def generate_random_performance_table(alts,
crits,
seed=None,
k=3,
worst=None,
best=None):
if seed is not None:
random.seed(seed)
pt = PerformanceTable()
for a in alts:
perfs = {}
for c in crits:
if worst is None or best is None:
rdom = round(random.random(), k)
else:
rdom = round(
random.uniform(worst.performances[c.id],
best.performances[c.id]), k)
perfs[c.id] = rdom
ap = AlternativePerformances(a.id, perfs)
pt.append(ap)
return pt
def generate_binary_performance_table_and_assignments(criteria,
categories, fmins):
cids = list(criteria.keys())
cats = categories.get_ordered_categories()
aa = AlternativesAssignments()
pt = PerformanceTable()
i = 1
for coalition in powerset(cids):
if set(coalition) == set({}) or set(coalition) == set(cids):
continue
aid = "a%d" % i
ap = AlternativePerformances(aid,
OrderedDict({c: 1 if c in coalition else 0
for c in cids}))
pt.append(ap)
cat = cats[0]
for fmin in fmins:
if fmin.issubset(set(coalition)) is True:
cat = cats[1]
break
aa.append(AlternativeAssignment(aid, cat))
i += 1
return pt, aa
def solve_cplex(self):
self.lp.solve()
status = self.lp.solution.get_status()
if status != self.lp.solution.status.MIP_optimal:
raise RuntimeError("Solver status: %s" % status)
obj = self.lp.solution.get_objective_value()
cvs = CriteriaValues()
for c in self.criteria:
cv = CriterionValue()
cv.id = c.id
cv.value = self.lp.solution.get_values('w_' + c.id)
cvs.append(cv)
self.model.cv = cvs
self.model.lbda = self.lp.solution.get_values("lambda")
pt = PerformanceTable()
for p in self.__profiles:
ap = AlternativePerformances(p)
for c in self.criteria:
perf = self.lp.solution.get_values("g_%s_%s" % (p, c.id))
ap.performances[c.id] = round(perf, 5)
pt.append(ap)
self.model.bpt = pt
self.model.bpt.update_direction(self.model.criteria)
return obj
def solve_cplex(self):
self.lp.solve()
status = self.lp.solution.get_status()
if status != self.lp.solution.status.MIP_optimal:
raise RuntimeError("Solver status: %s" % status)
obj = self.lp.solution.get_objective_value()
cvs = CriteriaValues()
for c in self.criteria:
cv = CriterionValue()
cv.id = c.id
cv.value = self.lp.solution.get_values('w_' + c.id)
cvs.append(cv)
self.model.cv = cvs
self.model.lbda = self.lp.solution.get_values("lambda")
pt = PerformanceTable()
for p in self.__profiles:
ap = AlternativePerformances(p)
for c in self.criteria:
perf = self.lp.solution.get_values("g_%s_%s" % (p, c.id))
ap.performances[c.id] = round(perf, 5)
pt.append(ap)
self.model.bpt = pt
self.model.bpt.update_direction(self.model.criteria)
return obj
def solve_glpk(self):
self.lp.solvopt(method='exact', integer='advanced')
self.lp.solve()
status = self.lp.status()
if status != 'opt':
raise RuntimeError("Solver status: %s" % self.lp.status())
#print(self.lp.reportKKT())
obj = self.lp.vobj()
cvs = CriteriaValues()
for c in self.criteria:
cv = CriterionValue()
cv.id = c.id
cv.value = float(self.w[c.id].primal)
cvs.append(cv)
self.model.cv = cvs
self.model.lbda = self.lbda.primal
pt = PerformanceTable()
for p in self.__profiles:
ap = AlternativePerformances(p)
for c in self.criteria:
perf = self.g[p][c.id].primal
ap.performances[c.id] = round(perf, 5)
pt.append(ap)
self.model.bpt = pt
self.model.bpt.update_direction(self.model.criteria)
return obj
def solve_glpk(self):
self.lp.solvopt(method='exact', integer='advanced')
self.lp.solve()
status = self.lp.status()
if status != 'opt':
raise RuntimeError("Solver status: %s" % self.lp.status())
#print(self.lp.reportKKT())
obj = self.lp.vobj()
cvs = CriteriaValues()
for c in self.criteria:
cv = CriterionValue()
cv.id = c.id
cv.value = float(self.w[c.id].primal)
cvs.append(cv)
self.model.cv = cvs
self.model.lbda = self.lbda.primal
pt = PerformanceTable()
for p in self.__profiles:
ap = AlternativePerformances(p)
for c in self.criteria:
perf = self.g[p][c.id].primal
ap.performances[c.id] = round(perf, 5)
pt.append(ap)
self.model.bpt = pt
self.model.bpt.update_direction(self.model.criteria)
return obj
def duplicate_performance_table_msjp(pt,
alts,
crits,
seed=None,
k=3,
worst=None,
best=None,
dupl_crits=None):
if seed is not None:
random.seed(seed)
pt_dupl = PerformanceTable()
tmp_ids = [i.id for i in dupl_crits]
for ap in pt:
ap_perfs = ap.performances
for c in crits:
#import pdb; pdb.set_trace()
# pt[c.id] = None
# perfs_dupl[c.id] = None
if (c.id + "d") in tmp_ids:
ap_perfs[(c.id + "d")] = ap_perfs[c.id]
ap_dupl = AlternativePerformances(ap.altid, ap_perfs)
#pt.append(ap)
pt_dupl.append(ap_dupl)
return pt_dupl
def generate_binary_performance_table_and_assignments(criteria, categories,
fmins):
cids = list(criteria.keys())
cats = categories.get_ordered_categories()
aa = AlternativesAssignments()
pt = PerformanceTable()
i = 1
for coalition in powerset(cids):
if set(coalition) == set({}) or set(coalition) == set(cids):
continue
aid = "a%d" % i
ap = AlternativePerformances(
aid, OrderedDict({c: 1 if c in coalition else 0
for c in cids}))
pt.append(ap)
cat = cats[0]
for fmin in fmins:
if fmin.issubset(set(coalition)) is True:
cat = cats[1]
break
aa.append(AlternativeAssignment(aid, cat))
i += 1
return pt, aa
def veto(self):
if self.vpt is None:
return None
veto = PerformanceTable()
for bp in self.bpt:
vbp = bp - self.vpt[bp.id]
veto.append(vbp)
return veto
def veto(self, veto):
if veto is None:
self.vpt = None
return
self.vpt = PerformanceTable()
for bp in self.bpt:
