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# moyenne des formes fléchies sans équivalent ou -1
self.nAKO = math.ceil(nOccur / nFlex) if nFlex > 0 else -1
def solveOccurMultipleFlexions (self, hDst, oStatsLex):
sBlank = " "
if self.nAKO >= 0:
for oFlex in self.lFlexions:
if oFlex.nMulti > 0 and not oFlex.bFixed:
if oFlex.nMulti > 0 and not oFlex.bBlocked:
# on trie les entrées avec AKO et sans AKO
lEntWithAKO = []
lEntNoAKO = []
for oEntry in oFlex.lMulti:
if oEntry.nAKO >= 0:
lEntWithAKO.append(oEntry)
else:
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1120
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1123
1124
1125
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1128
1129
1130
1131
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1135
1136
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if nDiff > 0:
# on peut passer à les formes fléchies à AKO
hDst.write(" * {0.sFlexion}\n".format(oFlex))
hDst.write(" moyenne connue\n")
for oFlexD in self.lFlexions:
if oFlex.sFlexion == oFlexD.sFlexion:
hDst.write(sBlank + "{2:<30} {0.sMorph:<30} {0.nOccur:>10} >> {1:>10}\n".format(oFlexD, self.nAKO, self.getShortDescr()))
oFlexD.setOccur(self.nAKO)
oFlexD.setOccurAndBlock(self.nAKO)
for oEntry in lEntWithAKO:
hDst.write(" moyenne connue\n")
for oFlexM in oEntry.lFlexions:
if oFlex.sFlexion == oFlexM.sFlexion:
hDst.write(sBlank + "{2:<30} {0.sMorph:<30} {0.nOccur:>10} >> {1:>10}\n".format(oFlexM, oEntry.nAKO, oEntry.getShortDescr()))
oFlexM.setOccur(oEntry.nAKO)
oFlexM.setOccurAndBlock(oEntry.nAKO)
# on répercute nDiff sur les flexions sans AKO
for oEntry in lEntNoAKO:
hDst.write(" sans moyenne connue\n")
for oFlexM in oEntry.lFlexions:
if oFlex.sFlexion == oFlexM.sFlexion:
nNewOccur = oFlexM.nOccur + math.ceil((nDiff / len(lEntNoAKO)) / oFlexM.nDup)
hDst.write(sBlank + "{2:<30} {0.sMorph:<30} {0.nOccur:>10} +> {1:>10}\n".format(oFlexM, nNewOccur, oEntry.getShortDescr()))
oFlexM.setOccur(nNewOccur)
oFlexM.setOccurAndBlock(nNewOccur)
else:
# Toutes les entrées sont avec AKO : on pondère
nFlexOccur = oStatsLex.getFlexionOccur(oFlex.sFlexion)
nTotAKO = self.nAKO
for oEnt in oFlex.lMulti:
nTotAKO += oEnt.nAKO
hDst.write(" = {0.sFlexion}\n".format(oFlex))
hDst.write(" moyennes connues\n")
for oFlexD in self.lFlexions:
if oFlex.sFlexion == oFlexD.sFlexion:
nNewOccur = math.ceil((nFlexOccur * (self.nAKO / nTotAKO)) / oFlexD.nDup) if nTotAKO else 0
hDst.write(sBlank + "{2:<30} {0.sMorph:<30} {0.nOccur:>10} %> {1:>10}\n".format(oFlexD, nNewOccur, self.getShortDescr()))
oFlexD.setOccur(nNewOccur)
oFlexD.setOccurAndBlock(nNewOccur)
for oEntry in oFlex.lMulti:
for oFlexM in oEntry.lFlexions:
if oFlex.sFlexion == oFlexM.sFlexion:
nNewOccur = math.ceil((nFlexOccur * (oEntry.nAKO / nTotAKO)) / oFlexM.nDup) if nTotAKO else 0
hDst.write(sBlank + "{2:<30} {0.sMorph:<30} {0.nOccur:>10} %> {1:>10}\n".format(oFlexM, nNewOccur, oEntry.getShortDescr()))
oFlexM.setOccur(nNewOccur)
oFlexM.setOccurAndBlock(nNewOccur)
def calcFreq (self, nTot):
self.fFreq = (self.nOccur * 100) / nTot
self.oldFq = self.fq
self.fq = getIfq(self.fFreq)
class Flexion:
def __init__ (self, oEntry, sFlex='', sMorph='', cDic=''):
self.oEntry = oEntry
self.sFlexion = sFlex
self.sMorph = sMorph
self.cDic = cDic
self.nOccur = 0
self.bFixed = False
self.bBlocked = False
self.nDup = 0 # duplicates in the same entry
self.nMulti = 0 # duplicates with other entries
self.lMulti = [] # list of similar flexions
self.fFreq = 0
self.cFq = ''
self.metagfx = '' # métagraphe
self.metaph2 = '' # métaphone 2
def setOccur (self, n):
self.nOccur = n
def setOccurAndBlock (self, n):
self.nOccur = n
self.bFixed = True
self.bBlocked = True
def calcOccur (self):
self.nOccur = math.ceil((self.nOccur / (self.nMulti+1)) / self.nDup)
def calcFreq (self, nTot):
self.fFreq = (self.nOccur * 100) / nTot
self.cFq = getIfq(self.fFreq)
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