zola/components/library/src/library.rs
2018-11-14 17:34:21 +01:00

355 lines
13 KiB
Rust

use std::collections::{HashMap, HashSet};
use std::path::{Path, PathBuf};
use slotmap::{DenseSlotMap, Key};
use front_matter::SortBy;
use content::{Page, Section};
use sorting::{find_siblings, sort_pages_by_date, sort_pages_by_weight};
/// Houses everything about pages and sections
/// Think of it as a database where each page and section has an id (Key here)
/// that can be used to find the actual value
/// Sections and pages can then refer to other elements by those keys, which are very cheap to
/// copy.
/// We can assume the keys are always existing as removing a page/section deletes all references
/// to that key.
#[derive(Debug)]
pub struct Library {
/// All the pages of the site
pages: DenseSlotMap<Page>,
/// All the sections of the site
sections: DenseSlotMap<Section>,
/// A mapping path -> key for pages so we can easily get their key
paths_to_pages: HashMap<PathBuf, Key>,
/// A mapping path -> key for sections so we can easily get their key
pub paths_to_sections: HashMap<PathBuf, Key>,
}
impl Library {
pub fn new(cap_pages: usize, cap_sections: usize) -> Self {
Library {
pages: DenseSlotMap::with_capacity(cap_pages),
sections: DenseSlotMap::with_capacity(cap_sections),
paths_to_pages: HashMap::with_capacity(cap_pages),
paths_to_sections: HashMap::with_capacity(cap_sections),
}
}
/// Add a section and return its Key
pub fn insert_section(&mut self, section: Section) -> Key {
let path = section.file.path.clone();
let key = self.sections.insert(section);
self.paths_to_sections.insert(path, key);
key
}
/// Add a page and return its Key
pub fn insert_page(&mut self, page: Page) -> Key {
let path = page.file.path.clone();
let key = self.pages.insert(page);
self.paths_to_pages.insert(path, key);
key
}
pub fn pages(&self) -> &DenseSlotMap<Page> {
&self.pages
}
pub fn pages_mut(&mut self) -> &mut DenseSlotMap<Page> {
&mut self.pages
}
pub fn pages_values(&self) -> Vec<&Page> {
self.pages.values().collect::<Vec<_>>()
}
pub fn sections(&self) -> &DenseSlotMap<Section> {
&self.sections
}
pub fn sections_mut(&mut self) -> &mut DenseSlotMap<Section> {
&mut self.sections
}
pub fn sections_values(&self) -> Vec<&Section> {
self.sections.values().collect::<Vec<_>>()
}
/// Find out the direct subsections of each subsection if there are some
/// as well as the pages for each section
pub fn populate_sections(&mut self) {
let (root_path, index_path) = self
.sections
.values()
.find(|s| s.is_index())
.map(|s| (s.file.parent.clone(), s.file.path.clone()))
.unwrap();
let root_key = self.paths_to_sections[&index_path];
// We are going to get both the ancestors and grandparents for each section in one go
let mut ancestors: HashMap<PathBuf, Vec<_>> = HashMap::new();
let mut subsections: HashMap<PathBuf, Vec<_>> = HashMap::new();
for section in self.sections.values_mut() {
// Make sure the pages of a section are empty since we can call that many times on `serve`
section.pages = vec![];
section.ignored_pages = vec![];
if let Some(ref grand_parent) = section.file.grand_parent {
subsections
.entry(grand_parent.join("_index.md"))
.or_insert_with(|| vec![])
.push(section.file.path.clone());
}
// Index has no ancestors, no need to go through it
if section.is_index() {
ancestors.insert(section.file.path.clone(), vec![]);
continue;
}
let mut path = root_path.clone();
// Index section is the first ancestor of every single section
let mut parents = vec![root_key];
for component in &section.file.components {
path = path.join(component);
// Skip itself
if path == section.file.parent {
continue;
}
if let Some(section_key) = self.paths_to_sections.get(&path.join("_index.md")) {
parents.push(*section_key);
}
}
ancestors.insert(section.file.path.clone(), parents);
}
for (key, page) in &mut self.pages {
let mut parent_section_path = page.file.parent.join("_index.md");
while let Some(section_key) = self.paths_to_sections.get(&parent_section_path) {
let parent_is_transparent;
// We need to get a reference to a section later so keep the scope of borrowing small
{
let mut section = self.sections.get_mut(*section_key).unwrap();
section.pages.push(key);
parent_is_transparent = section.meta.transparent;
}
page.ancestors =
ancestors.get(&parent_section_path).cloned().unwrap_or_else(|| vec![]);
// Don't forget to push the actual parent
page.ancestors.push(*section_key);
// Find the page template if one of a parent has page_template set
// Stops after the first one found, keep in mind page.ancestors
// is [index, ..., parent] so we need to reverse it first
if page.meta.template.is_none() {
for ancestor in page.ancestors.iter().rev() {
let s = self.sections.get(*ancestor).unwrap();
if s.meta.page_template.is_some() {
page.meta.template = s.meta.page_template.clone();
break;
}
}
}