vbp = bp - veto[bp.id]
self.vpt.append(vbp)
def veto(self):
if self.vpt is None:
return None
veto = PerformanceTable()
for bp in self.bpt:
vbp = bp - self.vpt[bp.id]
veto.append(vbp)
return veto
def generate_random_profiles_msjp(alts,
crits,
seed=None,
k=3,
worst=None,
best=None,
fct_percentile=[],
nb_unk_criteria=0):
if seed is not None:
random.seed(seed)
if worst is None:
worst = generate_worst_ap(crits)
if best is None:
best = generate_best_ap(crits)
crit_random = {}
n = len(alts)
pt = PerformanceTable()
random.seed(seed)
for c in crits:
rdom = []
random.seed(seed)
for i in range(n):
minp = worst.performances[c.id]
maxp = best.performances[c.id]
if minp > maxp:
minp, maxp = maxp, minp
if (c.id[-1] != "d") and (int(c.id[1:]) <= nb_unk_criteria):
rdom.append(
round(
random.uniform(
max(minp, fct_percentile[int(c.id[1:]) - 1][0]),
min(maxp, fct_percentile[int(c.id[1:]) - 1][1])),
k))
else:
rdom.append(round(random.uniform(minp, maxp), k))
if c.direction == -1:
rdom.sort(reverse=True)
else:
rdom.sort()
crit_random[c.id] = rdom
#import pdb; pdb.set_trace()
for i, a in enumerate(alts):
perfs = {}
for c in crits:
perfs[c.id] = crit_random[c.id][i]
ap = AlternativePerformances(a, perfs)
pt.append(ap)
return pt
def generate_random_performance_table_msjp_mip(alts,
crits,
seed=None,
k=2,
worst=None,
best=None,
dupl_crits=None,
cardinality=10):
if seed is not None:
random.seed(seed)
pt = PerformanceTable()
pt_dupl = PerformanceTable()
tmp_ids = [i.id for i in dupl_crits]
for a in alts:
perfs = {}
perfs_dupl = {}
for c in crits:
rdom = round(
random.choice([
f for f in np.arange(0, 1. + 1. / (10**k), 1. /
(cardinality - 1))
]), k)
perfs[c.id] = rdom
perfs_dupl[c.id] = rdom
if (c.id + "d") in tmp_ids:
perfs_dupl[(c.id + "d")] = rdom
ap = AlternativePerformances(a.id, perfs)
ap_dupl = AlternativePerformances(a.id, perfs_dupl)
pt.append(ap)
pt_dupl.append(ap_dupl)
return pt, pt_dupl
def generate_random_performance_table_msjp(alts, crits, seed = None, k = 3,
worst = None, best = None, dupl_crits = None):
if seed is not None:
random.seed(seed)
pt = PerformanceTable()
pt_dupl = PerformanceTable()
tmp_ids = [i.id for i in dupl_crits]
for a in alts:
perfs = {}
perfs_dupl = {}
for c in crits:
if worst is None or best is None:
#random.seed()
rdom = round(random.random(), k)
else:
rdom = round(random.uniform(worst.performances[c.id],
best.performances[c.id]), k)
perfs[c.id] = rdom
perfs_dupl[c.id] = rdom
if (c.id+"d") in tmp_ids:
perfs_dupl[(c.id+"d")] = rdom
ap = AlternativePerformances(a.id, perfs)
ap_dupl = AlternativePerformances(a.id, perfs_dupl)
pt.append(ap)
pt_dupl.append(ap_dupl)
return pt,pt_dupl
def test001(self):
c = generate_criteria(3)
cat = generate_categories(3)
cps = generate_categories_profiles(cat)
bp1 = AlternativePerformances('b1', {
'c1': 0.75,
'c2': 0.75,
'c3': 0.75
})
bp2 = AlternativePerformances('b2', {
'c1': 0.25,
'c2': 0.25,
'c3': 0.25
})
bpt = PerformanceTable([bp1, bp2])
cv1 = CriterionValue('c1', 0.2)
cv2 = CriterionValue('c2', 0.2)
cv3 = CriterionValue('c3', 0.2)
cv12 = CriterionValue(CriteriaSet(['c1', 'c2']), -0.1)
cv23 = CriterionValue(CriteriaSet(['c2', 'c3']), 0.2)
cv13 = CriterionValue(CriteriaSet(['c1', 'c3']), 0.3)
cvs = CriteriaValues([cv1, cv2, cv3, cv12, cv23, cv13])
lbda = 0.6
model = MRSort(c, cvs, bpt, lbda, cps)
ap1 = AlternativePerformances('a1', {'c1': 0.3, 'c2': 0.3, 'c3': 0.3})
ap2 = AlternativePerformances('a2', {'c1': 0.8, 'c2': 0.8, 'c3': 0.8})
ap3 = AlternativePerformances('a3', {'c1': 0.3, 'c2': 0.3, 'c3': 0.1})
ap4 = AlternativePerformances('a4', {'c1': 0.3, 'c2': 0.1, 'c3': 0.3})
ap5 = AlternativePerformances('a5', {'c1': 0.1, 'c2': 0.3, 'c3': 0.3})
ap6 = AlternativePerformances('a6', {'c1': 0.8, 'c2': 0.8, 'c3': 0.1})
ap7 = AlternativePerformances('a7', {'c1': 0.8, 'c2': 0.1, 'c3': 0.8})
ap8 = AlternativePerformances('a8', {'c1': 0.1, 'c2': 0.8, 'c3': 0.8})
pt = PerformanceTable([ap1, ap2, ap3, ap4, ap5, ap6, ap7, ap8])
aa = model.get_assignments(pt)
self.assertEqual(aa['a1'].category_id, "cat2")
self.assertEqual(aa['a2'].category_id, "cat1")
self.assertEqual(aa['a3'].category_id, "cat3")
self.assertEqual(aa['a4'].category_id, "cat2")
self.assertEqual(aa['a5'].category_id, "cat2")
self.assertEqual(aa['a6'].category_id, "cat3")
self.assertEqual(aa['a7'].category_id, "cat1")
self.assertEqual(aa['a8'].category_id, "cat1")
def generate_random_veto_profiles(model, worst = None, k = 3):
if worst is None:
worst = generate_worst_ap(model.criteria)
vpt = PerformanceTable()
for bid in model.profiles:
ap = AlternativePerformances(bid, {})
for c in model.criteria:
a = model.bpt[bid].performances[c.id]
b = worst.performances[c.id]
ap.performances[c.id] = round(random.uniform(a, b), k)
vpt.append(ap)
worst = ap
return vpt
def generate_random_veto_profiles(model, worst = None, k = 3):
if worst is None:
worst = generate_worst_ap(model.criteria)
vpt = PerformanceTable()
for bid in model.profiles:
ap = AlternativePerformances(bid, {})
for c in model.criteria:
a = model.bpt[bid].performances[c.id]
b = worst.performances[c.id]
ap.performances[c.id] = round(random.uniform(a, b), k)
vpt.append(ap)
worst = ap
return vpt
def solve(self):
cats = self.model.categories[:]
cats.reverse()
profiles = self.model.profiles[:]
profiles.reverse()
bpt = PerformanceTable()
pabove = self.pt_sorted.pt.get_best(self.model.criteria)
for i in range(len(cats) - 1):
