#!/usr/bin/env python # # Copyright 2011-2013 The Rust Project Developers. See the COPYRIGHT # file at the top-level directory of this distribution and at # http://rust-lang.org/COPYRIGHT. # # Licensed under the Apache License, Version 2.0 or the MIT license # , at your # option. This file may not be copied, modified, or distributed # except according to those terms. # This script uses the following Unicode tables: # - DerivedCoreProperties.txt # - EastAsianWidth.txt # - PropList.txt # - Scripts.txt # - UnicodeData.txt # # Since this should not require frequent updates, we just store this # out-of-line and check the unicode.rs file into git. import fileinput, re, os, sys, operator preamble = '''// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. // NOTE: The following code was generated by "src/etc/unicode.py", do not edit directly #![allow(missing_docs, non_upper_case_globals, non_snake_case)] ''' # Mapping taken from Table 12 from: # http://www.unicode.org/reports/tr44/#General_Category_Values expanded_categories = { 'Lu': ['LC', 'L'], 'Ll': ['LC', 'L'], 'Lt': ['LC', 'L'], 'Lm': ['L'], 'Lo': ['L'], 'Mn': ['M'], 'Mc': ['M'], 'Me': ['M'], 'Nd': ['N'], 'Nl': ['N'], 'No': ['No'], 'Pc': ['P'], 'Pd': ['P'], 'Ps': ['P'], 'Pe': ['P'], 'Pi': ['P'], 'Pf': ['P'], 'Po': ['P'], 'Sm': ['S'], 'Sc': ['S'], 'Sk': ['S'], 'So': ['S'], 'Zs': ['Z'], 'Zl': ['Z'], 'Zp': ['Z'], 'Cc': ['C'], 'Cf': ['C'], 'Cs': ['C'], 'Co': ['C'], 'Cn': ['C'], } # Grapheme cluster data # taken from UAX29, http://www.unicode.org/reports/tr29/ # these code points are excluded from the Control category # NOTE: CR and LF are also technically excluded, but for # the sake of convenience we leave them in the Control group # and manually check them in the appropriate place. This is # still compliant with the implementation requirements. grapheme_control_exceptions = set([0x200c, 0x200d]) # the Regional_Indicator category grapheme_regional_indicator = [(0x1f1e6, 0x1f1ff)] # "The following ... are specifically excluded" from the SpacingMark category # http://www.unicode.org/reports/tr29/#SpacingMark grapheme_spacingmark_exceptions = [(0x102b, 0x102c), (0x1038, 0x1038), (0x1062, 0x1064), (0x1067, 0x106d), (0x1083, 0x1083), (0x1087, 0x108c), (0x108f, 0x108f), (0x109a, 0x109c), (0x19b0, 0x19b4), (0x19b8, 0x19b9), (0x19bb, 0x19c0), (0x19c8, 0x19c9), (0x1a61, 0x1a61), (0x1a63, 0x1a64), (0xaa7b, 0xaa7b), (0xaa7d, 0xaa7d)] # these are included in the SpacingMark category grapheme_spacingmark_extra = set([0xe33, 0xeb3]) def fetch(f): if not os.path.exists(f): os.system("curl -O http://www.unicode.org/Public/UNIDATA/%s" % f) if not os.path.exists(f): sys.stderr.write("cannot load %s" % f) exit(1) def is_valid_unicode(n): return 0 <= n <= 0xD7FF or 0xE000 <= n <= 0x10FFFF def load_unicode_data(f): fetch(f) gencats = {} upperlower = {} lowerupper = {} combines = {} canon_decomp = {} compat_decomp = {} for line in fileinput.input(f): fields = line.split(";") if len(fields) != 15: continue [code, name, gencat, combine, bidi, decomp, deci, digit, num, mirror, old, iso, upcase, lowcase, titlecase ] = fields code_org = code code = int(code, 16) if not is_valid_unicode(code): continue # generate char to char direct common and simple conversions # uppercase to lowercase if gencat == "Lu" and lowcase != "" and code_org != lowcase: upperlower[code] = int(lowcase, 