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fuchsia / third_party / swift / 2db532300739b98f33c5661afa8621d9028f908e / . / lib / AST / GenericSignature.cpp
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//===--- GenericSignature.cpp - Generic Signature AST ---------------------===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See https://swift.org/LICENSE.txt for license information
// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//
//
// This file implements the GenericSignature class.
//
//===----------------------------------------------------------------------===//
#include "swift/AST/GenericSignature.h"
#include "swift/AST/ASTContext.h"
#include "swift/AST/GenericSignatureBuilder.h"
#include "swift/AST/Decl.h"
#include "swift/AST/GenericEnvironment.h"
#include "swift/AST/Module.h"
#include "swift/AST/Types.h"
#include "swift/Basic/STLExtras.h"
#include <functional>
using namespace swift;
void ConformanceAccessPath::print(raw_ostream &out) const {
interleave(begin(), end(),
[&](const Entry &entry) {
entry.first.print(out);
out << ": " << entry.second->getName();
}, [&] {
out << " -> ";
});
}
void ConformanceAccessPath::dump() const {
print(llvm::errs());
llvm::errs() << "\n";
}
GenericSignature::GenericSignature(ArrayRef<GenericTypeParamType *> params,
ArrayRef<Requirement> requirements,
bool isKnownCanonical)
: NumGenericParams(params.size()), NumRequirements(requirements.size()),
CanonicalSignatureOrASTContext()
{
auto paramsBuffer = getGenericParamsBuffer();
for (unsigned i = 0; i < NumGenericParams; ++i) {
paramsBuffer[i] = params[i];
}
auto reqtsBuffer = getRequirementsBuffer();
for (unsigned i = 0; i < NumRequirements; ++i) {
reqtsBuffer[i] = requirements[i];
}
#ifndef NDEBUG
// Make sure generic parameters are in the right order, and
// none are missing.
unsigned depth = 0;
unsigned count = 0;
for (auto param : params) {
if (param->getDepth() != depth) {
assert(param->getDepth() > depth &&
"Generic parameter depth mismatch");
depth = param->getDepth();
count = 0;
}
assert(param->getIndex() == count &&
"Generic parameter index mismatch");
count++;
}
#endif
if (isKnownCanonical)
CanonicalSignatureOrASTContext = &getASTContext(params, requirements);
}
ArrayRef<GenericTypeParamType *>
GenericSignature::getInnermostGenericParams() const {
auto params = getGenericParams();
// Find the point at which the depth changes.
unsigned depth = params.back()->getDepth();
for (unsigned n = params.size(); n > 0; --n) {
if (params[n-1]->getDepth() != depth) {
return params.slice(n);
}
}
// All parameters are at the same depth.
return params;
}
SmallVector<GenericTypeParamType *, 2>
GenericSignature::getSubstitutableParams() const {
SmallVector<GenericTypeParamType *, 2> result;
enumeratePairedRequirements([&](Type depTy, ArrayRef<Requirement>) -> bool {
if (auto *paramTy = depTy->getAs<GenericTypeParamType>())
result.push_back(paramTy);
return false;
});
return result;
}
std::string GenericSignature::gatherGenericParamBindingsText(
ArrayRef<Type> types, TypeSubstitutionFn substitutions) const {
llvm::SmallPtrSet<GenericTypeParamType *, 2> knownGenericParams;
for (auto type : types) {
type.visit([&](Type type) {
if (auto gp = type->getAs<GenericTypeParamType>()) {
knownGenericParams.insert(
gp->getCanonicalType()->castTo<GenericTypeParamType>());
}
});
}
if (knownGenericParams.empty())
return "";
SmallString<128> result;
for (auto gp : this->getGenericParams()) {
auto canonGP = gp->getCanonicalType()->castTo<GenericTypeParamType>();
if (!knownGenericParams.count(canonGP))
continue;
if (result.empty())
result += " [with ";
else
result += ", ";
result += gp->getName().str();
result += " = ";
auto type = substitutions(canonGP);
if (!type)
return "";
result += type.getString();
}
result += "]";
return result.str().str();
}
ASTContext &GenericSignature::getASTContext(
ArrayRef<swift::GenericTypeParamType *> params,
ArrayRef<swift::Requirement> requirements) {
// The params and requirements cannot both be empty.
