third_party/rust_crates/vendor/unicode-normalization/scripts/unicode.py - fuchsia - Git at Google

 #!/usr/bin/env python
 #
 # Copyright 2011-2018 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 <LICENSE-APACHE or
 # http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
 # <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
 # option. This file may not be copied, modified, or distributed
 # except according to those terms.

 # This script uses the following Unicode tables:
 # - DerivedNormalizationProps.txt
 # - NormalizationTest.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 collections
 import requests

 UNICODE_VERSION = "9.0.0"
 UCD_URL = "https://www.unicode.org/Public/%s/ucd/" % UNICODE_VERSION

 PREAMBLE = """// Copyright 2012-2018 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 <LICENSE-APACHE or
 // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
 // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
 // option. This file may not be copied, modified, or distributed
 // except according to those terms.

 // NOTE: The following code was generated by "scripts/unicode.py", do not edit directly

 #![allow(missing_docs)]
 """

 NormalizationTest = collections.namedtuple(
     "NormalizationTest",
     ["source", "nfc", "nfd", "nfkc", "nfkd"],
 )

 # 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'],
 }

 class UnicodeData(object):
     def __init__(self):
         self._load_unicode_data()
         self.norm_props = self._load_norm_props()
         self.norm_tests = self._load_norm_tests()

         self.canon_comp = self._compute_canonical_comp()
         self.canon_fully_decomp, self.compat_fully_decomp = self._compute_fully_decomposed()

         def stats(name, table):
             count = sum(len(v) for v in table.values())
             print "%s: %d chars => %d decomposed chars" % (name, len(table), count)

         print "Decomposition table stats:"
         stats("Canonical decomp", self.canon_decomp)
         stats("Compatible decomp", self.compat_decomp)
         stats("Canonical fully decomp", self.canon_fully_decomp)
         stats("Compatible fully decomp", self.compat_fully_decomp)

         self.ss_leading, self.ss_trailing = self._compute_stream_safe_tables()

     def _fetch(self, filename):
         resp = requests.get(UCD_URL + filename)
         return resp.text

     def _load_unicode_data(self):
         self.combining_classes = {}
         self.compat_decomp = {}
         self.canon_decomp = {}
         self.general_category_mark = []

         for line in self._fetch("UnicodeData.txt").splitlines():
             # See ftp://ftp.unicode.org/Public/3.0-Update/UnicodeData-3.0.0.html
             pieces = line.split(';')
             assert len(pieces) == 15
             char, category, cc, decomp = pieces[0], pieces[2], pieces[3], pieces[5]
             char_int = int(char, 16)

             if cc != '0':
                 self.combining_classes[char_int] = cc

             if decomp.startswith('<'):
                 self.compat_decomp[char_int] = [int(c, 16) for c in decomp.split()[1:]]
             elif decomp != '':
                 self.canon_decomp[char_int] = [int(c, 16) for c in decomp.split()]

             if category == 'M' or 'M' in expanded_categories.get(category, []):
                 self.general_category_mark.append(char_int)

     def _load_norm_props(self):
         props = collections.defaultdict(list)

         for line in self._fetch("DerivedNormalizationProps.txt").splitlines():
             (prop_data, _, _) = line.partition("#")
             prop_pieces = prop_data.split(";")

             if len(prop_pieces) < 2:
                 continue

             assert len(prop_pieces) <= 3
             (low, _, high) = prop_pieces[0].strip().partition("..")

             prop = prop_pieces[1].strip()

             data = None
             if len(prop_pieces) == 3:
                 data = prop_pieces[2].strip()

             props[prop].append((low, high, data))

         return props

     def _load_norm_tests(self):
         tests = []
         for line in self._fetch("NormalizationTest.txt").splitlines():
             (test_data, _, _) = line.partition("#")
             test_pieces = test_data.split(";")

             if len(test_pieces) < 5:
                 continue

             source, nfc, nfd, nfkc, nfkd = [[c.strip() for c in p.split()] for p in test_pieces[:5]]
             tests.append(NormalizationTest(source, nfc, nfd, nfkc, nfkd))

