# # (re)generate unicode property and type databases # # this script converts a unicode 3.0 database file to # Modules/unicodedata_db.h, Modules/unicodename_db.h, # and Objects/unicodetype_db.h # # history: # 2000-09-24 fl created (based on bits and pieces from unidb) # 2000-09-25 fl merged tim's splitbin fixes, separate decomposition table # 2000-09-25 fl added character type table # 2000-09-26 fl added LINEBREAK, DECIMAL, and DIGIT flags/fields (2.0) # 2000-11-03 fl expand first/last ranges # 2001-01-19 fl added character name tables (2.1) # 2001-01-21 fl added decomp compression; dynamic phrasebook threshold # # written by Fredrik Lundh (fredrik@pythonware.com) # import sys SCRIPT = sys.argv[0] VERSION = "2.1" UNICODE_DATA = "UnicodeData-Latest.txt" CATEGORY_NAMES = [ "Cn", "Lu", "Ll", "Lt", "Mn", "Mc", "Me", "Nd", "Nl", "No", "Zs", "Zl", "Zp", "Cc", "Cf", "Cs", "Co", "Cn", "Lm", "Lo", "Pc", "Pd", "Ps", "Pe", "Pi", "Pf", "Po", "Sm", "Sc", "Sk", "So" ] BIDIRECTIONAL_NAMES = [ "", "L", "LRE", "LRO", "R", "AL", "RLE", "RLO", "PDF", "EN", "ES", "ET", "AN", "CS", "NSM", "BN", "B", "S", "WS", "ON" ] # note: should match definitions in Objects/unicodectype.c ALPHA_MASK = 0x01 DECIMAL_MASK = 0x02 DIGIT_MASK = 0x04 LOWER_MASK = 0x08 LINEBREAK_MASK = 0x10 SPACE_MASK = 0x20 TITLE_MASK = 0x40 UPPER_MASK = 0x80 def maketables(trace=0): print "--- Reading", UNICODE_DATA, "..." unicode = UnicodeData(UNICODE_DATA) print len(filter(None, unicode.table)), "characters" makeunicodename(unicode, trace) makeunicodedata(unicode, trace) makeunicodetype(unicode, trace) # -------------------------------------------------------------------- # unicode character properties def makeunicodedata(unicode, trace): dummy = (0, 0, 0, 0) table = [dummy] cache = {0: dummy} index = [0] * len(unicode.chars) FILE = "Modules/unicodedata_db.h" print "--- Preparing", FILE, "..." # 1) database properties for char in unicode.chars: record = unicode.table[char] if record: # extract database properties category = CATEGORY_NAMES.index(record[2]) combining = int(record[3]) bidirectional = BIDIRECTIONAL_NAMES.index(record[4]) mirrored = record[9] == "Y" item = ( category, combining, bidirectional, mirrored ) # add entry to index and item tables i = cache.get(item) if i is None: cache[item] = i = len(table) table.append(item) index[char] = i # 2) decomposition data decomp_data = [0] decomp_prefix = [""] decomp_index = [0] * len(unicode.chars) decomp_size = 0 for char in unicode.chars: record = unicode.table[char] if record: if record[5]: decomp = record[5].split() # prefix if decomp[0][0] == "<": prefix = decomp.pop(0) else: prefix = "" try: i = decomp_prefix.index(prefix) except ValueError: i = len(decomp_prefix) decomp_prefix.append(prefix) prefix = i assert prefix < 256 # content decomp = [prefix + (len(decomp)<<8)] +\ map(lambda s: int(s, 16), decomp) try: i = decomp_data.index(decomp) except ValueError: i = len(decomp_data) decomp_data.extend(decomp) decomp_size = decomp_size + len(decomp) * 2 else: i = 0 decomp_index[char] = i print len(table), "unique properties" print len(decomp_prefix), "unique decomposition prefixes" print len(decomp_data), "unique decomposition entries:", print decomp_size, "bytes" print "--- Writing", FILE, "..." fp = open(FILE, "w") print >>fp, "/* this file was generated by %s %s */" % (SCRIPT, VERSION) print >>fp print >>fp, "/* a list of unique database records */" print >>fp, \ "const _PyUnicode_DatabaseRecord _PyUnicode_Database_Records[] = {" for item in table: print >>fp, " {%d, %d, %d, %d}," % item print >>fp, "};" print >>fp # FIXME: the following tables could be made static, and # the support code moved into unicodedatabase.c print >>fp, "/* string literals */" print >>fp, "const char *_PyUnicode_CategoryNames[] = {" for name in CATEGORY_NAMES: print >>fp, " \"%s\"," % name print >>fp, " NULL" print >>fp, "};" print >>fp, "const char *_PyUnicode_BidirectionalNames[] = {" for name in BIDIRECTIONAL_NAMES: print >>fp, " \"%s\"," % name print >>fp, " NULL" print >>fp, "};" print >>fp, "static const char *decomp_prefix[] = {" for name in decomp_prefix: print >>fp, " \"%s\"," % name print >>fp, " NULL" print >>fp, "};" # split record index table index1, index2, shift = splitbins(index, trace) print >>fp, "/* index tables for the database records */" print >>fp, "#define SHIFT", shift Array("index1", index1).dump(fp, trace) Array("index2", index2).dump(fp, trace) # split decomposition index table index1, index2, shift = splitbins(decomp_index, trace) print >>fp, "/* decomposition data */" Array("decomp_data", decomp_data).dump(fp, trace) print >>fp, "/* index tables for the decomposition data */" print >>fp, "#define DECOMP_SHIFT", shift Array("decomp_index1", index1).dump(fp, trace) Array("decomp_index2", index2).dump(fp, trace) fp.close() # -------------------------------------------------------------------- # unicode character type tables def makeunicodetype(unicode, trace): FILE = "Objects/unicodetype_db.h" print "--- Preparing", FILE, "..." # extract unicode types dummy = (0, 0, 0, 0, 0, 0) table = [dummy] cache = {0: dummy} index = [0] * len(unicode.chars) for char in unicode.chars: record = unicode.table[char] if record: # extract database properties category = record[2] bidirectional = record[4] flags = 0 if category in ["Lm", "Lt", "Lu", "Ll", "Lo"]: flags |= ALPHA_MASK if category == "Ll": flags |= LOWER_MASK if category == "Zl" or bidirectional == "B": flags |= LINEBREAK_MASK if category == "Zs" or bidirectional in ("WS", "B", "S"): flags |= SPACE_MASK if category == "Lt": flags |= TITLE_MASK if category == "Lu": flags |= UPPER_MASK # use delta predictor for upper/lower/title if record[12]: upper = (int(record[12], 16) - char) & 0xffff else: upper = 0 if record[13]: lower = (int(record[13], 16) - char) & 0xffff else: lower = 0 if record[14]: title = (int(record[14], 16) - char) & 0xffff else: title = 0 # decimal digit, integer digit decimal = 0 if record[6]: flags |= DECIMAL_MASK decimal = int(record[6]) digit = 0 if record[7]: flags |= DIGIT_MASK digit = int(record[7]) item = ( flags, upper, lower, title, decimal, digit ) # add entry to index and item tables i = cache.get(item) if i is None: cache[item] = i = len(table) table.append(item) index[char] = i print len(table), "unique character type entries" print "--- Writing", FILE, "..." fp = open(FILE, "w") print >>fp, "/* this file was generated by %s %s */" % (SCRIPT, VERSION) print >>fp print >>fp, "/* a list of unique character type descriptors */" print >>fp, "const _PyUnicode_TypeRecord _PyUnicode_TypeRecords[] = {" for item in table: print >>fp, " {%d, %d, %d, %d, %d, %d}," % item print >>fp, "};" print >>fp # split decomposition index table index1, index2, shift = splitbins(index, trace) print >>fp, "/* type indexes */" print >>fp, "#define SHIFT", shift Array("index1", index1).dump(fp, trace) Array("index2", index2).dump(fp, trace) fp.close() # -------------------------------------------------------------------- # unicode name database def makeunicodename(unicode, trace): FILE = "Modules/unicodename_db.h" print "--- Preparing", FILE, "..." # collect names names = [None] * len(unicode.chars) for char in unicode.chars: record = unicode.table[char] if record: name = record[1].strip() if name and name[0] != "<": names[char] = name + chr(0) print len(filter(lambda n: n is not None, names)), "distinct names" # collect unique words from names (note that we differ between # words inside a sentence, and words ending a sentence. the # latter includes the trailing null byte. words = {} n = b = 0 for char in unicode.chars: name = names[char] if name: w = name.split() b = b + len(name) n = n + len(w) for w in w: l = words.get(w) if l: l.append(None) else: words[w] = [len(words)] print n, "words in text;", b, "bytes" wordlist = words.items() # sort on falling frequency wordlist.sort(lambda a, b: len(b[1])-len(a[1])) # figure out