if (!params.empty())
return params.front()->getASTContext();
else
return requirements.front().getFirstType()->getASTContext();
}
GenericSignatureBuilder *GenericSignature::getGenericSignatureBuilder(ModuleDecl &mod) {
// The generic signature builder is associated with the canonical signature.
if (!isCanonical())
return getCanonicalSignature()->getGenericSignatureBuilder(mod);
// generic signature builders are stored on the ASTContext.
return getASTContext().getOrCreateGenericSignatureBuilder(CanGenericSignature(this),
&mod);
}
bool GenericSignature::isCanonical() const {
if (CanonicalSignatureOrASTContext.is<ASTContext*>()) return true;
return getCanonicalSignature() == this;
}
CanGenericSignature GenericSignature::getCanonical(
ArrayRef<GenericTypeParamType *> params,
ArrayRef<Requirement> requirements) {
// Canonicalize the parameters and requirements.
SmallVector<GenericTypeParamType*, 8> canonicalParams;
canonicalParams.reserve(params.size());
for (auto param : params) {
canonicalParams.push_back(cast<GenericTypeParamType>(param->getCanonicalType()));
}
SmallVector<Requirement, 8> canonicalRequirements;
canonicalRequirements.reserve(requirements.size());
for (auto &reqt : requirements) {
if (reqt.getKind() != RequirementKind::Layout) {
auto secondTy = reqt.getSecondType();
canonicalRequirements.push_back(
Requirement(reqt.getKind(), reqt.getFirstType()->getCanonicalType(),
secondTy ? secondTy->getCanonicalType() : CanType()));
} else
canonicalRequirements.push_back(
Requirement(reqt.getKind(), reqt.getFirstType()->getCanonicalType(),
reqt.getLayoutConstraint()));
}
auto canSig = get(canonicalParams, canonicalRequirements,
/*isKnownCanonical=*/true);
return CanGenericSignature(canSig);
}
CanGenericSignature
GenericSignature::getCanonicalSignature() const {
// If we haven't computed the canonical signature yet, do so now.
if (CanonicalSignatureOrASTContext.isNull()) {
// Compute the canonical signature.
CanGenericSignature canSig = getCanonical(getGenericParams(),
getRequirements());
// Record either the canonical signature or an indication that
// this is the canonical signature.
if (canSig != this)
CanonicalSignatureOrASTContext = canSig;
else
CanonicalSignatureOrASTContext = &getGenericParams()[0]->getASTContext();
// Return the canonical signature.
return canSig;
}
// A stored ASTContext indicates that this is the canonical
// signature.
if (CanonicalSignatureOrASTContext.is<ASTContext*>())
// TODO: CanGenericSignature should be const-correct.
return CanGenericSignature(const_cast<GenericSignature*>(this));
// Otherwise, return the stored canonical signature.
return CanGenericSignature(
CanonicalSignatureOrASTContext.get<GenericSignature*>());
}
GenericEnvironment *GenericSignature::createGenericEnvironment(
ModuleDecl &mod) {
auto *builder = getGenericSignatureBuilder(mod);
return GenericEnvironment::getIncomplete(this, builder);
}
ASTContext &GenericSignature::getASTContext() const {
// Canonical signatures store the ASTContext directly.
if (auto ctx = CanonicalSignatureOrASTContext.dyn_cast<ASTContext *>())
return *ctx;
// For everything else, just get it from the generic parameter.
return getASTContext(getGenericParams(), getRequirements());
}
Optional<ProtocolConformanceRef>
GenericSignature::lookupConformance(CanType type, ProtocolDecl *proto) const {
// FIXME: Actually implement this properly.
auto *M = proto->getParentModule();
if (type->isTypeParameter())
return ProtocolConformanceRef(proto);
return M->lookupConformance(type, proto,
M->getASTContext().getLazyResolver());
}
bool GenericSignature::enumeratePairedRequirements(
llvm::function_ref<bool(Type, ArrayRef<Requirement>)> fn) const {
// We'll be walking through the list of requirements.
ArrayRef<Requirement> reqs = getRequirements();
unsigned curReqIdx = 0, numReqs = reqs.size();
// ... and walking through the list of generic parameters.
ArrayRef<GenericTypeParamType *> genericParams = getGenericParams();
unsigned curGenericParamIdx = 0, numGenericParams = genericParams.size();
// Figure out which generic parameters are complete.
