use crate::prelude::*;
impl Runtime {
pub fn verify_non_equational_atomic_fact(
&mut self,
atomic_fact: &AtomicFact,
verify_state: &VerifyState,
post_process: bool,
) -> Result<StmtResult, RuntimeError> {
let mut result =
self.verify_non_equational_atomic_fact_with_builtin_rules(atomic_fact, verify_state)?;
if result.is_true() {
return Ok(result);
}
result = self.verify_non_equational_atomic_fact_with_known_atomic_facts(atomic_fact)?;
if result.is_true() {
return Ok(result);
}
if verify_state.is_round_0() {
let verify_state_add_one_round = verify_state.new_state_with_round_increased();
if let Some(verified_by_definition) =
self.verify_atomic_fact_using_builtin_or_prop_definition(atomic_fact, verify_state)?
{
return Ok(verified_by_definition);
}
result = self
.verify_atomic_fact_with_known_forall(atomic_fact, &verify_state_add_one_round)?;
if result.is_true() {
return Ok(result);
}
}
if post_process {
result =
self.post_process_non_equational_atomic_fact(atomic_fact, verify_state, result)?;
if result.is_true() {
return Ok(result);
}
}
Ok((StmtUnknown::new()).into())
}
pub fn verify_non_equational_atomic_fact_with_known_atomic_facts(
&mut self,
atomic_fact: &AtomicFact,
) -> Result<StmtResult, RuntimeError> {
let result = if atomic_fact.number_of_args() == 1 {
self.verify_atomic_fact_not_equality_with_known_atomic_fact_with_1_param(atomic_fact)?
} else if atomic_fact.number_of_args() == 2 {
self.verify_atomic_fact_not_equality_with_known_atomic_fact_with_2_params(atomic_fact)?
} else {
self.verify_atomic_fact_not_equality_with_known_atomic_fact_with_0_or_more_than_2_params(
atomic_fact,
)?
};
if result.is_true() {
return Ok(result);
}
Ok(result)
}
fn verify_atomic_fact_not_equality_with_known_atomic_fact_with_1_param(
&mut self,
atomic_fact: &AtomicFact,
) -> Result<StmtResult, RuntimeError> {
let mut all_objs_equal_to_arg =
self.get_all_objs_equal_to_given(&atomic_fact.args()[0].to_string());
if let Some(calculated_obj) = self.resolve_obj_to_number(&atomic_fact.args()[0]) {
if calculated_obj.to_string() != atomic_fact.args()[0].to_string() {
let equal_tos = self.get_all_objs_equal_to_given(&calculated_obj.to_string());
all_objs_equal_to_arg.extend(equal_tos);
}
}
if all_objs_equal_to_arg.is_empty() {
all_objs_equal_to_arg.push(atomic_fact.args()[0].to_string());
}
for environment in self.iter_environments_from_top() {
let result = Self::verify_atomic_fact_not_equality_with_known_atomic_fact_with_1_param_with_facts_in_environment(environment, atomic_fact, &all_objs_equal_to_arg)?;
if result.is_true() {
return Ok(result);
}
}
let arg = atomic_fact.args()[0].clone();
let arg_resolved = self.resolve_obj(&arg);
if arg_resolved.to_string() != arg.to_string() {
let rewritten =
Self::atomic_fact_with_resolved_unary_operand(atomic_fact, arg_resolved);
return self
.verify_atomic_fact_not_equality_with_known_atomic_fact_with_1_param(&rewritten);
}
Ok((StmtUnknown::new()).into())
}
fn verify_atomic_fact_not_equality_with_known_atomic_fact_with_2_params(
&mut self,
atomic_fact: &AtomicFact,
) -> Result<StmtResult, RuntimeError> {
let mut all_objs_equal_to_arg0 =
self.get_all_objs_equal_to_given(&atomic_fact.args()[0].to_string());
if let Some(calculated_obj) = self.resolve_obj_to_number(&atomic_fact.args()[0]) {
if calculated_obj.to_string() != atomic_fact.args()[0].to_string() {
let equal_tos = self.get_all_objs_equal_to_given(&calculated_obj.to_string());
all_objs_equal_to_arg0.extend(equal_tos);
}
}
if all_objs_equal_to_arg0.is_empty() {
all_objs_equal_to_arg0.push(atomic_fact.args()[0].to_string());
}
let mut all_objs_equal_to_arg1 =
self.get_all_objs_equal_to_given(&atomic_fact.args()[1].to_string());
if let Some(calculated_obj) = self.resolve_obj_to_number(&atomic_fact.args()[1]) {