profile_id = profiles[i]
bp = self.init_profile(profile_id, cats[i], cats[i + 1], pabove)
bpt.append(bp)
pabove = bp
self.model.bpt = bpt
def solve(self):
cats = self.model.categories[:]
cats.reverse()
profiles = self.model.profiles[:]
profiles.reverse()
vpt = PerformanceTable()
pabove = self.pt_sorted.pt.get_best(self.model.criteria)
for i in range(len(cats) - 1):
profile_id = profiles[i]
b1 = self.model.bpt['b1']
vp = self.init_profile(profile_id, cats[i], cats[i+1])
vpt.append(b1 - vp)
self.model.veto = vpt
def solve(self):
cats = self.model.categories[:]
cats.reverse()
profiles = self.model.profiles[:]
profiles.reverse()
bpt = PerformanceTable()
pabove = self.pt_sorted.pt.get_best(self.model.criteria)
for i in range(len(cats) - 1):
profile_id = profiles[i]
bp = self.init_profile(profile_id, cats[i], cats[i+1], pabove)
bpt.append(bp)
pabove = bp
self.model.bpt = bpt
def solve(self):
cats = self.model.categories[:]
cats.reverse()
profiles = self.model.profiles[:]
profiles.reverse()
vpt = PerformanceTable()
pabove = self.pt_sorted.pt.get_best(self.model.criteria)
for i in range(len(cats) - 1):
profile_id = profiles[i]
b1 = self.model.bpt['b1']
vp = self.init_profile(profile_id, cats[i], cats[i + 1])
vpt.append(b1 - vp)
self.model.veto = vpt
def __init__(self, criteria = None, cv = None, bpt = None,
lbda = None, categories_profiles = None, veto = None,
veto_weights = None, veto_lbda = None, id = None):
super(MRSort, self).__init__(criteria, cv, bpt, lbda,
categories_profiles)
#for possibly single-peaked criteria (or single valleyed) :
#self.bpt_sp = [(0,1)]*len(categories_profiles)
self.bpt_sp = PerformanceTable()
#import pdb; pdb.set_trace()
if not(self.bpt is None):
for i,j in categories_profiles.items():
ap = deepcopy(self.bpt[i])
self.bpt_sp.append(ap)
#import pdb; pdb.set_trace()
self.b_peak = None
self.veto = veto
self.veto_weights = veto_weights
self.veto_lbda = veto_lbda
def veto(self, veto):
if veto is None:
self.vpt = None
return
self.vpt = PerformanceTable()
for bp in self.bpt:
vbp = bp - veto[bp.id]
self.vpt.append(vbp)
def generate_random_profiles_msjp(alts,
crits,
seed=None,
k=3,
worst=None,
best=None):
if seed is not None:
random.seed(seed)
if worst is None:
worst = generate_worst_ap(crits)
if best is None:
best = generate_best_ap(crits)
crit_random = {}
n = len(alts)
pt = PerformanceTable()
random.seed(seed)
for c in crits:
rdom = []
random.seed(seed)
for i in range(n):
minp = worst.performances[c.id]
maxp = best.performances[c.id]
if minp > maxp:
minp, maxp = maxp, minp
rdom.append(round(random.uniform(minp, maxp), k))
if c.direction == -1:
rdom.sort(reverse=True)
else:
rdom.sort()
crit_random[c.id] = rdom
for i, a in enumerate(alts):
perfs = {}
for c in crits:
perfs[c.id] = crit_random[c.id][i]
ap = AlternativePerformances(a, perfs)
pt.append(ap)
return pt
def solve(self):
self.lp.solve()
status = self.lp.solution.get_status()
if status != self.lp.solution.status.MIP_optimal:
raise RuntimeError("Solver status: %s" % status)
obj = self.lp.solution.get_objective_value()
cvs = CriteriaValues()
for c in self.criteria:
cv = CriterionValue()
cv.id = c.id
cv.value = self.lp.solution.get_values('w_' + c.id)
cvs.append(cv)
self.model.cv = cvs
self.model.lbda = self.lp.solution.get_values("lambda")
pt = PerformanceTable()
for p in self.__profiles:
ap = AlternativePerformances(p)
for c in self.criteria:
perf = self.lp.solution.get_values("g_%s_%s" % (p, c.id))
ap.performances[c.id] = round(perf, 5)
pt.append(ap)
self.model.bpt = pt
self.model.bpt.update_direction(self.model.criteria)
wv = CriteriaValues()
for c in self.criteria:
w = CriterionValue()
w.id = c.id
w.value = self.lp.solution.get_values('z_' + c.id)
wv.append(w)
self.model.veto_weights = wv
self.model.veto_lbda = self.lp.solution.get_values("LAMBDA")
v = PerformanceTable()
for p in self.__profiles:
vp = AlternativePerformances(p, {})
for c in self.criteria:
perf = self.lp.solution.get_values('v_%s_%s' % (p, c.id))
vp.performances[c.id] = round(perf, 5)
v.append(vp)
self.model.veto = v
return obj
def generate_random_performance_table(alts, crits, seed = None, k = 3,
worst = None, best = None):
if seed is not None:
random.seed(seed)
pt = PerformanceTable()
for a in alts:
perfs = {}
for c in crits:
if worst is None or best is None:
rdom = round(random.random(), k)
else:
rdom = round(random.uniform(worst.performances[c.id],
best.performances[c.id]), k)
perfs[c.id] = rdom
ap = AlternativePerformances(a.id, perfs)
pt.append(ap)
return pt
def test002(self):
random.seed(2)
c = generate_criteria(4)
cv1 = CriterionValue('c1', 0.25)
cv2 = CriterionValue('c2', 0.25)
cv3 = CriterionValue('c3', 0.25)
cv4 = CriterionValue('c4', 0.25)
cv = CriteriaValues([cv1, cv2, cv3, cv4])
cat = generate_categories(3)
cps = generate_categories_profiles(cat)
bp1 = AlternativePerformances('b1', {
'c1': 0.75,
'c2': 0.75,
'c3': 0.75,
'c4': 0.75
})
bp2 = AlternativePerformances('b2', {
'c1': 0.25,
'c2': 0.25,
'c3': 0.25,
'c4': 0.25
})
bpt = PerformanceTable([bp1, bp2])
lbda = 0.5
etri = MRSort(c, cv, bpt, 0.5, cps)
a = generate_alternatives(1000)
pt = generate_random_performance_table(a, c)
aas = etri.pessimist(pt)
for aa in aas:
w1 = w2 = 0
perfs = pt[aa.id].performances
for c, val in perfs.items():
if val >= bp1.performances[c]:
w1 += cv[c].value
if val >= bp2.performances[c]:
w2 += cv[c].value
if aa.category_id == 'cat3':
