Google Git
Sign in
fuchsia / third_party / swift / eaefd7194696865f32ca2938abc83f5dfbc9a66f / . / lib / Sema / DerivedConformanceEquatableHashable.cpp
blob: c888a5ce8445a438073e2bd2f2bbecfc0136903c [file] [log] [blame]
//===--- DerivedConformanceEquatableHashable.cpp - Derived Equatable & co -===//
//
// 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 implicit derivation of the Equatable and Hashable
// protocols. (Comparable is similar enough in spirit that it would make
// sense to live here too when we implement its derivation.)
//
//===----------------------------------------------------------------------===//
#include "TypeChecker.h"
#include "swift/AST/Decl.h"
#include "swift/AST/Stmt.h"
#include "swift/AST/Expr.h"
#include "swift/AST/Module.h"
#include "swift/AST/Pattern.h"
#include "swift/AST/ParameterList.h"
#include "swift/AST/ProtocolConformance.h"
#include "swift/AST/Types.h"
#include "llvm/ADT/APInt.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/Support/raw_ostream.h"
#include "DerivedConformances.h"
using namespace swift;
enum NonconformingMemberKind {
AssociatedValue,
StoredProperty
};
/// Returns the ParamDecl for each associated value of the given enum whose type
/// does not conform to a protocol
/// \p theEnum The enum whose elements and associated values should be checked.
/// \p protocol The protocol being requested.
/// \return The ParamDecl of each associated value whose type does not conform.
static SmallVector<ParamDecl *, 3>
associatedValuesNotConformingToProtocol(DeclContext *DC, EnumDecl *theEnum,
ProtocolDecl *protocol) {
SmallVector<ParamDecl *, 3> nonconformingAssociatedValues;
for (auto elt : theEnum->getAllElements()) {
// FIXME: Remove this once getInterfaceType() on a ParamDecl works.
(void) elt->getInterfaceType();
auto PL = elt->getParameterList();
if (!PL)
continue;
for (auto param : *PL) {
auto type = param->getInterfaceType();
if (!TypeChecker::conformsToProtocol(DC->mapTypeIntoContext(type),
protocol, DC, None)) {
nonconformingAssociatedValues.push_back(param);
}
}
}
return nonconformingAssociatedValues;
}
/// Returns true if, for every element of the given enum, it either has no
/// associated values or all of them conform to a protocol.
/// \p theEnum The enum whose elements and associated values should be checked.
/// \p protocol The protocol being requested.
/// \return True if all associated values of all elements of the enum conform.
static bool allAssociatedValuesConformToProtocol(DeclContext *DC,
EnumDecl *theEnum,
ProtocolDecl *protocol) {
return associatedValuesNotConformingToProtocol(DC, theEnum, protocol).empty();
}
/// Returns the VarDecl of each stored property in the given struct whose type
/// does not conform to a protocol.
/// \p theStruct The struct whose stored properties should be checked.
/// \p protocol The protocol being requested.
/// \return The VarDecl of each stored property whose type does not conform.
static SmallVector<VarDecl *, 3>
storedPropertiesNotConformingToProtocol(DeclContext *DC, StructDecl *theStruct,
ProtocolDecl *protocol) {
auto storedProperties = theStruct->getStoredProperties();
SmallVector<VarDecl *, 3> nonconformingProperties;
for (auto propertyDecl : storedProperties) {
if (!propertyDecl->isUserAccessible())
continue;
auto type = propertyDecl->getValueInterfaceType();
if (!type)
nonconformingProperties.push_back(propertyDecl);
if (!TypeChecker::conformsToProtocol(DC->mapTypeIntoContext(type), protocol,
DC, None)) {
nonconformingProperties.push_back(propertyDecl);
}
}
return nonconformingProperties;
}
/// Returns true if every stored property in the given struct conforms to the
/// protocol (or, vacuously, if it has no stored properties).
/// \p theStruct The struct whose stored properties should be checked.
/// \p protocol The protocol being requested.