16) # lowercase to uppercase if gencat == "Ll" and upcase != "" and code_org != upcase: lowerupper[code] = int(upcase, 16) # store decomposition, if given if decomp != "": if decomp.startswith('<'): seq = [] for i in decomp.split()[1:]: seq.append(int(i, 16)) compat_decomp[code] = seq else: seq = [] for i in decomp.split(): seq.append(int(i, 16)) canon_decomp[code] = seq # place letter in categories as appropriate for cat in [gencat, "Assigned"] + expanded_categories.get(gencat, []): if cat not in gencats: gencats[cat] = [] gencats[cat].append(code) # record combining class, if any if combine != "0": if combine not in combines: combines[combine] = [] combines[combine].append(code) # generate Not_Assigned from Assigned gencats["Cn"] = gen_unassigned(gencats["Assigned"]) # Assigned is not a real category del(gencats["Assigned"]) # Other contains Not_Assigned gencats["C"].extend(gencats["Cn"]) gencats = group_cats(gencats) combines = to_combines(group_cats(combines)) return (canon_decomp, compat_decomp, gencats, combines, lowerupper, upperlower) def group_cats(cats): cats_out = {} for cat in cats: cats_out[cat] = group_cat(cats[cat]) return cats_out def group_cat(cat): cat_out = [] letters = sorted(set(cat)) cur_start = letters.pop(0) cur_end = cur_start for letter in letters: assert letter > cur_end, \ "cur_end: %s, letter: %s" % (hex(cur_end), hex(letter)) if letter == cur_end + 1: cur_end = letter else: cat_out.append((cur_start, cur_end)) cur_start = cur_end = letter cat_out.append((cur_start, cur_end)) return cat_out def ungroup_cat(cat): cat_out = [] for (lo, hi) in cat: while lo <= hi: cat_out.append(lo) lo += 1 return cat_out def gen_unassigned(assigned): assigned = set(assigned) return ([i for i in range(0, 0xd800) if i not in assigned] + [i for i in range(0xe000, 0x110000) if i not in assigned]) def to_combines(combs): combs_out = [] for comb in combs: for (lo, hi) in combs[comb]: combs_out.append((lo, hi, comb)) combs_out.sort(key=lambda comb: comb[0]) return combs_out def format_table_content(f, content, indent): line = " "*indent first = True for chunk in content.split(","): if len(line) + len(chunk) < 98: if first: line += chunk else: line += ", " + chunk first = False else: f.write(line + ",\n") line = " "*indent + chunk f.write(line) def load_properties(f, interestingprops): fetch(f) props = {} re1 = re.compile("^([0-9A-F]+) +; (\w+)") re2 = re.compile("^([0-9A-F]+)\.\.([0-9A-F]+) +; (\w+)") for line in fileinput.input(f): prop = None d_lo = 0 d_hi = 0 m = re1.match(line) if m: d_lo = m.group(1) d_hi = m.group(1) prop = m.group(2) else: m = re2.match(line) if m: d_lo = m.group(1) d_hi = m.group(2) prop = m.group(3) else: continue if interestingprops and prop not in interestingprops: continue d_lo = int(d_lo, 16) d_hi = int(d_hi, 16) if prop not in props: props[prop] = [] props[prop].append((d_lo, d_hi)) return props # load all widths of want_widths, except those in except_cats def load_east_asian_width(want_widths, except_cats): f = "EastAsianWidth.txt" fetch(f) widths = {} re1 = re.compile("^([0-9A-F]+);(\w+) +# (\w+)") re2 = re.compile("^([0-9A-F]+)\.\.