#!python3
"""
FSA DICTIONARY BUILDER
by Olivier R.
License: MPL 2
This tool encodes lexicon into an indexable binary dictionary
Input files MUST be encoded in UTF-8.
"""
import sys
import os
import collections
import json
import time
import re
import traceback
from . import str_transform as st
from .progressbar import ProgressBar
dLexiconData = {}
def readFile (spf):
"generator: read file <spf> and return for each line a list of elements separated by a tabulation."
print(" < Read lexicon: " + spf)
if os.path.isfile(spf):
dLexiconData.clear()
with open(spf, "r", encoding="utf-8") as hSrc:
for sLine in hSrc:
sLine = sLine.strip()
if sLine.startswith("##") :
m = re.match("## *(\\w+) *:(.*)$", sLine)
if m:
dLexiconData[m.group(1)] = m.group(2).strip()
elif sLine and not sLine.startswith("#"):
yield sLine.split("\t")
if dLexiconData:
print("Data from dictionary:")
print(dLexiconData)
else:
raise OSError("# Error. File not found or not loadable: " + spf)
class DAWG:
"""DIRECT ACYCLIC WORD GRAPH"""
# This code is inspired from Steve Hanov’s DAWG, 2011. (http://stevehanov.ca/blog/index.php?id=115)
# We store suffix/affix codes and tags within the graph after the “real” word.
# A word is a list of numbers [ c1, c2, c3 . . . cN, iAffix, iTags]
# Each arc is an index in self.lArcVal, where are stored characters, suffix/affix codes for stemming and tags.
# Important: As usual, the last node (after ‘iTags’) is tagged final, AND the node after ‘cN’ is ALSO tagged final.
def __init__ (self, src, cStemming, sLangCode, sLangName="", sDicName="", sDescription="", sSelectFilterRegex=""):
print("===== Direct Acyclic Word Graph - Minimal Acyclic Finite State Automaton =====")
cStemming = cStemming.upper()
if cStemming == "A":
funcStemmingGen = st.defineAffixCode
elif cStemming == "S":
funcStemmingGen = st.defineSuffixCode
elif cStemming == "N":
funcStemmingGen = st.noStemming
else:
raise ValueError("# Error. Unknown stemming code: {}".format(cStemming))
aEntry = set()
lChar = ['']; dChar = {}; nChar = 1; dCharOccur = {}
lAff = []; dAff = {}; nAff = 0; dAffOccur = {}
lTag = []; dTag = {}; nTag = 0; dTagOccur = {}
nErr = 0
self.a2grams = set()
try:
zFilter = re.compile(sSelectFilterRegex) if sSelectFilterRegex else None
except:
print(" # Error. Wrong filter regex. Filter ignored.")
traceback.print_exc()
zFilter = None
# read lexicon
if type(src) is str:
iterable = readFile(src)
else:
iterable = src
for sFlex, sStem, sTag in iterable:
if not zFilter or zFilter.search(sTag):
self.a2grams.update(st.getNgrams(sFlex))
addWordToCharDict(sFlex)
# chars
for c in sFlex:
if c not in dChar:
dChar[c] = nChar
lChar.append(c)
nChar += 1
dCharOccur[c] = dCharOccur.get(c, 0) + 1
# affixes to find stem from flexion
sAff = funcStemmingGen(sFlex, sStem)
if sAff not in dAff:
dAff[sAff] = nAff
lAff.append(sAff)
nAff += 1
dAffOccur[sAff] = dAffOccur.get(sAff, 0) + 1
# tags
if sTag not in dTag:
dTag[sTag] = nTag
lTag.append(sTag)
nTag += 1
dTagOccur[sTag] = dTagOccur.get(sTag, 0) + 1
aEntry.add((sFlex, dAff[sAff], dTag[sTag]))
if not aEntry:
raise ValueError("# Error. Empty lexicon")
# Preparing DAWG
print(" > Preparing list of words")
print(" Filter: " + (sSelectFilterRegex or "[None]"))
lVal = lChar + lAff + lTag
lWord = [ [dChar[c] for c in sFlex] + [iAff+nChar] + [iTag+nChar+nAff] for sFlex, iAff, iTag in aEntry ]
aEntry = None
# Dictionary of arc values occurrency, to sort arcs of each node
dValOccur = dict( [ (dChar[c], dCharOccur[c]) for c in dChar ] \
+ [ (dAff[aff]+nChar, dAffOccur[aff]) for aff in dAff ] \
+ [ (dTag[tag]+nChar+nAff, dTagOccur[tag]) for tag in dTag ] )
self.sFileName = src if type(src) is str else "[None]"
self.sLangCode = sLangCode
self.sLangName = sLangName
self.sDicName = sDicName
self.sDescription = sDescription
if dLexiconData:
self.sLangCode = dLexiconData.get("LangCode", self.sLangCode)
self.sLangName = dLexiconData.get("LangName", self.sLangName)
self.sDicName = dLexiconData.get("DicName", self.sDicName)
self.sDescription = dLexiconData.get("Description", self.sDescription)
self.nEntry = len(lWord)
self.aPreviousEntry = []
DawgNode.resetNextId()
self.oRoot = DawgNode()
self.lUncheckedNodes = [] # list of nodes that have not been checked for duplication.