if calculated_obj.to_string() != atomic_fact.args()[1].to_string() {
let equal_tos = self.get_all_objs_equal_to_given(&calculated_obj.to_string());
all_objs_equal_to_arg1.extend(equal_tos);
}
}
if all_objs_equal_to_arg1.is_empty() {
all_objs_equal_to_arg1.push(atomic_fact.args()[1].to_string());
}
for environment in self.iter_environments_from_top() {
let result = Self::verify_atomic_fact_not_equality_with_known_atomic_fact_with_2_params_with_facts_in_environment(environment, atomic_fact, &all_objs_equal_to_arg0, &all_objs_equal_to_arg1)?;
if result.is_true() {
return Ok(result);
}
}
let left = atomic_fact.args()[0].clone();
let right = atomic_fact.args()[1].clone();
let left_resolved = self.resolve_obj(&left);
let right_resolved = self.resolve_obj(&right);
if left_resolved.to_string() != left.to_string()
|| right_resolved.to_string() != right.to_string()
{
let rewritten = Self::atomic_fact_with_resolved_binary_operands(
atomic_fact,
left_resolved,
right_resolved,
);
return self
.verify_atomic_fact_not_equality_with_known_atomic_fact_with_2_params(&rewritten);
}
Ok((StmtUnknown::new()).into())
}
fn verify_atomic_fact_not_equality_with_known_atomic_fact_with_0_or_more_than_2_params(
&mut self,
atomic_fact: &AtomicFact,
) -> Result<StmtResult, RuntimeError> {
let mut all_objs_equal_to_each_arg: Vec<Vec<String>> = Vec::new();
for arg in atomic_fact.args().iter() {
let mut all_objs_equal_to_current_arg =
self.get_all_objs_equal_to_given(&arg.to_string());
if all_objs_equal_to_current_arg.is_empty() {
all_objs_equal_to_current_arg.push(arg.to_string());
}
all_objs_equal_to_each_arg.push(all_objs_equal_to_current_arg);
}
for environment in self.iter_environments_from_top() {
let result = Self::verify_atomic_fact_not_equality_with_known_atomic_fact_with_0_or_more_than_2_params_with_facts_in_environment(
environment,
atomic_fact,
&all_objs_equal_to_each_arg,
)?;
if result.is_true() {
return Ok(result);
}
}
let old_args = atomic_fact.args();
let mut new_args: Vec<Obj> = Vec::with_capacity(old_args.len());
let mut any_changed = false;
for a in old_args.iter() {
let r = self.resolve_obj(a);
if r.to_string() != a.to_string() {
any_changed = true;
}
new_args.push(r);
}
if any_changed {
let rewritten = Self::atomic_fact_with_resolved_predicate_args(atomic_fact, new_args);
return self
.verify_atomic_fact_not_equality_with_known_atomic_fact_with_0_or_more_than_2_params(
&rewritten,
);
}
Ok((StmtUnknown::new()).into())
}
fn atomic_fact_with_resolved_unary_operand(fact: &AtomicFact, x: Obj) -> AtomicFact {
let line_file = fact.line_file();
match fact {
AtomicFact::IsSetFact(_) => IsSetFact::new(x, line_file).into(),
AtomicFact::IsNonemptySetFact(_) => IsNonemptySetFact::new(x, line_file).into(),
AtomicFact::IsFiniteSetFact(_) => IsFiniteSetFact::new(x, line_file).into(),
AtomicFact::IsCartFact(_) => IsCartFact::new(x, line_file).into(),
AtomicFact::IsTupleFact(_) => IsTupleFact::new(x, line_file).into(),
AtomicFact::NotIsSetFact(_) => NotIsSetFact::new(x, line_file).into(),
AtomicFact::NotIsNonemptySetFact(_) => NotIsNonemptySetFact::new(x, line_file).into(),
AtomicFact::NotIsFiniteSetFact(_) => NotIsFiniteSetFact::new(x, line_file).into(),
AtomicFact::NotIsCartFact(_) => NotIsCartFact::new(x, line_file).into(),
AtomicFact::NotIsTupleFact(_) => NotIsTupleFact::new(x, line_file).into(),
AtomicFact::NormalAtomicFact(n) => {
NormalAtomicFact::new(n.predicate.clone(), vec![x], line_file).into()
}
AtomicFact::NotNormalAtomicFact(n) => {
NotNormalAtomicFact::new(n.predicate.clone(), vec![x], line_file).into()
}
_ => unreachable!(
"atomic_fact_with_resolved_unary_operand: expected a one-argument atomic fact"
),
}
}
fn atomic_fact_with_resolved_binary_operands(
