{Element, Node}; /// /// let mut elem = Element::bare("node", "ns1"); /// /// elem.append_node(Node::Text("hello".to_owned())); /// /// assert_eq!(elem.text(), "hello"); /// ``` pub fn append_node(&mut self, node: Node) { self.children.push(node); } /// Returns the concatenation of all text nodes in the `Element`. /// /// # Examples /// /// ```rust /// use minidom::Element; /// /// let elem: Element = "hello, world!".parse().unwrap(); /// /// assert_eq!(elem.text(), "hello, world!"); /// ``` pub fn text(&self) -> String { self.texts().fold(String::new(), |ret, new| ret + new) } /// Returns a reference to the first child element with the specific name and namespace, if it /// exists in the direct descendants of this `Element`, else returns `None`. /// /// # Examples /// /// ```rust /// use minidom::{Element, NSChoice}; /// /// let elem: Element = r#""#.parse().unwrap(); /// assert!(elem.get_child("a", "ns").unwrap().is("a", "ns")); /// assert!(elem.get_child("a", "other_ns").unwrap().is("a", "other_ns")); /// assert!(elem.get_child("b", "ns").unwrap().is("b", "ns")); /// assert_eq!(elem.get_child("c", "ns"), None); /// assert_eq!(elem.get_child("b", "other_ns"), None); /// assert_eq!(elem.get_child("a", "inexistent_ns"), None); /// ``` pub fn get_child<'a, N: AsRef, NS: Into>>( &self, name: N, namespace: NS, ) -> Option<&Element> { let namespace = namespace.into(); for fork in &self.children { if let Node::Element(ref e) = *fork { if e.is(name.as_ref(), namespace) { return Some(e); } } } None } /// Returns a mutable reference to the first child element with the specific name and namespace, /// if it exists in the direct descendants of this `Element`, else returns `None`. pub fn get_child_mut<'a, N: AsRef, NS: Into>>( &mut self, name: N, namespace: NS, ) -> Option<&mut Element> { let namespace = namespace.into(); for fork in &mut self.children { if let Node::Element(ref mut e) = *fork { if e.is(name.as_ref(), namespace) { return Some(e); } } } None } /// Returns whether a specific child with this name and namespace exists in the direct /// descendants of the `Element`. /// /// # Examples /// /// ```rust /// use minidom::{Element, NSChoice}; /// /// let elem: Element = r#""#.parse().unwrap(); /// assert_eq!(elem.has_child("a", "other_ns"), true); /// assert_eq!(elem.has_child("a", "ns"), true); /// assert_eq!(elem.has_child("a", "inexistent_ns"), false); /// assert_eq!(elem.has_child("b", "ns"), true); /// assert_eq!(elem.has_child("b", "other_ns"), false); /// assert_eq!(elem.has_child("b", "inexistent_ns"), false); /// ``` pub fn has_child<'a, N: AsRef, NS: Into>>( &self, name: N, namespace: NS, ) -> bool { self.get_child(name, namespace).is_some() } /// Removes the first child with this name and namespace, if it exists, and returns an /// `Option` containing this child if it succeeds. /// Returns `None` if no child matches this name and namespace. /// /// # Examples /// /// ```rust /// use minidom::{Element, NSChoice}; /// /// let mut elem: Element = r#""#.parse().unwrap(); /// assert!(elem.remove_child("a", "ns").unwrap().is("a", "ns")); /// assert!(elem.remove_child("a", "ns").is_none()); /// assert!(elem.remove_child("inexistent", "inexistent").is_none()); /// ``` pub fn remove_child<'a, N: AsRef, NS: Into>>( &mut self, name: N, namespace: NS, ) -> Option { let name = name.as_ref(); let namespace = namespace.into(); let idx = self.children.iter().position(|x| { if let Node::Element(ref elm) = x { elm.is(name, namespace) } else { false } })?; self.children.remove(idx).into_element() } /// Remove the leading nodes up to the first child element and /// return it pub fn unshift_child(&mut self) -> Option { while !self.children.is_empty() { if let Some(el) = self.children.remove(0).into_element() { return Some(el); } } None } } /// An iterator over references to child elements of an `Element`. pub struct Children<'a> { iter: slice::Iter<'a, Node>, } impl<'a> Iterator for Children<'a> { type Item = &'a Element; fn next(&mut self) -> Option<&'a Element> { for item in &mut self.iter { if let Node::Element(ref child) = *item { return Some(child); } } None } } /// An iterator over mutable references to child elements of an `Element`. pub struct ChildrenMut<'a> { iter: slice::IterMut<'a, Node>, } impl<'a> Iterator for ChildrenMut<'a> { type Item = &'a mut Element; fn next(&mut self) -> Option<&'a mut Element> { for item in &mut self.iter { if let Node::Element(ref mut child) = *item { return Some(child); } } None } } /// An iterator over references to child elements of an `Element`. pub struct ContentsAsChildren<'a> { iter: std::vec::Drain<'a, Node>, } impl<'a> Iterator for ContentsAsChildren<'a> { type Item = Element; fn next(&mut self) -> Option { for item in &mut self.iter { if let Node::Element(child) = item { return Some(child); } } None } } /// An iterator over references to child text nodes of an `Element`. pub struct Texts<'a> { iter: slice::Iter<'a, Node>, } impl<'a> Iterator for Texts<'a> { type Item = &'a str; fn next(&mut