/// \return True if all stored properties of the struct conform.
static bool allStoredPropertiesConformToProtocol(DeclContext *DC,
StructDecl *theStruct,
ProtocolDecl *protocol) {
return storedPropertiesNotConformingToProtocol(DC, theStruct, protocol)
.empty();
}
/// Common preconditions for Equatable and Hashable.
static bool canDeriveConformance(DeclContext *DC,
NominalTypeDecl *target,
ProtocolDecl *protocol) {
// The type must be an enum or a struct.
if (auto enumDecl = dyn_cast<EnumDecl>(target)) {
// The cases must not have associated values, or all associated values must
// conform to the protocol.
return allAssociatedValuesConformToProtocol(DC, enumDecl, protocol);
}
if (auto structDecl = dyn_cast<StructDecl>(target)) {
// All stored properties of the struct must conform to the protocol.
return allStoredPropertiesConformToProtocol(DC, structDecl, protocol);
}
return false;
}
/// Diagnose failed conformance synthesis caused by a member type not conforming
/// to the same protocol
void diagnoseFailedDerivation(DeclContext *DC, NominalTypeDecl *nominal,
ProtocolDecl *protocol) {
ASTContext &ctx = DC->getASTContext();
if (auto *enumDecl = dyn_cast<EnumDecl>(nominal)) {
auto nonconformingAssociatedTypes =
associatedValuesNotConformingToProtocol(DC, enumDecl, protocol);
for (auto *typeToDiagnose : nonconformingAssociatedTypes) {
ctx.Diags.diagnose(
typeToDiagnose->getTypeLoc().getLoc(),
diag::missing_member_type_conformance_prevents_synthesis,
NonconformingMemberKind::AssociatedValue,
typeToDiagnose->getInterfaceType(), protocol->getDeclaredType(),
nominal->getDeclaredInterfaceType());
}
}
if (auto *structDecl = dyn_cast<StructDecl>(nominal)) {
auto nonconformingStoredProperties =
storedPropertiesNotConformingToProtocol(DC, structDecl, protocol);
for (auto *propertyToDiagnose : nonconformingStoredProperties) {
ctx.Diags.diagnose(
propertyToDiagnose->getLoc(),
diag::missing_member_type_conformance_prevents_synthesis,
NonconformingMemberKind::StoredProperty,
propertyToDiagnose->getInterfaceType(), protocol->getDeclaredType(),
nominal->getDeclaredInterfaceType());
}
}
}
/// Creates a named variable based on a prefix character and a numeric index.
/// \p prefixChar The prefix character for the variable's name.
/// \p index The numeric index to append to the variable's name.
/// \p type The type of the variable.
/// \p varContext The context of the variable.
/// \return A VarDecl named with the prefix and number.
static VarDecl *indexedVarDecl(char prefixChar, int index, Type type,
DeclContext *varContext) {
ASTContext &C = varContext->getASTContext();
llvm::SmallString<8> indexVal;
indexVal.append(1, prefixChar);
APInt(32, index).toString(indexVal, 10, /*signed*/ false);
auto indexStr = C.AllocateCopy(indexVal);
auto indexStrRef = StringRef(indexStr.data(), indexStr.size());
auto varDecl = new (C) VarDecl(/*IsStatic*/false, VarDecl::Introducer::Let,
/*IsCaptureList*/true, SourceLoc(),
C.getIdentifier(indexStrRef),
varContext);
varDecl->setType(type);
varDecl->setHasNonPatternBindingInit(true);
return varDecl;
}
/// Returns the pattern used to match and bind the associated values (if any) of
/// an enum case.
/// \p enumElementDecl The enum element to match.
/// \p varPrefix The prefix character for variable names (e.g., a0, a1, ...).
/// \p varContext The context into which payload variables should be declared.
/// \p boundVars The array to which the pattern's variables will be appended.
static Pattern*
enumElementPayloadSubpattern(EnumElementDecl *enumElementDecl,
char varPrefix, DeclContext *varContext,
SmallVectorImpl<VarDecl*> &boundVars) {
auto parentDC = enumElementDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
// No arguments, so no subpattern to match.
