- Fixed VSP check
- Parse magic output files disregarding header row
- TODO: Fix parsing multiple implication tables in a row
This commit is contained in:
Brandon Rozek 2024-05-09 17:08:15 -04:00
parent ff666c326e
commit cf636eb7fd
No known key found for this signature in database
GPG key ID: 26E457DA82C9F480
2 changed files with 249 additions and 3 deletions

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@ -59,7 +59,7 @@ class ModelFunction:
for k, v in self.mapping.items(): for k, v in self.mapping.items():
inputstr = "(" + ", ".join(str(ki) for ki in k) + ")" inputstr = "(" + ", ".join(str(ki) for ki in k) + ")"
str_dict[inputstr] = str(v) str_dict[inputstr] = str(v)
return str(str_dict) return self.operation_name + " " + str(str_dict)
def __call__(self, *args): def __call__(self, *args):
return self.mapping[args] return self.mapping[args]
@ -247,11 +247,14 @@ def has_vsp(model: Model, interpretation: Dict[Operation, ModelFunction]) -> boo
if len(carrier_set_left & carrier_set_right) > 0: if len(carrier_set_left & carrier_set_right) > 0:
continue continue
invalid = False
for (x2, y2) in product(carrier_set_left, carrier_set_right): for (x2, y2) in product(carrier_set_left, carrier_set_right):
if impfunction(x2, y2) in model.designated_values: if impfunction(x2, y2) in model.designated_values:
continue invalid = True
break
return True if not invalid:
return True
return False return False

243
parse_magic.py Normal file
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@ -0,0 +1,243 @@
"""
Parses the Magic Ugly Data File Format
Assumes the base logic is R with no extra connectives
"""
import sys
from typing import TextIO, List, Optional, Tuple, Set, Dict
from model import Model, ModelValue, ModelFunction
from logic import (
Implication,
Conjunction,
Negation,
Disjunction
)
def parse_matrices(infile: TextIO) -> List[Tuple[Model, Dict]]:
next(infile) # Skip header line
solutions: List[Tuple[Model, Dict]] = []
while True:
size = parse_size(infile)
if size is None:
break
carrier_set = carrier_set_from_size(size)
while True:
mnegation = parse_negation(infile, size)
if mnegation is None:
break
while True:
result = parse_order(infile, size)
if result is None:
break
mconjunction, mdisjunction = result
while True:
designated_values = parse_designated(infile, size)
if designated_values is None:
break
while True:
result = parse_implication(infile, size)
if result is None:
break
mimplication, hasnext = result
logical_operations = {
mnegation, mconjunction, mdisjunction,
mimplication
}
model = Model(carrier_set, logical_operations, designated_values)
interpretation = {
Negation: mnegation,
Conjunction: mconjunction,
Disjunction: mdisjunction,
Implication: mimplication
}
solutions.append((model, interpretation))
print(f"Parsed {len(solutions)} so far")
if not hasnext:
break
return solutions
def carrier_set_from_size(size: int):
return {
mvalue_from_index(i) for i in range(size + 1)
}
def parse_size(infile: TextIO) -> Optional[int]:
# Elements are represented in hexidecimal
size = int(next(infile), 16)
if size == -1:
return None
assert size > 0, "Unexpected size"
return size
def parse_negation(infile: TextIO, size: int) -> Optional[ModelFunction]:
line = next(infile).strip()
if line == '-1':
return None
row = line.split(" ")
assert len(row) == size + 1, "Negation table doesn't match size"
mapping = {}
for i, j in zip(range(size + 1), row):
x = mvalue_from_index(i)
y = parse_mvalue(j)
mapping[(x, )] = y
return ModelFunction(1, mapping, "Negation")
def mvalue_from_index(i: int):
return ModelValue(f"a{hex(i)[-1]}")
def parse_mvalue(x: str) -> ModelValue:
return mvalue_from_index(int(x, 16))
def determine_cresult(size: int, ordering: Dict[ModelValue, ModelValue], a: ModelValue, b: ModelValue) -> ModelValue:
for i in range(size + 1):
c = mvalue_from_index(i)
if not ordering[(c, a)]:
continue
if not ordering[(c, b)]:
continue
invalid = False
for j in range(size + 1):
d = mvalue_from_index(j)
if c == d:
continue
if ordering[(c, d)]:
if ordering[(d, a)] and ordering [(d, b)]:
invalid = True
if not invalid:
return c
print(a, "&", b, "is not defined")
def determine_dresult(size: int, ordering: Dict[ModelValue, ModelValue], a: ModelValue, b: ModelValue) -> ModelValue:
for i in range(size + 1):
c = mvalue_from_index(i)
if not ordering[(a, c)]:
continue
if not ordering[(b, c)]:
continue
invalid = False
for j in range(size + 1):
d = mvalue_from_index(j)
if d == c:
continue
if ordering[(d, c)]:
if ordering[(a, d)] and ordering[(b, d)]:
invalid = True
if not invalid:
return c
def parse_order(infile: TextIO, size: int) -> Optional[Tuple[ModelFunction, ModelFunction]]:
line = next(infile).strip()
if line == '-1':
return None
table = line.split(" ")
assert len(table) == (size + 1)**2
omapping = {}
table_i = 0
for i in range(size + 1):
x = mvalue_from_index(i)
for j in range(size + 1):
y = mvalue_from_index(j)
omapping[(x, y)] = table[table_i] == '1'
table_i += 1
cmapping = {}
dmapping = {}
for i in range(size + 1):
x = mvalue_from_index(i)
for j in range(size + 1):
y = mvalue_from_index(j)
cmapping[(x, y)] = determine_cresult(size, omapping, x, y)
dmapping[(x, y)] = determine_dresult(size, omapping, x, y)
mconjunction = ModelFunction(2, cmapping, "Conjunction")
mdisjunction = ModelFunction(2, dmapping, "Disjunction")
return mconjunction, mdisjunction
def parse_designated(infile: TextIO, size: int) -> Optional[Set[ModelValue]]:
line = next(infile).strip()
if line == '-1':
return None
row = line.split(" ")
assert len(row) == size + 1, "Designated table doesn't match size"
designated_values = set()
for i, j in zip(range(size + 1), row):
if j == '1':
x = mvalue_from_index(i)
designated_values.add(x)
return designated_values
def parse_implication(infile: TextIO, size: int) -> Optional[Tuple[ModelFunction, bool]]:
line = next(infile).strip()
if line == '-1':
return None
table = line.split(" ")
has_next = True
if table[-1] == '-1':
has_next = False
table = table[:-1]
assert len(table) == (size + 1)**2
mapping = {}
table_i = 0
for i in range(size + 1):
x = mvalue_from_index(i)
for j in range(size + 1):
y = mvalue_from_index(j)
r = parse_mvalue(table[table_i])
table_i += 1
mapping[(x, y)] = r
mimplication = ModelFunction(2, mapping, "Implication")
return mimplication, has_next
if __name__ == "__main__":
from model import has_vsp
solutions: List[Model] = parse_matrices(sys.stdin)
print(f"Parsed {len(solutions)} matrices")
for model, interpretation in solutions:
# print(model)
if has_vsp(model, interpretation):
print(model)
print("Has VSP")