self.lMinimizedNodes = {} # list of unique nodes that have been checked for duplication.
self.lSortedNodes = [] # version 2 and 3
self.nNode = 0
self.nArc = 0
self.dChar = dChar
self.nChar = len(dChar)
self.nAff = nAff
self.lArcVal = lVal
self.nArcVal = len(lVal)
self.nTag = self.nArcVal - self.nChar - nAff
self.cStemming = cStemming
if cStemming == "A":
self.funcStemming = st.changeWordWithAffixCode
elif cStemming == "S":
self.funcStemming = st.changeWordWithSuffixCode
else:
self.funcStemming = st.noStemming
# build
lWord.sort()
oProgBar = ProgressBar(0, len(lWord))
for aEntry in lWord:
self.insert(aEntry)
oProgBar.increment(1)
oProgBar.done()
self.finish()
self.countNodes()
self.countArcs()
self.sortNodes() # version 2 and 3
self.sortNodeArcs(dValOccur)
#self.sortNodeArcs2 (self.oRoot, "")
self.displayInfo()
# BUILD DAWG
def insert (self, aEntry):
"insert a new entry (insertion must be made in alphabetical order)."
if aEntry < self.aPreviousEntry:
sys.exit("# Error: Words must be inserted in alphabetical order.")
# find common prefix between word and previous word
nCommonPrefix = 0
for i in range(min(len(aEntry), len(self.aPreviousEntry))):
if aEntry[i] != self.aPreviousEntry[i]:
break
nCommonPrefix += 1
# Check the lUncheckedNodes for redundant nodes, proceeding from last
# one down to the common prefix size. Then truncate the list at that point.
self._minimize(nCommonPrefix)
# add the suffix, starting from the correct node mid-way through the graph
if len(self.lUncheckedNodes) == 0:
oNode = self.oRoot
else:
oNode = self.lUncheckedNodes[-1][2]
iChar = nCommonPrefix
for c in aEntry[nCommonPrefix:]:
oNextNode = DawgNode()
oNode.arcs[c] = oNextNode
self.lUncheckedNodes.append((oNode, c, oNextNode))
if iChar == (len(aEntry) - 2):
oNode.final = True
iChar += 1
oNode = oNextNode
oNode.final = True
self.aPreviousEntry = aEntry
def finish (self):
"minimize unchecked nodes"
self._minimize(0)
def _minimize (self, downTo):
# proceed from the leaf up to a certain point
for i in range( len(self.lUncheckedNodes)-1, downTo-1, -1 ):
oNode, char, oChildNode = self.lUncheckedNodes[i]
if oChildNode in self.lMinimizedNodes:
# replace the child with the previously encountered one
oNode.arcs[char] = self.lMinimizedNodes[oChildNode]
else:
# add the state to the minimized nodes.
self.lMinimizedNodes[oChildNode] = oChildNode
self.lUncheckedNodes.pop()
def countNodes (self):
"count the number of nodes of the whole word graph"
self.nNode = len(self.lMinimizedNodes)
def countArcs (self):
"count the number of arcs in the whole word graph"
self.nArc = len(self.oRoot.arcs)
for oNode in self.lMinimizedNodes:
self.nArc += len(oNode.arcs)
def sortNodeArcs (self, dValOccur):
"sort arcs of each node according to <dValOccur>"
print(" > Sort node arcs")
self.oRoot.sortArcs(dValOccur)
for oNode in self.lMinimizedNodes:
oNode.sortArcs(dValOccur)
def sortNodeArcs2 (self, oNode, cPrevious=""):
"sort arcs of each node depending on the previous char"
# recursive function
dCharOccur = getCharOrderAfterChar(cPrevious)
if dCharOccur:
oNode.sortArcs2(dCharOccur, self.lArcVal)
for nArcVal, oNextNode in oNode.arcs.items():
self.sortNodeArcs2(oNextNode, self.lArcVal[nArcVal])
def sortNodes (self):
"sort nodes"
print(" > Sort nodes")
for oNode in self.oRoot.arcs.values():
self._parseNodes(oNode)
def _parseNodes (self, oNode):
# Warning: recursive method
if oNode.pos > 0:
return
oNode.setPos()
self.lSortedNodes.append(oNode)
for oNextNode in oNode.arcs.values():
self._parseNodes(oNextNode)
def lookup (self, sWord):
"return True if <sWord> is within the word graph (debugging)"
oNode = self.oRoot
for c in sWord:
if self.dChar.get(c, '') not in oNode.arcs:
return False
oNode = oNode.arcs[self.dChar[c]]
return oNode.final
def morph (self, sWord):
"return a string of the morphologies of <sWord> (debugging)"
oNode = self.oRoot
for c in sWord:
if self.dChar.get(c, '') not in oNode.arcs:
return ''
oNode = oNode.arcs[self.dChar[c]]
if oNode.final:
s = "* "
for arc in oNode.arcs:
if arc >= self.nChar:
s += " [" + self.funcStemming(sWord, self.lArcVal[arc])
oNode2 = oNode.arcs[arc]
for arc2 in oNode2.arcs:
s += " / " + self.lArcVal[arc2]
s += "]"
return s
return ''
def displayInfo (self):
"display informations about the word graph"
print(" * {:<12} {:>16,}".format("Entries:", self.nEntry))
print(" * {:<12} {:>16,}".format("Characters:", self.nChar))
print(" * {:<12} {:>16,}".format("Affixes:", self.nAff))
print(" * {:<12} {:>16,}".format("Tags:", self.nTag))
print(" * {:<12} {:>16,}".format("Arc values:", self.nArcVal))
print(" * {:<12} {:>16,}".format("Nodes:", self.nNode))
print(" * {:<12} {:>16,}".format("Arcs:", self.nArc))
print(" * {:<12} {:>16,}".format("2grams:", len(self.a2grams)))
print(" * {:<12} {:>16}".format("Stemming:", self.cStemming + "FX"))
def getArcStats (self):
"return a string with statistics about nodes and arcs"
d = {}
for oNode in self.lMinimizedNodes:
n = len(oNode.arcs)
d[n] = d.get(n, 0) + 1
s = " * Nodes:\n"
for n in d:
s = s + " {:>9} nodes have {:>3} arcs\n".format(d[n], n)
return s
def writeInfo (self, sPathFile):
"write informations in file <sPathFile>"
print(" > Write informations")
with open(sPathFile, 'w', encoding='utf-8', newline="\n") as hDst:
hDst.write(self.getArcStats())
hDst.write("\n * Values:\n")
for i, s in enumerate(self.lArcVal):
hDst.write(" {:>6}. {}\n".format(i, s))
hDst.close()
def select (self, sPattern=""):
"generator: returns all entries which morphology fits <sPattern>"
zPattern = None
if sPattern:
try:
zPattern = re.compile(sPattern)
except:
print("# Error in regex pattern")
traceback.print_exc()
yield from self._select(zPattern, self.oRoot, "")
def _select (self, zPattern, oNode, sWord):
# recursive generator
for nVal, oNextNode in oNode.arcs.items():
if nVal <= self.nChar:
# simple character
yield from self._select(zPattern, oNextNode, sWord + self.lArcVal[nVal])
else:
sEntry = sWord + "\t" + self.funcStemming(sWord, self.lArcVal[nVal])
for nMorphVal, _ in oNextNode.arcs.items():
if not zPattern or zPattern.search(self.lArcVal[nMorphVal]):
yield sEntry + "\t" + self.lArcVal[nMorphVal]
# BINARY CONVERSION
def _calculateBinary (self, nCompressionMethod):