if (!enumElementDecl->hasAssociatedValues())
return nullptr;
auto argumentType = enumElementDecl->getArgumentInterfaceType();
if (auto tupleType = argumentType->getAs<TupleType>()) {
// Either multiple (labeled or unlabeled) arguments, or one labeled
// argument. Return a tuple pattern that matches the enum element in arity,
// types, and labels. For example:
// case a(x: Int) => (x: let a0)
// case b(Int, String) => (let a0, let a1)
SmallVector<TuplePatternElt, 3> elementPatterns;
int index = 0;
for (auto tupleElement : tupleType->getElements()) {
auto payloadVar = indexedVarDecl(varPrefix, index++,
tupleElement.getType(), varContext);
boundVars.push_back(payloadVar);
auto namedPattern = new (C) NamedPattern(payloadVar);
namedPattern->setImplicit();
auto letPattern = new (C) VarPattern(SourceLoc(), /*isLet*/ true,
namedPattern);
elementPatterns.push_back(TuplePatternElt(tupleElement.getName(),
SourceLoc(), letPattern));
}
auto pat = TuplePattern::create(C, SourceLoc(), elementPatterns,
SourceLoc());
pat->setImplicit();
return pat;
}
// Otherwise, a one-argument unlabeled payload. Return a paren pattern whose
// underlying type is the same as the payload. For example:
// case a(Int) => (let a0)
auto underlyingType = argumentType->getWithoutParens();
auto payloadVar = indexedVarDecl(varPrefix, 0, underlyingType, varContext);
boundVars.push_back(payloadVar);
auto namedPattern = new (C) NamedPattern(payloadVar);
namedPattern->setImplicit();
auto letPattern = new (C) VarPattern(SourceLoc(), /*isLet*/ true,
namedPattern);
auto pat = new (C) ParenPattern(SourceLoc(), letPattern, SourceLoc());
pat->setImplicit();
return pat;
}
/// Build a type-checked integer literal.
static IntegerLiteralExpr *buildIntegerLiteral(ASTContext &C, unsigned index) {
Type intType = C.getIntDecl()->getDeclaredType();
auto literal = IntegerLiteralExpr::createFromUnsigned(C, index);
literal->setType(intType);
literal->setBuiltinInitializer(C.getIntBuiltinInitDecl(C.getIntDecl()));
return literal;
}
/// Create AST statements which convert from an enum to an Int with a switch.
/// \p stmts The generated statements are appended to this vector.
/// \p parentDC Either an extension or the enum itself.
/// \p enumDecl The enum declaration.
/// \p enumVarDecl The enum input variable.
/// \p funcDecl The parent function.
/// \p indexName The name of the output variable.
/// \return A DeclRefExpr of the output variable (of type Int).
static DeclRefExpr *convertEnumToIndex(SmallVectorImpl<ASTNode> &stmts,
DeclContext *parentDC,
EnumDecl *enumDecl,
VarDecl *enumVarDecl,
AbstractFunctionDecl *funcDecl,
const char *indexName) {
ASTContext &C = enumDecl->getASTContext();
Type enumType = enumVarDecl->getType();
Type intType = C.getIntDecl()->getDeclaredType();
auto indexVar = new (C) VarDecl(/*IsStatic*/false, VarDecl::Introducer::Var,
/*IsCaptureList*/false, SourceLoc(),
C.getIdentifier(indexName),
funcDecl);
indexVar->setInterfaceType(intType);
indexVar->setImplicit();
// generate: var indexVar
Pattern *indexPat = new (C) NamedPattern(indexVar, /*implicit*/ true);
indexPat->setType(intType);
indexPat = TypedPattern::createImplicit(C, indexPat, intType);
indexPat->setType(intType);
auto *indexBind = PatternBindingDecl::createImplicit(
C, StaticSpellingKind::None, indexPat, /*InitExpr*/ nullptr, funcDecl);
unsigned index = 0;
SmallVector<ASTNode, 4> cases;
for (auto elt : enumDecl->getAllElements()) {
// generate: case .<Case>:
auto pat = new (C) EnumElementPattern(TypeLoc::withoutLoc(enumType),
SourceLoc(), SourceLoc(),
Identifier(), elt, nullptr);
pat->setImplicit();
pat->setType(enumType);
auto labelItem = CaseLabelItem(pat);
// generate: indexVar = <index>
auto indexExpr = buildIntegerLiteral(C, index++);
auto indexRef = new (C) DeclRefExpr(indexVar, DeclNameLoc(),
/*implicit*/true,
AccessSemantics::Ordinary,
LValueType::get(intType));
auto assignExpr = new (C) AssignExpr(indexRef, SourceLoc(),
indexExpr, /*implicit*/ true);
assignExpr->setType(TupleType::getEmpty(C));
auto body = BraceStmt::create(C, SourceLoc(), ASTNode(assignExpr),
SourceLoc());
cases.push_back(CaseStmt::create(C, SourceLoc(), labelItem, SourceLoc(),
SourceLoc(), body,
/*case body vardecls*/ None));
}
// generate: switch enumVar { }
auto enumRef = new (C) DeclRefExpr(enumVarDecl, DeclNameLoc(),
/*implicit*/true,
AccessSemantics::Ordinary,
enumVarDecl->getType());
auto switchStmt = SwitchStmt::create(LabeledStmtInfo(), SourceLoc(), enumRef,
SourceLoc(), cases, SourceLoc(), C);
stmts.push_back(indexBind);
stmts.push_back(switchStmt);
return new (C) DeclRefExpr(indexVar, DeclNameLoc(), /*implicit*/ true,
AccessSemantics::Ordinary, intType);
}
/// Returns a generated guard statement that checks whether the given lhs and
/// rhs expressions are equal. If not equal, the else block for the guard
/// returns false.