SmallVector<bool, 4> genericParamsAreConcrete(genericParams.size(), false);
for (auto req : reqs) {
if (req.getKind() != RequirementKind::SameType) continue;
if (req.getSecondType()->isTypeParameter()) continue;
auto gp = req.getFirstType()->getAs<GenericTypeParamType>();
if (!gp) continue;
unsigned index = GenericParamKey(gp).findIndexIn(genericParams);
genericParamsAreConcrete[index] = true;
}
/// Local function to 'catch up' to the next dependent type we're going to
/// visit, calling the function for each of the generic parameters in the
/// generic parameter list prior to this parameter.
auto enumerateGenericParamsUpToDependentType = [&](CanType depTy) -> bool {
// Figure out where we should stop when enumerating generic parameters.
unsigned stopDepth, stopIndex;
if (auto gp = dyn_cast_or_null<GenericTypeParamType>(depTy)) {
stopDepth = gp->getDepth();
stopIndex = gp->getIndex();
} else {
stopDepth = genericParams.back()->getDepth() + 1;
stopIndex = 0;
}
// Enumerate generic parameters up to the stopping point, calling the
// callback function for each one
while (curGenericParamIdx != numGenericParams) {
auto curGenericParam = genericParams[curGenericParamIdx];
// If the current generic parameter is before our stopping point, call
// the function.
if (curGenericParam->getDepth() < stopDepth ||
(curGenericParam->getDepth() == stopDepth &&
curGenericParam->getIndex() < stopIndex)) {
if (!genericParamsAreConcrete[curGenericParamIdx] &&
fn(curGenericParam, { }))
return true;
++curGenericParamIdx;
continue;
}
// If the current generic parameter is at our stopping point, we're
// done.
if (curGenericParam->getDepth() == stopDepth &&
curGenericParam->getIndex() == stopIndex) {
++curGenericParamIdx;
return false;
}
// Otherwise, there's nothing to do.
break;
}
return false;
};
// Walk over all of the requirements.
while (curReqIdx != numReqs) {
// "Catch up" by enumerating generic parameters up to this dependent type.
CanType depTy = reqs[curReqIdx].getFirstType()->getCanonicalType();
if (enumerateGenericParamsUpToDependentType(depTy)) return true;
// Utility to skip over non-conformance constraints that apply to this
// type.
auto skipNonConformanceConstraints = [&] {
while (curReqIdx != numReqs &&
reqs[curReqIdx].getKind() != RequirementKind::Conformance &&
reqs[curReqIdx].getFirstType()->getCanonicalType() == depTy) {
++curReqIdx;
}
};
// First, skip past any non-conformance constraints on this type.
skipNonConformanceConstraints();
// Collect all of the conformance constraints for this dependent type.
unsigned startIdx = curReqIdx;
unsigned endIdx = curReqIdx;
while (curReqIdx != numReqs &&
reqs[curReqIdx].getKind() == RequirementKind::Conformance &&
reqs[curReqIdx].getFirstType()->getCanonicalType() == depTy) {
++curReqIdx;
endIdx = curReqIdx;
}
// Skip any trailing non-conformance constraints.
skipNonConformanceConstraints();
// If there were any conformance constraints, or we have a generic
// parameter we can't skip, invoke the callback.
if ((startIdx != endIdx ||
(isa<GenericTypeParamType>(depTy) &&
!genericParamsAreConcrete[
GenericParamKey(cast<GenericTypeParamType>(depTy))
.findIndexIn(genericParams)])) &&
fn(depTy, reqs.slice(startIdx, endIdx-startIdx)))
return true;
}
// Catch up on any remaining generic parameters.
return enumerateGenericParamsUpToDependentType(CanType());
}
SubstitutionMap
GenericSignature::getSubstitutionMap(SubstitutionList subs) const {
SubstitutionMap result(const_cast<GenericSignature *>(this));
enumeratePairedRequirements(
[&](Type depTy, ArrayRef<Requirement> reqts) -> bool {
auto sub = subs.front();
subs = subs.slice(1);
auto canTy = depTy->getCanonicalType();
if (isa<SubstitutableType>(canTy))
result.addSubstitution(cast<SubstitutableType>(canTy),
sub.getReplacement());
assert(reqts.size() == sub.getConformances().size());
for (auto conformance : sub.getConformances())
result.addConformance(canTy, conformance);
return false;
});
assert(subs.empty() && "did not use all substitutions?!");
result.verify();
return result;
}
SubstitutionMap
GenericSignature::
getSubstitutionMap(TypeSubstitutionFn subs,
GenericSignature::LookupConformanceFn lookupConformance) const {
SubstitutionMap subMap(const_cast<GenericSignature *>(this));
// Enumerate all of the requirements that require substitution.
enumeratePairedRequirements([&](Type depTy, ArrayRef<Requirement> reqs) {
auto canTy = depTy->getCanonicalType();
// Compute the replacement type.