([0-9A-F]+);(\w+) +# (\w+)") for line in fileinput.input(f): width = None d_lo = 0 d_hi = 0 cat = None m = re1.match(line) if m: d_lo = m.group(1) d_hi = m.group(1) width = m.group(2) cat = m.group(3) else: m = re2.match(line) if m: d_lo = m.group(1) d_hi = m.group(2) width = m.group(3) cat = m.group(4) else: continue if cat in except_cats or width not in want_widths: continue d_lo = int(d_lo, 16) d_hi = int(d_hi, 16) if width not in widths: widths[width] = [] widths[width].append((d_lo, d_hi)) return widths def escape_char(c): return "'\\u{%x}'" % c def emit_bsearch_range_table(f): f.write(""" fn bsearch_range_table(c: char, r: &'static [(char,char)]) -> bool { use core::cmp::Ordering::{Equal, Less, Greater}; use core::slice::SliceExt; r.binary_search(|&(lo,hi)| { if lo <= c && c <= hi { Equal } else if hi < c { Less } else { Greater } }).found().is_some() }\n """) def emit_table(f, name, t_data, t_type = "&'static [(char, char)]", is_pub=True, pfun=lambda x: "(%s,%s)" % (escape_char(x[0]), escape_char(x[1]))): pub_string = "" if is_pub: pub_string = "pub " f.write(" %sstatic %s: %s = &[\n" % (pub_string, name, t_type)) data = "" first = True for dat in t_data: if not first: data += "," first = False data += pfun(dat) format_table_content(f, data, 8) f.write("\n ];\n\n") def emit_property_module(f, mod, tbl, emit_fn): f.write("pub mod %s {\n" % mod) keys = tbl.keys() keys.sort() for cat in keys: emit_table(f, "%s_table" % cat, tbl[cat]) if cat in emit_fn: f.write(" pub fn %s(c: char) -> bool {\n" % cat) f.write(" super::bsearch_range_table(c, %s_table)\n" % cat) f.write(" }\n\n") f.write("}\n\n") def emit_regex_module(f, cats, w_data): f.write("pub mod regex {\n") regex_class = "&'static [(char, char)]" class_table = "&'static [(&'static str, &'static %s)]" % regex_class emit_table(f, "UNICODE_CLASSES", cats, class_table, pfun=lambda x: "(\"%s\",&super::%s::%s_table)" % (x[0], x[1], x[0])) f.write(" pub static PERLD: &'static %s = &super::general_category::Nd_table;\n\n" % regex_class) f.write(" pub static PERLS: &'static %s = &super::property::White_Space_table;\n\n" % regex_class) emit_table(f, "PERLW", w_data, regex_class) f.write("}\n\n") def emit_conversions_module(f, lowerupper, upperlower): f.write("pub mod conversions {") f.write(""" use core::cmp::Ordering::{Equal, Less, Greater}; use core::slice::SliceExt; use core::option::Option; use core::option::Option::{Some, None}; use core::slice; pub fn to_lower(c: char) -> char { match bsearch_case_table(c, LuLl_table) { None => c, Some(index) => LuLl_table[index].1 } } pub fn to_upper(c: char) -> char { match bsearch_case_table(c, LlLu_table) { None => c, Some(index) => LlLu_table[index].1 } } fn bsearch_case_table(c: char, table: &'static [(char, char)]) -> Option { match table.binary_search(|&(key, _)| { if c == key { Equal } else if key < c { Less } else { Greater } }) { slice::BinarySearchResult::Found(i) => Some(i), slice::BinarySearchResult::NotFound(_) => None, } } """) emit_table(f, "LuLl_table", sorted(upperlower.iteritems(), key=operator.itemgetter(0)), is_pub=False) emit_table(f, "LlLu_table", sorted(lowerupper.iteritems(), key=operator.itemgetter(0)), is_pub=False) f.write("}\n\n") def emit_grapheme_module(f, grapheme_table, grapheme_cats): f.write("""pub mod grapheme { use core::kinds::Copy; use core::slice::SliceExt; pub use self::GraphemeCat::*; use core::slice; #[allow(non_camel_case_types)] #[derive(Clone)] pub enum GraphemeCat { """) for cat in grapheme_cats + ["Any"]: f.write(" GC_" + cat + ",\n") f.write(""" } impl