use std::borrow::ToOwned; use std::collections::HashMap; use std::fmt::Write; use std::io::BufRead; use std::iter::Iterator; pub struct Config {} const HEADER: &str = r#" "#; const FOOTER: &str = "

"; #[derive(PartialEq, Eq, Debug)] pub struct HTML(String); impl HTML { fn escape(value: &str) -> HTML { let mut escaped: String = String::new(); for c in value.chars() { match c { '>' => escaped.push_str(">"), '<' => escaped.push_str("<"), '\'' => escaped.push_str("'"), '"' => escaped.push_str("""), '&' => escaped.push_str("&"), ok_c => escaped.push(ok_c), } } HTML(escaped) } } impl From<&str> for HTML { fn from(value: &str) -> HTML { HTML(String::from(value)) } } impl FromIterator for HTML { fn from_iter(iter: T) -> HTML where T: IntoIterator, { HTML(iter.into_iter().map(|html| html.0).collect::()) } } impl std::fmt::Display for HTML { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { write!(f, "{}", self.0) } } #[derive(Debug, PartialEq, Eq)] enum InputLine<'a> { Blank, RowHeader(&'a str), Entry(&'a str, Option<&'a str>), } impl<'a> From<&'a str> for InputLine<'a> { fn from(value: &'a str) -> InputLine<'a> { let trimmed = value.trim_end(); if trimmed.is_empty() { InputLine::Blank } else if !trimmed.starts_with(' ') { InputLine::RowHeader(value.trim()) } else { match value.split_once(':') { None => InputLine::Entry(value.trim(), None), Some((col, instance)) => InputLine::Entry(col.trim(), Some(instance.trim())), } } } } #[derive(Debug, PartialEq, Eq)] struct Row { label: String, entries: HashMap>>, } struct Reader>> { input: std::iter::Enumerate, row: Option, } impl>> Reader { fn new(input: Input) -> Self { Self { input: input.enumerate(), row: None, } } } impl>> Iterator for Reader { type Item = Result; fn next(&mut self) -> Option { loop { match self.input.next() { None => return Ok(std::mem::take(&mut self.row)).transpose(), Some((_, Err(e))) => return Some(Err(e)), Some((n, Ok(line))) => match InputLine::from(line.as_ref()) { InputLine::Blank if self.row.is_some() => { return Ok(std::mem::take(&mut self.row)).transpose() } InputLine::Blank => {} InputLine::Entry(col, instance) => match &mut self.row { None => { return Some(Err(std::io::Error::other(format!( "{}: Entry with no header", n + 1 )))) } Some(ref mut row) => { row.entries .entry(col.to_owned()) .and_modify(|is| is.push(instance.map(ToOwned::to_owned))) .or_insert_with(|| vec![instance.map(ToOwned::to_owned)]); } }, InputLine::RowHeader(row) => { let prev = std::mem::take(&mut self.row); self.row = Some(Row { label: row.to_owned(), entries: HashMap::new(), }); if prev.is_some() { return Ok(prev).transpose(); } } }, } } } } fn read_rows(input: impl std::io::Read) -> impl Iterator> { Reader::new(std::io::BufReader::new(input).lines()) } fn column_counts(rows: &[Row]) -> Vec<(usize, String)> { let mut counts: Vec<_> = rows .iter() .flat_map(|r| r.entries.keys()) .fold(HashMap::new(), |mut cs, col| { cs.entry(col.to_owned()) .and_modify(|n| *n += 1) .or_insert(1); cs }) .into_iter() .map(|(col, n)| (n, col)) .collect(); counts.sort_unstable_by(|(an, acol), (bn, bcol)| bn.cmp(an).then(acol.cmp(bcol))); counts } fn column_order(rows: &[Row]) -> Vec { column_counts(rows) .into_iter() .map(|(_, col)| col) .collect() } fn render_instance(instance: &Option) -> HTML { match instance { None => HTML::from("✓"), Some(instance) => HTML::escape(instance.as_ref()), } } fn render_cell(col: &str, row: &mut Row) -> HTML { let row_label = HTML::escape(row.label.as_ref()); let col_label = HTML::escape(col); let instances: Option<&Vec>> = row.entries.get(col); let class = HTML::from(if instances.is_none() { "" } else { "yes" }); let all_empty = instances .iter() .flat_map(|is| is.iter()) .all(Option::is_none); let contents = if instances.is_none() || (all_empty && instances.unwrap().len() == 1) { HTML::from("") } else if all_empty { HTML(format!