Type currentReplacement = depTy.subst(subs, lookupConformance,
SubstFlags::UseErrorType);
if (auto substTy = dyn_cast<SubstitutableType>(canTy))
subMap.addSubstitution(substTy, currentReplacement);
// Collect the conformances.
for (auto req: reqs) {
assert(req.getKind() == RequirementKind::Conformance);
auto protoType = req.getSecondType()->castTo<ProtocolType>();
if (auto conformance = lookupConformance(canTy,
currentReplacement,
protoType)) {
subMap.addConformance(canTy, *conformance);
}
}
return false;
});
subMap.verify();
return subMap;
}
void GenericSignature::
getSubstitutions(TypeSubstitutionFn subs,
GenericSignature::LookupConformanceFn lookupConformance,
SmallVectorImpl<Substitution> &result) const {
// Enumerate all of the requirements that require substitution.
enumeratePairedRequirements([&](Type depTy, ArrayRef<Requirement> reqs) {
auto &ctx = getASTContext();
// Compute the replacement type.
Type currentReplacement = depTy.subst(subs, lookupConformance);
if (!currentReplacement)
currentReplacement = ErrorType::get(depTy);
// Collect the conformances.
SmallVector<ProtocolConformanceRef, 4> currentConformances;
for (auto req: reqs) {
assert(req.getKind() == RequirementKind::Conformance);
auto protoType = req.getSecondType()->castTo<ProtocolType>();
if (auto conformance = lookupConformance(depTy->getCanonicalType(),
currentReplacement,
protoType)) {
currentConformances.push_back(*conformance);
} else {
if (!currentReplacement->hasError())
currentReplacement = ErrorType::get(currentReplacement);
currentConformances.push_back(
ProtocolConformanceRef(protoType->getDecl()));
}
}
// Add it to the final substitution list.
result.push_back({
currentReplacement,
ctx.AllocateCopy(currentConformances)
});
return false;
});
}
void GenericSignature::
getSubstitutions(const SubstitutionMap &subMap,
SmallVectorImpl<Substitution> &result) const {
getSubstitutions(QuerySubstitutionMap{subMap},
LookUpConformanceInSubstitutionMap(subMap),
result);
}
bool GenericSignature::requiresClass(Type type, ModuleDecl &mod) {
if (!type->isTypeParameter()) return false;
auto &builder = *getGenericSignatureBuilder(mod);
auto pa = builder.resolveArchetype(type);
if (!pa) return false;
pa = pa->getRepresentative();
// If this type was mapped to a concrete type, then there is no
// requirement.
if (pa->isConcreteType()) return false;
// If there is a superclass bound, then obviously it must be a class.
if (pa->getSuperclass()) return true;
// If any of the protocols are class-bound, then it must be a class.
for (auto proto : pa->getConformsTo()) {
if (proto->requiresClass()) return true;
}
return false;
}
/// Determine the superclass bound on the given dependent type.
Type GenericSignature::getSuperclassBound(Type type, ModuleDecl &mod) {
if (!type->isTypeParameter()) return nullptr;
auto &builder = *getGenericSignatureBuilder(mod);
auto pa = builder.resolveArchetype(type);
if (!pa) return nullptr;
pa = pa->getRepresentative();
// If this type was mapped to a concrete type, then there is no
// requirement.
if (pa->isConcreteType()) return nullptr;
// Retrieve the superclass bound.
return pa->getSuperclass();
}
/// Determine the set of protocols to which the given dependent type
/// must conform.
SmallVector<ProtocolDecl *, 2> GenericSignature::getConformsTo(Type type,
ModuleDecl &mod) {
if (!type->isTypeParameter()) return { };
auto &builder = *getGenericSignatureBuilder(mod);
auto pa = builder.resolveArchetype(type);
if (!pa) return { };
pa = pa->getRepresentative();
// If this type was mapped to a concrete type, then there are no
// requirements.
if (pa->isConcreteType()) return { };
// Retrieve the protocols to which this type conforms.