         return tests

     def _compute_canonical_comp(self):
         canon_comp = {}
         comp_exclusions = [
             (int(low, 16), int(high or low, 16))
             for low, high, _ in self.norm_props["Full_Composition_Exclusion"]
         ]
         for char_int, decomp in self.canon_decomp.items():
             if any(lo <= char_int <= hi for lo, hi in comp_exclusions):
                 continue

             assert len(decomp) == 2
             assert (decomp[0], decomp[1]) not in canon_comp
             canon_comp[(decomp[0], decomp[1])] = char_int

         return canon_comp

     def _compute_fully_decomposed(self):
         """
         Even though the decomposition algorithm is recursive, it is possible
         to precompute the recursion at table generation time with modest
         increase to the table size.  Then, for these precomputed tables, we
         note that 1) compatible decomposition is a subset of canonical
         decomposition and 2) they mostly agree on their intersection.
         Therefore, we don't store entries in the compatible table for
         characters that decompose the same way under canonical decomposition.

             Decomposition table stats:
             Canonical decomp: 2060 chars => 3085 decomposed chars
             Compatible decomp: 3662 chars => 5440 decomposed chars
             Canonical fully decomp: 2060 chars => 3404 decomposed chars
             Compatible fully decomp: 3678 chars => 5599 decomposed chars

         The upshot is that decomposition code is very simple and easy to inline
         at mild code size cost.
         """
         # Constants from Unicode 9.0.0 Section 3.12 Conjoining Jamo Behavior
         # http://www.unicode.org/versions/Unicode9.0.0/ch03.pdf#M9.32468.Heading.310.Combining.Jamo.Behavior
         S_BASE, L_COUNT, V_COUNT, T_COUNT = 0xAC00, 19, 21, 28
         S_COUNT = L_COUNT * V_COUNT * T_COUNT

         def _decompose(char_int, compatible):
             # 7-bit ASCII never decomposes
             if char_int <= 0x7f:
                 yield char_int
                 return

             # Assert that we're handling Hangul separately.
             assert not (S_BASE <= char_int < S_BASE + S_COUNT)

             decomp = self.canon_decomp.get(char_int)
             if decomp is not None:
                 for decomposed_ch in decomp:
                     for fully_decomposed_ch in _decompose(decomposed_ch, compatible):
                         yield fully_decomposed_ch
                 return

             if compatible and char_int in self.compat_decomp:
                 for decomposed_ch in self.compat_decomp[char_int]:
                     for fully_decomposed_ch in _decompose(decomposed_ch, compatible):
                         yield fully_decomposed_ch
                 return

             yield char_int
             return

         end_codepoint = max(
             max(self.canon_decomp.keys()),
             max(self.compat_decomp.keys()),
         )

         canon_fully_decomp = {}
         compat_fully_decomp = {}

         for char_int in range(0, end_codepoint + 1):
             # Always skip Hangul, since it's more efficient to represent its
             # decomposition programmatically.
             if S_BASE <= char_int < S_BASE + S_COUNT:
                 continue

             canon = list(_decompose(char_int, False))
             if not (len(canon) == 1 and canon[0] == char_int):
                 canon_fully_decomp[char_int] = canon

             compat = list(_decompose(char_int, True))
             if not (len(compat) == 1 and compat[0] == char_int):
                 compat_fully_decomp[char_int] = compat

         # Since canon_fully_decomp is a subset of compat_fully_decomp, we don't
         # need to store their overlap when they agree.  When they don't agree,
         # store the decomposition in the compatibility table since we'll check
         # that first when normalizing to NFKD.
         assert canon_fully_decomp <= compat_fully_decomp

         for ch in set(canon_fully_decomp) & set(compat_fully_decomp):
             if canon_fully_decomp[ch] == compat_fully_decomp[ch]:
                 del compat_fully_decomp[ch]

         return canon_fully_decomp, compat_fully_decomp

     def _compute_stream_safe_tables(self):
         """
         To make a text stream-safe with the Stream-Safe Text Process (UAX15-D4),
         we need to be able to know the number of contiguous non-starters *after*
         applying compatibility decomposition to each character.