self.assertLess(w1, lbda)
self.assertLess(w2, lbda)
elif aa.category_id == 'cat2':
self.assertLess(w1, lbda)
self.assertGreaterEqual(w2, lbda)
else:
self.assertGreaterEqual(w1, lbda)
self.assertGreaterEqual(w2, lbda)
def generate_random_profiles(alts, crits, seed = None, k = 3,
worst = None, best = None):
if seed is not None:
random.seed(seed)
if worst is None:
worst = generate_worst_ap(crits)
if best is None:
best = generate_best_ap(crits)
crit_random = {}
n = len(alts)
pt = PerformanceTable()
for c in crits:
rdom = []
for i in range(n):
minp = worst.performances[c.id]
maxp = best.performances[c.id]
if minp > maxp:
minp, maxp = maxp, minp
rdom.append(round(random.uniform(minp, maxp), k))
if c.direction == -1:
rdom.sort(reverse = True)
else:
rdom.sort()
crit_random[c.id] = rdom
for i, a in enumerate(alts):
perfs = {}
for c in crits:
perfs[c.id] = crit_random[c.id][i]
ap = AlternativePerformances(a, perfs)
pt.append(ap)
return pt
def from_xmcda(self, xmcda, id=None):
xmcda = find_xmcda_tag(xmcda, 'ElectreTri', id)
self.id = xmcda.get('id')
value = xmcda.find(".//methodParameters/parameter/value[@id='lambda']")
self.lbda = unmarshal(value.getchildren()[0])
setattr(self, 'criteria', Criteria().from_xmcda(xmcda, 'criteria'))
setattr(self, 'cv', CriteriaValues().from_xmcda(xmcda, 'cv'))
setattr(self, 'bpt', PerformanceTable().from_xmcda(xmcda, 'bpt'))
setattr(self, 'categories_profiles',
CategoriesProfiles().from_xmcda(xmcda, 'categories_profiles'))
return self
def from_xmcda(self, xmcda, id=None):
super(MRSort, self).from_xmcda(xmcda, id)
xmcda = find_xmcda_tag(xmcda, 'ElectreTri', id)
value = xmcda.find(
".//methodParameters/parameter/value[@id='veto_lbda']")
if value is not None:
self.veto_lbda = unmarshal(value.getchildren()[0])
if xmcda.find(".//criteriaValues[@id='veto_weights']") is not None:
setattr(self, 'veto_weights',
CriteriaValues().from_xmcda(xmcda, 'veto_weights'))
if xmcda.find(".//performanceTable[@id='veto']") is not None:
setattr(self, 'veto', PerformanceTable().from_xmcda(xmcda, 'veto'))
return self
def solve(self):
self.lp.solve()
status = self.lp.solution.get_status()
if status != self.lp.solution.status.MIP_optimal:
raise RuntimeError("Solver status: %s" % status)
obj = self.lp.solution.get_objective_value()
cvs = CriteriaValues()
for c in self.criteria:
cv = CriterionValue()
cv.id = c.id
cv.value = self.lp.solution.get_values('w_' + c.id)
cvs.append(cv)
self.model.cv = cvs
self.model.lbda = self.lp.solution.get_values("lambda")
pt = PerformanceTable()
for p in self.__profiles:
ap = AlternativePerformances(p)
for c in self.criteria:
perf = self.lp.solution.get_values("g_%s_%s" % (p, c.id))
ap.performances[c.id] = round(perf, 5)
pt.append(ap)
self.model.bpt = pt
self.model.bpt.update_direction(self.model.criteria)
wv = CriteriaValues()
for c in self.criteria:
w = CriterionValue()
w.id = c.id
w.value = self.lp.solution.get_values('z_' + c.id)
wv.append(w)
self.model.veto_weights = wv
self.model.veto_lbda = self.lp.solution.get_values("LAMBDA")
v = PerformanceTable()
for p in self.__profiles:
vp = AlternativePerformances(p, {})
for c in self.criteria:
perf = self.lp.solution.get_values('v_%s_%s' % (p, c.id))
vp.performances[c.id] = round(perf, 5)
v.append(vp)
self.model.veto = v
return obj
def test002(self):
c = generate_criteria(3)
cat = generate_categories(3)
cps = generate_categories_profiles(cat)
bp1 = AlternativePerformances('b1', {
'c1': 0.75,
'c2': 0.75,
'c3': 0.75
})
bp2 = AlternativePerformances('b2', {
'c1': 0.25,
'c2': 0.25,
'c3': 0.25
})
bpt = PerformanceTable([bp1, bp2])
cv1 = CriterionValue('c1', 0.2)
cv2 = CriterionValue('c2', 0.2)
cv3 = CriterionValue('c3', 0.2)
cv12 = CriterionValue(CriteriaSet(['c1', 'c2']), -0.1)
cv23 = CriterionValue(CriteriaSet(['c2', 'c3']), 0.2)
cv13 = CriterionValue(CriteriaSet(['c1', 'c3']), 0.3)
cvs = CriteriaValues([cv1, cv2, cv3, cv12, cv23, cv13])
lbda = 0.6
model = MRSort(c, cvs, bpt, lbda, cps)
a = generate_alternatives(10000)
pt = generate_random_performance_table(a, model.criteria)
aa = model.get_assignments(pt)
model2 = MRSort(c, None, bpt, None, cps)
lp = LpMRSortMobius(model2, pt, aa)
obj = lp.solve()
aa2 = model2.get_assignments(pt)
self.assertEqual(obj, 0)
self.assertEqual(aa, aa2)
from pymcda.types import AlternativesAssignments
from pymcda.utils import print_pt_and_assignments
from pymcda.ui.graphic import display_electre_tri_models
cat = generate_categories(2)
cps = generate_categories_profiles(cat)
c = generate_criteria(4)
# Generate assignment incompatible with an MR-Sort model
ap1 = AlternativePerformances('a1', {'c1': 1, 'c2': 1, 'c3': 0, 'c4': 0})
ap2 = AlternativePerformances('a2', {'c1': 0, 'c2': 0, 'c3': 1, 'c4': 1})
ap3 = AlternativePerformances('a3', {'c1': 1, 'c2': 0, 'c3': 1, 'c4': 0})
ap4 = AlternativePerformances('a4', {'c1': 1, 'c2': 0, 'c3': 0, 'c4': 1})
ap5 = AlternativePerformances('a5', {'c1': 0, 'c2': 1, 'c3': 1, 'c4': 0})
ap6 = AlternativePerformances('a6', {'c1': 0, 'c2': 1, 'c3': 0, 'c4': 1})
pt = PerformanceTable([ap1, ap2, ap3, ap4, ap5, ap6])
aa1 = AlternativeAssignment('a1', 'cat1')
aa2 = AlternativeAssignment('a2', 'cat1')
aa3 = AlternativeAssignment('a3', 'cat2')
aa4 = AlternativeAssignment('a4', 'cat2')
aa5 = AlternativeAssignment('a5', 'cat2')
aa6 = AlternativeAssignment('a6', 'cat2')
aa = AlternativesAssignments([aa1, aa2, aa3, aa4, aa5, aa6])