SmallVector<ProtocolDecl *, 2> result;
for (auto proto : pa->getConformsTo())
result.push_back(proto);
// Canonicalize the resulting set of protocols.
ProtocolType::canonicalizeProtocols(result);
return result;
}
bool GenericSignature::conformsToProtocol(Type type, ProtocolDecl *proto,
ModuleDecl &mod) {
// FIXME: Deal with concrete conformances here?
if (!type->isTypeParameter()) return false;
auto &builder = *getGenericSignatureBuilder(mod);
auto pa = builder.resolveArchetype(type);
if (!pa) return false;
pa = pa->getRepresentative();
// FIXME: Deal with concrete conformances here?
if (pa->isConcreteType()) return false;
// Check whether the representative conforms to this protocol.
if (auto equivClass = pa->getEquivalenceClassIfPresent())
if (equivClass->conformsTo.count(proto) > 0)
return true;
return false;
}
/// Determine whether the given dependent type is equal to a concrete type.
bool GenericSignature::isConcreteType(Type type, ModuleDecl &mod) {
return bool(getConcreteType(type, mod));
}
/// Return the concrete type that the given dependent type is constrained to,
/// or the null Type if it is not the subject of a concrete same-type
/// constraint.
Type GenericSignature::getConcreteType(Type type, ModuleDecl &mod) {
if (!type->isTypeParameter()) return Type();
auto &builder = *getGenericSignatureBuilder(mod);
auto pa = builder.resolveArchetype(type);
if (!pa) return Type();
pa = pa->getRepresentative();
if (!pa->isConcreteType()) return Type();
return pa->getConcreteType();
}
LayoutConstraint GenericSignature::getLayoutConstraint(Type type,
ModuleDecl &mod) {
if (!type->isTypeParameter()) return LayoutConstraint();
auto &builder = *getGenericSignatureBuilder(mod);
auto pa = builder.resolveArchetype(type);
if (!pa) return LayoutConstraint();
pa = pa->getRepresentative();
return pa->getLayout();
}
bool GenericSignature::areSameTypeParameterInContext(Type type1, Type type2,
ModuleDecl &mod) {
assert(type1->isTypeParameter());
assert(type2->isTypeParameter());
if (type1.getPointer() == type2.getPointer())
return true;
auto &builder = *getGenericSignatureBuilder(mod);
auto pa1 = builder.resolveArchetype(type1);
assert(pa1 && "not a valid dependent type of this signature?");
pa1 = pa1->getRepresentative();
assert(!pa1->isConcreteType());
auto pa2 = builder.resolveArchetype(type2);
assert(pa2 && "not a valid dependent type of this signature?");
pa2 = pa2->getRepresentative();
assert(!pa2->isConcreteType());
return pa1 == pa2;
}
bool GenericSignature::isCanonicalTypeInContext(Type type, ModuleDecl &mod) {
// If the type isn't independently canonical, it's certainly not canonical
// in this context.
if (!type->isCanonical())
return false;
// All the contextual canonicality rules apply to type parameters, so if the
// type doesn't involve any type parameters, it's already canonical.
if (!type->hasTypeParameter())
return true;
auto &builder = *getGenericSignatureBuilder(mod);
return isCanonicalTypeInContext(type, builder);
}
bool GenericSignature::isCanonicalTypeInContext(Type type,
GenericSignatureBuilder &builder) {
// If the type isn't independently canonical, it's certainly not canonical
// in this context.
if (!type->isCanonical())
return false;
// All the contextual canonicality rules apply to type parameters, so if the
// type doesn't involve any type parameters, it's already canonical.
if (!type->hasTypeParameter())
return true;
// Look for non-canonical type parameters.
return !type.findIf([&](Type component) -> bool {
if (!component->isTypeParameter()) return false;
auto pa = builder.resolveArchetype(component);
if (!pa) return false;
auto rep = pa->getArchetypeAnchor(builder);
return (rep->isConcreteType() || pa != rep);
});
}
CanType GenericSignature::getCanonicalTypeInContext(Type type,
GenericSignatureBuilder &builder) {
type = type->getCanonicalType();
// All the contextual canonicality rules apply to type parameters, so if the
// type doesn't involve any type parameters, it's already canonical.