         We can do this incrementally by computing the number of leading and
         trailing non-starters for each character's compatibility decomposition
         with the following rules:

         1) If a character is not affected by compatibility decomposition, look
            up its canonical combining class to find out if it's a non-starter.
         2) All Hangul characters are starters, even under decomposition.
         3) Otherwise, very few decomposing characters have a nonzero count
            of leading or trailing non-starters, so store these characters
            with their associated counts in a separate table.
         """
         leading_nonstarters = {}
         trailing_nonstarters = {}

         for c in set(self.canon_fully_decomp) | set(self.compat_fully_decomp):
             decomposed = self.compat_fully_decomp.get(c) or self.canon_fully_decomp[c]

             num_leading = 0
             for d in decomposed:
                 if d not in self.combining_classes:
                     break
                 num_leading += 1

             num_trailing = 0
             for d in reversed(decomposed):
                 if d not in self.combining_classes:
                     break
                 num_trailing += 1

             if num_leading > 0:
                 leading_nonstarters[c] = num_leading
             if num_trailing > 0:
                 trailing_nonstarters[c] = num_trailing

         return leading_nonstarters, trailing_nonstarters

 hexify = lambda c: hex(c)[2:].upper().rjust(4, '0')

 def gen_combining_class(combining_classes, out):
     out.write("#[inline]\n")
     out.write("pub fn canonical_combining_class(c: char) -> u8 {\n")
     out.write("    match c {\n")

     for char, combining_class in sorted(combining_classes.items()):
         out.write("        '\u{%s}' => %s,\n" % (hexify(char), combining_class))

     out.write("        _ => 0,\n")
     out.write("    }\n")
     out.write("}\n")

 def gen_composition_table(canon_comp, out):
     out.write("#[inline]\n")
     out.write("pub fn composition_table(c1: char, c2: char) -> Option<char> {\n")
     out.write("    match (c1, c2) {\n")

     for (c1, c2), c3 in sorted(canon_comp.items()):
         out.write("        ('\u{%s}', '\u{%s}') => Some('\u{%s}'),\n" % (hexify(c1), hexify(c2), hexify(c3)))

     out.write("        _ => None,\n")
     out.write("    }\n")
     out.write("}\n")

 def gen_decomposition_tables(canon_decomp, compat_decomp, out):
     tables = [(canon_decomp, 'canonical'), (compat_decomp, 'compatibility')]
     for table, name in tables:
         out.write("#[inline]\n")
         out.write("pub fn %s_fully_decomposed(c: char) -> Option<&'static [char]> {\n" % name)
         # The "Some" constructor is around the match statement here, because
         # putting it into the individual arms would make the item_bodies
         # checking of rustc takes almost twice as long, and it's already pretty
         # slow because of the huge number of match arms and the fact that there
         # is a borrow inside each arm
         out.write("    Some(match c {\n")

         for char, chars in sorted(table.items()):
             d = ", ".join("'\u{%s}'" % hexify(c) for c in chars)
             out.write("        '\u{%s}' => &[%s],\n" % (hexify(char), d))

         out.write("        _ => return None,\n")
         out.write("    })\n")
         out.write("}\n")
         out.write("\n")

 def gen_qc_match(prop_table, out):
     out.write("    match c {\n")

     for low, high, data in prop_table:
         assert data in ('N', 'M')
         result = "No" if data == 'N' else "Maybe"
         if high:
             out.write(r"        '\u{%s}'...'\u{%s}' => %s," % (low, high, result))
         else:
             out.write(r"        '\u{%s}' => %s," % (low, result))
         out.write("\n")

     out.write("        _ => Yes,\n")
     out.write("    }\n")

 def gen_nfc_qc(prop_tables, out):
     out.write("#[inline]\n")
     out.write("pub fn qc_nfc(c: char) -> IsNormalized {\n")
     gen_qc_match(prop_tables['NFC_QC'], out)
     out.write("}\n")

 def gen_nfkc_qc(prop_tables, out):
     out.write("#[inline]\n")
     out.write("pub fn qc_nfkc(c: char) -> IsNormalized {\n")
     gen_qc_match(prop_tables['NFKC_QC'], out)
     out.write("}\n")

