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//! Deal with content in other content.
//!
//! To deal with content in content, *you* (a `markdown-rs` contributor) add
//! info on events.
//! Events are a flat list, but they can be connected to each other with a
//! [`Link`][crate::event::Link].
//! Links must occur on [`Enter`][Kind::Enter] events only, which are void
//! (they are followed by their corresponding [`Exit`][Kind::Exit] event).
//!
//! Links will then be passed through a tokenizer for the corresponding content
//! type by `subtokenize`.
//! The subevents they result in are split up into slots for each linked event
//! and replace those links.
//!
//! Subevents are not immediately subtokenized as markdown prevents us from
//! doing so due to definitions, which can occur after references, and thus the
//! whole document needs to be parsed up to the level of definitions, before
//! any level that can include references can be parsed.
use crate::event::{Content, Event, Kind, Name, VOID_EVENTS};
use crate::parser::ParseState;
use crate::state::{Name as StateName, State};
use crate::tokenizer::Tokenizer;
use crate::util::{edit_map::EditMap, skip};
use alloc::{string::String, vec, vec::Vec};
#[derive(Debug)]
pub struct Subresult {
pub done: bool,
pub gfm_footnote_definitions: Vec<String>,
pub definitions: Vec<String>,
}
/// Link two [`Event`][]s.
///
/// Arbitrary (void) events can be linked together.
/// This optimizes for the common case where the event at `index` is connected
/// to the previous void event.
pub fn link(events: &mut [Event], index: usize) {
link_to(events, index - 2, index);
}
/// Link two arbitrary [`Event`][]s together.
pub fn link_to(events: &mut [Event], previous: usize, next: usize) {
debug_assert_eq!(events[previous].kind, Kind::Enter);
debug_assert!(
VOID_EVENTS.iter().any(|d| d == &events[previous].name),
"expected event to be void"
);
debug_assert_eq!(events[previous + 1].kind, Kind::Exit);
debug_assert_eq!(events[previous].name, events[previous + 1].name);
debug_assert_eq!(events[next].kind, Kind::Enter);
debug_assert!(
VOID_EVENTS.iter().any(|d| d == &events[next].name),
"expected event to be void"
);
// Note: the exit of this event may not exist, so don’t check for that.
let link_previous = events[previous]
.link
.as_mut()
.expect("expected `link` on previous");
link_previous.next = Some(next);
let link_next = events[next].link.as_mut().expect("expected `link` on next");
link_next.previous = Some(previous);
debug_assert_eq!(
events[previous].link.as_ref().unwrap().content,
events[next].link.as_ref().unwrap().content,
"expected `content` to match"
);
}
/// Parse linked events.
///
/// Supposed to be called repeatedly, returns `true` when done.
pub fn subtokenize(
events: &mut Vec<Event>,
parse_state: &ParseState,
filter: &Option<Content>,
) -> Result<Subresult, String> {
let mut map = EditMap::new();
let mut index = 0;
let mut value = Subresult {
done: true,
gfm_footnote_definitions: vec![],
definitions: vec![],
};
let mut acc = (0, 0);
while index < events.len() {
let event = &events[index];
// Find each first opening chunk.
if let Some(ref link) = event.link {
debug_assert_eq!(event.kind, Kind::Enter);
// No need to enter linked events again.
if link.previous == None
&& (filter.is_none() || &link.content == filter.as_ref().unwrap())
{
// Index into `events` pointing to a chunk.
let mut link_index = Some(index);
// Subtokenizer.
let mut tokenizer = Tokenizer::new(event.point.clone(), parse_state);
debug_assert!(
!matches!(link.content, Content::Flow),
"cannot use flow as subcontent yet"
);
// Substate.
let mut state = State::Next(match link.content {
Content::Content => StateName::ContentDefinitionBefore,
Content::String => StateName::StringStart,
_ => StateName::TextStart,
});
// Check if this is the first paragraph, after zero or more
// definitions (or a blank line), in a list item.