print(" > Write DAWG as an indexable binary dictionary [method: %d]" % nCompressionMethod)
if nCompressionMethod == 1:
self.nBytesArc = ( (self.nArcVal.bit_length() + 2) // 8 ) + 1 # We add 2 bits. See DawgNode.convToBytes1()
self.nBytesOffset = 0
self._calcNumBytesNodeAddress()
self._calcNodesAddress1()
elif nCompressionMethod == 2:
self.nBytesArc = ( (self.nArcVal.bit_length() + 3) // 8 ) + 1 # We add 3 bits. See DawgNode.convToBytes2()
self.nBytesOffset = 0
self._calcNumBytesNodeAddress()
self._calcNodesAddress2()
elif nCompressionMethod == 3:
self.nBytesArc = ( (self.nArcVal.bit_length() + 3) // 8 ) + 1 # We add 3 bits. See DawgNode.convToBytes3()
self.nBytesOffset = 1
self.nMaxOffset = (2 ** (self.nBytesOffset * 8)) - 1
self._calcNumBytesNodeAddress()
self._calcNodesAddress3()
else:
print(" # Error: unknown compression method")
print(" Arc values (chars, affixes and tags): {} -> {} bytes".format( self.nArcVal, len("\t".join(self.lArcVal).encode("utf-8")) ))
print(" Arc size: {} bytes, Address size: {} bytes -> {} * {} = {} bytes".format( self.nBytesArc, self.nBytesNodeAddress, \
self.nBytesArc+self.nBytesNodeAddress, self.nArc, \
(self.nBytesArc+self.nBytesNodeAddress)*self.nArc ))
def _calcNumBytesNodeAddress (self):
"how many bytes needed to store all nodes/arcs in the binary dictionary"
self.nBytesNodeAddress = 1
while ((self.nBytesArc + self.nBytesNodeAddress) * self.nArc) > (2 ** (self.nBytesNodeAddress * 8)):
self.nBytesNodeAddress += 1
def _calcNodesAddress1 (self):
nBytesNode = self.nBytesArc + self.nBytesNodeAddress
iAddr = len(self.oRoot.arcs) * nBytesNode
for oNode in self.lMinimizedNodes:
oNode.addr = iAddr
iAddr += max(len(oNode.arcs), 1) * nBytesNode
def _calcNodesAddress2 (self):
nBytesNode = self.nBytesArc + self.nBytesNodeAddress
iAddr = len(self.oRoot.arcs) * nBytesNode
for oNode in self.lSortedNodes:
oNode.addr = iAddr
iAddr += max(len(oNode.arcs), 1) * nBytesNode
for oNextNode in oNode.arcs.values():
if (oNode.pos + 1) == oNextNode.pos:
iAddr -= self.nBytesNodeAddress
#break
def _calcNodesAddress3 (self):
nBytesNode = self.nBytesArc + self.nBytesNodeAddress
# theorical nodes size if only addresses and no offset
self.oRoot.size = len(self.oRoot.arcs) * nBytesNode
for oNode in self.lSortedNodes:
oNode.size = max(len(oNode.arcs), 1) * nBytesNode
# rewind and calculate dropdown from the end, several times
nDiff = self.nBytesNodeAddress - self.nBytesOffset
bEnd = False
while not bEnd:
bEnd = True
# recalculate addresses
iAddr = self.oRoot.size
for oNode in self.lSortedNodes:
oNode.addr = iAddr
iAddr += oNode.size
# rewind and calculate dropdown from the end, several times
for i in range(self.nNode-1, -1, -1):
nSize = max(len(self.lSortedNodes[i].arcs), 1) * nBytesNode
for oNextNode in self.lSortedNodes[i].arcs.values():
if 1 < (oNextNode.addr - self.lSortedNodes[i].addr) < self.nMaxOffset:
nSize -= nDiff
if self.lSortedNodes[i].size != nSize:
self.lSortedNodes[i].size = nSize
bEnd = False
def getBinaryAsJSON (self, nCompressionMethod=1, bBinaryDictAsHexString=True):
"return a JSON string containing all necessary data of the dictionary (compressed as a binary string)"
self._calculateBinary(nCompressionMethod)
byDic = b""
if nCompressionMethod == 1:
byDic = self.oRoot.convToBytes1(self.nBytesArc, self.nBytesNodeAddress)
for oNode in self.lMinimizedNodes:
byDic += oNode.convToBytes1(self.nBytesArc, self.nBytesNodeAddress)
elif nCompressionMethod == 2:
byDic = self.oRoot.convToBytes2(self.nBytesArc, self.nBytesNodeAddress)
for oNode in self.lSortedNodes:
byDic += oNode.convToBytes2(self.nBytesArc, self.nBytesNodeAddress)
elif nCompressionMethod == 3:
byDic = self.oRoot.convToBytes3(self.nBytesArc, self.nBytesNodeAddress, self.nBytesOffset)
for oNode in self.lSortedNodes:
byDic += oNode.convToBytes3(self.nBytesArc, self.nBytesNodeAddress, self.nBytesOffset)