 def gen_nfd_qc(prop_tables, out):
     out.write("#[inline]\n")
     out.write("pub fn qc_nfd(c: char) -> IsNormalized {\n")
     gen_qc_match(prop_tables['NFD_QC'], out)
     out.write("}\n")

 def gen_nfkd_qc(prop_tables, out):
     out.write("#[inline]\n")
     out.write("pub fn qc_nfkd(c: char) -> IsNormalized {\n")
     gen_qc_match(prop_tables['NFKD_QC'], out)
     out.write("}\n")

 def gen_combining_mark(general_category_mark, out):
     out.write("#[inline]\n")
     out.write("pub fn is_combining_mark(c: char) -> bool {\n")
     out.write("    match c {\n")

     for char in general_category_mark:
         out.write("        '\u{%s}' => true,\n" % hexify(char))

     out.write("        _ => false,\n")
     out.write("    }\n")
     out.write("}\n")

 def gen_stream_safe(leading, trailing, out):
     out.write("#[inline]\n")
     out.write("pub fn stream_safe_leading_nonstarters(c: char) -> usize {\n")
     out.write("    match c {\n")

     for char, num_leading in leading.items():
         out.write("        '\u{%s}' => %d,\n" % (hexify(char), num_leading))

     out.write("        _ => 0,\n")
     out.write("    }\n")
     out.write("}\n")
     out.write("\n")

     out.write("#[inline]\n")
     out.write("pub fn stream_safe_trailing_nonstarters(c: char) -> usize {\n")
     out.write("    match c {\n")

     for char, num_trailing in trailing.items():
         out.write("        '\u{%s}' => %d,\n" % (hexify(char), num_trailing))

     out.write("        _ => 0,\n")
     out.write("    }\n")
     out.write("}\n")

 def gen_tests(tests, out):
     out.write("""#[derive(Debug)]
 pub struct NormalizationTest {
     pub source: &'static str,
     pub nfc: &'static str,
     pub nfd: &'static str,
     pub nfkc: &'static str,
     pub nfkd: &'static str,
 }

 """)

     out.write("pub const NORMALIZATION_TESTS: &[NormalizationTest] = &[\n")
     str_literal = lambda s: '"%s"' % "".join("\u{%s}" % c for c in s)

     for test in tests:
         out.write("    NormalizationTest {\n")
         out.write("        source: %s,\n" % str_literal(test.source))
         out.write("        nfc: %s,\n" % str_literal(test.nfc))
         out.write("        nfd: %s,\n" % str_literal(test.nfd))
         out.write("        nfkc: %s,\n" % str_literal(test.nfkc))
         out.write("        nfkd: %s,\n" % str_literal(test.nfkd))
         out.write("    },\n")

     out.write("];\n")

 if __name__ == '__main__':
     data = UnicodeData()
     with open("tables.rs", "w") as out:
         out.write(PREAMBLE)
         out.write("use quick_check::IsNormalized;\n")
         out.write("use quick_check::IsNormalized::*;\n")
         out.write("\n")

         version = "(%s, %s, %s)" % tuple(UNICODE_VERSION.split("."))
         out.write("#[allow(unused)]\n")
         out.write("pub const UNICODE_VERSION: (u64, u64, u64) = %s;\n\n" % version)

         gen_combining_class(data.combining_classes, out)
         out.write("\n")

         gen_composition_table(data.canon_comp, out)
         out.write("\n")

         gen_decomposition_tables(data.canon_fully_decomp, data.compat_fully_decomp, out)

         gen_combining_mark(data.general_category_mark, out)
         out.write("\n")

         gen_nfc_qc(data.norm_props, out)
         out.write("\n")

         gen_nfkc_qc(data.norm_props, out)
         out.write("\n")

         gen_nfd_qc(data.norm_props, out)
         out.write("\n")

         gen_nfkd_qc(data.norm_props, out)
         out.write("\n")

         gen_stream_safe(data.ss_leading, data.ss_trailing, out)
         out.write("\n")

     with open("normalization_tests.rs", "w") as out:
         out.write(PREAMBLE)
         gen_tests(data.norm_tests, out)
	#!/usr/bin/env python
	#
	# Copyright 2011-2018 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 <LICENSE-APACHE or
	# http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
	# <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
	# option. This file may not be copied, modified, or distributed
	# except according to those terms.

