ref: 81c9ede53f6f9ebd67e7134e664c98e08b9fcca6
dir: /sys/src/cmd/python/Tools/unicode/mkstringprep.py/
import re, unicodedata, sys if sys.maxunicode == 65535: raise RuntimeError, "need UCS-4 Python" def gen_category(cats): for i in range(0, 0x110000): if unicodedata.category(unichr(i)) in cats: yield(i) def gen_bidirectional(cats): for i in range(0, 0x110000): if unicodedata.bidirectional(unichr(i)) in cats: yield(i) def compact_set(l): single = [] tuple = [] prev = None span = 0 for e in l: if prev is None: prev = e span = 0 continue if prev+span+1 != e: if span > 2: tuple.append((prev,prev+span+1)) else: for i in range(prev, prev+span+1): single.append(i) prev = e span = 0 else: span += 1 if span: tuple.append((prev,prev+span+1)) else: single.append(prev) tuple = " + ".join(["range(%d,%d)" % t for t in tuple]) if not single: return "set(%s)" % tuple if not tuple: return "set(%s)" % repr(single) return "set(%s + %s)" % (repr(single),tuple) ############## Read the tables in the RFC ####################### data = open("rfc3454.txt").readlines() tables = [] curname = None for l in data: l = l.strip() if not l: continue # Skip RFC page breaks if l.startswith("Hoffman & Blanchet") or\ l.startswith("RFC 3454"): continue # Find start/end lines m = re.match("----- (Start|End) Table ([A-Z](.[0-9])+) -----", l) if m: if m.group(1) == "Start": if curname: raise "Double Start",(curname, l) curname = m.group(2) table = {} tables.append((curname, table)) continue else: if not curname: raise "End without start", l curname = None continue if not curname: continue # Now we are in a table fields = l.split(";") if len(fields) > 1: # Drop comment field fields = fields[:-1] if len(fields) == 1: fields = fields[0].split("-") if len(fields) > 1: # range try: start, end = fields except ValueError: raise "Unpacking problem", l else: start = end = fields[0] start = int(start, 16) end = int(end, 16) for i in range(start, end+1): table[i] = i else: code, value = fields value = value.strip() if value: value = [int(v, 16) for v in value.split(" ")] else: # table B.1 value = None table[int(code, 16)] = value ########### Generate compact Python versions of the tables ############# print """# This file is generated by mkstringprep.py. DO NOT EDIT. \"\"\"Library that exposes various tables found in the StringPrep RFC 3454. There are two kinds of tables: sets, for which a member test is provided, and mappings, for which a mapping function is provided. \"\"\" import unicodedata """ print "assert unicodedata.unidata_version == %s" % repr(unicodedata.unidata_version) # A.1 is the table of unassigned characters # XXX Plane 15 PUA is listed as unassigned in Python. name, table = tables[0] del tables[0] assert name == "A.1" table = set(table.keys()) Cn = set(gen_category(["Cn"])) # FDD0..FDEF are process internal codes Cn -= set(range(0xFDD0, 0xFDF0)) # not a character Cn -= set(range(0xFFFE, 0x110000, 0x10000)) Cn -= set(range(0xFFFF, 0x110000, 0x10000)) # assert table == Cn print """ def in_table_a1(code): if unicodedata.category(code) != 'Cn': return False c = ord(code) if 0xFDD0 <= c < 0xFDF0: return False return (c & 0xFFFF) not in (0xFFFE, 0xFFFF) """ # B.1 cannot easily be derived name, table = tables[0] del tables[0] assert name == "B.1" table = table.keys() table.sort() print """ b1_set = """ + compact_set(table) + """ def in_table_b1(code): return ord(code) in b1_set """ # B.2 and B.3 is case folding. # It takes CaseFolding.txt into account, which is # not available in the Python database. Since # B.2 is derived from B.3, we process B.3 first. # B.3 supposedly *is* CaseFolding-3.2.0.txt. name, table_b2 = tables[0] del tables[0] assert name == "B.2" name, table_b3 = tables[0] del tables[0] assert name == "B.3" # B.3 is mostly Python's .lower, except for a number # of special cases, e.g. considering canonical forms. b3_exceptions = {} for k,v in table_b2.items(): if map(ord, unichr(k).lower()) != v: b3_exceptions[k] = u"".join(map(unichr,v)) b3 = b3_exceptions.items() b3.sort() print """ b3_exceptions = {""" for i,(k,v) in enumerate(b3): print "0x%x:%s," % (k, repr(v)), if i % 4 == 3: print print "}" print """ def map_table_b3(code): r = b3_exceptions.get(ord(code)) if r is not None: return r return code.lower() """ def map_table_b3(code): r = b3_exceptions.get(ord(code)) if r is not None: return r return code.lower() # B.2 is case folding for NFKC. This is the same as B.3, # except where NormalizeWithKC(Fold(a)) != # NormalizeWithKC(Fold(NormalizeWithKC(Fold(a)))) def