return {
"sHeader": "/grammalecte-fsa/",
"sLangCode": self.sLangCode,
"sLangName": self.sLangName,
"sDicName": self.sDicName,
"sDescription": self.sDescription,
"sFileName": self.sFileName,
"sDate": self._getDate(),
"nEntry": self.nEntry,
"nChar": self.nChar,
"nAff": self.nAff,
"nTag": self.nTag,
"cStemming": self.cStemming,
"dChar": self.dChar,
"nNode": self.nNode,
"nArc": self.nArc,
"nArcVal": self.nArcVal,
"lArcVal": self.lArcVal,
"nCompressionMethod": nCompressionMethod,
"nBytesArc": self.nBytesArc,
"nBytesNodeAddress": self.nBytesNodeAddress,
"nBytesOffset": self.nBytesOffset,
# Mozilla’s JS parser don’t like file bigger than 4 Mb!
# So, if necessary, we use an hexadecimal string, that we will convert later in Firefox’s extension.
# https://github.com/mozilla/addons-linter/issues/1361
"sByDic": byDic.hex() if bBinaryDictAsHexString else [ e for e in byDic ],
"l2grams": list(self.a2grams)
}
def writeAsJSObject (self, spfDst, nCompressionMethod, bInJSModule=False, bBinaryDictAsHexString=True):
"write a file (JSON or JS module) with all the necessary data"
if not spfDst.endswith(".json"):
spfDst += "."+str(nCompressionMethod)+".json"
with open(spfDst, "w", encoding="utf-8", newline="\n") as hDst:
if bInJSModule:
hDst.write('// JavaScript\n// Generated data (do not edit)\n\n"use strict";\n\nconst dictionary = ')
hDst.write( json.dumps(self.getBinaryAsJSON(nCompressionMethod, bBinaryDictAsHexString), ensure_ascii=False) )
if bInJSModule:
hDst.write(";\n\nexports.dictionary = dictionary;\n")
def writeBinary (self, sPathFile, nCompressionMethod, bDebug=False):
"""
Save as a binary file.
Format of the binary indexable dictionary:
Each section is separated with 4 bytes of \0
- Section Header:
/grammalecte-fsa/[compression method]
* compression method is an ASCII string
- Section Informations:
/[lang code]
/[lang name]
/[dictionary name]
/[date creation]
/[number of chars]
/[number of bytes for each arc]
/[number of bytes for each address node]
/[number of entries]
/[number of nodes]
/[number of arcs]
/[number of affixes]
* each field is a ASCII string
/[stemming code]
* "S" means stems are generated by /suffix_code/,
"A" means they are generated by /affix_code/
See defineSuffixCode() and defineAffixCode() for details.
"N" means no stemming
- Section Values:
* a list of strings encoded in binary from utf-8, each value separated with a tabulation
- Section Word Graph (nodes / arcs)
* A list of nodes which are a list of arcs with an address of the next node.
See DawgNode.convToBytes() for details.
- Section 2grams:
* A list of 2grams (as strings: 2 chars) encoded in binary from utf-8, each value separated with a tabulation
"""
self._calculateBinary(nCompressionMethod)
if not sPathFile.endswith(".bdic"):
sPathFile += "."+str(nCompressionMethod)+".bdic"
with open(sPathFile, 'wb') as hDst:
# header
hDst.write("/grammalecte-fsa/{}/".format(nCompressionMethod).encode("utf-8"))
hDst.write(b"\0\0\0\0")
# infos
sInfo = "{}//{}//{}//{}//{}//{}//{}//{}//{}//{}//{}//{}//{}".format(self.sLangCode, self.sLangName, self.sDicName, self.sDescription, self._getDate(), \
self.nChar, self.nBytesArc, self.nBytesNodeAddress, \
self.nEntry, self.nNode, self.nArc, self.nAff, self.cStemming)
hDst.write(sInfo.encode("utf-8"))
hDst.write(b"\0\0\0\0")
# lArcVal
hDst.write("\t".join(self.lArcVal).encode("utf-8"))
hDst.write(b"\0\0\0\0")
# 2grams
hDst.write("\t".join(self.a2grams).encode("utf-8"))
hDst.write(b"\0\0\0\0")
# DAWG: nodes / arcs
if nCompressionMethod == 1:
hDst.write(self.oRoot.convToBytes1(self.nBytesArc, self.nBytesNodeAddress))
for oNode in self.lMinimizedNodes:
hDst.write(oNode.convToBytes1(self.nBytesArc, self.nBytesNodeAddress))
elif nCompressionMethod == 2:
hDst.write(self.oRoot.convToBytes2(self.nBytesArc, self.nBytesNodeAddress))
for oNode in self.lSortedNodes:
hDst.write(oNode.convToBytes2(self.nBytesArc, self.nBytesNodeAddress))
elif nCompressionMethod == 3:
hDst.write(self.oRoot.convToBytes3(self.nBytesArc, self.nBytesNodeAddress, self.nBytesOffset))
for oNode in self.lSortedNodes:
hDst.write(oNode.convToBytes3(self.nBytesArc, self.nBytesNodeAddress, self.nBytesOffset))
if bDebug:
self._writeNodes(sPathFile, nCompressionMethod)
def _getDate (self):
return time.strftime("%Y-%m-%d %H:%M:%S")
def _writeNodes (self, sPathFile, nCompressionMethod):
"for debugging only"
print(" > Write nodes")
with open(sPathFile+".nodes."+str(nCompressionMethod)+".txt", 'w', encoding='utf-8', newline="\n") as hDst:
if nCompressionMethod == 1:
hDst.write(self.oRoot.getTxtRepr1(self.nBytesArc, self.lArcVal)+"\n")
#hDst.write( ''.join( [ "%02X " % z for z in self.oRoot.convToBytes1(self.nBytesArc, self.nBytesNodeAddress) ] ).strip() )
for oNode in self.lMinimizedNodes:
hDst.write(oNode.getTxtRepr1(self.nBytesArc, self.lArcVal)+"\n")
if nCompressionMethod == 2:
hDst.write(self.oRoot.getTxtRepr2(self.nBytesArc, self.lArcVal)+"\n")
for oNode in self.lSortedNodes:
hDst.write(oNode.getTxtRepr2(self.nBytesArc, self.lArcVal)+"\n")
if nCompressionMethod == 3:
hDst.write(self.oRoot.getTxtRepr3(self.nBytesArc, self.nBytesOffset, self.lArcVal)+"\n")
#hDst.write( ''.join( [ "%02X " % z for z in self.oRoot.convToBytes3(self.nBytesArc, self.nBytesNodeAddress, self.nBytesOffset) ] ).strip() )
for oNode in self.lSortedNodes:
hDst.write(oNode.getTxtRepr3(self.nBytesArc, self.nBytesOffset, self.lArcVal)+"\n")
class DawgNode:
"""Node of the word graph"""
NextId = 0
NextPos = 1 # (version 2)
def __init__ (self):
self.i = DawgNode.NextId
DawgNode.NextId += 1
self.final = False
self.arcs = {} # key: arc value; value: a node
self.addr = 0 # address in the binary dictionary
self.pos = 0 # position in the binary dictionary (version 2)
self.size = 0 # size of node in bytes (version 3)
@classmethod
def resetNextId (cls):
"set NextId to 0 "
cls.NextId = 0
def setPos (self): # version 2
"define a position for node (version 2)"
self.pos = DawgNode.NextPos
DawgNode.NextPos += 1
def __str__ (self):
s = "Node " + str(self.i) + " @ " + str(self.addr) + (" [final]" if self.final else "") + "\n"
for arc, node in self.arcs.items():
s += " " +str(arc)
s += " > " + str(node.i)
s += " @ " + str(node.addr) + "\n"
return s
def __repr__ (self):
# Caution! this function is used for hashing and comparison!
sFinalChar = "1" if self.final else "0"
l = [sFinalChar]
for arc, node in self.arcs.items():
l.append(str(arc))
l.append(str(node.i))
return "_".join(l)
def __hash__ (self):
# Used as a key in a python dictionary.
return self.__repr__().__hash__()
def __eq__ (self, other):
# Used as a key in a python dictionary.
# Nodes are equivalent if they have identical arcs, and each identical arc leads to identical states.
return self.__repr__() == other.__repr__()
def sortArcs (self, dValOccur):
"sort arcs of node according to <dValOccur>"
self.arcs = collections.OrderedDict(sorted(self.arcs.items(), key=lambda t: dValOccur.get(t[0], 0), reverse=True))
def sortArcs2 (self, dValOccur, lArcVal):
"sort arcs of each node depending on the previous char"
self.arcs = collections.OrderedDict(sorted(self.arcs.items(), key=lambda t: dValOccur.get(lArcVal[t[0]], 0), reverse=True))
# VERSION 1 =====================================================================================================
def convToBytes1 (self, nBytesArc, nBytesNodeAddress):
"""
Convert to bytes (method 1).
Node scheme:
- Arc length is defined by nBytesArc
- Address length is defined by nBytesNodeAddress
| Arc | Address of next node |
| | |
┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓
┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃
┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛
[...]
┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓
┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃
┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛
^ ^
┃ ┃
┃ ┃
┃ ┗━━━ if 1, last arc of this node
┗━━━━━ if 1, this node is final (only on the first arc)
"""
nArc = len(self.arcs)
nFinalNodeMask = 1 << ((nBytesArc*8)-1)
nFinalArcMask = 1 << ((nBytesArc*8)-2)
if not nArc:
val = nFinalNodeMask | nFinalArcMask
by = val.to_bytes(nBytesArc, byteorder='big')
by += (0).to_bytes(nBytesNodeAddress, byteorder='big')
return by
by = b""
for i, arc in enumerate(self.arcs, 1):
val = arc
if i == 1 and self.final:
val = val | nFinalNodeMask
if i == nArc:
val = val | nFinalArcMask
by += val.to_bytes(nBytesArc, byteorder='big')
by += self.arcs[arc].addr.to_bytes(nBytesNodeAddress, byteorder='big')
return by
def getTxtRepr1 (self, nBytesArc, lVal):
"return representation as string of node (method 1)"
nArc = len(self.arcs)
nFinalNodeMask = 1 << ((nBytesArc*8)-1)
nFinalArcMask = 1 << ((nBytesArc*8)-2)
s = "i{:_>10} -- #{:_>10}\n".format(self.i, self.addr)
if not nArc:
s += " {:<20} {:0>16} i{:_>10} #{:_>10}\n".format("", bin(nFinalNodeMask | nFinalArcMask)[2:], "0", "0")
return s
for i, arc in enumerate(self.arcs, 1):
val = arc
if i == 1 and self.final:
val = val | nFinalNodeMask
if i == nArc:
val = val | nFinalArcMask
s += " {:<20} {:0>16} i{:_>10} #{:_>10}\n".format(lVal[arc], bin(val)[2:], self.arcs[arc].i, self.arcs[arc].addr)
return s
# VERSION 2 =====================================================================================================
def convToBytes2 (self, nBytesArc, nBytesNodeAddress):
"""
Convert to bytes (method 2).
Node scheme:
- Arc length is defined by nBytesArc
- Address length is defined by nBytesNodeAddress
| Arc | Address of next node |
| | |
┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓
┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃
┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛
[...]
┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓
┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃
┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛
^ ^ ^
┃ ┃ ┃
┃ ┃ ┗━━ if 1, caution, no address: next node is the following node
┃ ┗━━━━ if 1, last arc of this node
┗━━━━━━ if 1, this node is final (only on the first arc)
"""
nArc = len(self.arcs)
nFinalNodeMask = 1 << ((nBytesArc*8)-1)
nFinalArcMask = 1 << ((nBytesArc*8)-2)
nNextNodeMask = 1 << ((nBytesArc*8)-3)
if not nArc:
val = nFinalNodeMask | nFinalArcMask
by = val.to_bytes(nBytesArc, byteorder='big')
by += (0).to_bytes(nBytesNodeAddress, byteorder='big')
return by
by = b""
for i, arc in enumerate(self.arcs, 1):
val = arc
if i == 1 and self.final:
val = val | nFinalNodeMask
if i == nArc:
val = val | nFinalArcMask
if (self.pos + 1) == self.arcs[arc].pos and self.i != 0:
val = val | nNextNodeMask
by += val.to_bytes(nBytesArc, byteorder='big')
else:
by += val.to_bytes(nBytesArc, byteorder='big')
by += self.arcs[arc].addr.to_bytes(nBytesNodeAddress, byteorder='big')
return by
def getTxtRepr2 (self, nBytesArc, lVal):
"return representation as string of node (method 2)"
nArc = len(self.arcs)
nFinalNodeMask = 1 << ((nBytesArc*8)-1)
nFinalArcMask = 1 << ((nBytesArc*8)-2)
nNextNodeMask = 1 << ((nBytesArc*8)-3)
s = "i{:_>10} -- #{:_>10}\n".format(self.i, self.addr)
if not nArc:
s += " {:<20} {:0>16} i{:_>10} #{:_>10}\n".format("", bin(nFinalNodeMask | nFinalArcMask)[2:], "0", "0")
return s
for i, arc in enumerate(self.arcs, 1):
val = arc
if i == 1 and self.final:
val = val | nFinalNodeMask
if i == nArc:
val = val | nFinalArcMask
if (self.pos + 1) == self.arcs[arc].pos and self.i != 0:
val = val | nNextNodeMask
s += " {:<20} {:0>16}\n".format(lVal[arc], bin(val)[2:])
else:
s += " {:<20} {:0>16} i{:_>10} #{:_>10}\n".format(lVal[arc], bin(val)[2:], self.arcs[arc].i, self.arcs[arc].addr)
return s
# VERSION 3 =====================================================================================================
def convToBytes3 (self, nBytesArc, nBytesNodeAddress, nBytesOffset):
"""
Convert to bytes (method 3).