	# This script uses the following Unicode tables:
	# - DerivedNormalizationProps.txt
	# - NormalizationTest.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 collections
	import requests

	UNICODE_VERSION = "9.0.0"
	UCD_URL = "https://www.unicode.org/Public/%s/ucd/" % UNICODE_VERSION

	PREAMBLE = """// Copyright 2012-2018 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 <LICENSE-APACHE or
	// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
	// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
	// option. This file may not be copied, modified, or distributed
	// except according to those terms.

	// NOTE: The following code was generated by "scripts/unicode.py", do not edit directly

	#![allow(missing_docs)]
	"""

	NormalizationTest = collections.namedtuple(
	"NormalizationTest",
	["source", "nfc", "nfd", "nfkc", "nfkd"],
	)

	# 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'],
	}

	class UnicodeData(object):
	def __init__(self):
	self._load_unicode_data()
	self.norm_props = self._load_norm_props()
	self.norm_tests = self._load_norm_tests()

	self.canon_comp = self._compute_canonical_comp()
	self.canon_fully_decomp, self.compat_fully_decomp = self._compute_fully_decomposed()

	def stats(name, table):
	count = sum(len(v) for v in table.values())
	print "%s: %d chars => %d decomposed chars" % (name, len(table), count)

	print "Decomposition table stats:"
	stats("Canonical decomp", self.canon_decomp)
	stats("Compatible decomp", self.compat_decomp)
	stats("Canonical fully decomp", self.canon_fully_decomp)
	stats("Compatible fully decomp", self.compat_fully_decomp)

	self.ss_leading, self.ss_trailing = self._compute_stream_safe_tables()

	def _fetch(self, filename):
	resp = requests.get(UCD_URL + filename)
	return resp.text

	def _load_unicode_data(self):
	self.combining_classes = {}
	self.compat_decomp = {}
	self.canon_decomp = {}
	self.general_category_mark = []

	for line in self._fetch("UnicodeData.txt").splitlines():
	# See ftp://ftp.unicode.org/Public/3.0-Update/UnicodeData-3.0.0.html
	pieces = line.split(';')
	assert len(pieces) == 15
	char, category, cc, decomp = pieces[0], pieces[2], pieces[3], pieces[5]
	char_int = int(char, 16)

	if cc != '0':
	self.combining_classes[char_int] = cc

	if decomp.startswith('<'):
	self.compat_decomp[char_int] = [int(c, 16) for c in decomp.split()[1:]]
	elif decomp != '':
	self.canon_decomp[char_int] = [int(c, 16) for c in decomp.split()]

	if category == 'M' or 'M' in expanded_categories.get(category, []):
	self.general_category_mark.append(char_int)

	def _load_norm_props(self):
	props = collections.defaultdict(list)

	for line in self._fetch("DerivedNormalizationProps.txt").splitlines():
	(prop_data, _, _) = line.partition("#")
	prop_pieces = prop_data.split(";")

	if len(prop_pieces) < 2:
	continue

	assert len(prop_pieces) <= 3
	(low, _, high) = prop_pieces[0].strip().partition("..")

	prop = prop_pieces[1].strip()

	data = None
	if len(prop_pieces) == 3:
	data = prop_pieces[2].strip()

	props[prop].append((low, high, data))

	return props

	def _load_norm_tests(self):
	tests = []
	for line in self._fetch("NormalizationTest.txt").splitlines():
	(test_data, _, _) = line.partition("#")
	test_pieces = test_data.split(";")

	if len(test_pieces) < 5:
	continue

	source, nfc, nfd, nfkc, nfkd = [[c.strip() for c in p.split()] for p in test_pieces[:5]]
	tests.append(NormalizationTest(source, nfc, nfd, nfkc, nfkd))