print_pt_and_assignments(aa.keys(), c.keys(), [aa], pt)
model = MRSort(c, None, None, None, cps)
worst = pt.get_worst(model.criteria)
best = pt.get_best(model.criteria)
cmatrix_test = {}
DATADIR = os.getenv('DATADIR', '%s/pymcda-data' % os.path.expanduser('~'))
directory='%s/test-veto2' % (DATADIR)
for f in sys.argv[1:]:
fname = os.path.splitext(os.path.basename(f))[0]
if is_bz2_file(f) is True:
f = bz2.BZ2File(f)
tree = ElementTree.parse(f)
root = tree.getroot()
m = MRSort().from_xmcda(root, 'learned')
pt_learning = PerformanceTable().from_xmcda(root, 'learning_set')
pt_test = PerformanceTable().from_xmcda(root, 'test_set')
aa_learning = AlternativesAssignments().from_xmcda(root,
'learning_set')
aa_test = AlternativesAssignments().from_xmcda(root,
'test_set')
aa_learning_m2 = m.pessimist(pt_learning)
aa_test_m2 = m.pessimist(pt_test)
# # Remove alternatives that cannot be corrected with a veto rule
# aa_learning_m2p = discard_undersorted_alternatives(m.categories,
# aa_learning,
# aa_learning_m2)
# aa_learning_m2p = discard_alternatives_in_category(aa_learning_m2p,
class MRSort(ElectreTri):
def __init__(self,
criteria=None,
cv=None,
bpt=None,
lbda=None,
categories_profiles=None,
veto=None,
veto_weights=None,
veto_lbda=None,
id=None):
super(MRSort, self).__init__(criteria, cv, bpt, lbda,
categories_profiles)
self.veto = veto
self.veto_weights = veto_weights
self.veto_lbda = veto_lbda
@property
def veto(self):
if self.vpt is None:
return None
veto = PerformanceTable()
for bp in self.bpt:
vbp = bp - self.vpt[bp.id]
veto.append(vbp)
return veto
@veto.setter
def veto(self, veto):
if veto is None:
self.vpt = None
return
self.vpt = PerformanceTable()
for bp in self.bpt:
vbp = bp - veto[bp.id]
self.vpt.append(vbp)
def criteria_coalition(self, ap1, ap2):
criteria_set = set()
for c in self.criteria:
diff = ap2.performances[c.id] - ap1.performances[c.id]
diff *= c.direction
if diff <= 0:
criteria_set.add(c.id)
return criteria_set
def concordance(self, ap, profile):
criteria_set = self.criteria_coalition(ap, profile)
return sum(
[c.value for c in self.cv if c.id_issubset(criteria_set) is True])
def coalition_weight(self, criteria_coalition):
return sum([
c.value for c in self.cv
if c.id_issubset(criteria_coalition) is True
])
def veto_concordance(self, ap, profile):
if self.bpt is None:
return 0
criteria_set = self.criteria_coalition(profile, ap)
if self.veto_weights is None:
if len(criteria_set) > 0:
return 1
else:
return 0
return sum([
c.value for c in self.veto_weights
if c.id_issubset(criteria_set) is True
])
def get_assignment(self, ap):
categories = list(reversed(self.categories))
cat = categories[0]
for i, profile in enumerate(reversed(self.profiles)):
bp = self.bpt[profile]
cw = self.concordance(ap, bp)
if cw >= self.lbda:
if self.vpt is None:
break
else:
vp = self.vpt[profile]
vw = self.veto_concordance(ap, vp)
if self.veto_lbda and vw < self.veto_lbda:
break
if vw == 0:
break
cat = categories[i + 1]
return AlternativeAssignment(ap.id, cat)
def get_assignments(self, pt):
aa = AlternativesAssignments()
for ap in pt:
a = self.get_assignment(ap)
aa.append(a)
return aa
def pessimist(self, pt):
return self.get_assignments(pt)
def credibility(self, x, y, profile):
c = self.concordance(x, y)
if self.vpt is None:
return c
vp = self.vpt[profile]
vc = self.veto_concordance(x, vp)
if self.veto_lbda and (eq(vc, self.veto_lbda) or vc > self.veto_lbda):
return 0
elif self.veto_lbda is None and vc > 0:
return 0
return c
def count_veto_pessimist(self, ap):
n = 0
profiles = self.profiles[:]
profiles.reverse()
for i, profile in enumerate(profiles):
c = self.concordance(ap, self.bpt[profile])
if c < self.lbda:
continue
vc = self.veto_concordance(ap, self.bpt[profile])
if self.veto_lbda and (eq(vc, self.veto_lbda)
or vc > self.veto_lbda):
n += 1
elif self.veto_lbda is None and vc > 0:
n += 1
return n
def get_profile_upper_limit(self, bid):
index = self.profiles.index(bid)
if index == (len(self.profiles) - 1):
return None
return self.bpt[self.profiles[index + 1]]
def get_profile_lower_limit(self, bid):
index = self.profiles.index(bid)
if self.vpt is None:
if index == 0:
return None
else:
return self.bpt[self.profiles[index - 1]]
if index == 0:
return self.vpt[bid]
bp = self.bpt[self.profiles[index - 1]]
vp = self.vpt[self.profiles[index]]
ap = AlternativePerformances(bid, {})
for crit in bp.performances.keys():
direction = self.criteria[crit].direction
bperf = bp.performances[crit] * direction
vperf = vp.performances[crit] * direction
ap.performances[crit] = max(bperf, vperf) * direction
return ap
def get_veto_profile_upper_limit(self, bid):
index = self.profiles.index(bid)
if index == (len(self.profiles) - 1):
return self.bpt[self.profiles[index]]
bp = self.bpt[bid]
vp = self.vpt[self.profiles[index + 1]]
ap = AlternativePerformances(bid, {})
for crit in bp.performances.keys():
direction = self.criteria[crit].direction
bperf = bp.performances[crit] * direction
vperf = vp.performances[crit] * direction
ap.performances[crit] = min(bperf, vperf) * direction
return ap
def get_veto_profile_lower_limit(self, bid):
index = self.profiles.index(bid)
if index == 0:
return None
return self.vpt[self.profiles[index - 1]]
def to_xmcda(self):
root = super(MRSort, self).to_xmcda()
for obj in ['veto', 'veto_weights']:
mcda = getattr(self, obj)
if mcda is None:
continue
mcda.id = obj