("{}", instances.unwrap().len())) } else { HTML( instances .unwrap() .iter() .map(render_instance) .map(|html| html.0) // Waiting for slice_concat_trait to stabilize .collect::>() .join(" "), ) }; row.entries.remove(col); HTML(format!( r#"{contents}"# )) } fn render_row(columns: &[String], row: &mut Row) -> HTML { let row_label = HTML::escape(row.label.as_ref()); HTML(format!( "{row_label}{}\n", &columns .iter() .map(|col| render_cell(col, row)) .collect::() )) } fn render_column_headers(columns: &[String]) -> HTML { HTML( String::from(r#""#) + &columns.iter().fold(String::new(), |mut acc, col| { let col_header = HTML::escape(col.as_ref()); write!( &mut acc, r#"

{col_header}

"# ) .unwrap(); acc }) + "\n", ) } /// # Errors /// /// Will return `Err` if /// * there's an i/o error while reading `input` /// * the log has invalid syntax: /// * an indented line with no preceding non-indented line pub fn tablify(config: &Config, input: impl std::io::Read) -> Result { let rows = read_rows(input).collect::, _>>()?; let columns = column_order(&rows); Ok(HTML(format!( "{HEADER}{}{}{FOOTER}", render_column_headers(&columns), rows.into_iter() .map(|mut r| render_row(&columns, &mut r)) .collect::() ))) } #[cfg(test)] mod tests { use super::*; #[test] fn test_parse_line() { assert_eq!(InputLine::from(""), InputLine::Blank); assert_eq!(InputLine::from(" "), InputLine::Blank); assert_eq!(InputLine::from("foo"), InputLine::RowHeader("foo")); assert_eq!(InputLine::from("foo "), InputLine::RowHeader("foo")); assert_eq!(InputLine::from(" foo"), InputLine::Entry("foo", None)); assert_eq!( InputLine::from(" foo:bar"), InputLine::Entry("foo", Some("bar")) ); assert_eq!( InputLine::from(" foo: bar"), InputLine::Entry("foo", Some("bar")) ); assert_eq!( InputLine::from(" foo: bar "), InputLine::Entry("foo", Some("bar")) ); assert_eq!( InputLine::from(" foo: bar "), InputLine::Entry("foo", Some("bar")) ); assert_eq!( InputLine::from(" foo : bar "), InputLine::Entry("foo", Some("bar")) ); } #[test] fn test_read_rows() { assert_eq!( read_rows(&b"foo"[..]).flatten().collect::>(), vec![Row { label: "foo".to_owned(), entries: HashMap::new(), }] ); assert_eq!( read_rows(&b"bar"[..]).flatten().collect::>(), vec![Row { label: "bar".to_owned(), entries: HashMap::new(), }] ); assert_eq!( read_rows(&b"foo\nbar\n"[..]).flatten().collect::>(), vec![ Row { label: "foo".to_owned(), entries: HashMap::new(), }, Row { label: "bar".to_owned(), entries: HashMap::new(), } ] ); assert_eq!( read_rows(&b"foo\n bar\n"[..]).flatten().collect::>(), vec![Row { label: "foo".to_owned(), entries: HashMap::from([("bar".to_owned(), vec![None])]), }] ); assert_eq!( read_rows(&b"foo\n bar\n baz\n"[..]) .flatten() .collect::>(), vec![Row { label: "foo".to_owned(), entries: HashMap::from([ ("bar".to_owned(), vec![None]), ("baz".to_owned(), vec![None]) ]), }] ); assert_eq!