if (!type->hasTypeParameter())
return CanType(type);
// Replace non-canonical type parameters.
type = type.transformRec([&](TypeBase *component) -> Optional<Type> {
if (!isa<GenericTypeParamType>(component) &&
!isa<DependentMemberType>(component))
return None;
// Resolve the potential archetype. This can be null in nested generic
// types, which we can't immediately canonicalize.
auto pa = builder.resolveArchetype(Type(component));
if (!pa) return None;
auto rep = pa->getArchetypeAnchor(builder);
if (rep->isConcreteType()) {
return getCanonicalTypeInContext(rep->getConcreteType(), builder);
}
return rep->getDependentType(getGenericParams(), /*allowUnresolved*/ false);
});
auto result = type->getCanonicalType();
assert(isCanonicalTypeInContext(result, builder));
return result;
}
CanType GenericSignature::getCanonicalTypeInContext(Type type,
ModuleDecl &mod) {
type = type->getCanonicalType();
// All the contextual canonicality rules apply to type parameters, so if the
// type doesn't involve any type parameters, it's already canonical.
if (!type->hasTypeParameter())
return CanType(type);
auto &builder = *getGenericSignatureBuilder(mod);
return getCanonicalTypeInContext(type, builder);
}
GenericEnvironment *CanGenericSignature::getGenericEnvironment(
ModuleDecl &module) const {
// generic signature builders are stored on the ASTContext.
return module.getASTContext().getOrCreateCanonicalGenericEnvironment(
module.getASTContext().getOrCreateGenericSignatureBuilder(*this, &module),
module);
}
/// Remove all of the associated type declarations from the given type
/// parameter, producing \c DependentMemberTypes with names alone.
static Type eraseAssociatedTypes(Type type) {
if (auto depMemTy = type->getAs<DependentMemberType>())
return DependentMemberType::get(eraseAssociatedTypes(depMemTy->getBase()),
depMemTy->getName());
return type;
}
namespace {
typedef GenericSignatureBuilder::RequirementSource RequirementSource;
template<typename T>
using GSBConstraint = GenericSignatureBuilder::Constraint<T>;
}
/// Retrieve the best requirement source from the list
static const RequirementSource *
getBestRequirementSource(ArrayRef<GSBConstraint<ProtocolDecl *>> constraints) {
const RequirementSource *bestSource = nullptr;
for (const auto &constraint : constraints) {
auto source = constraint.source;
if (!bestSource || source->compare(bestSource) < 0)
bestSource = source;
}
return bestSource;
}
ConformanceAccessPath GenericSignature::getConformanceAccessPath(
Type type,
ProtocolDecl *protocol,
ModuleDecl &mod) {
assert(type->isTypeParameter() && "not a type parameter");
// Resolve this type to a potential archetype.
auto &builder = *getGenericSignatureBuilder(mod);
auto pa = builder.resolveArchetype(type);
auto equivClass = pa->getOrCreateEquivalenceClass();
// Dig out the conformance of this type to the given protocol, because we
// want its requirement source.
auto conforms = equivClass->conformsTo.find(protocol);
assert(conforms != equivClass->conformsTo.end());
// Follow the requirement source to form the conformance access path.
typedef GenericSignatureBuilder::RequirementSource RequirementSource;
ConformanceAccessPath path;
#ifndef NDEBUG
// Local function to determine whether there is a conformance of the given
// subject type to the given protocol within the given generic signature's
// explicit requirements.
auto hasConformanceInSignature = [&](const GenericSignature *genericSig,
Type subjectType,
ProtocolDecl *proto) -> bool {
// Make sure this requirement exists in the requirement signature.
for (const auto& req: genericSig->getRequirements()) {
if (req.getKind() == RequirementKind::Conformance &&
req.getFirstType()->isEqual(subjectType) &&
req.getSecondType()->castTo<ProtocolType>()->getDecl()
== proto) {
return true;
}
}
return false;
};
#endif
// Local function to construct the conformance access path from the
// requirement.
std::function<void(GenericSignature *, const RequirementSource *,
ProtocolDecl *, Type)> buildPath;
buildPath = [&](GenericSignature *sig, const RequirementSource *source,
ProtocolDecl *conformingProto, Type rootType) {
// Each protocol requirement is a step along the path.
if (source->kind == RequirementSource::ProtocolRequirement) {
// Follow the rest of the path to derive the conformance into which
// this particular protocol requirement step would look.
auto inProtocol = source->getProtocolDecl();
buildPath(sig, source->parent, inProtocol, rootType);
assert(path.path.back().second == inProtocol &&
"path produces incorrect conformance");
// If this step was computed via the requirement signature, add it
// directly.
if (source->usesRequirementSignature) {
// Add this step along the path, which involves looking for the
// conformance we want (\c conformingProto) within the protocol
// described by this source.
