SolutionCompareResult
ConstraintSystem::compareSolutions(ConstraintSystem &cs,
ArrayRef<Solution> solutions,
const SolutionDiff &diff,
unsigned idx1, unsigned idx2) {
if (cs.TC.getLangOpts().DebugConstraintSolver) {
auto &log = cs.getASTContext().TypeCheckerDebug->getStream();
log.indent(cs.solverState->depth * 2)
<< "comparing solutions " << idx1 << " and " << idx2 <<"\n";
}
// Whether the solutions are identical.
bool identical = true;
// Compare the fixed scores by themselves.
if (solutions[idx1].getFixedScore() != solutions[idx2].getFixedScore()) {
return solutions[idx1].getFixedScore() < solutions[idx2].getFixedScore()
? SolutionCompareResult::Better
: SolutionCompareResult::Worse;
}
// Compute relative score.
unsigned score1 = 0;
unsigned score2 = 0;
auto foundRefinement1 = false;
auto foundRefinement2 = false;
bool isStdlibOptionalMPlusOperator1 = false;
bool isStdlibOptionalMPlusOperator2 = false;
// Compare overload sets.
for (auto &overload : diff.overloads) {
auto choice1 = overload.choices[idx1];
auto choice2 = overload.choices[idx2];
// If the systems made the same choice, there's nothing interesting here.
if (sameOverloadChoice(choice1, choice2))
continue;
auto decl1 = choice1.getDecl();
auto dc1 = decl1->getDeclContext();
auto decl2 = choice2.getDecl();
auto dc2 = decl2->getDeclContext();
// The two systems are not identical. If the decls in question are distinct
// protocol members, let the checks below determine if the two choices are
// 'identical' or not. This allows us to structurally unify disparate
// protocol members during overload resolution.
// FIXME: Along with the FIXME below, this is a hack to work around
// problems with restating requirements in protocols.
bool decl1InSubprotocol = false;
bool decl2InSubprotocol = false;
if ((dc1->getContextKind() == DeclContextKind::NominalTypeDecl) &&
(dc1->getContextKind() == dc2->getContextKind())) {
auto ntd1 = dyn_cast<NominalTypeDecl>(dc1);
auto ntd2 = dyn_cast<NominalTypeDecl>(dc2);
identical = (ntd1 != ntd2) &&
(ntd1->getKind() == DeclKind::Protocol) &&
(ntd2->getKind() == DeclKind::Protocol);
// FIXME: This hack tells us to prefer members of subprotocols over
// those of the protocols they inherit, if all else fails.
// If we were properly handling overrides of protocol members when
// requirements get restated, it would not be necessary.
if (identical) {
decl1InSubprotocol = cast<ProtocolDecl>(ntd1)->inheritsFrom(
cast<ProtocolDecl>(ntd2));
decl2InSubprotocol = cast<ProtocolDecl>(ntd2)->inheritsFrom(
cast<ProtocolDecl>(ntd1));
}
} else {
identical = false;
}
// If the kinds of overload choice don't match...
if (choice1.getKind() != choice2.getKind()) {
identical = false;
// A declaration found directly beats any declaration found via dynamic
// lookup, bridging, or optional unwrapping.
if (choice1.getKind() == OverloadChoiceKind::Decl &&
(choice2.getKind() == OverloadChoiceKind::DeclViaDynamic ||
choice2.getKind() == OverloadChoiceKind::DeclViaBridge ||
choice2.getKind() == OverloadChoiceKind::DeclViaUnwrappedOptional)) {
++score1;
continue;
}
if ((choice1.getKind() == OverloadChoiceKind::DeclViaDynamic ||
choice1.getKind() == OverloadChoiceKind::DeclViaBridge ||
choice1.getKind() == OverloadChoiceKind::DeclViaUnwrappedOptional) &&
choice2.getKind() == OverloadChoiceKind::Decl) {
++score2;
continue;
}
continue;
}
// The kinds of overload choice match, but the contents don't.
auto &tc = cs.getTypeChecker();
switch (choice1.getKind()) {
case OverloadChoiceKind::TupleIndex:
case OverloadChoiceKind::TypeDecl:
continue;
case OverloadChoiceKind::BaseType:
llvm_unreachable("Never considered different");
case OverloadChoiceKind::DeclViaDynamic:
case OverloadChoiceKind::Decl:
case OverloadChoiceKind::DeclViaBridge:
case OverloadChoiceKind::DeclViaUnwrappedOptional:
break;
}
// Determine whether one declaration is more specialized than the other.
bool firstAsSpecializedAs = false;
bool secondAsSpecializedAs = false;
if (isDeclAsSpecializedAs(tc, cs.DC, decl1, decl2)) {
++score1;
firstAsSpecializedAs = true;
}
if (isDeclAsSpecializedAs(tc, cs.DC, decl2, decl1)) {
++score2;
secondAsSpecializedAs = true;
}
// If each is as specialized as the other, and both are constructors,
// check the constructor kind.