self) -> Option<&'a str> { for item in &mut self.iter { if let Node::Text(ref child) = *item { return Some(child); } } None } } /// An iterator over mutable references to child text nodes of an `Element`. pub struct TextsMut<'a> { iter: slice::IterMut<'a, Node>, } impl<'a> Iterator for TextsMut<'a> { type Item = &'a mut String; fn next(&mut self) -> Option<&'a mut String> { for item in &mut self.iter { if let Node::Text(ref mut child) = *item { return Some(child); } } None } } /// An iterator over references to all child nodes of an `Element`. pub type Nodes<'a> = slice::Iter<'a, Node>; /// An iterator over mutable references to all child nodes of an `Element`. pub type NodesMut<'a> = slice::IterMut<'a, Node>; /// An iterator over the attributes of an `Element`. pub struct Attrs<'a> { iter: btree_map::Iter<'a, String, String>, } impl<'a> Iterator for Attrs<'a> { type Item = (&'a str, &'a str); fn next(&mut self) -> Option { self.iter.next().map(|(x, y)| (x.as_ref(), y.as_ref())) } } /// An iterator over the attributes of an `Element`, with the values mutable. pub struct AttrsMut<'a> { iter: btree_map::IterMut<'a, String, String>, } impl<'a> Iterator for AttrsMut<'a> { type Item = (&'a str, &'a mut String); fn next(&mut self) -> Option { self.iter.next().map(|(x, y)| (x.as_ref(), y)) } } /// A builder for `Element`s. pub struct ElementBuilder { root: Element, } impl ElementBuilder { /// Sets a custom prefix. It is not possible to set the same prefix twice. pub fn prefix>( mut self, prefix: Prefix, namespace: S, ) -> Result { if self.root.prefixes.get(&prefix).is_some() { return Err(Error::DuplicatePrefix); } self.root.prefixes.insert(prefix, namespace.into()); Ok(self) } /// Sets an attribute. pub fn attr, V: IntoAttributeValue>( mut self, name: S, value: V, ) -> ElementBuilder { self.root.set_attr(name, value); self } /// Appends anything implementing `Into` into the tree. pub fn append>(mut self, node: T) -> ElementBuilder { self.root.append_node(node.into()); self } /// Appends an iterator of things implementing `Into` into the tree. pub fn append_all, I: IntoIterator>( mut self, iter: I, ) -> ElementBuilder { for node in iter { self.root.append_node(node.into()); } self } /// Builds the `Element`. pub fn build(self) -> Element { self.root } } #[cfg(test)] mod tests { use super::*; #[test] fn test_element_new() { let elem = Element::new( "name".to_owned(), "namespace".to_owned(), (None, "namespace".to_owned()), BTreeMap::from_iter(vec![("name".to_string(), "value".to_string())].into_iter()), Vec::new(), ); assert_eq!(elem.name(), "name"); assert_eq!(elem.ns(), "namespace".to_owned()); assert_eq!(elem.attr("name"), Some("value")); assert_eq!(elem.attr("inexistent"), None); } #[test] fn test_from_reader_simple() { let xml = b""; let elem = Element::from_reader(&xml[..]); let elem2 = Element::builder("foo", "ns1").build(); assert_eq!(elem.unwrap(), elem2); } #[test] fn test_from_reader_nested() { let xml = b""; let elem = Element::from_reader(&xml[..]); let nested = Element::builder("bar", "ns1").attr("baz", "qxx").build(); let elem2 = Element::builder("foo", "ns1").append(nested).build(); assert_eq!(elem.unwrap(), elem2); } #[test] fn test_from_reader_with_prefix() { let xml = b""; let elem = Element::from_reader(&xml[..]); let nested = Element::builder("bar", "ns1").attr("baz", "qxx").build(); let elem2 = Element::builder("foo", "ns1").append(nested).build(); assert_eq!(elem.unwrap(), elem2); } #[test] fn test_from_reader_split_prefix() { let xml = b""; let elem = Element::from_reader(&xml[..]).unwrap(); assert_eq!(elem.name(), String::from("bar")); assert_eq!(elem.ns(), String::from("ns1")); // Ensure the prefix is properly added to the store assert_eq!( elem.prefixes.get(&Some(String::from("foo"))), Some(&String::from("ns1")) ); } #[test] fn parses_spectest_xml() { // From: https://gitlab.com/lumi/minidom-rs/issues/8 let xml = br#" "#; let _ = Element::from_reader(&xml[..]).unwrap(); } #[test] fn does_not_unescape_cdata() { let xml = b"]]>"; let elem = Element::from_reader(&xml[..]).unwrap(); assert_eq!(elem.text(), "'>blah"); } #[test] fn test_compare_all_ns() { let xml = b""; let elem = Element::from_reader(&xml[..]).unwrap(); let elem2 = elem.clone(); let xml3 = b""; let elem3 = Element::from_reader(&xml3[..]).unwrap(); let xml4 = b""; let elem4 = Element::from_reader(&xml4[..]).unwrap(); assert_eq!(elem, elem2); assert_eq!(elem, elem3); assert_eq!(elem, elem4); } #[test] fn test_compare_empty_children() { let elem1 = Element::bare("p", ""); let elem2 = Element::builder("p", "") .append(Node::Element(Element::bare("span", ""))) .build(); assert_ne!(elem1, elem2); } #[test] fn test_from_reader_with_prefixes() { let xml = b""; let elem = Element::from_reader_with_prefixes(&xml[..], String::from("jabber:client")).unwrap(); let xml2 = b""; let elem2 = Element::from_reader(&xml2[..]).unwrap(); assert_eq!(elem, elem2); } #[test] fn failure_with_duplicate_namespace() { let _: Element = r###" "### .parse() .unwrap(); } }