/// \p C The AST context.
/// \p lhsExpr The first expression to compare for equality.
/// \p rhsExpr The second expression to compare for equality.
static GuardStmt *returnIfNotEqualGuard(ASTContext &C,
Expr *lhsExpr,
Expr *rhsExpr) {
SmallVector<StmtConditionElement, 1> conditions;
SmallVector<ASTNode, 1> statements;
// First, generate the statement for the body of the guard.
// return false
auto falseExpr = new (C) BooleanLiteralExpr(false, SourceLoc(),
/*Implicit*/true);
auto returnStmt = new (C) ReturnStmt(SourceLoc(), falseExpr);
statements.emplace_back(ASTNode(returnStmt));
// Next, generate the condition being checked.
// lhs == rhs
auto cmpFuncExpr = new (C) UnresolvedDeclRefExpr(
DeclName(C.getIdentifier("==")), DeclRefKind::BinaryOperator,
DeclNameLoc());
auto cmpArgsTuple = TupleExpr::create(C, SourceLoc(),
{ lhsExpr, rhsExpr },
{ }, { }, SourceLoc(),
/*HasTrailingClosure*/false,
/*Implicit*/true);
auto cmpExpr = new (C) BinaryExpr(cmpFuncExpr, cmpArgsTuple,
/*Implicit*/true);
conditions.emplace_back(cmpExpr);
// Build and return the complete guard statement.
// guard lhs == rhs else { return false }
auto body = BraceStmt::create(C, SourceLoc(), statements, SourceLoc());
return new (C) GuardStmt(SourceLoc(), C.AllocateCopy(conditions), body);
}
static std::pair<BraceStmt *, bool>
deriveBodyEquatable_enum_uninhabited_eq(AbstractFunctionDecl *eqDecl, void *) {
auto parentDC = eqDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
auto args = eqDecl->getParameters();
auto aParam = args->get(0);
auto bParam = args->get(1);
assert(!cast<EnumDecl>(aParam->getType()->getAnyNominal())->hasCases());
SmallVector<ASTNode, 1> statements;
SmallVector<ASTNode, 0> cases;
// switch (a, b) { }
auto aRef = new (C) DeclRefExpr(aParam, DeclNameLoc(), /*implicit*/ true,
AccessSemantics::Ordinary,
aParam->getType());
auto bRef = new (C) DeclRefExpr(bParam, DeclNameLoc(), /*implicit*/ true,
AccessSemantics::Ordinary,
bParam->getType());
TupleTypeElt abTupleElts[2] = { aParam->getType(), bParam->getType() };
auto abExpr = TupleExpr::create(C, SourceLoc(), {aRef, bRef}, {}, {},
SourceLoc(), /*HasTrailingClosure*/ false,
/*implicit*/ true,
TupleType::get(abTupleElts, C));
auto switchStmt = SwitchStmt::create(LabeledStmtInfo(), SourceLoc(), abExpr,
SourceLoc(), cases, SourceLoc(), C);
statements.push_back(switchStmt);
auto body = BraceStmt::create(C, SourceLoc(), statements, SourceLoc());
return { body, /*isTypeChecked=*/true };
}
/// Derive the body for an '==' operator for an enum that has no associated
/// values. This generates code that converts each value to its integer ordinal
/// and compares them, which produces an optimal single icmp instruction.
static std::pair<BraceStmt *, bool>
deriveBodyEquatable_enum_noAssociatedValues_eq(AbstractFunctionDecl *eqDecl,
void *) {
auto parentDC = eqDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
auto args = eqDecl->getParameters();
auto aParam = args->get(0);
auto bParam = args->get(1);
auto enumDecl = cast<EnumDecl>(aParam->getType()->getAnyNominal());
// Generate the conversion from the enums to integer indices.
SmallVector<ASTNode, 6> statements;
DeclRefExpr *aIndex = convertEnumToIndex(statements, parentDC, enumDecl,
aParam, eqDecl, "index_a");
DeclRefExpr *bIndex = convertEnumToIndex(statements, parentDC, enumDecl,
bParam, eqDecl, "index_b");
// Generate the compare of the indices.