( read_rows(&b"foo\n\nbar\n"[..]) .flatten() .collect::>(), vec![ Row { label: "foo".to_owned(), entries: HashMap::new(), }, Row { label: "bar".to_owned(), entries: HashMap::new(), } ] ); assert_eq!( read_rows(&b"foo\n \nbar\n"[..]) .flatten() .collect::>(), vec![ Row { label: "foo".to_owned(), entries: HashMap::new(), }, Row { label: "bar".to_owned(), entries: HashMap::new(), } ] ); assert_eq!( read_rows(&b"foo \n bar \n"[..]) .flatten() .collect::>(), vec![Row { label: "foo".to_owned(), entries: HashMap::from([("bar".to_owned(), vec![None])]), }] ); let bad = read_rows(&b" foo"[..]).next().unwrap(); assert!(bad.is_err()); assert!(format!("{bad:?}").contains("1: Entry with no header")); let bad2 = read_rows(&b"foo\n\n bar"[..]).nth(1).unwrap(); assert!(bad2.is_err()); assert!(format!("{bad2:?}").contains("3: Entry with no header")); } #[test] fn test_column_counts() { assert_eq!( column_counts( &read_rows(&b"foo\n bar\n baz\n"[..]) .collect::, _>>() .unwrap() ), vec![(1, String::from("bar")), (1, String::from("baz"))] ); assert_eq!( column_counts( &read_rows(&b"foo\n bar\n baz\nquux\n baz"[..]) .collect::, _>>() .unwrap() ), vec![(2, String::from("baz")), (1, String::from("bar"))] ); assert_eq!( column_counts( &read_rows(&b"foo\n bar\n bar\n baz\n bar\nquux\n baz"[..]) .collect::, _>>() .unwrap() ), vec![(2, String::from("baz")), (1, String::from("bar"))] ); assert_eq!( column_counts( &read_rows(&b"foo\n bar: 1\n bar: 2\n baz\n bar\nquux\n baz"[..]) .collect::, _>>() .unwrap() ), vec![(2, String::from("baz")), (1, String::from("bar"))] ); } #[test] fn test_render_cell() { assert_eq!( render_cell( "foo", &mut Row { label: "nope".to_owned(), entries: HashMap::new(), } ), HTML::from( r#""# ) ); assert_eq!( render_cell( "foo", &mut Row { label: "nope".to_owned(), entries: HashMap::from([("bar".to_owned(), vec![None])]), } ), HTML::from( r#""# ) ); assert_eq!( render_cell( "foo", &mut Row { label: "nope".to_owned(), entries: HashMap::from([("foo".to_owned(), vec![None])]), } ), HTML::from( r#""# ) ); assert_eq!( render_cell( "foo", &mut Row { label: "nope".to_owned(), entries: HashMap::from([("foo".to_owned(), vec![None, None])]), } ), HTML::from( r#"2"# ) ); assert_eq!( render_cell( "foo", &mut Row { label: "nope".to_owned(), entries: HashMap::from([( "foo".to_owned(), vec![Some("5".to_owned()), Some("10".to_owned())] )]), } ), HTML::from( r#"5 10"# ) ); assert_eq!( render_cell( "foo", &mut Row { label: "nope".to_owned(), entries: HashMap::from([("foo".to_owned(), vec![Some("5".to_owned()), None])]), } ), HTML::from( r#"5 ✓"# ) ); assert_eq!( render_cell( "heart", &mut Row { label: "nope".to_owned(), entries: HashMap::from([("heart".to_owned(), vec![Some("<3".to_owned())])]), } ), HTML::from( r#"<3"# ) ); assert_eq!( render_cell( "foo", &mut Row { label: "bob's".to_owned(), entries: HashMap::from([("foo".to_owned(), vec![None])]), } ), HTML::from( r#""# ) ); let mut r = Row { label: "nope".to_owned(), entries: HashMap::from([ ("foo".to_owned(), vec![None]), ("baz".to_owned(), vec![None]), ]), }; assert_eq!(r.entries.len(), 2); render_cell("foo", &mut r); assert_eq!(r.entries.len(), 1); render_cell("bar", &mut r); assert_eq!(r.entries.len(), 1); render_cell("baz", &mut r); assert_eq!(r.entries.len(), 0); } #[test] fn test_render_row() { assert_eq!( render_row( &["foo".to_owned()], &mut Row { label: "nope".to_owned(), entries: HashMap::from([("bar".to_owned(), vec![None])]), } ), HTML::from( r#"nope "# ) ); } }