// Used for GFM task list items.
if tokenizer.parse_state.options.constructs.gfm_task_list_item
&& index > 2
&& events[index - 1].kind == Kind::Enter
&& events[index - 1].name == Name::Paragraph
{
let before = skip::opt_back(
events,
index - 2,
&[
Name::BlankLineEnding,
Name::Definition,
Name::LineEnding,
Name::SpaceOrTab,
],
);
if events[before].kind == Kind::Exit
&& events[before].name == Name::ListItemPrefix
{
tokenizer
.tokenize_state
.document_at_first_paragraph_of_list_item = true;
}
}
// Loop through links to pass them in order to the subtokenizer.
while let Some(index) = link_index {
let enter = &events[index];
let link_curr = enter.link.as_ref().expect("expected link");
debug_assert_eq!(enter.kind, Kind::Enter);
if link_curr.previous != None {
tokenizer.define_skip(enter.point.clone());
}
let end = &events[index + 1].point;
state = tokenizer.push(
(enter.point.index, enter.point.vs),
(end.index, end.vs),
state,
);
link_index = link_curr.next;
}
let mut result = tokenizer.flush(state, true)?;
value
.gfm_footnote_definitions
.append(&mut result.gfm_footnote_definitions);
value.definitions.append(&mut result.definitions);
value.done = false;
acc = divide_events(&mut map, events, index, &mut tokenizer.events, acc);
}
}
index += 1;
}
map.consume(events);
Ok(value)
}
/// Divide `child_events` over links in `events`, the first of which is at
/// `link_index`.
pub fn divide_events(
map: &mut EditMap,
events: &[Event],
mut link_index: usize,
child_events: &mut Vec<Event>,
acc_before: (usize, usize),
) -> (usize, usize) {
// Loop through `child_events` to figure out which parts belong where and
// fix deep links.
let mut child_index = 0;
let mut slices = vec![];
let mut slice_start = 0;
let mut old_prev: Option<usize> = None;
let len = child_events.len();
while child_index < len {
let current = &child_events[child_index].point;
let end = &events[link_index + 1].point;
// Find the first event that starts after the end we’re looking
// for.
if current.index > end.index || (current.index == end.index && current.vs > end.vs) {
slices.push((link_index, slice_start));
slice_start = child_index;
link_index = events[link_index].link.as_ref().unwrap().next.unwrap();
}
// Fix sublinks.
if let Some(sublink_curr) = &child_events[child_index].link {
if sublink_curr.previous.is_some() {
let old_prev = old_prev.unwrap();
let prev_event = &mut child_events[old_prev];
// The `index` in `events` where the current link is,
// minus one to get the previous link,
// minus 2 events (the enter and exit) for each removed
// link.
let new_link = if slices.is_empty() {
old_prev + link_index + 2
} else {
old_prev + link_index - (slices.len() - 1) * 2
};
prev_event.link.as_mut().unwrap().next =
Some(new_link + acc_before.1 - acc_before.0);
}
}
// If there is a `next` link in the subevents, we have to change
// its `previous` index to account for the shifted events.
// If it points to a next event, we also change the next event’s
// reference back to *this* event.
if let Some(sublink_curr) = &child_events[child_index].link {
if let Some(next) = sublink_curr.next {
let sublink_next = child_events[next].link.as_mut().unwrap();
old_prev = sublink_next.previous;
sublink_next.previous = sublink_next
.previous
// The `index` in `events` where the current link is,
// minus 2 events (the enter and exit) for each removed
// link.
.map(|previous| {
previous + link_index - (slices.len() * 2) + acc_before.1 - acc_before.0
});
}
}
child_index += 1;
}
if !child_events.is_empty() {
slices.push((link_index, slice_start));
}
// Finally, inject the subevents.
let mut index = slices.len();
while index > 0 {
index -= 1;
debug_assert!(
slices[index].0 < events.len(),
"expected slice start in bounds"
);
map.add(slices[index].0, 2, child_events.split_off(slices[index].1));
}
(acc_before.0 + (slices.len() * 2), acc_before.1 + len)
}
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