/* * This file is part of `fmt` from the uutils coreutils package. * * (c) kwantam * * For the full copyright and license information, please view the LICENSE * file that was distributed with this source code. */ use core::iter::Peekable; use std::io::Lines; use std::slice::Iter; use std::str::CharRange; use FileOrStdReader; use FmtOptions; #[inline(always)] fn char_width(c: char) -> uint { if (c as uint) < 0xA0 { // if it is ASCII, call it exactly 1 wide (including control chars) // calling control chars' widths 1 is consistent with OpenBSD fmt 1 } else { // otherwise, get the unicode width // note that we shouldn't actually get None here because only c < 0xA0 // can return None, but for safety and future-proofing we do it this way c.width(false).unwrap_or(1) } } // lines with PSKIP, lacking PREFIX, or which are entirely blank are // NoFormatLines; otherwise, they are FormatLines #[derive(Show)] pub enum Line { FormatLine(FileLine), NoFormatLine(String, bool) } impl Line { // when we know that it's a FormatLine, as in the ParagraphStream iterator fn get_formatline(self) -> FileLine { match self { Line::FormatLine(fl) => fl, Line::NoFormatLine(..) => panic!("Found NoFormatLine when expecting FormatLine") } } // when we know that it's a NoFormatLine, as in the ParagraphStream iterator fn get_noformatline(self) -> (String, bool) { match self { Line::NoFormatLine(s, b) => (s, b), Line::FormatLine(..) => panic!("Found FormatLine when expecting NoFormatLine") } } } // each line's prefix has to be considered to know whether to merge it with // the next line or not #[derive(Show)] struct FileLine { line : String, indent_end : uint, // the end of the indent, always the start of the text pfxind_end : uint, // the end of the PREFIX's indent, that is, the spaces before the prefix indent_len : uint, // display length of indent taking into account tabs prefix_len : uint, // PREFIX indent length taking into account tabs } // iterator that produces a stream of Lines from a file pub struct FileLines<'a> { opts : &'a FmtOptions, lines : Lines<'a, FileOrStdReader>, } impl<'a> FileLines<'a> { fn new<'b>(opts: &'b FmtOptions, lines: Lines<'b, FileOrStdReader>) -> FileLines<'b> { FileLines { opts: opts, lines: lines } } // returns true if this line should be formatted fn match_prefix(&self, line: &str) -> (bool, uint) { if !self.opts.use_prefix { return (true, 0u); } FileLines::match_prefix_generic(self.opts.prefix.as_slice(), line, self.opts.xprefix) } // returns true if this line should be formatted fn match_anti_prefix(&self, line: &str) -> bool { if !self.opts.use_anti_prefix { return true; } match FileLines::match_prefix_generic(self.opts.anti_prefix.as_slice(), line, self.opts.xanti_prefix) { (true, _) => false, (_ , _) => true } } fn match_prefix_generic(pfx: &str, line: &str, exact: bool) -> (bool, uint) { if line.starts_with(pfx) { return (true, 0); } if !exact { // we do it this way rather than byte indexing to support unicode whitespace chars let mut i = 0u; while (i < line.len()) && line.char_at(i).is_whitespace() { i = match line.char_range_at(i) { CharRange { ch: _ , next: nxi } => nxi }; if line.slice_from(i).starts_with(pfx) { return (true, i); } } } (false, 0) } fn compute_indent(&self, string: &str, prefix_end: uint) -> (uint, uint, uint) { let mut prefix_len = 0; let mut indent_len = 0; let mut indent_end = 0; for (os, c) in string.char_indices() { if os == prefix_end { // we found the end of the prefix, so this is the printed length of the prefix here prefix_len = indent_len; } if (os >= prefix_end) && !c.is_whitespace() { // found first non-whitespace after prefix, this is indent_end indent_end = os; break; } else if c == '\t' { // compute tab length indent_len = (indent_len / self.opts.tabwidth + 1) * self.opts.tabwidth; } else { // non-tab character indent_len += char_width(c); } } (indent_end, prefix_len, indent_len) } } impl<'a> Iterator for FileLines<'a> { fn next(&mut self) -> Option { let n = match self.lines.next() { Some(t) => match t { Ok(tt) => tt, Err(_) => return None }, None => return None }; // if this line