// Canonicalize the subject type within the protocol's generic
// signature.
Type subjectType = source->getStoredType();
subjectType = inProtocol->getGenericSignature()
->getCanonicalTypeInContext(subjectType,
*inProtocol->getParentModule());
assert(hasConformanceInSignature(inProtocol->getRequirementSignature(),
subjectType, conformingProto) &&
"missing explicit conformance in requirement signature");
// Record this step.
path.path.push_back({subjectType, conformingProto});
return;
}
// Canonicalize this step with respect to the requirement signature.
if (!inProtocol->isRequirementSignatureComputed()) {
inProtocol->computeRequirementSignature();
assert(inProtocol->isRequirementSignatureComputed() &&
"missing signature");
}
// Get a generic signature builder for the requirement signature. This has
// the requirement we need.
auto reqSig = inProtocol->getRequirementSignature();
auto &reqSigBuilder = *reqSig->getGenericSignatureBuilder(
*inProtocol->getModuleContext());
// Retrieve the stored type, but erase all of the specific associated
// type declarations; we don't want any details of the enclosing context
// to sneak in here.
Type storedType = eraseAssociatedTypes(source->getStoredType());
// Dig out the potential archetype for this stored type.
auto pa = reqSigBuilder.resolveArchetype(storedType);
auto equivClass = pa->getOrCreateEquivalenceClass();
// Find the conformance of this potential archetype to the protocol in
// question.
auto conforms = equivClass->conformsTo.find(conformingProto);
assert(conforms != equivClass->conformsTo.end());
// Compute the root type, canonicalizing it w.r.t. the protocol context.
auto inProtoSig = inProtocol->getGenericSignature();
auto conformsSource = getBestRequirementSource(conforms->second);
Type localRootType = conformsSource->getRootPotentialArchetype()
->getDependentType(inProtoSig->getGenericParams(),
/*allowUnresolved*/true);
localRootType = inProtoSig->getCanonicalTypeInContext(
localRootType,
*inProtocol->getModuleContext());
// Build the path according to the requirement signature.
buildPath(reqSig, conformsSource, conformingProto, localRootType);
// We're done.
return;
}
// If we still have a parent, keep going.
if (source->parent) {
buildPath(sig, source->parent, conformingProto, rootType);
return;
}
// We are at an explicit or inferred requirement.
assert(source->kind == RequirementSource::Explicit ||
source->kind == RequirementSource::Inferred);
// Skip trivial path elements. These occur when querying a requirement
// signature.
if (!path.path.empty() && conformingProto == path.path.back().second &&
rootType->isEqual(conformingProto->getSelfInterfaceType()))
return;
assert(hasConformanceInSignature(sig, rootType, conformingProto) &&
"missing explicit conformance in signature");
// Add the root of the path, which starts at this explicit requirement.
path.path.push_back({rootType, conformingProto});
};
// Canonicalize the root type.
auto source = getBestRequirementSource(conforms->second);
auto subjectPA = source->getRootPotentialArchetype();
subjectPA = subjectPA->getArchetypeAnchor(*subjectPA->getBuilder());
Type rootType = subjectPA->getDependentType(getGenericParams(),
/*allowUnresolved=*/false);
// Build the path.
buildPath(this, source, protocol, rootType);
// Return the path; we're done!
return path;
}
unsigned GenericParamKey::findIndexIn(
llvm::ArrayRef<GenericTypeParamType *> genericParams) const {
// For depth 0, we have random access. We perform the extra checking so that
// we can return
if (Depth == 0 && Index < genericParams.size() &&
genericParams[Index] == *this)
return Index;
// At other depths, perform a binary search.
unsigned result =
std::lower_bound(genericParams.begin(), genericParams.end(), *this,
Ordering())
- genericParams.begin();
if (result < genericParams.size() && genericParams[result] == *this)
return result;
// We didn't find the parameter we were looking for.
return genericParams.size();
}