""" Comparison utilities for STIX pattern observation expressions. """ from stix2.equivalence.patterns.compare import generic_cmp, iter_lex_cmp from stix2.equivalence.patterns.compare.comparison import ( comparison_expression_cmp, generic_constant_cmp, ) from stix2.patterns import ( AndObservationExpression, FollowedByObservationExpression, ObservationExpression, OrObservationExpression, QualifiedObservationExpression, RepeatQualifier, StartStopQualifier, WithinQualifier, _CompoundObservationExpression, ) _OBSERVATION_EXPRESSION_TYPE_ORDER = ( ObservationExpression, AndObservationExpression, OrObservationExpression, FollowedByObservationExpression, QualifiedObservationExpression, ) _QUALIFIER_TYPE_ORDER = ( RepeatQualifier, WithinQualifier, StartStopQualifier, ) def repeats_cmp(qual1, qual2): """ Compare REPEATS qualifiers. This orders by repeat count. """ return generic_constant_cmp(qual1.times_to_repeat, qual2.times_to_repeat) def within_cmp(qual1, qual2): """ Compare WITHIN qualifiers. This orders by number of seconds. """ return generic_constant_cmp( qual1.number_of_seconds, qual2.number_of_seconds, ) def startstop_cmp(qual1, qual2): """ Compare START/STOP qualifiers. This lexicographically orders by start time, then stop time. """ return iter_lex_cmp( (qual1.start_time, qual1.stop_time), (qual2.start_time, qual2.stop_time), generic_constant_cmp, ) _QUALIFIER_COMPARATORS = { RepeatQualifier: repeats_cmp, WithinQualifier: within_cmp, StartStopQualifier: startstop_cmp, } def observation_expression_cmp(expr1, expr2): """ Compare two observation expression ASTs. This is sensitive to the order of the expressions' sub-components. To achieve an order-insensitive comparison, the ASTs must be canonically ordered first. :param expr1: The first observation expression :param expr2: The second observation expression :return: <0, 0, or >0 depending on whether the first arg is less, equal or greater than the second """ type1 = type(expr1) type2 = type(expr2) type1_idx = _OBSERVATION_EXPRESSION_TYPE_ORDER.index(type1) type2_idx = _OBSERVATION_EXPRESSION_TYPE_ORDER.index(type2) if type1_idx != type2_idx: result = generic_cmp(type1_idx, type2_idx) # else, both exprs are of same type. # If they're simple, use contained comparison expression order elif type1 is ObservationExpression: result = comparison_expression_cmp( expr1.operand, expr2.operand, ) elif isinstance(expr1, _CompoundObservationExpression): # Both compound, and of same type (and/or/followedby): sort according # to contents. result = iter_lex_cmp( expr1.operands, expr2.operands, observation_expression_cmp, ) else: # QualifiedObservationExpression # Both qualified. Check qualifiers first; if they are the same, # use order of the qualified expressions. qual1_type = type(expr1.qualifier) qual2_type = type(expr2.qualifier) qual1_type_idx = _QUALIFIER_TYPE_ORDER.index(qual1_type) qual2_type_idx = _QUALIFIER_TYPE_ORDER.index(qual2_type) result = generic_cmp(qual1_type_idx, qual2_type_idx) if result == 0: # Same qualifier type; compare qualifier details qual_cmp = _QUALIFIER_COMPARATORS.get(qual1_type) if qual_cmp: result = qual_cmp(expr1.qualifier, expr2.qualifier) else: raise TypeError( "Can't compare qualifier type: " + qual1_type.__name__, ) if result == 0: # Same qualifier type and details; use qualified expression order result = observation_expression_cmp( expr1.observation_expression, expr2.observation_expression, ) return result