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Initial draft implementation of a signed VSP checker

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Brandon Rozek 2025-11-05 13:21:19 -05:00
parent 0a0b62f3a0
commit 4179345956
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344
vsp.py
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@ -2,7 +2,7 @@
Check to see if the model has the variable
sharing property.
"""
from itertools import product
from itertools import product, chain, combinations
from typing import List, Optional, Set, Tuple
from common import set_to_str
from model import (
@ -121,3 +121,345 @@ def has_vsp(model: Model, impfunction: ModelFunction,
return VSP_Result(True, model.name, carrier_set_left, carrier_set_right)
return VSP_Result(False, model.name)
class SVSP_Result:
def __init__(
self, has_svsp: bool, model_name: Optional[str] = None,
subalgebra1: Optional[Set[ModelValue]] = None,
subalgebra2: Optional[Set[ModelValue]] = None,
U: Optional[Set[ModelValue]] = None,
L: Optional[Set[ModelValue]] = None):
self.has_svsp = has_svsp
self.model_name = model_name
self.subalgebra1 = subalgebra1
self.subalgebra2 = subalgebra2
self.U = U
self.L = L
def __str__(self):
if not self.has_svsp:
return f"Model {self.model_name} does not have the signed variable sharing property."
return f"""Model {self.model_name} has the signed variable sharing property.
Subalgebra 1: {set_to_str(self.subalgebra1)}
Subalgebra 2: {set_to_str(self.subalgebra2)}
U: {set_to_str(self.U)}
L: {set_to_str(self.L)}
"""
def powerset_minus_empty(s):
return chain.from_iterable(combinations(s, r) for r in range(1, len(s) + 1))
def find_k1_k2(model, impfunction: ModelFunction,
negation_defined: bool) -> List[Tuple[Set[ModelValue], Set[ModelValue]]]:
"""
Returns a list of possible subalgebra pairs (K1, K2)
"""
assert model.ordering is not None, "Expected ordering table in model"
result = []
top = model.ordering.top()
bottom = model.ordering.bottom()
# Compute I the set of tuples (x, y) where
# x -> y does not take a designiated value
I: List[Tuple[ModelValue, ModelValue]] = []
for (x, y) in product(model.designated_values, model.designated_values):
if impfunction(x, y) not in model.designated_values:
I.append((x, y))
# Find the subalgebras which falsify implication
for xys in I:
xi = xys[0]
# Discard ({⊥} A', B) subalgebras
if bottom is not None and xi == bottom:
continue
# Discard ({} A', B) subalgebras when negation is defined
if top is not None and negation_defined and xi == top:
continue
yi = xys[1]
# Discard (A, {} B') subalgebras
if top is not None and yi == top:
continue
# Discard (A, {⊥} B') subalgebras when negation is defined
if bottom is not None and negation_defined and yi == bottom:
continue
# Discard ({a} A', {b} B') subalgebras when a <= b
if model.ordering.is_lt(xi, yi):
continue
# Discard ({a} A', {b} B') subalgebras when b <= a and negation is defined
if negation_defined and model.ordering.is_lt(yi, xi):
continue
# Compute the left closure of the set containing xi under all the operations
carrier_set_left: Set[ModelValue] = model_closure({xi,}, model.logical_operations, bottom)
# Discard ({⊥} A', B) subalgebras
if bottom is not None and bottom in carrier_set_left:
continue
# Discard ({} A', B) subalgebras when negation is defined
if top is not None and negation_defined and top in carrier_set_left:
continue
# Compute the closure of all operations
# with just the ys
carrier_set_right: Set[ModelValue] = model_closure({yi,}, model.logical_operations, top)
# Discard (A, {} B') subalgebras
if top is not None and top in carrier_set_right:
continue
# Discard (A, {⊥} B') subalgebras when negation is defined
if bottom is not None and negation_defined and bottom in carrier_set_right:
continue
# Discard subalgebras that intersect
if not carrier_set_left.isdisjoint(carrier_set_right):