Copy for GraphemeCat {} fn bsearch_range_value_table(c: char, r: &'static [(char, char, GraphemeCat)]) -> GraphemeCat { use core::cmp::Ordering::{Equal, Less, Greater}; match r.binary_search(|&(lo, hi, _)| { if lo <= c && c <= hi { Equal } else if hi < c { Less } else { Greater } }) { slice::BinarySearchResult::Found(idx) => { let (_, _, cat) = r[idx]; cat } slice::BinarySearchResult::NotFound(_) => GC_Any } } pub fn grapheme_category(c: char) -> GraphemeCat { bsearch_range_value_table(c, grapheme_cat_table) } """) emit_table(f, "grapheme_cat_table", grapheme_table, "&'static [(char, char, GraphemeCat)]", pfun=lambda x: "(%s,%s,GC_%s)" % (escape_char(x[0]), escape_char(x[1]), x[2]), is_pub=False) f.write("}\n") def emit_charwidth_module(f, width_table): f.write("pub mod charwidth {\n") f.write(" use core::option::Option;\n") f.write(" use core::option::Option::{Some, None};\n") f.write(" use core::slice::SliceExt;\n") f.write(" use core::slice;\n") f.write(""" fn bsearch_range_value_table(c: char, is_cjk: bool, r: &'static [(char, char, u8, u8)]) -> u8 { use core::cmp::Ordering::{Equal, Less, Greater}; match r.binary_search(|&(lo, hi, _, _)| { if lo <= c && c <= hi { Equal } else if hi < c { Less } else { Greater } }) { slice::BinarySearchResult::Found(idx) => { let (_, _, r_ncjk, r_cjk) = r[idx]; if is_cjk { r_cjk } else { r_ncjk } } slice::BinarySearchResult::NotFound(_) => 1 } } """) f.write(""" pub fn width(c: char, is_cjk: bool) -> Option { match c as uint { _c @ 0 => Some(0), // null is zero width cu if cu < 0x20 => None, // control sequences have no width cu if cu < 0x7F => Some(1), // ASCII cu if cu < 0xA0 => None, // more control sequences _ => Some(bsearch_range_value_table(c, is_cjk, charwidth_table) as uint) } } """) f.write(" // character width table. Based on Markus Kuhn's free wcwidth() implementation,\n") f.write(" // http://www.cl.cam.ac.uk/~mgk25/ucs/wcwidth.c\n") emit_table(f, "charwidth_table", width_table, "&'static [(char, char, u8, u8)]", is_pub=False, pfun=lambda x: "(%s,%s,%s,%s)" % (escape_char(x[0]), escape_char(x[1]), x[2], x[3])) f.write("}\n\n") def emit_norm_module(f, canon, compat, combine, norm_props): canon_keys = canon.keys() canon_keys.sort() compat_keys = compat.keys() compat_keys.sort() canon_comp = {} comp_exclusions = norm_props["Full_Composition_Exclusion"] for char in canon_keys: if True in map(lambda (lo, hi): lo <= char <= hi, comp_exclusions): continue decomp = canon[char] if len(decomp) == 2: if not canon_comp.has_key(decomp[0]): canon_comp[decomp[0]] = [] canon_comp[decomp[0]].append( (decomp[1], char) ) canon_comp_keys = canon_comp.keys() canon_comp_keys.sort() f.write("pub mod normalization {\n") def mkdata_fun(table): def f(char): data = "(%s,&[" % escape_char(char) first = True for d in table[char]: if not first: data += "," first = False data += escape_char(d) data += "])" return data return f f.write(" // Canonical decompositions\n") emit_table(f, "canonical_table", canon_keys, "&'static [(char, &'static [char])]", pfun=mkdata_fun(canon)) f.write(" // Compatibility decompositions\n") emit_table(f, "compatibility_table", compat_keys, "&'static [(char, &'static [char])]", pfun=mkdata_fun(compat)) def comp_pfun(char): data = "(%s,&[" % escape_char(char) canon_comp[char].sort(lambda x, y: x[0] - y[0]) first = True for pair in