	return tests

	def _compute_canonical_comp(self):
	canon_comp = {}
	comp_exclusions = [
	(int(low, 16), int(high or low, 16))
	for low, high, _ in self.norm_props["Full_Composition_Exclusion"]
	]
	for char_int, decomp in self.canon_decomp.items():
	if any(lo <= char_int <= hi for lo, hi in comp_exclusions):
	continue

	assert len(decomp) == 2
	assert (decomp[0], decomp[1]) not in canon_comp
	canon_comp[(decomp[0], decomp[1])] = char_int

	return canon_comp

	def _compute_fully_decomposed(self):
	"""
	Even though the decomposition algorithm is recursive, it is possible
	to precompute the recursion at table generation time with modest
	increase to the table size. Then, for these precomputed tables, we
	note that 1) compatible decomposition is a subset of canonical
	decomposition and 2) they mostly agree on their intersection.
	Therefore, we don't store entries in the compatible table for
	characters that decompose the same way under canonical decomposition.

	Decomposition table stats:
	Canonical decomp: 2060 chars => 3085 decomposed chars
	Compatible decomp: 3662 chars => 5440 decomposed chars
	Canonical fully decomp: 2060 chars => 3404 decomposed chars
	Compatible fully decomp: 3678 chars => 5599 decomposed chars

	The upshot is that decomposition code is very simple and easy to inline
	at mild code size cost.
	"""
	# Constants from Unicode 9.0.0 Section 3.12 Conjoining Jamo Behavior
	# http://www.unicode.org/versions/Unicode9.0.0/ch03.pdf#M9.32468.Heading.310.Combining.Jamo.Behavior
	S_BASE, L_COUNT, V_COUNT, T_COUNT = 0xAC00, 19, 21, 28
	S_COUNT = L_COUNT * V_COUNT * T_COUNT

	def _decompose(char_int, compatible):
	# 7-bit ASCII never decomposes
	if char_int <= 0x7f:
	yield char_int
	return

	# Assert that we're handling Hangul separately.
	assert not (S_BASE <= char_int < S_BASE + S_COUNT)

	decomp = self.canon_decomp.get(char_int)
	if decomp is not None:
	for decomposed_ch in decomp:
	for fully_decomposed_ch in _decompose(decomposed_ch, compatible):
	yield fully_decomposed_ch
	return

	if compatible and char_int in self.compat_decomp:
	for decomposed_ch in self.compat_decomp[char_int]:
	for fully_decomposed_ch in _decompose(decomposed_ch, compatible):
	yield fully_decomposed_ch
	return

	yield char_int
	return

	end_codepoint = max(
	max(self.canon_decomp.keys()),
	max(self.compat_decomp.keys()),
	)

	canon_fully_decomp = {}
	compat_fully_decomp = {}

	for char_int in range(0, end_codepoint + 1):
	# Always skip Hangul, since it's more efficient to represent its
	# decomposition programmatically.
	if S_BASE <= char_int < S_BASE + S_COUNT:
	continue

	canon = list(_decompose(char_int, False))
	if not (len(canon) == 1 and canon[0] == char_int):
	canon_fully_decomp[char_int] = canon

	compat = list(_decompose(char_int, True))
	if not (len(compat) == 1 and compat[0] == char_int):
	compat_fully_decomp[char_int] = compat

	# Since canon_fully_decomp is a subset of compat_fully_decomp, we don't
	# need to store their overlap when they agree. When they don't agree,
	# store the decomposition in the compatibility table since we'll check
	# that first when normalizing to NFKD.
	assert canon_fully_decomp <= compat_fully_decomp

	for ch in set(canon_fully_decomp) & set(compat_fully_decomp):
	if canon_fully_decomp[ch] == compat_fully_decomp[ch]:
	del compat_fully_decomp[ch]

	return canon_fully_decomp, compat_fully_decomp

	def _compute_stream_safe_tables(self):
	"""
	To make a text stream-safe with the Stream-Safe Text Process (UAX15-D4),
	we need to be able to know the number of contiguous non-starters after
	applying compatibility decomposition to each character.