if (firstAsSpecializedAs && secondAsSpecializedAs) {
if (auto ctor1 = dyn_cast<ConstructorDecl>(decl1)) {
if (auto ctor2 = dyn_cast<ConstructorDecl>(decl2)) {
if (ctor1->getInitKind() != ctor2->getInitKind()) {
if (ctor1->getInitKind() < ctor2->getInitKind())
++score1;
else
++score2;
} else if (ctor1->getInitKind() ==
CtorInitializerKind::Convenience) {
// If both are convenience initializers, and the instance type of
// one is a subtype of the other's, favor the subtype constructor.
auto resType1 = ctor1->getResultType();
auto resType2 = ctor2->getResultType();
if (!resType1->isEqual(resType2)) {
if (tc.isSubtypeOf(resType1, resType2, cs.DC)) {
++score1;
} else if (tc.isSubtypeOf(resType2, resType1, cs.DC)) {
++score2;
}
}
}
}
}
}
// If both declarations come from Clang, and one is a type and the other
// is a function, prefer the function.
if (decl1->hasClangNode() &&
decl2->hasClangNode() &&
((isa<TypeDecl>(decl1) &&
isa<AbstractFunctionDecl>(decl2)) ||
(isa<AbstractFunctionDecl>(decl1) &&
isa<TypeDecl>(decl2)))) {
if (isa<TypeDecl>(decl1))
++score2;
else
++score1;
}
// A class member is always better than a curried instance member.
// If the members agree on instance-ness, a property is better than a
// method (because a method is usually immediately invoked).
if (!decl1->isInstanceMember() && decl2->isInstanceMember())
++score1;
else if (!decl2->isInstanceMember() && decl1->isInstanceMember())
++score2;
else if (isa<VarDecl>(decl1) && isa<FuncDecl>(decl2))
++score1;
else if (isa<VarDecl>(decl2) && isa<FuncDecl>(decl1))
++score2;
// If we haven't found a refinement, record whether one overload is in
// any way more constrained than another. We'll only utilize this
// information in the case of a potential ambiguity.
if (!(foundRefinement1 && foundRefinement2)) {
if (isDeclMoreConstrainedThan(decl1, decl2)) {
foundRefinement1 = true;
}
if (isDeclMoreConstrainedThan(decl2, decl1)) {
foundRefinement2 = true;
}
}
// If we still haven't found a refinement, check if there's a parameter-
// wise comparison between an empty existential collection and a non-
// existential type.
if (!(foundRefinement1 && foundRefinement2)) {
if (hasEmptyExistentialParameterMismatch(decl1, decl2)) {
foundRefinement1 = true;
}
if (hasEmptyExistentialParameterMismatch(decl2, decl1)) {
foundRefinement2 = true;
}
}
// FIXME: The rest of the hack for restating requirements.
if (!(foundRefinement1 && foundRefinement2)) {
if (identical && decl1InSubprotocol != decl2InSubprotocol) {
foundRefinement1 = decl1InSubprotocol;
foundRefinement2 = decl2InSubprotocol;
}
}
// FIXME: Lousy hack for ?? to prefer the catamorphism (flattening)
// over the mplus (non-flattening) overload if all else is equal.
if (decl1->getName().str() == "??") {
assert(decl2->getName().str() == "??");
auto check = [](const ValueDecl *VD) -> bool {
if (!VD->getModuleContext()->isStdlibModule())
return false;
auto fnTy = VD->getType()->castTo<AnyFunctionType>();
if (!fnTy->getResult()->getAnyOptionalObjectType())
return false;
// Check that the standard library hasn't added another overload of
// the ?? operator.
auto inputTupleTy = fnTy->getInput()->castTo<TupleType>();
auto inputTypes = inputTupleTy->getElementTypes();
assert(inputTypes.size() == 2);
assert(inputTypes[0]->getAnyOptionalObjectType());
auto autoclosure = inputTypes[1]->castTo<AnyFunctionType>();
assert(autoclosure->isAutoClosure());
auto secondParamTy = autoclosure->getResult();
assert(secondParamTy->getAnyOptionalObjectType());
(void)secondParamTy;
return true;
};
isStdlibOptionalMPlusOperator1 = check(decl1);
isStdlibOptionalMPlusOperator2 = check(decl2);
}
}
// Compare the type variable bindings.
auto &tc = cs.getTypeChecker();
for (auto &binding : diff.typeBindings) {
// If the type variable isn't one for which we should be looking at the
// bindings, don't.
if (!binding.typeVar->getImpl().prefersSubtypeBinding())
continue;
auto type1 = binding.bindings[idx1];
auto type2 = binding.bindings[idx2];
// Strip any initializers from tuples in the type; they aren't
// to be compared.
type1 = stripInitializers(type1);
type2 = stripInitializers(type2);
// If the types are equivalent, there's nothing more to do.
if (type1->isEqual(type2))
continue;
// If either of the types still contains type variables, we can't
// compare them.