xmcda = mcda.to_xmcda()
root.append(xmcda)
if self.veto_lbda:
mparams = ElementTree.SubElement(root, 'methodParameters')
param = ElementTree.SubElement(mparams, 'parameter')
value = ElementTree.SubElement(param, 'value')
value.set('id', 'veto_lbda')
lbda = marshal(self.veto_lbda)
value.append(lbda)
return root
def from_xmcda(self, xmcda, id=None):
super(MRSort, self).from_xmcda(xmcda, id)
xmcda = find_xmcda_tag(xmcda, 'ElectreTri', id)
value = xmcda.find(
".//methodParameters/parameter/value[@id='veto_lbda']")
if value is not None:
self.veto_lbda = unmarshal(value.getchildren()[0])
if xmcda.find(".//criteriaValues[@id='veto_weights']") is not None:
setattr(self, 'veto_weights',
CriteriaValues().from_xmcda(xmcda, 'veto_weights'))
if xmcda.find(".//performanceTable[@id='veto']") is not None:
setattr(self, 'veto', PerformanceTable().from_xmcda(xmcda, 'veto'))
return self
from pymcda.generate import generate_alternatives
from pymcda.generate import generate_random_performance_table
from pymcda.generate import generate_random_criteria_weights
from pymcda.utils import compute_winning_and_loosing_coalitions
from pymcda.types import AlternativePerformances
from pymcda.ui.graphic import display_electre_tri_models
# Generate a random ELECTRE TRI BM model
model = generate_random_mrsort_model(7, 2, 5)
worst = AlternativePerformances("worst", {c.id: 0 for c in model.criteria})
best = AlternativePerformances("best", {c.id: 1 for c in model.criteria})
# Add veto
vpt = generate_random_profiles(model.profiles, model.criteria, None, 3,
worst, model.bpt['b1'])
model.veto = PerformanceTable([model.bpt['b1'] - vpt['b1']])
model.veto_weights = generate_random_criteria_weights(model.criteria)
model.veto_lbda = random.random()
# Generate a set of alternatives
a = generate_alternatives(1000)
pt = generate_random_performance_table(a, model.criteria)
aa = model.pessimist(pt)
nmeta = 20
nloops = 10
print('Original model')
print('==============')
cids = model.criteria.keys()
model.bpt.display(criterion_ids=cids)
class MRSort(ElectreTri):
def __init__(self, criteria = None, cv = None, bpt = None,
lbda = None, categories_profiles = None, veto = None,
veto_weights = None, veto_lbda = None, id = None):
super(MRSort, self).__init__(criteria, cv, bpt, lbda,
categories_profiles)
self.veto = veto
self.veto_weights = veto_weights
self.veto_lbda = veto_lbda
@property
def veto(self):
if self.vpt is None:
return None
veto = PerformanceTable()
for bp in self.bpt:
vbp = bp - self.vpt[bp.id]
veto.append(vbp)
return veto
@veto.setter
def veto(self, veto):
if veto is None:
self.vpt = None
return
self.vpt = PerformanceTable()
for bp in self.bpt:
vbp = bp - veto[bp.id]
self.vpt.append(vbp)
def criteria_coalition(self, ap1, ap2):
criteria_set = set()
for c in self.criteria:
diff = ap2.performances[c.id] - ap1.performances[c.id]
diff *= c.direction
if diff <= 0:
criteria_set.add(c.id)
return criteria_set
def concordance(self, ap, profile):
criteria_set = self.criteria_coalition(ap, profile)
return sum([c.value for c in self.cv
if c.id_issubset(criteria_set) is True])
def coalition_weight(self, criteria_coalition):
return sum([c.value for c in self.cv
if c.id_issubset(criteria_coalition) is True])
def veto_concordance(self, ap, profile):
if self.bpt is None:
return 0
criteria_set = self.criteria_coalition(profile, ap)
if self.veto_weights is None:
if len(criteria_set) > 0:
return 1
else:
return 0
return sum([c.value for c in self.veto_weights
if c.id_issubset(criteria_set) is True])
def get_assignment(self, ap):
categories = list(reversed(self.categories))
cat = categories[0]
for i, profile in enumerate(reversed(self.profiles)):
bp = self.bpt[profile]
cw = self.concordance(ap, bp)
if cw >= self.lbda:
if self.vpt is None:
break
else:
vp = self.vpt[profile]
vw = self.veto_concordance(ap, vp)
if self.veto_lbda and vw < self.veto_lbda:
break
if vw == 0:
break
cat = categories[i + 1]
return AlternativeAssignment(ap.id, cat)
def get_assignments(self, pt):
aa = AlternativesAssignments()
for ap in pt:
a = self.get_assignment(ap)
aa.append(a)
return aa
def pessimist(self, pt):
return self.get_assignments(pt)
def credibility(self, x, y, profile):
c = self.concordance(x, y)
if self.vpt is None:
return c
vp = self.vpt[profile]
vc = self.veto_concordance(x, vp)
if self.veto_lbda and (eq(vc, self.veto_lbda)
or vc > self.veto_lbda):
return 0
elif self.veto_lbda is None and vc > 0:
return 0
return c
def count_veto_pessimist(self, ap):
n = 0
profiles = self.profiles[:]
profiles.reverse()
for i, profile in enumerate(profiles):
c = self.concordance(ap, self.bpt[profile])
if c < self.lbda:
continue
vc = self.veto_concordance(ap, self.bpt[profile])
if self.veto_lbda and (eq(vc, self.veto_lbda)
or vc > self.veto_lbda):
n += 1
elif self.veto_lbda is None and vc > 0:
n += 1
return n
def get_profile_upper_limit(self, bid):
index = self.profiles.index(bid)
if index == (len(self.profiles) - 1):
return None
return self.bpt[self.profiles[index + 1]]
def get_profile_lower_limit(self, bid):
index = self.profiles.index(bid)
if self.vpt is None:
if index == 0:
return None
else:
return self.bpt[self.profiles[index - 1]]
if index == 0:
return self.vpt[bid]
bp = self.bpt[self.profiles[index - 1]]
vp = self.vpt[self.profiles[index]]
ap = AlternativePerformances(bid, {})
for crit in bp.performances.keys():
direction = self.criteria[crit].direction