fact: &AtomicFact,
left: Obj,
right: Obj,
) -> AtomicFact {
let line_file = fact.line_file();
match fact {
AtomicFact::EqualFact(_) => EqualFact::new(left, right, line_file).into(),
AtomicFact::LessFact(_) => LessFact::new(left, right, line_file).into(),
AtomicFact::GreaterFact(_) => GreaterFact::new(left, right, line_file).into(),
AtomicFact::LessEqualFact(_) => LessEqualFact::new(left, right, line_file).into(),
AtomicFact::GreaterEqualFact(_) => GreaterEqualFact::new(left, right, line_file).into(),
AtomicFact::InFact(_) => InFact::new(left, right, line_file).into(),
AtomicFact::SubsetFact(_) => SubsetFact::new(left, right, line_file).into(),
AtomicFact::SupersetFact(_) => SupersetFact::new(left, right, line_file).into(),
AtomicFact::NotEqualFact(_) => NotEqualFact::new(left, right, line_file).into(),
AtomicFact::NotLessFact(_) => NotLessFact::new(left, right, line_file).into(),
AtomicFact::NotGreaterFact(_) => NotGreaterFact::new(left, right, line_file).into(),
AtomicFact::NotLessEqualFact(_) => NotLessEqualFact::new(left, right, line_file).into(),
AtomicFact::NotGreaterEqualFact(_) => {
NotGreaterEqualFact::new(left, right, line_file).into()
}
AtomicFact::NotInFact(_) => NotInFact::new(left, right, line_file).into(),
AtomicFact::NotSubsetFact(_) => NotSubsetFact::new(left, right, line_file).into(),
AtomicFact::NotSupersetFact(_) => NotSupersetFact::new(left, right, line_file).into(),
AtomicFact::RestrictFact(_) => RestrictFact::new(left, right, line_file).into(),
AtomicFact::NotRestrictFact(_) => NotRestrictFact::new(left, right, line_file).into(),
AtomicFact::NormalAtomicFact(x) => {
NormalAtomicFact::new(x.predicate.clone(), vec![left, right], line_file).into()
}
AtomicFact::NotNormalAtomicFact(x) => {
NotNormalAtomicFact::new(x.predicate.clone(), vec![left, right], line_file).into()
}
_ => unreachable!(
"atomic_fact_with_resolved_binary_operands: expected a two-argument atomic fact"
),
}
}
fn atomic_fact_with_resolved_predicate_args(fact: &AtomicFact, args: Vec<Obj>) -> AtomicFact {
let line_file = fact.line_file();
match fact {
AtomicFact::NormalAtomicFact(x) => {
NormalAtomicFact::new(x.predicate.clone(), args, line_file).into()
}
AtomicFact::NotNormalAtomicFact(x) => {
NotNormalAtomicFact::new(x.predicate.clone(), args, line_file).into()
}
_ => unreachable!(
"atomic_fact_with_resolved_predicate_args: expected NormalAtomicFact or NotNormalAtomicFact"
),
}
}
fn verify_atomic_fact_not_equality_with_known_atomic_fact_with_1_param_with_facts_in_environment(
environment: &Environment,
atomic_fact: &AtomicFact,
all_objs_equal_to_arg: &Vec<String>,
) -> Result<StmtResult, RuntimeError> {
if let Some(known_facts_map) = environment
.known_atomic_facts_with_1_arg
.get(&(atomic_fact.key(), atomic_fact.is_true()))
{
for obj in all_objs_equal_to_arg.iter() {
if let Some(known_atomic_fact) = known_facts_map.get(obj) {
return Ok((FactualStmtSuccess::new_with_verified_by_known_fact_source_recording_facts(
atomic_fact.clone().into(),
known_atomic_fact.to_string(),
Some(known_atomic_fact.clone().into()),
None,
Vec::new(),
)).into());
}
}
}
Ok((StmtUnknown::new()).into())
}
fn verify_atomic_fact_not_equality_with_known_atomic_fact_with_2_params_with_facts_in_environment(
environment: &Environment,
atomic_fact: &AtomicFact,
all_objs_equal_to_arg0: &Vec<String>,
all_objs_equal_to_arg1: &Vec<String>,
) -> Result<StmtResult, RuntimeError> {
if let Some(known_facts_map) = environment
.known_atomic_facts_with_2_args
.get(&(atomic_fact.key(), atomic_fact.is_true()))
{
for obj0 in all_objs_equal_to_arg0.iter() {
for obj1 in all_objs_equal_to_arg1.iter() {
if let Some(known_atomic_fact) =
known_facts_map.get(&(obj0.clone(), obj1.clone()))
{