map_table_b2(a): al = map_table_b3(a) b = unicodedata.normalize("NFKC", al) bl = u"".join([map_table_b3(ch) for ch in b]) c = unicodedata.normalize("NFKC", bl) if b != c: return c else: return al specials = {} for k,v in table_b2.items(): if map(ord, map_table_b2(unichr(k))) != v: specials[k] = v # B.3 should not add any additional special cases assert specials == {} print """ def map_table_b2(a): al = map_table_b3(a) b = unicodedata.normalize("NFKC", al) bl = u"".join([map_table_b3(ch) for ch in b]) c = unicodedata.normalize("NFKC", bl) if b != c: return c else: return al """ # C.1.1 is a table with a single character name, table = tables[0] del tables[0] assert name == "C.1.1" assert table == {0x20:0x20} print """ def in_table_c11(code): return code == u" " """ # C.1.2 is the rest of all space characters name, table = tables[0] del tables[0] assert name == "C.1.2" # table = set(table.keys()) # Zs = set(gen_category(["Zs"])) - set([0x20]) # assert Zs == table print """ def in_table_c12(code): return unicodedata.category(code) == "Zs" and code != u" " def in_table_c11_c12(code): return unicodedata.category(code) == "Zs" """ # C.2.1 ASCII control characters name, table_c21 = tables[0] del tables[0] assert name == "C.2.1" Cc = set(gen_category(["Cc"])) Cc_ascii = Cc & set(range(128)) table_c21 = set(table_c21.keys()) assert Cc_ascii == table_c21 print """ def in_table_c21(code): return ord(code) < 128 and unicodedata.category(code) == "Cc" """ # C.2.2 Non-ASCII control characters. It also includes # a number of characters in category Cf. name, table_c22 = tables[0] del tables[0] assert name == "C.2.2" Cc_nonascii = Cc - Cc_ascii table_c22 = set(table_c22.keys()) assert len(Cc_nonascii - table_c22) == 0 specials = list(table_c22 - Cc_nonascii) specials.sort() print """c22_specials = """ + compact_set(specials) + """ def in_table_c22(code): c = ord(code) if c < 128: return False if unicodedata.category(code) == "Cc": return True return c in c22_specials def in_table_c21_c22(code): return unicodedata.category(code) == "Cc" or \\ ord(code) in c22_specials """ # C.3 Private use name, table = tables[0] del tables[0] assert name == "C.3" Co = set(gen_category(["Co"])) assert set(table.keys()) == Co print """ def in_table_c3(code): return unicodedata.category(code) == "Co" """ # C.4 Non-character code points, xFFFE, xFFFF # plus process internal codes name, table = tables[0] del tables[0] assert name == "C.4" nonchar = set(range(0xFDD0,0xFDF0) + range(0xFFFE,0x110000,0x10000) + range(0xFFFF,0x110000,0x10000)) table = set(table.keys()) assert table == nonchar print """ def in_table_c4(code): c = ord(code) if c < 0xFDD0: return False if c < 0xFDF0: return True return (ord(code) & 0xFFFF) in (0xFFFE, 0xFFFF) """ # C.5 Surrogate codes name, table = tables[0] del tables[0] assert name == "C.5" Cs = set(gen_category(["Cs"])) assert set(table.keys()) == Cs print """ def in_table_c5(code): return unicodedata.category(code) == "Cs" """ # C.6 Inappropriate for plain text name, table = tables[0] del tables[0] assert name == "C.6" table = table.keys() table.sort() print """ c6_set = """ + compact_set(table) + """ def in_table_c6(code): return ord(code) in c6_set """ # C.7 Inappropriate for canonical representation name, table = tables[0] del tables[0] assert name == "C.7" table = table.keys() table.sort() print """ c7_set = """ + compact_set(table) + """ def in_table_c7(code): return ord(code) in c7_set """ # C.8 Change display properties or are deprecated name, table = tables[0] del tables[0] assert name == "C.8" table = table.keys() table.sort() print """ c8_set = """ + compact_set(table) + """ def in_table_c8(code): return ord(code) in c8_set """ # C.9 Tagging characters name, table = tables[0] del tables[0] assert name == "C.9" table = table.keys() table.sort() print """ c9_set = """ + compact_set(table) + """ def in_table_c9(code): return ord(code) in c9_set """ # D.1 Characters with bidirectional property "R" or "AL" name, table = tables[0] del tables[0] assert name == "D.1" RandAL = set(gen_bidirectional(["R","AL"])) assert set(table.keys()) == RandAL print """ def in_table_d1(code): return unicodedata.bidirectional(code) in ("R","AL") """ # D.2 Characters with bidirectional property "L" name, table = tables[0] del tables[0] assert name == "D.2" L = set(gen_bidirectional(["L"])) assert set(table.keys()) == L print """ def in_table_d2(code): return unicodedata.bidirectional(code) == "L" """