how many phrasebook escapes we need escapes = 0 while escapes * 256 < len(wordlist): escapes = escapes + 1 print escapes, "escapes" short = 256 - escapes assert short > 0 print short, "short indexes in lexicon" # statistics n = 0 for i in range(short): n = n + len(wordlist[i][1]) print n, "short indexes in phrasebook" # pick the most commonly used words, and sort the rest on falling # length (to maximize overlap) wordlist, wordtail = wordlist[:short], wordlist[short:] wordtail.sort(lambda a, b: len(b[0])-len(a[0])) wordlist.extend(wordtail) # generate lexicon from words lexicon_offset = [0] lexicon = "" words = {} # build a lexicon string offset = 0 for w, x in wordlist: # encoding: bit 7 indicates last character in word (chr(128) # indicates the last character in an entire string) ww = w[:-1] + chr(ord(w[-1])+128) # reuse string tails, when possible o = lexicon.find(ww) if o < 0: o = offset lexicon = lexicon + ww offset = offset + len(w) words[w] = len(lexicon_offset) lexicon_offset.append(o) lexicon = map(ord, lexicon) # generate phrasebook from names and lexicon phrasebook = [0] phrasebook_offset = [0] * len(unicode.chars) for char in unicode.chars: name = names[char] if name: w = name.split() phrasebook_offset[char] = len(phrasebook) for w in w: i = words[w] if i < short: phrasebook.append(i) else: # store as two bytes phrasebook.append((i>>8) + short) phrasebook.append(i&255) assert getsize(phrasebook) == 1 # # unicode name hash table # extract names data = [] for char in unicode.chars: record = unicode.table[char] if record: name = record[1].strip() if name and name[0] != "<": data.append((name, char)) # the magic number 47 was chosen to minimize the number of # collisions on the current data set. if you like, change it # and see what happens... codehash = Hash("code", data, 47) print "--- Writing", FILE, "..." fp = open(FILE, "w") print >>fp, "/* this file was generated by %s %s */" % (SCRIPT, VERSION) print >>fp print >>fp, "#define NAME_MAXLEN", 256 print >>fp print >>fp, "/* lexicon */" Array("lexicon", lexicon).dump(fp, trace) Array("lexicon_offset", lexicon_offset).dump(fp, trace) # split decomposition index table offset1, offset2, shift = splitbins(phrasebook_offset, trace) print >>fp, "/* code->name phrasebook */" print >>fp, "#define phrasebook_shift", shift print >>fp, "#define phrasebook_short", short Array("phrasebook", phrasebook).dump(fp, trace) Array("phrasebook_offset1", offset1).dump(fp, trace) Array("phrasebook_offset2", offset2).dump(fp, trace) print >>fp, "/* name->code dictionary */" codehash.dump(fp, trace) fp.close() # -------------------------------------------------------------------- # the following support code is taken from the unidb utilities # Copyright (c) 1999-2000 by Secret Labs AB # load a unicode-data file from disk import sys class UnicodeData: def __init__(self, filename, expand=1): file = open(filename) table = [None] * 65536 while 1: s = file.readline() if not s: break s = s.strip().split(";") char = int(s[0], 16) table[char] = s # expand first-last ranges (ignore surrogates and private use) if expand: field = None for i in range(0, 0xD800): s = table[i] if s: if s[1][-6:] == "First>": s[1] = "" field = s[:] elif s[1][-5:] == "Last>": s[1] = "" field = None elif field: field[0] = hex(i) table[i] = field # public attributes self.filename = filename self.table = table self.chars = range(65536) # unicode def uselatin1(self): # restrict character range to ISO Latin 1 self.chars = range(256) # hash table tools # this is a straight-forward reimplementation of Python's built-in # dictionary type, using a static data structure, and a custom string # hash algorithm. def myhash(s, magic): h = 0 for c in map(ord, s.upper()): h = (h * magic) + c ix = h & 0xff000000 if ix: h = (h ^ ((ix>>24) & 0xff)) & 0x00ffffff return h SIZES = [ (4,3), (8,3), (16,3), (32,5), (64,3), (128,3), (256,29), (512,17), (1024,9), (2048,5), (4096,83), (8192,27), (16384,43), (32768,3), (65536,45), (131072,9), (262144,39), (524288,39), (1048576,9), (2097152,5), (4194304,3), (8388608,33), (16777216,27) ] class Hash: def __init__(self, name, data, magic): # turn a (key, value) list into a static hash table structure # determine table size for size, poly in SIZES: if size > len(data): poly = size + poly break else: raise AssertionError, "ran out of polynominals" print size, "slots in hash table" table = [None] * size mask = size-1 n = 0 hash = myhash # initialize hash table for key, value in data: h = hash(key, magic) i = (~h) & mask v = table[i] if v is None: table[i] = value continue incr = (h ^ (h >> 3)) & mask; if not incr: incr = mask while 1: n = n + 1 i = (i + incr) & mask v = table[i] if v is None: table[i] = value break incr = incr << 1 if incr > mask: incr = incr ^ poly print n, "collisions" self.collisions = n for i in range(len(table)): if table[i] is None: table[i] = 0 self.data = Array(name + "_hash", table) self.magic = magic self.name = name self.size = size self.poly = poly def dump(self, file, trace): # write data to file, as a C array self.data.dump(file, trace) file.write("#define %s_magic %d\n" % (self.name, self.magic)) file.write("#define %s_size %d\n" % (self.name, self.size)) file.write("#define %s_poly %d\n" % (self.name, self.poly)) # stuff to deal with arrays of unsigned integers class Array: def __init__(self, name, data): self.name = name self.data = data def dump(self, file, trace=0): # write data to file, as a C array size = getsize(self.data) if trace: print >>sys.stderr, self.name+":", size*len(self.data), "bytes" file.write("static ") if size == 1: file.write("unsigned char") elif size == 2: file.write("unsigned short") else: file.write("unsigned int") file.write(" " + self.name + "[] = {\n") if self.data: s = " " for item in self.data: i = str(item) + ", " if len(s) + len(i) > 78: file.write(s + "\n") s = " " + i else: s = s + i if s.strip(): file.write(s + "\n") file.write("};\n\n") def getsize(data): # return smallest possible integer size for the given array maxdata = max(data) if maxdata < 256: return 1 elif maxdata < 65536: return 2 else: return 4 def splitbins(t, trace=0): """t, trace=0 -> (t1, t2, shift). Split a table to save space. t is a sequence of ints. This function can be useful to save space if many of the ints are the same. t1 and t2 are lists of ints, and shift is an int, chosen to minimize the combined size of t1 and t2 (in C code), and where for each i in range(len(t)), t[i] == t2[(t1[i >> shift] << shift) + (i & mask)] where mask is a bitmask isolating the last "shift" bits. If optional arg trace is non-zero (default zero), progress info is printed to sys.stderr. The higher the value, the more info you'll get. """ import sys if trace: def dump(t1, t2, shift, bytes): print >>sys.stderr, "%d+%d bins at shift %d; %d bytes" % ( len(t1), len(t2), shift, bytes) print >>sys.stderr, "Size of original table:", len(t)*getsize(t), \ "bytes" n = len(t)-1 # last valid index maxshift = 0 # the most we can shift n and still have something left if n > 0: while n >> 1: n >>= 1 maxshift += 1 del n bytes = sys.maxint # smallest total size so far t = tuple(t) # so slices can be dict keys for shift in range(maxshift + 1): t1 = [] t2 = [] size = 2**shift bincache = {} for i in range(0, len(t), size): bin = t[i:i+size] index = bincache.get(bin) if index is None: index = len(t2) bincache[bin] = index t2.extend(bin) t1.append(index >> shift) # determine memory size b = len(t1)*getsize(t1) + len(t2)*getsize(t2) if trace > 1: dump(t1, t2, shift, b) if b < bytes: best = t1, t2, shift bytes = b t1, t2, shift = best if trace: print >>sys.stderr, "Best:", dump(t1, t2, shift, bytes) if __debug__: # exhaustively verify that the decomposition is correct mask = ~((~0) << shift) # i.e., low-bit mask of shift bits for i in xrange(len(t)): assert t[i] == t2[(t1[i >> shift] << shift) + (i & mask)] return best if __name__ == "__main__": maketables(1)