return Ok((FactualStmtSuccess::new_with_verified_by_known_fact_source_recording_facts(
atomic_fact.clone().into(),
known_atomic_fact.to_string(),
Some(known_atomic_fact.clone().into()),
None,
Vec::new(),
)).into());
}
}
}
}
if let Some(alt) = atomic_fact.transposed_binary_order_equivalent() {
if let Some(known_facts_map) = environment
.known_atomic_facts_with_2_args
.get(&(alt.key(), alt.is_true()))
{
for obj0 in all_objs_equal_to_arg1.iter() {
for obj1 in all_objs_equal_to_arg0.iter() {
if let Some(known_atomic_fact) =
known_facts_map.get(&(obj0.clone(), obj1.clone()))
{
return Ok((FactualStmtSuccess::new_with_verified_by_known_fact_source_recording_facts(
atomic_fact.clone().into(),
known_atomic_fact.to_string(),
Some(known_atomic_fact.clone().into()),
None,
Vec::new(),
)).into());
}
}
}
}
}
Ok((StmtUnknown::new()).into())
}
fn verify_atomic_fact_not_equality_with_known_atomic_fact_with_0_or_more_than_2_params_with_facts_in_environment(
environment: &Environment,
atomic_fact: &AtomicFact,
all_objs_equal_to_each_arg: &Vec<Vec<String>>,
) -> Result<StmtResult, RuntimeError> {
if let Some(known_facts) = environment
.known_atomic_facts_with_0_or_more_than_2_args
.get(&(atomic_fact.key(), atomic_fact.is_true()))
{
for known_fact in known_facts.iter() {
if known_fact.args().len() != atomic_fact.args().len() {
let message = format!(
"known atomic fact {} has different number of args than the given fact {}",
known_fact.to_string(),
atomic_fact.to_string()
);
return Err({
VerifyRuntimeError(RuntimeErrorStruct::new(
Some(Fact::from(atomic_fact.clone()).into_stmt()),
message.clone(),
atomic_fact.line_file(),
Some(
UnknownRuntimeError(RuntimeErrorStruct::new(
Some(Fact::from(atomic_fact.clone()).into_stmt()),
message,
atomic_fact.line_file(),
None,
vec![],
))
.into(),
),
vec![],
))
.into()
});
}
let mut all_args_match = true;
for (index, known_arg) in known_fact.args().iter().enumerate() {
let known_arg_string = known_arg.to_string();
if !all_objs_equal_to_each_arg[index].contains(&known_arg_string) {
all_args_match = false;
break;
}
}
if all_args_match {
return Ok((FactualStmtSuccess::new_with_verified_by_known_fact_source_recording_facts(
atomic_fact.clone().into(),
known_fact.to_string(),
Some(known_fact.clone().into()),
None,
Vec::new(),
)).into());
}
}
}
Ok((StmtUnknown::new()).into())
}
pub fn verify_fact(
&mut self,
fact: &Fact,
verify_state: &VerifyState,
) -> Result<StmtResult, RuntimeError> {
match fact {
Fact::AtomicFact(atomic_fact) => self.verify_atomic_fact(atomic_fact, verify_state),
Fact::AndFact(and_fact) => self.verify_and_fact(and_fact, verify_state),
Fact::ChainFact(chain_fact) => self.verify_chain_fact(chain_fact, verify_state),
Fact::ForallFact(forall_fact) => self.verify_forall_fact(forall_fact, verify_state),
Fact::ForallFactWithIff(forall_iff) => {
self.verify_forall_fact_with_iff(forall_iff, verify_state)
}
Fact::NotForall(not_forall) => self.verify_not_forall_fact(not_forall, verify_state),
Fact::ExistFact(exist_fact) => self.verify_exist_fact(exist_fact, verify_state),
Fact::OrFact(or_fact) => self.verify_or_fact(or_fact, verify_state),
}
}
fn verify_subset_fact_by_membership_forall_definition(
&mut self,
subset_fact: &SubsetFact,
verify_state: &VerifyState,
) -> Result<Option<StmtResult>, RuntimeError> {
let bound_param_name = self.generate_random_unused_name();
let membership_forall_fact = ForallFact::new(
ParamDefWithType::new(vec![ParamGroupWithParamType::new(
vec![bound_param_name.clone()],
ParamType::Obj(subset_fact.left.clone()),
)]),
vec![],
vec![InFact::new(
obj_for_bound_param_in_scope(bound_param_name.clone(), ParamObjType::Forall),
subset_fact.right.clone(),
subset_fact.line_file.clone(),
)
.into()],
subset_fact.line_file.clone(),
)?