canon_comp[char]: if not first: data += "," first = False data += "(%s,%s)" % (escape_char(pair[0]), escape_char(pair[1])) data += "])" return data f.write(" // Canonical compositions\n") emit_table(f, "composition_table", canon_comp_keys, "&'static [(char, &'static [(char, char)])]", pfun=comp_pfun) f.write(""" fn bsearch_range_value_table(c: char, r: &'static [(char, char, u8)]) -> u8 { use core::cmp::Ordering::{Equal, Less, Greater}; use core::slice::SliceExt; use core::slice; match r.binary_search(|&(lo, hi, _)| { if lo <= c && c <= hi { Equal } else if hi < c { Less } else { Greater } }) { slice::BinarySearchResult::Found(idx) => { let (_, _, result) = r[idx]; result } slice::BinarySearchResult::NotFound(_) => 0 } }\n """) emit_table(f, "combining_class_table", combine, "&'static [(char, char, u8)]", is_pub=False, pfun=lambda x: "(%s,%s,%s)" % (escape_char(x[0]), escape_char(x[1]), x[2])) f.write(" pub fn canonical_combining_class(c: char) -> u8 {\n" + " bsearch_range_value_table(c, combining_class_table)\n" + " }\n") f.write(""" } """) def remove_from_wtable(wtable, val): wtable_out = [] while wtable: if wtable[0][1] < val: wtable_out.append(wtable.pop(0)) elif wtable[0][0] > val: break else: (wt_lo, wt_hi, width, width_cjk) = wtable.pop(0) if wt_lo == wt_hi == val: continue elif wt_lo == val: wtable_out.append((wt_lo+1, wt_hi, width, width_cjk)) elif wt_hi == val: wtable_out.append((wt_lo, wt_hi-1, width, width_cjk)) else: wtable_out.append((wt_lo, val-1, width, width_cjk)) wtable_out.append((val+1, wt_hi, width, width_cjk)) if wtable: wtable_out.extend(wtable) return wtable_out def optimize_width_table(wtable): wtable_out = [] w_this = wtable.pop(0) while wtable: if w_this[1] == wtable[0][0] - 1 and w_this[2:3] == wtable[0][2:3]: w_tmp = wtable.pop(0) w_this = (w_this[0], w_tmp[1], w_tmp[2], w_tmp[3]) else: wtable_out.append(w_this) w_this = wtable.pop(0) wtable_out.append(w_this) return wtable_out if __name__ == "__main__": r = "tables.rs" if os.path.exists(r): os.remove(r) with open(r, "w") as rf: # write the file's preamble rf.write(preamble) # download and parse all the data fetch("ReadMe.txt") with open("ReadMe.txt") as readme: pattern = "for Version (\d+)\.(\d+)\.(\d+) of the Unicode" unicode_version = re.search(pattern, readme.read()).groups() rf.write(""" /// The version of [Unicode](http://www.unicode.org/) /// that the `UnicodeChar` and `UnicodeStrPrelude` traits are based on. pub const UNICODE_VERSION: (uint, uint, uint) = (%s, %s, %s); """ % unicode_version) (canon_decomp, compat_decomp, gencats, combines, lowerupper, upperlower) = load_unicode_data("UnicodeData.txt") want_derived = ["XID_Start", "XID_Continue", "Alphabetic", "Lowercase", "Uppercase"] other_derived = ["Default_Ignorable_Code_Point", "Grapheme_Extend"] derived = load_properties("DerivedCoreProperties.txt", want_derived + other_derived) scripts = load_properties("Scripts.txt", []) props = load_properties("PropList.txt", ["White_Space", "Join_Control", "Noncharacter_Code_Point"]) norm_props = load_properties("DerivedNormalizationProps.txt", ["Full_Composition_Exclusion"]) # grapheme cluster category from DerivedCoreProperties # the rest are defined below grapheme_cats = {} grapheme_cats["Extend"] = derived["Grapheme_Extend"] del(derived["Grapheme_Extend"]) # bsearch_range_table is used in all the property modules