	We can do this incrementally by computing the number of leading and
	trailing non-starters for each character's compatibility decomposition
	with the following rules:

	1) If a character is not affected by compatibility decomposition, look
	up its canonical combining class to find out if it's a non-starter.
	2) All Hangul characters are starters, even under decomposition.
	3) Otherwise, very few decomposing characters have a nonzero count
	of leading or trailing non-starters, so store these characters
	with their associated counts in a separate table.
	"""
	leading_nonstarters = {}
	trailing_nonstarters = {}

	for c in set(self.canon_fully_decomp) \| set(self.compat_fully_decomp):
	decomposed = self.compat_fully_decomp.get(c) or self.canon_fully_decomp[c]

	num_leading = 0
	for d in decomposed:
	if d not in self.combining_classes:
	break
	num_leading += 1

	num_trailing = 0
	for d in reversed(decomposed):
	if d not in self.combining_classes:
	break
	num_trailing += 1

	if num_leading > 0:
	leading_nonstarters[c] = num_leading
	if num_trailing > 0:
	trailing_nonstarters[c] = num_trailing

	return leading_nonstarters, trailing_nonstarters

	hexify = lambda c: hex(c)[2:].upper().rjust(4, '0')

	def gen_combining_class(combining_classes, out):
	out.write("#[inline]\n")
	out.write("pub fn canonical_combining_class(c: char) -> u8 {\n")
	out.write(" match c {\n")

	for char, combining_class in sorted(combining_classes.items()):
	out.write(" '\u{%s}' => %s,\n" % (hexify(char), combining_class))

	out.write(" _ => 0,\n")
	out.write(" }\n")
	out.write("}\n")

	def gen_composition_table(canon_comp, out):
	out.write("#[inline]\n")
	out.write("pub fn composition_table(c1: char, c2: char) -> Option<char> {\n")
	out.write(" match (c1, c2) {\n")

	for (c1, c2), c3 in sorted(canon_comp.items()):
	out.write(" ('\u{%s}', '\u{%s}') => Some('\u{%s}'),\n" % (hexify(c1), hexify(c2), hexify(c3)))

	out.write(" _ => None,\n")
	out.write(" }\n")
	out.write("}\n")

	def gen_decomposition_tables(canon_decomp, compat_decomp, out):
	tables = [(canon_decomp, 'canonical'), (compat_decomp, 'compatibility')]
	for table, name in tables:
	out.write("#[inline]\n")
	out.write("pub fn %s_fully_decomposed(c: char) -> Option<&'static [char]> {\n" % name)
	# The "Some" constructor is around the match statement here, because
	# putting it into the individual arms would make the item_bodies
	# checking of rustc takes almost twice as long, and it's already pretty
	# slow because of the huge number of match arms and the fact that there
	# is a borrow inside each arm
	out.write(" Some(match c {\n")

	for char, chars in sorted(table.items()):
	d = ", ".join("'\u{%s}'" % hexify(c) for c in chars)
	out.write(" '\u{%s}' => &[%s],\n" % (hexify(char), d))

	out.write(" _ => return None,\n")
	out.write(" })\n")
	out.write("}\n")
	out.write("\n")

	def gen_qc_match(prop_table, out):
	out.write(" match c {\n")

	for low, high, data in prop_table:
	assert data in ('N', 'M')
	result = "No" if data == 'N' else "Maybe"
	if high:
	out.write(r" '\u{%s}'...'\u{%s}' => %s," % (low, high, result))
	else:
	out.write(r" '\u{%s}' => %s," % (low, result))
	out.write("\n")

	out.write(" _ => Yes,\n")
	out.write(" }\n")

	def gen_nfc_qc(prop_tables, out):
	out.write("#[inline]\n")
	out.write("pub fn qc_nfc(c: char) -> IsNormalized {\n")
	gen_qc_match(prop_tables['NFC_QC'], out)
	out.write("}\n")

	def gen_nfkc_qc(prop_tables, out):
	out.write("#[inline]\n")
	out.write("pub fn qc_nfkc(c: char) -> IsNormalized {\n")
	gen_qc_match(prop_tables['NFKC_QC'], out)
	out.write("}\n")