// FIXME: This is really unfortunate. More type variable sharing
// (when it's sane) would help us do much better here.
if (type1->hasTypeVariable() || type2->hasTypeVariable()) {
identical = false;
continue;
}
// If one type is an implicitly unwrapped optional of the other,
// prefer the non-optional.
bool type1Better = false;
bool type2Better = false;
if (auto type1Obj = type1->getImplicitlyUnwrappedOptionalObjectType()) {
if (type1Obj->isEqual(type2))
type2Better = true;
}
if (auto type2Obj = type2->getImplicitlyUnwrappedOptionalObjectType()) {
if (type2Obj->isEqual(type1))
type1Better = true;
}
if (type1Better || type2Better) {
if (type1Better)
++score1;
if (type2Better)
++score2;
continue;
}
// If one type is a subtype of the other, but not vice-versa,
// we prefer the system with the more-constrained type.
// FIXME: Collapse this check into the second check.
type1Better = tc.isSubtypeOf(type1, type2, cs.DC);
type2Better = tc.isSubtypeOf(type2, type1, cs.DC);
if (type1Better || type2Better) {
if (type1Better)
++score1;
if (type2Better)
++score2;
// Prefer the unlabeled form of a type.
auto unlabeled1 = type1->getUnlabeledType(cs.getASTContext());
auto unlabeled2 = type2->getUnlabeledType(cs.getASTContext());
if (unlabeled1->isEqual(unlabeled2)) {
if (type1->isEqual(unlabeled1)) {
++score1;
continue;
}
if (type2->isEqual(unlabeled2)) {
++score2;
continue;
}
}
identical = false;
continue;
}
// The systems are not considered equivalent.
identical = false;
// If one type is convertible to of the other, but not vice-versa.
type1Better = tc.isConvertibleTo(type1, type2, cs.DC);
type2Better = tc.isConvertibleTo(type2, type1, cs.DC);
if (type1Better || type2Better) {
if (type1Better)
++score1;
if (type2Better)
++score2;
continue;
}
// A concrete type is better than an archetype.
// FIXME: Total hack.
if (type1->is<ArchetypeType>() != type2->is<ArchetypeType>()) {
if (type1->is<ArchetypeType>())
++score2;
else
++score1;
continue;
}
// FIXME:
// This terrible hack is in place to support equality comparisons of non-
// equatable option types to 'nil'. Until we have a way to constrain a type
// variable on "!Equatable", if all other aspects of the overload choices
// are equal, favor the overload that does not require an implicit literal
// argument conversion to 'nil'.
// Post-1.0, we'll need to remove this hack in favor of richer constraint
// declarations.
if (!(score1 || score2)) {
if (auto nominalType2 = type2->getNominalOrBoundGenericNominal()) {
if ((nominalType2->getName() ==
cs.TC.Context.Id_OptionalNilComparisonType)) {
++score1;
}
} else if (auto nominalType1 = type1->getNominalOrBoundGenericNominal()) {
if ((nominalType1->getName() ==
cs.TC.Context.Id_OptionalNilComparisonType)) {
++score2;
}
}
}
}
// All other things considered equal, if any overload choice is more
// more constrained than the other, increment the score.
if (score1 == score2) {
if (foundRefinement1) {
++score1;
}
if (foundRefinement2) {
++score2;
}
}
// FIXME: All other things being equal, prefer the catamorphism (flattening)
// overload of ?? over the mplus (non-flattening) overload.
if (score1 == score2) {
// This is correct: we want to /disprefer/ the mplus.
score2 += isStdlibOptionalMPlusOperator1;
score1 += isStdlibOptionalMPlusOperator2;
}
// FIXME: There are type variables and overloads not common to both solutions
// that haven't been considered. They make the systems different, but don't
// affect ranking. We need to handle this.
// If the scores are different, we have a winner.
if (score1 != score2) {
return score1 > score2? SolutionCompareResult::Better
: SolutionCompareResult::Worse;
}
// Neither system wins; report whether they were identical or not.
return identical? SolutionCompareResult::Identical
: SolutionCompareResult::Incomparable;
}
AssignmentFailure::AssignmentFailure(Expr *destExpr, ConstraintSystem &cs,
SourceLoc diagnosticLoc)
: FailureDiagnostic(destExpr, cs, cs.getConstraintLocator(destExpr)),
Loc(diagnosticLoc),
DeclDiagnostic(findDeclDiagonstic(cs.getASTContext(), destExpr)),
TypeDiagnostic(diag::assignment_lhs_not_lvalue) {}