Node scheme:
- Arc length is defined by nBytesArc
- Address length is defined by nBytesNodeAddress
- Offset length is defined by nBytesOffset
| Arc | Address of next node or offset to next node |
| | |
┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓
┃1┃0┃0┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃
┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛
[...]
┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓
┃0┃0┃1┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ Offsets are shorter than addresses
┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛
┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓ ┏━━━━━━━━━━━━━━━┓
┃0┃1┃0┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃ ┃
┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛ ┗━━━━━━━━━━━━━━━┛
^ ^ ^
┃ ┃ ┃
┃ ┃ ┗━━ if 1, offset instead of address of next node
┃ ┗━━━━ if 1, last arc of this node
┗━━━━━━ if 1, this node is final (only on the first arc)
"""
nArc = len(self.arcs)
nFinalNodeMask = 1 << ((nBytesArc*8)-1)
nFinalArcMask = 1 << ((nBytesArc*8)-2)
nNextNodeMask = 1 << ((nBytesArc*8)-3)
nMaxOffset = (2 ** (nBytesOffset * 8)) - 1
if not nArc:
val = nFinalNodeMask | nFinalArcMask
by = val.to_bytes(nBytesArc, byteorder='big')
by += (0).to_bytes(nBytesNodeAddress, byteorder='big')
return by
by = b""
for i, arc in enumerate(self.arcs, 1):
val = arc
if i == 1 and self.final:
val = val | nFinalNodeMask
if i == nArc:
val = val | nFinalArcMask
if 1 < (self.arcs[arc].addr - self.addr) < nMaxOffset and self.i != 0:
val = val | nNextNodeMask
by += val.to_bytes(nBytesArc, byteorder='big')
by += (self.arcs[arc].addr-self.addr).to_bytes(nBytesOffset, byteorder='big')
else:
by += val.to_bytes(nBytesArc, byteorder='big')
by += self.arcs[arc].addr.to_bytes(nBytesNodeAddress, byteorder='big')
return by
def getTxtRepr3 (self, nBytesArc, nBytesOffset, lVal):
"return representation as string of node (method 3)"
nArc = len(self.arcs)
nFinalNodeMask = 1 << ((nBytesArc*8)-1)
nFinalArcMask = 1 << ((nBytesArc*8)-2)
nNextNodeMask = 1 << ((nBytesArc*8)-3)
nMaxOffset = (2 ** (nBytesOffset * 8)) - 1
s = "i{:_>10} -- #{:_>10} ({})\n".format(self.i, self.addr, self.size)
if not nArc:
s += " {:<20} {:0>16} i{:_>10} #{:_>10}\n".format("", bin(nFinalNodeMask | nFinalArcMask)[2:], "0", "0")
return s
for i, arc in enumerate(self.arcs, 1):
val = arc
if i == 1 and self.final:
val = val | nFinalNodeMask
if i == nArc:
val = val | nFinalArcMask
if 1 < (self.arcs[arc].addr - self.addr) < nMaxOffset and self.i != 0:
val = val | nNextNodeMask
s += " {:<20} {:0>16} i{:_>10} +{:_>10}\n".format(lVal[arc], bin(val)[2:], self.arcs[arc].i, self.arcs[arc].addr - self.addr)
else:
s += " {:<20} {:0>16} i{:_>10} #{:_>10}\n".format(lVal[arc], bin(val)[2:], self.arcs[arc].i, self.arcs[arc].addr)
return s
# Another attempt to sort node arcs
_dCharOrder = {
# key: previous char, value: dictionary of chars {c: nValue}
"": {}
}
def addWordToCharDict (sWord):
"for each character of <sWord>, count how many times it appears after the previous character, and store result in a <_dCharOrder>"
cPrevious = ""
for cChar in sWord:
if cPrevious not in _dCharOrder:
_dCharOrder[cPrevious] = {}
_dCharOrder[cPrevious][cChar] = _dCharOrder[cPrevious].get(cChar, 0) + 1
cPrevious = cChar
def getCharOrderAfterChar (cChar):
"return a dictionary of chars with number of times it appears after character <cChar>"
return _dCharOrder.get(cChar, None)
def displayCharOrder ():
"display how many times each character appear after another one"
for key, value in _dCharOrder.items():
print("[" + key + "]: ", ", ".join([ c+":"+str(n) for c, n in sorted(value.items(), key=lambda t: t[1], reverse=True) ]))