if !parent_is_transparent {
break;
}
// We've added `_index.md` so if we are here so we need to go up twice
match parent_section_path.clone().parent().unwrap().parent() {
Some(parent) => parent_section_path = parent.join("_index.md"),
None => break,
}
}
}
self.sort_sections_pages();
let sections = self.paths_to_sections.clone();
let mut sections_weight = HashMap::new();
for (key, section) in &self.sections {
sections_weight.insert(key, section.meta.weight);
}
for section in self.sections.values_mut() {
if let Some(ref children) = subsections.get(&section.file.path) {
let mut children: Vec<_> = children.iter().map(|p| sections[p]).collect();
children.sort_by(|a, b| sections_weight[a].cmp(&sections_weight[b]));
section.subsections = children;
}
section.ancestors =
ancestors.get(&section.file.path).cloned().unwrap_or_else(|| vec![]);
}
}
/// Sort all sections pages
pub fn sort_sections_pages(&mut self) {
let mut updates = HashMap::new();
for (key, section) in &self.sections {
let (sorted_pages, cannot_be_sorted_pages) = match section.meta.sort_by {
SortBy::None => continue,
SortBy::Date => {
let data = section
.pages
.iter()
.map(|k| {
if let Some(page) = self.pages.get(*k) {
(k, page.meta.datetime, page.permalink.as_ref())
} else {
unreachable!("Sorting got an unknown page")
}
})
.collect();
sort_pages_by_date(data)
}
SortBy::Weight => {
let data = section
.pages
.iter()
.map(|k| {
if let Some(page) = self.pages.get(*k) {
(k, page.meta.weight, page.permalink.as_ref())
} else {
unreachable!("Sorting got an unknown page")
}
})
.collect();
sort_pages_by_weight(data)
}
};
updates.insert(key, (sorted_pages, cannot_be_sorted_pages, section.meta.sort_by));
}
for (key, (sorted, cannot_be_sorted, sort_by)) in updates {
// Find sibling between sorted pages first
let with_siblings = find_siblings(
sorted
.iter()
.map(|k| {
if let Some(page) = self.pages.get(*k) {
(k, page.is_draft())
} else {
unreachable!("Sorting got an unknown page")
}
})
.collect(),
);
for (k2, val1, val2) in with_siblings {
if let Some(page) = self.pages.get_mut(k2) {
match sort_by {
SortBy::Date => {
page.earlier = val2;
page.later = val1;
}
SortBy::Weight => {
page.lighter = val1;
page.heavier = val2;
}
SortBy::None => unreachable!("Impossible to find siblings in SortBy::None"),
}
} else {
unreachable!("Sorting got an unknown page")
}
}
if let Some(s) = self.sections.get_mut(key) {
s.pages = sorted;
s.ignored_pages = cannot_be_sorted;
}
}
}
/// Find all the orphan pages: pages that are in a folder without an `_index.md`
pub fn get_all_orphan_pages(&self) -> Vec<&Page> {
let pages_in_sections =
self.sections.values().flat_map(|s| &s.pages).collect::<HashSet<_>>();
self.pages
.iter()
.filter(|(key, _)| !pages_in_sections.contains(&key))
.map(|(_, page)| page)
.collect()
}
pub fn find_parent_section<P: AsRef<Path>>(&self, path: P) -> Option<&Section> {
let page_key = self.paths_to_pages[path.as_ref()];
for s in self.sections.values() {
if s.pages.contains(&page_key) {
return Some(s);
}
}
None
}
/// Only used in tests
pub fn get_section_key<P: AsRef<Path>>(&self, path: P) -> Option<&Key> {
self.paths_to_sections.get(path.as_ref())
}
pub fn get_section<P: AsRef<Path>>(&self, path: P) -> Option<&Section> {
self.sections.get(self.paths_to_sections.get(path.as_ref()).cloned().unwrap_or_default())
}
pub fn get_section_mut<P: AsRef<Path>>(&mut self, path: P) -> Option<&mut Section> {
self.sections
.get_mut(self.paths_to_sections.get(path.as_ref()).cloned().unwrap_or_default())
}
pub fn get_section_by_key(&self, key: Key) -> &Section {
self.sections.get(key).unwrap()
}
pub fn get_section_mut_by_key(&mut self, key: Key) -> &mut Section {
self.sections.get_mut(key).unwrap()
}
pub fn get_section_path_by_key(&self, key: Key) -> &str {
&self.get_section_by_key(key).file.relative
}
pub fn get_page<P: AsRef<Path>>(&self, path: P) -> Option<&Page> {
self.pages.get(self.paths_to_pages.get(path.as_ref()).cloned().unwrap_or_default())
}
pub fn get_page_by_key(&self, key: Key) -> &Page {
self.pages.get(key).unwrap()
}
pub fn get_page_mut_by_key(&mut self, key: Key) -> &mut Page {
self.pages.get_mut(key).unwrap()
}
pub fn remove_section<P: AsRef<Path>>(&mut self, path: P) -> Option<Section> {
if let Some(k) = self.paths_to_sections.remove(path.as_ref()) {
self.sections.remove(k)
} else {
None
}
}
pub fn remove_page<P: AsRef<Path>>(&mut self, path: P) -> Option<Page> {
if let Some(k) = self.paths_to_pages.remove(path.as_ref()) {
self.pages.remove(k)
} else {
None
}
}
/// Used in rebuild, to check if we know it already
pub fn contains_section<P: AsRef<Path>>(&self, path: P) -> bool {
self.paths_to_sections.contains_key(path.as_ref())
}
/// Used in rebuild, to check if we know it already
pub fn contains_page<P: AsRef<Path>>(&self, path: P) -> bool {
self.paths_to_pages.contains_key(path.as_ref())
}
}