.into();
let verify_forall_result = self.verify_fact(&membership_forall_fact, verify_state)?;
if !verify_forall_result.is_true() {
return Ok(None);
}
Ok(Some(
(FactualStmtSuccess::new_with_verified_by_builtin_rules_recording_stmt(
subset_fact.clone().into(),
"subset by definition (forall x in left: x in right)".to_string(),
Vec::new(),
))
.into(),
))
}
fn verify_superset_fact_by_membership_forall_definition(
&mut self,
superset_fact: &SupersetFact,
verify_state: &VerifyState,
) -> Result<Option<StmtResult>, RuntimeError> {
let bound_param_name = self.generate_random_unused_name();
let membership_forall_fact = ForallFact::new(
ParamDefWithType::new(vec![ParamGroupWithParamType::new(
vec![bound_param_name.clone()],
ParamType::Obj(superset_fact.right.clone()),
)]),
vec![],
vec![InFact::new(
obj_for_bound_param_in_scope(bound_param_name.clone(), ParamObjType::Forall),
superset_fact.left.clone(),
superset_fact.line_file.clone(),
)
.into()],
superset_fact.line_file.clone(),
)?
.into();
let verify_forall_result = self.verify_fact(&membership_forall_fact, verify_state)?;
if !verify_forall_result.is_true() {
return Ok(None);
}
Ok(Some(
(FactualStmtSuccess::new_with_verified_by_builtin_rules_recording_stmt(
superset_fact.clone().into(),
"superset by definition (forall x in right: x in left)".to_string(),
Vec::new(),
))
.into(),
))
}
fn verify_atomic_fact_using_builtin_or_prop_definition(
&mut self,
atomic_fact: &AtomicFact,
verify_state: &VerifyState,
) -> Result<Option<StmtResult>, RuntimeError> {
if let Some(result) =
self.verify_builtin_fact_with_their_definition(atomic_fact, verify_state)?
{
return Ok(Some(result));
}
if let AtomicFact::NormalAtomicFact(n) = atomic_fact {
return self.verify_normal_atomic_fact_using_its_definition(n, verify_state);
}
Ok(None)
}
fn verify_normal_atomic_fact_using_its_definition(
&mut self,
normal_atomic_fact: &NormalAtomicFact,
verify_state: &VerifyState,
) -> Result<Option<StmtResult>, RuntimeError> {
if let Some(_) =
self.get_abstract_prop_definition_by_name(&normal_atomic_fact.predicate.to_string())
{
return Ok(None);
}
let predicate_name = normal_atomic_fact.predicate.to_string();
let definition = match self.get_prop_definition_by_name(&predicate_name) {
Some(definition_reference) => definition_reference.clone(),
None => {
return Err({
VerifyRuntimeError(RuntimeErrorStruct::new(
Some(Fact::from(normal_atomic_fact.clone()).into_stmt()),
format!("prop definition not found for {}", predicate_name),
normal_atomic_fact.line_file.clone(),
None,
vec![],
))
.into()
})
}
};
let verify_state_for_definition_clauses = verify_state;
let args_param_types = match self.verify_args_satisfy_param_def_flat_types(
&definition.params_def_with_type,
&normal_atomic_fact.body,
verify_state_for_definition_clauses,
ParamObjType::DefHeader,
) {
Ok(x) => x,
Err(_) => {
return Err({
VerifyRuntimeError(RuntimeErrorStruct::new(
Some(Fact::from(normal_atomic_fact.clone()).into_stmt()),
format!("failed to verify parameter types for {}", predicate_name),
normal_atomic_fact.line_file.clone(),
None,
vec![],
))
.into()
})
}
};
if args_param_types.is_unknown() {
return Ok(None);
}
if definition.iff_facts.is_empty() {
return Ok(None);
}
let param_to_arg_map = definition
.params_def_with_type