is entirely whitespace, // emit a blank line // Err(true) indicates that this was a linebreak, // which is important to know when detecting mail headers if n.as_slice().is_whitespace() { return Some(Line::NoFormatLine("\n".to_string(), true)); } // if this line does not match the prefix, // emit the line unprocessed and iterate again let (pmatch, poffset) = self.match_prefix(n.as_slice()); if !pmatch { return Some(Line::NoFormatLine(n, false)); } else if n.as_slice().slice_from(poffset + self.opts.prefix.len()).is_whitespace() { // if the line matches the prefix, but is blank after, // don't allow lines to be combined through it (that is, // treat it like a blank line, except that since it's // not truly blank we will not allow mail headers on the // following line) return Some(Line::NoFormatLine(n, false)); } // skip if this line matches the anti_prefix // (NOTE definition of match_anti_prefix is TRUE if we should process) if !self.match_anti_prefix(n.as_slice()) { return Some(Line::NoFormatLine(n, false)); } // figure out the indent, prefix, and prefixindent ending points let prefix_end = poffset + self.opts.prefix.len(); let (indent_end, prefix_len, indent_len) = self.compute_indent(n.as_slice(), prefix_end); Some(Line::FormatLine(FileLine { line : n, indent_end : indent_end, pfxind_end : poffset, indent_len : indent_len, prefix_len : prefix_len })) } } // a paragraph : a collection of FileLines that are to be formatted // plus info about the paragraph's indentation // (but we only retain the String from the FileLine; the other info // is only there to help us in deciding how to merge lines into Paragraphs #[derive(Show)] pub struct Paragraph { lines : Vec, // the lines of the file pub init_str : String, // string representing the init, that is, the first line's indent pub init_len : uint, // printable length of the init string considering TABWIDTH init_end : uint, // byte location of end of init in first line String pub indent_str : String, // string representing indent pub indent_len : uint, // length of above indent_end : uint, // byte location of end of indent (in crown and tagged mode, only applies to 2nd line and onward) pub mail_header : bool // we need to know if this is a mail header because we do word splitting differently in that case } // an iterator producing a stream of paragraphs from a stream of lines // given a set of options. pub struct ParagraphStream<'a> { lines : Peekable>, next_mail : bool, opts : &'a FmtOptions, } impl<'a> ParagraphStream<'a> { pub fn new<'b>(opts: &'b FmtOptions, reader: &'b mut FileOrStdReader) -> ParagraphStream<'b> { let lines = FileLines::new(opts, reader.lines()).peekable(); // at the beginning of the file, we might find mail headers ParagraphStream { lines: lines, next_mail: true, opts: opts } } // detect RFC822 mail header fn is_mail_header(line: &FileLine) -> bool { // a mail header begins with either "From " (envelope sender line) // or with a sequence of printable ASCII chars (33 to 126, inclusive, // except colon) followed by a colon. if line.indent_end > 0 { false } else { let l_slice = line.line.as_slice(); if l_slice.starts_with("From ") { true } else { let colon_posn = match l_slice.find(':') { Some(n) => n, None => return false }; // header field must be nonzero length if colon_posn == 0 { return false; } return l_slice.slice_to(colon_posn).chars().all(|x| match x as uint { y if y < 33 || y > 126 => false, _ => true }); } } } } impl<'a> Iterator> for ParagraphStream<'a> { fn next(&mut self) -> Option> { // return a NoFormatLine in an Err; it should immediately be output let noformat = match self.lines.peek() { None => return None, Some(l) => match l { &Line::FormatLine(_) => false, &Line::NoFormatLine(_, _) => true } }; // found a NoFormatLine, immediately dump it out if noformat { let (s, nm) = self.lines.next().unwrap().get_noformatline(); self.next_mail = nm; return Some(Err(s)); } // found a FormatLine, now build a paragraph let mut init_str = String::new(); let mut init_end = 0; let mut init_len = 0; let mut indent_str = String::new(); let mut indent_end = 0; let mut indent_len = 0; let mut prefix_len = 0; let mut pfxind_end = 0; let mut p_lines = Vec::new(); let mut in_mail = false; let mut second_done = false; // for when we use crown or tagged mode loop { { // peek ahead // need to explicitly force fl out of scope before we can call self.lines.next() let fl = match self.lines.peek() { None => break, Some(l) => { match l { &Line::FormatLine(ref x) => x, &Line::NoFormatLine(..) => break } } }; if p_lines.len() == 0 { // first time through the loop, get things set up // detect mail header if self.opts.mail && self.next_mail && ParagraphStream::is_mail_header(fl) { in_mail = true; // there can't be any indent or pfxind because otherwise is_mail_header would fail // since there cannot be any whitespace before the colon in a valid header field indent_str.push_str(" "); indent_len = 2; } else { if self.opts.crown || self.opts.tagged { init_str.push_str(fl.line.as_slice().slice_to(fl.indent_end)); init_len = fl.indent_len; init_end = fl.indent_end; } else { second_done = true; } // these will be overwritten in the 2nd line of crown or tagged mode, but // we are not guaranteed to get to the 2nd line, e.g., if the next line // is a NoFormatLine or None. Thus, we set sane defaults the 1st time around indent_str.push_str(fl.line.as_slice().slice_to(fl.indent_end)); indent_len = fl.indent_len; indent_end = fl.indent_end; // save these to check for matching lines prefix_len = fl.prefix_len; pfxind_end = fl.pfxind_end; // in tagged mode, add 4 spaces of additional indenting by default // (gnu fmt's behavior is different: it seems to find the closest column to // indent_end that is divisible by 3. But honesly that behavior seems // pretty arbitrary. // Perhaps a better default would be 1 TABWIDTH? But ugh that's so big. if self.opts.tagged { indent_str.push_str(" "); indent_len += 4; } } } else if in_mail { // lines following mail headers must begin with spaces if fl.indent_end == 0 || (self.opts.use_prefix && fl.pfxind_end == 0) { break; // this line does not begin with spaces } } else if !second_done { // now we have enough info to handle crown margin and tagged mode if prefix_len != fl.prefix_len || pfxind_end != fl.pfxind_end { // in both crown and tagged modes we require that prefix_len is the same break; } else if self.opts.tagged && indent_len - 4 == fl.indent_len && indent_end == fl.indent_end { // in tagged mode, indent has to be *different* on following lines break; } else { // this is part of the same paragraph, get the indent info from this line indent_str.clear(); indent_str.push_str(fl.line.as_slice().slice_to(fl.indent_end)); indent_len = fl.indent_len; indent_end = fl.indent_end; } second_done = true; } else { // detect mismatch if indent_end != fl.indent_end || pfxind_end != fl.pfxind_end || indent_len != fl.indent_len || prefix_len != fl.prefix_len { break; } } } p_lines.push(self.lines.next().unwrap().get_formatline().line); // when we're in split-only mode, we never join lines, so stop here if self.opts.split_only { break; } } // if this was a mail header, then the next line can be detected as one. Otherwise, it cannot. // NOTE next_mail is true at ParagraphStream instantiation, and is set to true after a blank // NoFormatLine. self.next_mail = in_mail; Some(Ok(Paragraph { lines : p_lines, init_str : init_str, init_len : init_len, init_end : init_end, indent_str : indent_str, indent_len : indent_len, indent_end : indent_end, mail_header : in_mail })) } } pub struct ParaWords<'a> { opts : &'a FmtOptions, para : &'a Paragraph, words : Vec> } impl<'a> ParaWords<'a> { pub fn new<'b>(opts: &'b FmtOptions, para: &'b Paragraph) -> ParaWords<'b> { let mut pw = ParaWords { opts: opts, para: para, words: Vec::new() }; pw.create_words(); pw } fn create_words<'r>(&'r mut self) { if self.para.mail_header { // no extra spacing for mail headers; always exactly 1 space // safe to trim_left on every line of a mail header, since the // first line is guaranteed not to have any spaces self.words.extend(self.para.lines.iter().flat_map(|x| x.as_slice().words()).map(|x| WordInfo { word : x, word_start : 0, word_nchars : x.len(), // OK for mail headers; only ASCII allowed (unicode is escaped) before_tab : None, after_tab : 0, sentence_start : false, ends_punct : false, new_line : false })); } else { // first line self.words.extend( if self.opts.crown || self.opts.tagged { // crown and tagged mode has the "init" in the first line, so slice from there WordSplit::new(self.opts, self.para.lines[0].as_slice().slice_from(self.para.init_end)) } else { // otherwise we slice from the indent WordSplit::new(self.opts, self.para.lines[0].as_slice().slice_from(self.para.indent_end)) }); if self.para.lines.len() > 1 { let indent_end = self.para.indent_end; let opts = self.opts; self.words.extend( self.para.lines.iter().skip(1).flat_map(|x| WordSplit::new(opts, x.as_slice().slice_from(indent_end)))); } } } pub fn words(&'a self) -> Iter<'a, WordInfo<'a>> { return self.words.iter() } } struct WordSplit<'a> { opts : &'a FmtOptions, string : &'a str, length : uint, position : uint, prev_punct : bool } impl<'a> WordSplit<'a> { fn analyze_tabs(&self, string: &str) -> (Option, uint, Option) { // given a string, determine (length before tab) and (printed length after first tab) // if there are no tabs, beforetab = -1 and aftertab is the printed length let mut beforetab = None; let mut aftertab = 0; let mut word_start = None; for (os, c) in string.char_indices() { if !c.is_whitespace() { word_start = Some(os); break; } else if c == '\t' { if beforetab == None { beforetab = Some(aftertab); aftertab = 0; } else { aftertab = (aftertab / self.opts.tabwidth + 1) * self.opts.tabwidth; } } else { aftertab += 1; } } (beforetab, aftertab, word_start) } } impl<'a> WordSplit<'a> { fn new<'b>(opts: &'b FmtOptions, string: &'b str) -> WordSplit<'b> { // wordsplits *must* start at a non-whitespace character let trim_string = string.trim_left(); WordSplit { opts: opts, string: trim_string, length: string.len(), position: 0, prev_punct: false } } fn is_punctuation(c: char) -> bool { match c { '!' | '.' | '?' => true, _ => false } } } pub struct WordInfo<'a> { pub word : &'a str, pub word_start : uint, pub word_nchars : uint, pub before_tab : Option, pub after_tab : uint, pub sentence_start : bool, pub ends_punct : bool, pub new_line : bool } // returns (&str, is_start_of_sentence) impl<'a> Iterator> for WordSplit<'a> { fn next(&mut self) -> Option> { if self.position >= self.length { return None } let old_position = self.position; let new_line = old_position == 0; // find the start of the next word, and record if we find a tab character let (before_tab, after_tab, word_start) = match self.analyze_tabs(self.string.slice_from(old_position)) { (b, a, Some(s)) => (b, a, s + old_position), (_, _, None) => { self.position = self.length; return None; } }; // find the beginning of the next whitespace // note that this preserves the invariant that self.position // points to whitespace character OR end of string let mut word_nchars = 0; self.position = match self.string.slice_from(word_start) .find(|&mut: x: char| if !x.is_whitespace() { word_nchars += char_width(x); false } else { true }) { None => self.length, Some(s) => s + word_start }; let word_start_relative = word_start - old_position; // if the previous sentence was punctuation and this sentence has >2 whitespace or one tab, is a new sentence. let is_start_of_sentence = self.prev_punct && (before_tab.is_some() || word_start_relative > 1); // now record whether this word ends in punctuation self.prev_punct = match self.string.char_range_at_reverse(self.position) { CharRange { ch, next: _ } => WordSplit::is_punctuation(ch) }; let (word, word_start_relative, before_tab, after_tab) = if self.opts.uniform { (self.string.slice(word_start, self.position), 0, None, 0) } else { (self.string.slice(old_position, self.position), word_start_relative, before_tab, after_tab) }; Some(WordInfo { word : word, word_start : word_start_relative, word_nchars : word_nchars, before_tab : before_tab, after_tab : after_tab, sentence_start : is_start_of_sentence, ends_punct : self.prev_punct, new_line : new_line }) } }