below emit_bsearch_range_table(rf) # all of these categories will also be available as \p{} in libregex allcats = [] for (name, cat, pfuns) in ("general_category", gencats, ["N", "Cc"]), \ ("derived_property", derived, want_derived), \ ("script", scripts, []), \ ("property", props, ["White_Space"]): emit_property_module(rf, name, cat, pfuns) allcats.extend(map(lambda x: (x, name), cat)) allcats.sort(key=lambda c: c[0]) # the \w regex corresponds to Alphabetic + Mark + Decimal_Number + # Connector_Punctuation + Join-Control according to UTS#18 # http://www.unicode.org/reports/tr18/#Compatibility_Properties perl_words = [] for cat in derived["Alphabetic"], gencats["M"], gencats["Nd"], \ gencats["Pc"], props["Join_Control"]: perl_words.extend(ungroup_cat(cat)) perl_words = group_cat(perl_words) # emit lookup tables for \p{}, along with \d, \w, and \s for libregex emit_regex_module(rf, allcats, perl_words) # normalizations and conversions module emit_norm_module(rf, canon_decomp, compat_decomp, combines, norm_props) emit_conversions_module(rf, lowerupper, upperlower) ### character width module width_table = [] for zwcat in ["Me", "Mn", "Cf"]: width_table.extend(map(lambda (lo, hi): (lo, hi, 0, 0), gencats[zwcat])) width_table.append((4448, 4607, 0, 0)) # get widths, except those that are explicitly marked zero-width above ea_widths = load_east_asian_width(["W", "F", "A"], ["Me", "Mn", "Cf"]) # these are doublewidth for dwcat in ["W", "F"]: width_table.extend(map(lambda (lo, hi): (lo, hi, 2, 2), ea_widths[dwcat])) width_table.extend(map(lambda (lo, hi): (lo, hi, 1, 2), ea_widths["A"])) width_table.sort(key=lambda w: w[0]) # soft hyphen is not zero width in preformatted text; it's used to indicate # a hyphen inserted to facilitate a linebreak. width_table = remove_from_wtable(width_table, 173) # optimize the width table by collapsing adjacent entities when possible width_table = optimize_width_table(width_table) emit_charwidth_module(rf, width_table) ### grapheme cluster module # from http://www.unicode.org/reports/tr29/#Grapheme_Cluster_Break_Property_Values # Hangul syllable categories want_hangul = ["L", "V", "T", "LV", "LVT"] grapheme_cats.update(load_properties("HangulSyllableType.txt", want_hangul)) # Control # This category also includes Cs (surrogate codepoints), but Rust's `char`s are # Unicode Scalar Values only, and surrogates are thus invalid `char`s. grapheme_cats["Control"] = set() for cat in ["Zl", "Zp", "Cc", "Cf"]: grapheme_cats["Control"] |= set(ungroup_cat(gencats[cat])) grapheme_cats["Control"] = group_cat(list( grapheme_cats["Control"] - grapheme_control_exceptions | (set(ungroup_cat(gencats["Cn"])) & set(ungroup_cat(derived["Default_Ignorable_Code_Point"]))))) # Regional Indicator grapheme_cats["RegionalIndicator"] = grapheme_regional_indicator # Prepend - "Currently there are no characters with this value" # (from UAX#29, Unicode 7.0) # SpacingMark grapheme_cats["SpacingMark"] = group_cat(list( set(ungroup_cat(gencats["Mc"])) - set(ungroup_cat(grapheme_cats["Extend"])) | grapheme_spacingmark_extra - set(ungroup_cat(grapheme_spacingmark_exceptions)))) grapheme_table = [] for cat in grapheme_cats: grapheme_table.extend([(x, y, cat) for (x, y) in grapheme_cats[cat]]) grapheme_table.sort(key=lambda w: w[0]) emit_grapheme_module(rf, grapheme_table, grapheme_cats.keys())