.param_defs_and_args_to_param_to_arg_map(normal_atomic_fact.body.as_slice());
let mut infer_result = InferResult::new();
let mut definition_clause_descriptions: Vec<String> = Vec::new();
for iff_fact in definition.iff_facts.iter() {
let instantiated_iff_fact = self
.inst_fact(iff_fact, ¶m_to_arg_map, ParamObjType::DefHeader, None)
.map_err(|e| {
{
RuntimeError::from(VerifyRuntimeError(RuntimeErrorStruct::new(
Some(Fact::from(normal_atomic_fact.clone()).into_stmt()),
String::new(),
normal_atomic_fact.line_file.clone(),
Some(e),
vec![],
)))
}
})?;
let iff_clause_verify_result =
self.verify_fact(&instantiated_iff_fact, &verify_state_for_definition_clauses)?;
if iff_clause_verify_result.is_unknown() {
return Ok(None);
}
match &iff_clause_verify_result {
StmtResult::FactualStmtSuccess(factual_success) => {
infer_result.new_infer_result_inside(factual_success.infers.clone());
definition_clause_descriptions.push(factual_success.msg.clone());
}
StmtResult::NonFactualStmtSuccess(non_factual_success) => {
infer_result.new_infer_result_inside(non_factual_success.infers.clone());
}
StmtResult::StmtUnknown(_) => return Ok(None),
}
}
let verified_by_text = format!(
"prop with meaning `{}` (param constraints and definition clauses): {}",
predicate_name,
definition_clause_descriptions.join("; ")
);
infer_result.new_fact(&normal_atomic_fact.clone().into());
Ok(Some(
(FactualStmtSuccess::new_with_verified_by_known_fact_source(
normal_atomic_fact.clone().into(),
infer_result,
verified_by_text,
None,
Some(normal_atomic_fact.line_file.clone()),
Vec::new(),
))
.into(),
))
}
fn verify_builtin_fact_with_their_definition(
&mut self,
fact: &AtomicFact,
verify_state: &VerifyState,
) -> Result<Option<StmtResult>, RuntimeError> {
match fact {
AtomicFact::SubsetFact(subset_fact) => {
if let Some(verified_by_subset_definition) = self
.verify_subset_fact_by_membership_forall_definition(subset_fact, verify_state)?
{
return Ok(Some(verified_by_subset_definition));
}
return Ok(None);
}
AtomicFact::SupersetFact(superset_fact) => {
if let Some(verified_by_superset_definition) = self
.verify_superset_fact_by_membership_forall_definition(
superset_fact,
verify_state,
)?
{
return Ok(Some(verified_by_superset_definition));
}
return Ok(None);
}
AtomicFact::RestrictFact(restrict_fact) => {
if let Some(verified_by_restrict_definition) =
self.verify_restrict_fact_using_its_definition(restrict_fact, verify_state)?
{
return Ok(Some(verified_by_restrict_definition));
}
return Ok(None);
}
_ => {}
}
Ok(None)
}
fn post_process_non_equational_atomic_fact(
&mut self,
atomic_fact: &AtomicFact,
verify_state: &VerifyState,
result: StmtResult,
) -> Result<StmtResult, RuntimeError> {
let Some(transposed_fact) = atomic_fact.transposed_binary_order_equivalent() else {
return Ok(result);
};
let transposed_result =
self.verify_non_equational_atomic_fact(&transposed_fact, verify_state, false)?;
match transposed_result {
StmtResult::FactualStmtSuccess(inner_success) => Ok(
(FactualStmtSuccess::new_with_verified_by_known_fact_source_recording_facts(
atomic_fact.clone().into(),
inner_success.msg,
inner_success.verified_by_fact,
inner_success.verified_by_fact_known_line_file,
inner_success.inside_results,
))
.into(),
),
other if other.is_true() => Ok(other),
_ => Ok(result),
}
}
}