	def gen_nfd_qc(prop_tables, out):
	out.write("#[inline]\n")
	out.write("pub fn qc_nfd(c: char) -> IsNormalized {\n")
	gen_qc_match(prop_tables['NFD_QC'], out)
	out.write("}\n")

	def gen_nfkd_qc(prop_tables, out):
	out.write("#[inline]\n")
	out.write("pub fn qc_nfkd(c: char) -> IsNormalized {\n")
	gen_qc_match(prop_tables['NFKD_QC'], out)
	out.write("}\n")

	def gen_combining_mark(general_category_mark, out):
	out.write("#[inline]\n")
	out.write("pub fn is_combining_mark(c: char) -> bool {\n")
	out.write(" match c {\n")

	for char in general_category_mark:
	out.write(" '\u{%s}' => true,\n" % hexify(char))

	out.write(" _ => false,\n")
	out.write(" }\n")
	out.write("}\n")

	def gen_stream_safe(leading, trailing, out):
	out.write("#[inline]\n")
	out.write("pub fn stream_safe_leading_nonstarters(c: char) -> usize {\n")
	out.write(" match c {\n")

	for char, num_leading in leading.items():
	out.write(" '\u{%s}' => %d,\n" % (hexify(char), num_leading))

	out.write(" _ => 0,\n")
	out.write(" }\n")
	out.write("}\n")
	out.write("\n")

	out.write("#[inline]\n")
	out.write("pub fn stream_safe_trailing_nonstarters(c: char) -> usize {\n")
	out.write(" match c {\n")

	for char, num_trailing in trailing.items():
	out.write(" '\u{%s}' => %d,\n" % (hexify(char), num_trailing))

	out.write(" _ => 0,\n")
	out.write(" }\n")
	out.write("}\n")

	def gen_tests(tests, out):
	out.write("""#[derive(Debug)]
	pub struct NormalizationTest {
	pub source: &'static str,
	pub nfc: &'static str,
	pub nfd: &'static str,
	pub nfkc: &'static str,
	pub nfkd: &'static str,
	}

	""")

	out.write("pub const NORMALIZATION_TESTS: &[NormalizationTest] = &[\n")
	str_literal = lambda s: '"%s"' % "".join("\u{%s}" % c for c in s)

	for test in tests:
	out.write(" NormalizationTest {\n")
	out.write(" source: %s,\n" % str_literal(test.source))
	out.write(" nfc: %s,\n" % str_literal(test.nfc))
	out.write(" nfd: %s,\n" % str_literal(test.nfd))
	out.write(" nfkc: %s,\n" % str_literal(test.nfkc))
	out.write(" nfkd: %s,\n" % str_literal(test.nfkd))
	out.write(" },\n")

	out.write("];\n")

	if __name__ == '__main__':
	data = UnicodeData()
	with open("tables.rs", "w") as out:
	out.write(PREAMBLE)
	out.write("use quick_check::IsNormalized;\n")
	out.write("use quick_check::IsNormalized::*;\n")
	out.write("\n")

	version = "(%s, %s, %s)" % tuple(UNICODE_VERSION.split("."))
	out.write("#[allow(unused)]\n")
	out.write("pub const UNICODE_VERSION: (u64, u64, u64) = %s;\n\n" % version)

	gen_combining_class(data.combining_classes, out)
	out.write("\n")

	gen_composition_table(data.canon_comp, out)
	out.write("\n")

	gen_decomposition_tables(data.canon_fully_decomp, data.compat_fully_decomp, out)

	gen_combining_mark(data.general_category_mark, out)
	out.write("\n")

	gen_nfc_qc(data.norm_props, out)
	out.write("\n")

	gen_nfkc_qc(data.norm_props, out)
	out.write("\n")

	gen_nfd_qc(data.norm_props, out)
	out.write("\n")

	gen_nfkd_qc(data.norm_props, out)
	out.write("\n")

	gen_stream_safe(data.ss_leading, data.ss_trailing, out)
	out.write("\n")

	with open("normalization_tests.rs", "w") as out:
	out.write(PREAMBLE)
	gen_tests(data.norm_tests, out)