bperf = bp.performances[crit] * direction
vperf = vp.performances[crit] * direction
ap.performances[crit] = max(bperf, vperf) * direction
return ap
def get_veto_profile_upper_limit(self, bid):
index = self.profiles.index(bid)
if index == (len(self.profiles) - 1):
return self.bpt[self.profiles[index]]
bp = self.bpt[bid]
vp = self.vpt[self.profiles[index + 1]]
ap = AlternativePerformances(bid, {})
for crit in bp.performances.keys():
direction = self.criteria[crit].direction
bperf = bp.performances[crit] * direction
vperf = vp.performances[crit] * direction
ap.performances[crit] = min(bperf, vperf) * direction
return ap
def get_veto_profile_lower_limit(self, bid):
index = self.profiles.index(bid)
if index == 0:
return None
return self.vpt[self.profiles[index - 1]]
def to_xmcda(self):
root = super(MRSort, self).to_xmcda()
for obj in ['veto', 'veto_weights']:
mcda = getattr(self, obj)
if mcda is None:
continue
mcda.id = obj
xmcda = mcda.to_xmcda()
root.append(xmcda)
if self.veto_lbda:
mparams = ElementTree.SubElement(root, 'methodParameters')
param = ElementTree.SubElement(mparams, 'parameter')
value = ElementTree.SubElement(param, 'value')
value.set('id', 'veto_lbda')
lbda = marshal(self.veto_lbda)
value.append(lbda)
return root
def from_xmcda(self, xmcda, id = None):
super(MRSort, self).from_xmcda(xmcda, id)
xmcda = find_xmcda_tag(xmcda, 'ElectreTri', id)
value = xmcda.find(".//methodParameters/parameter/value[@id='veto_lbda']")
if value is not None:
self.veto_lbda = unmarshal(value.getchildren()[0])
if xmcda.find(".//criteriaValues[@id='veto_weights']") is not None:
setattr(self, 'veto_weights',
CriteriaValues().from_xmcda(xmcda, 'veto_weights'))
if xmcda.find(".//performanceTable[@id='veto']") is not None:
setattr(self, 'veto',
PerformanceTable().from_xmcda(xmcda, 'veto'))
return self
from pymcda.generate import generate_random_performance_table
from pymcda.types import AlternativePerformances, PerformanceTable
from pymcda.types import CriterionValue, CriteriaValues, CriteriaSet
from pymcda.electre_tri import MRSort
random.seed(0)
c = generate_criteria(5)
cat = generate_categories(3)
cps = generate_categories_profiles(cat)
bp1 = AlternativePerformances('b1', {'c1': 0.75, 'c2': 0.75, 'c3': 0.75,
'c4': 0.75, 'c5': 0.75})
bp2 = AlternativePerformances('b2', {'c1': 0.25, 'c2': 0.25, 'c3': 0.25,
'c4': 0.25, 'c5': 0.25})
bpt = PerformanceTable([bp1, bp2])
cv1 = CriterionValue('c1', 0.2)
cv2 = CriterionValue('c2', 0.2)
cv3 = CriterionValue('c3', 0.2)
cv4 = CriterionValue('c4', 0.2)
cv5 = CriterionValue('c5', 0.2)
cv12 = CriterionValue(CriteriaSet(['c1', 'c2']), -0.1)
cv13 = CriterionValue(CriteriaSet(['c1', 'c3']), 0.1)
cv14 = CriterionValue(CriteriaSet(['c1', 'c4']), -0.1)
cv15 = CriterionValue(CriteriaSet(['c1', 'c5']), 0.1)
cv23 = CriterionValue(CriteriaSet(['c2', 'c3']), 0.1)
cv24 = CriterionValue(CriteriaSet(['c2', 'c4']), -0.1)
cv25 = CriterionValue(CriteriaSet(['c2', 'c5']), 0.1)
cv34 = CriterionValue(CriteriaSet(['c3', 'c4']), 0.1)
cv35 = CriterionValue(CriteriaSet(['c3', 'c5']), -0.1)
model = generate_random_mrsort_model(10, 5, 890)
# Generate random alternatives
a = generate_alternatives(15000)
pt = generate_random_performance_table(a, model.criteria)
errors = 0.0
delta = 0.0001
nlearn = 1.00
# Assign the alternative with the model
aa = model.pessimist(pt)
a_learn = random.sample(a, int(nlearn * len(a)))
aa_learn = AlternativesAssignments([aa[alt.id] for alt in a_learn])
pt_learn = PerformanceTable([pt[alt.id] for alt in a_learn])
aa_err = aa_learn.copy()
aa_erroned = add_errors_in_assignments(aa_err, model.categories, errors)
print('Original model')
print('==============')
print("Number of alternatives: %d" % len(a))
print("Number of learning alternatives: %d" % len(aa_learn))
print("Errors in alternatives assignments: %g%%" % (errors * 100))
cids = model.criteria.keys()
model.bpt.display(criterion_ids=cids)
model.cv.display(criterion_ids=cids)
print("lambda\t%.7s" % model.lbda)
print("delta: %g" % delta)
#print(aa)
for f in sys.argv[1:]:
if not os.path.isfile(f):
xmcda_models_toshow.append(f)
continue
if is_bz2_file(f) is True:
f = bz2.BZ2File(f)
tree = ElementTree.parse(f)
root = tree.getroot()
xmcda_models = root.findall(".//ElectreTri")
m = MRSort().from_xmcda(xmcda_models[0])
pt_learning = PerformanceTable().from_xmcda(root, 'learning_set')
aa_learning = AlternativesAssignments().from_xmcda(root, 'learning_set')
uniquevalues = pt_learning.get_unique_values()
bname = os.path.basename(os.path.splitext(f.name)[0])
fweights = open('%s-w.dat' % bname, 'w+')
fprofiles = open('%s-p.dat' % bname, 'w+')
print("Processing %s..." % bname)
criteria = m.criteria.keys()
for c in criteria:
print("{%s} " % criteria_names[c], end='', file=fprofiles)
print('', file=fprofiles)
def generate_random_profiles(alts,
crits,
seed=None,
k=3,
worst=None,
best=None,
prof_threshold=0.05,
fixed_profc1=None):
if seed is not None:
random.seed(seed)
if worst is None:
worst = generate_worst_ap(crits)
if best is None:
best = generate_best_ap(crits)
crit_random = {}
n = len(alts)
#print(alts)
pt = PerformanceTable()
for c in crits:
rdom = []
for i in range(n):
minp = worst.performances[c.id]
maxp = best.performances[c.id]
if minp > maxp:
minp, maxp = maxp, minp
if fixed_profc1 is not None and c.id == "c1":
#rdom.append(0.5)
rdom.append(
round(