continue
# Check whether for all pairs in the subalgebra,
# that implication is falsified.
falsified = True
for (x2, y2) in product(carrier_set_left, carrier_set_right):
if impfunction(x2, y2) in model.designated_values:
falsified = False
break
if falsified:
result.append((carrier_set_left, carrier_set_right))
return result
def find_candidate_u_l(model: Model, impfn: ModelFunction, negfn: Optional[ModelFunction]) -> List[Tuple[Set[ModelValue], Set[ModelValue]]]:
result: List[Tuple[Set[ModelValue], Set[ModelValue]]] = []
F = model.carrier_set - model.designated_values
Us = powerset_minus_empty(model.carrier_set)
Ls = powerset_minus_empty(model.carrier_set)
for (U, L) in product(Us, Ls):
unsat = False
U = set(U)
L = set(L)
LFi = F.intersection(L)
# Required property: ∀x ∈ U, y ∈ L(x → y ∈ L ∩ F)
for (x, y) in product(U, L):
if impfn(x, y) not in LFi:
unsat = True
break
if unsat:
continue
# Required Property: ∀x ∈ L, y ∈ U(x → y ∈ U)
for (x, y) in product(L, U):
if impfn(x, y) not in U:
unsat = True
break
if unsat:
continue
if negfn is not None:
for x in L:
# Required Property: ∀x(x ∈ L ⇒ ¬x ∈ U)
if negfn(x) not in U:
unsat = True
break
if unsat:
continue
for x in U:
# Required Property: ∀x(x ∈ U ⇒ ¬x ∈ L)
if negfn(x) not in L:
unsat = True
break
if unsat:
continue
# Passed all required properties
result.append((U, L))
return result
def has_svsp(model: Model, impfn: ModelFunction,
conjfn: Optional[ModelFunction],
disjfn: Optional[ModelFunction],
negfn: Optional[ModelFunction]) -> SVSP_Result:
"""
Checks whether a model has the signed
variable sharing property.
"""
# NOTE: No models with only one designated
# value satisfies SVSP
if len(model.designated_values) == 1:
return SVSP_Result(False, model.name)
F = model.carrier_set - model.designated_values
starops = [conjfn, disjfn]
K1K2s = find_k1_k2(model, impfn, negfn is not None)
ULs = find_candidate_u_l(model, impfn, negfn)
candidates = ((k1, k2, u, l) for (k1, k2), (u, l) in product(K1K2s, ULs))
for K1, K2, U, L in candidates:
unsat = False
K1Uu = K1 | U
K1Lu = K1 | L
K1LuFi = K1Lu.intersection(F) # (K1 L) ∩ F
K2Uu = K2 | U
K2Lu = K2 | L
K2LuFi = K2Lu.intersection(F) # (K2 L) ∩ F
# (6)
for x, y in product(K1, U):
# b) x → y ∈ K1 U
if impfn(x, y) not in K1Uu:
unsat = True
break
# c) y → x ∈ K1 L
if impfn(y, x) not in K1Lu:
unsat = True
break
# a) x y, y x, y z ∈ K1 U
for z in U:
for op in starops:
if op is not None:
if op(x, y) not in K1Uu:
unsat = True
break
if op(y, x) not in K1Uu:
unsat = True
break
if op(y, z) not in K1Uu:
unsat = True
break
if unsat:
break
if unsat:
# Verification for these set of matrices failed
break
if unsat:
# Move onto the next candidates K1, K2, U, L
continue
# (7)
for x, y in product(K1, L):
# b) x → y ∈ (K1 L) ∩ F
if impfn(x, y) not in K1LuFi:
unsat = True
break
# c) y → x ∈ K1 U
if impfn(y, x) not in K1Uu:
unsat = True
break
# a) x y, y x, y z ∈ K1 L
for z in L:
for op in starops:
if op is not None:
if op(x, y) not in K1Lu:
unsat = True
break
if op(y, x) not in K1Lu:
unsat = True
break
if op(y, z) not in K1Lu:
unsat = True
break
if unsat:
break
if unsat:
break
if unsat:
continue
# (8)
for x, y in product(K2, U):
# b) x → y ∈ K2 U
if impfn(x, y) not in K2Uu:
unsat = True
break
# c) y → x ∈ (K2 L) ∩ F
if impfn(y, x) not in K2LuFi:
unsat = True
break
# a) x y, y x, y z ∈ K2 U
for z in U:
for op in starops:
if op is not None:
if op(x, y) not in K2Uu:
unsat = True
break
if op(y, x) not in K2Uu:
unsat = True
break
if op(y, z) not in K2Uu:
unsat = True
break
if unsat:
break
if unsat:
break
if unsat:
continue
# (9)
for x, y in product(K2, L):
# b) x → y ∈ K2 L
if impfn(x, y) not in K2Lu:
unsat = True
break
# c) y → x ∈ K2 U
if impfn(y, x) not in K2Uu:
unsat = True
break
# a) x y, y x, y z ∈ K2 L
for z in L:
for op in starops:
if op is not None:
if op(x, y) not in K2Lu:
unsat = True
break
if op(y, x) not in K2Lu:
unsat = True
break
if op(y, z) not in K2Lu:
unsat = True
break
if unsat:
break
if unsat:
break
if not unsat:
return SVSP_Result(True, model.name, K1, K2, U, L)
return SVSP_Result(False, model.name)