use std::{any::Any, ops::Range, rc::Rc}; use ariadne::Report; use mlua::{Function, Lua}; use regex::Regex; use crate::{compiler::compiler::{Compiler, Target}, document::{document::Document, element::{ElemKind, Element}}, parser::{parser::Parser, rule::Rule, source::{Cursor, Source, Token}}}; // TODO: Full refactor // Problem is that document parsed from other sources i.e by variables // are not merged correctly into existing paragraph // A solution would be to use the "(\n){2,}" regex to split paragraph, which would reduce the work needed for process_text // Another fix would be to keep parsing (recursively) into the same document (like previous version) // The issue is that this would break the current `Token` implementation // Which would need to be reworked #[derive(Debug)] pub struct Paragraph { location: Token, pub content: Vec> } impl Paragraph { pub fn new(location: Token) -> Self { Self { location, content: Vec::new() } } pub fn is_empty(&self) -> bool { self.content.is_empty() } pub fn push(&mut self, elem: Box) { if elem.location().source() == self.location().source() { self.location.range = self.location.start() .. elem.location().end(); } self.content.push(elem); } pub fn find_back) -> bool>(&self, mut predicate: P) -> Option<&Box> { self.content.iter().rev() .find(predicate) } } impl Element for Paragraph { fn location(&self) -> &Token { &self.location } fn kind(&self) -> ElemKind { ElemKind::Special } fn element_name(&self) -> &'static str { "Paragraph" } fn to_string(&self) -> String { format!("{:#?}", self) } fn compile(&self, compiler: &Compiler, document: &Document) -> Result { if self.content.is_empty() { return Ok(String::new()) } match compiler.target() { Target::HTML => { let mut result = String::new(); //if prev.is_none() || prev.unwrap().downcast_ref::().is_none() { result.push_str("

"); } //else //{ result.push_str(" "); } let err = self.content.iter().try_for_each(|elem| { match elem.compile(compiler, document) { Err(e) => return Err(e), Ok(content) => { result.push_str(content.as_str()); Ok(()) }, } }); //if next.is_none() || next.unwrap().downcast_ref::().is_none() { result.push_str("

"); } match err { Err(e) => Err(e), Ok(()) => Ok(result), } } Target::LATEX => todo!("Unimplemented compiler") } } } pub struct ParagraphRule { re: Regex, } impl ParagraphRule { pub fn new() -> Self { Self { re: Regex::new(r"\n{2,}").unwrap() } } } impl Rule for ParagraphRule { fn name(&self) -> &'static str { "Paragraphing" } fn next_match(&self, cursor: &Cursor) -> Option<(usize, Box)> { self.re.find_at(cursor.source.content(), cursor.pos) .and_then(|m| Some((m.start(), Box::new([false;0]) as Box)) ) } fn on_match(&self, parser: &dyn Parser, document: &Document, cursor: Cursor, _match_data: Option>) -> (Cursor, Vec, Range)>>) { let end_cursor = match self.re.captures_at(cursor.source.content(), cursor.pos) { None => panic!("Unknown error"), Some(capture) => cursor.at(capture.get(0).unwrap().end()-1) }; parser.push(document, Box::new(Paragraph::new( Token::new(cursor.pos..end_cursor.pos, cursor.source.clone()) ))); (end_cursor, Vec::new()) } // TODO fn lua_bindings<'lua>(&self, _lua: &'lua Lua) -> Vec<(String, Function<'lua>)> { vec![] } }