random.uniform(0.5 - fixed_profc1, 0.5 + fixed_profc1),
k))
#print("rdom ",rdom)
else:
if c.direction == 2 or c.direction == -2:
#print(c,crits)
#if criteria are known
b_sp = tuple(
sorted([
round(
random.uniform(max(minp, prof_threshold),
min(1 - prof_threshold, maxp)),
k),
round(
random.uniform(max(minp, prof_threshold),
min(1 - prof_threshold, maxp)),
k)
]))
#b_sp = (round(random.uniform(max(minp,prof_threshold), min(1-prof_threshold,maxp)), k),1)
rdom.append(b_sp)
#the following assumes that criteria types are not known, but all fixed under SP construction
# if c.id == [c.id for c in crits][-1]:
# b_sp =tuple(sorted([round(random.uniform(max(minp,prof_threshold), min(1-prof_threshold,maxp)), k),round(random.uniform(max(minp,prof_threshold), min(1-prof_threshold,maxp)), k)]))
# rdom.append(b_sp)
# else:
# b_sp = (round(random.uniform(max(minp,prof_threshold), min(1-prof_threshold,maxp)), k),1)
# rdom.append(b_sp)
#print(rdom)
else:
rdom.append(
round(
random.uniform(max(minp, prof_threshold),
min(1 - prof_threshold, maxp)), k))
#rdom.append((round(random.uniform(max(minp,prof_threshold), min(1-prof_threshold,maxp)), k),1))
#rdom.append(round(random.uniform(max(minp,prof_threshold), min(1-prof_threshold,maxp)), k))
if c.direction == -1:
rdom.sort(reverse=True)
else:
rdom.sort()
#rdom.sort(reverse = True)
crit_random[c.id] = rdom
# if n==2:
# import pdb; pdb.set_trace()
for i, a in enumerate(alts):
perfs = {}
for c in crits:
perfs[c.id] = crit_random[c.id][i]
ap = AlternativePerformances(a, perfs)
pt.append(ap)
# if n==2:
# import pdb; pdb.set_trace()
return pt
cmatrix_learning = {}
cmatrix_test = {}
nveto = 0
for f in sys.argv[1:]:
f = os.path.abspath(f)
if is_bz2_file(f) is True:
f = bz2.BZ2File(f)
import pdb
pdb.set_trace()
tree = ElementTree.parse(f)
root = tree.getroot()
m = MRSort().from_xmcda(root, 'learned')
pt_learning = PerformanceTable().from_xmcda(root, 'learning_set')
pt_test = PerformanceTable().from_xmcda(root, 'test_set')
aa_learning = AlternativesAssignments().from_xmcda(root, 'learning_set')
aa_test = AlternativesAssignments().from_xmcda(root, 'test_set')
aa_learning_m2 = m.pessimist(pt_learning)
aa_test_m2 = m.pessimist(pt_test)
# Compute classification accuracy
ca_learning = compute_ca(aa_learning, aa_learning_m2)
ca_test = compute_ca(aa_test, aa_test_m2)
table_ca_learning.append(ca_learning)
table_ca_test.append(ca_test)
def generate_random_profiles_msjp_sp(alts,
crits,
seed=None,
k=3,
worst=None,
best=None,
fct_percentile=[],
nb_unk_criteria=0):
if seed is not None:
random.seed(seed)
if worst is None:
worst = generate_worst_ap(crits)
if best is None:
best = generate_best_ap(crits)
crit_random = {}
n = len(alts) # here it represents profiles
pt = PerformanceTable()
random.seed(seed)
for c in crits:
rdom = []
random.seed(seed)
for i in range(n):
minp = worst.performances[c.id]
maxp = best.performances[c.id]
if minp > maxp:
minp, maxp = maxp, minp
# if (c.id[-1] != "d") and (int(c.id[1:]) <= nb_unk_criteria):
# rdom.append(round(random.uniform(max(minp,fct_percentile[int(c.id[1:])-1][0]), min(maxp,fct_percentile[int(c.id[1:])-1][1])), k))
# else:
# rdom.append(round(random.uniform(minp,maxp),k))
if c.direction == 2 or c.direction == -2:
b_sp = tuple(
sorted([
round(random.uniform(minp, maxp), k),
round(random.uniform(minp, maxp), k)
]))
#we assume to know temporarily the value of the bottom
#b_sp = (0.4,round(random.uniform(0.4,maxp), k))
#b_sp = (round(random.uniform(0,0.6), k),0.6)
rdom.append(b_sp)
else:
# if c.id == "c1":
# rdom.append(0.3)
# elif c.id == "c2" or c.id == "c3":
# rdom.append(0.8)
# else:
rdom.append(round(random.uniform(minp, maxp), k))
#For the moment this test below is useless as long as we have only 2 categories (neeed to be may be review)
if c.direction == -1:
rdom.sort(reverse=True)
else:
rdom.sort()
#import pdb; pdb.set_trace()
crit_random[c.id] = rdom
#import pdb; pdb.set_trace()
for i, a in enumerate(alts):
perfs = {}
for c in crits:
perfs[c.id] = crit_random[c.id][i]
ap = AlternativePerformances(a, perfs)
pt.append(ap)
#import pdb; pdb.set_trace()
return pt
from pymcda.types import AlternativesAssignments
from pymcda.utils import print_pt_and_assignments
from pymcda.ui.graphic import display_electre_tri_models
cat = generate_categories(2)
cps = generate_categories_profiles(cat)
c = generate_criteria(4)
# Generate assignment incompatible with an MR-Sort model
ap1 = AlternativePerformances('a1', {'c1': 1, 'c2': 1, 'c3': 0, 'c4': 0})
ap2 = AlternativePerformances('a2', {'c1': 0, 'c2': 0, 'c3': 1, 'c4': 1})
ap3 = AlternativePerformances('a3', {'c1': 1, 'c2': 0, 'c3': 1, 'c4': 0})
ap4 = AlternativePerformances('a4', {'c1': 1, 'c2': 0, 'c3': 0, 'c4': 1})
ap5 = AlternativePerformances('a5', {'c1': 0, 'c2': 1, 'c3': 1, 'c4': 0})
ap6 = AlternativePerformances('a6', {'c1': 0, 'c2': 1, 'c3': 0, 'c4': 1})
pt = PerformanceTable([ap1, ap2, ap3, ap4, ap5, ap6])
aa1 = AlternativeAssignment('a1', 'cat1')
aa2 = AlternativeAssignment('a2', 'cat1')
aa3 = AlternativeAssignment('a3', 'cat2')
aa4 = AlternativeAssignment('a4', 'cat2')
aa5 = AlternativeAssignment('a5', 'cat2')
aa6 = AlternativeAssignment('a6', 'cat2')
aa = AlternativesAssignments([aa1, aa2, aa3, aa4, aa5, aa6])
print_pt_and_assignments(aa.keys(), c.keys(), [aa], pt)
model = MRSort(c, None, None, None, cps)
worst = pt.get_worst(model.criteria)
best = pt.get_best(model.criteria)