FuncDecl *cmpFunc = C.getEqualIntDecl();
assert(cmpFunc && "should have a == for int as we already checked for it");
auto fnType = cmpFunc->getInterfaceType()->castTo<FunctionType>();
Expr *cmpFuncExpr;
if (cmpFunc->getDeclContext()->isTypeContext()) {
auto contextTy = cmpFunc->getDeclContext()->getSelfInterfaceType();
Expr *base = TypeExpr::createImplicitHack(SourceLoc(), contextTy, C);
Expr *ref = new (C) DeclRefExpr(cmpFunc, DeclNameLoc(), /*Implicit*/ true,
AccessSemantics::Ordinary, fnType);
fnType = fnType->getResult()->castTo<FunctionType>();
cmpFuncExpr = new (C) DotSyntaxCallExpr(ref, SourceLoc(), base, fnType);
cmpFuncExpr->setImplicit();
} else {
cmpFuncExpr = new (C) DeclRefExpr(cmpFunc, DeclNameLoc(),
/*implicit*/ true,
AccessSemantics::Ordinary,
fnType);
}
TupleTypeElt abTupleElts[2] = { aIndex->getType(), bIndex->getType() };
TupleExpr *abTuple = TupleExpr::create(C, SourceLoc(), { aIndex, bIndex },
{ }, { }, SourceLoc(),
/*HasTrailingClosure*/ false,
/*Implicit*/ true,
TupleType::get(abTupleElts, C));
auto *cmpExpr = new (C) BinaryExpr(
cmpFuncExpr, abTuple, /*implicit*/ true,
fnType->castTo<FunctionType>()->getResult());
statements.push_back(new (C) ReturnStmt(SourceLoc(), cmpExpr));
BraceStmt *body = BraceStmt::create(C, SourceLoc(), statements, SourceLoc());
return { body, /*isTypeChecked=*/true };
}
/// Derive the body for an '==' operator for an enum where at least one of the
/// cases has associated values.
static std::pair<BraceStmt *, bool>
deriveBodyEquatable_enum_hasAssociatedValues_eq(AbstractFunctionDecl *eqDecl,
void *) {
auto parentDC = eqDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
auto args = eqDecl->getParameters();
auto aParam = args->get(0);
auto bParam = args->get(1);
Type enumType = aParam->getType();
auto enumDecl = cast<EnumDecl>(aParam->getType()->getAnyNominal());
SmallVector<ASTNode, 6> statements;
SmallVector<ASTNode, 4> cases;
unsigned elementCount = 0;
// For each enum element, generate a case statement matching a pair containing
// the same case, binding variables for the left- and right-hand associated
// values.
for (auto elt : enumDecl->getAllElements()) {
elementCount++;
// .<elt>(let l0, let l1, ...)
SmallVector<VarDecl*, 3> lhsPayloadVars;
auto lhsSubpattern = enumElementPayloadSubpattern(elt, 'l', eqDecl,
lhsPayloadVars);
auto lhsElemPat = new (C) EnumElementPattern(TypeLoc::withoutLoc(enumType),
SourceLoc(), SourceLoc(),
Identifier(), elt,
lhsSubpattern);
lhsElemPat->setImplicit();
// .<elt>(let r0, let r1, ...)
SmallVector<VarDecl*, 3> rhsPayloadVars;
auto rhsSubpattern = enumElementPayloadSubpattern(elt, 'r', eqDecl,
rhsPayloadVars);
auto rhsElemPat = new (C) EnumElementPattern(TypeLoc::withoutLoc(enumType),
SourceLoc(), SourceLoc(),
Identifier(), elt,
rhsSubpattern);
rhsElemPat->setImplicit();
auto hasBoundDecls = !lhsPayloadVars.empty();
Optional<MutableArrayRef<VarDecl *>> caseBodyVarDecls;
if (hasBoundDecls) {
// We allocated a direct copy of our lhs var decls for the case
// body.
auto copy = C.Allocate<VarDecl *>(lhsPayloadVars.size());
for (unsigned i : indices(lhsPayloadVars)) {
auto *vOld = lhsPayloadVars[i];
auto *vNew = new (C) VarDecl(
/*IsStatic*/ false, vOld->getIntroducer(), false /*IsCaptureList*/,
vOld->getNameLoc(), vOld->getName(), vOld->getDeclContext());
vNew->setHasNonPatternBindingInit();
vNew->setImplicit();
copy[i] = vNew;
}
caseBodyVarDecls.emplace(copy);
}
// case (.<elt>(let l0, let l1, ...), .<elt>(let r0, let r1, ...))
auto caseTuplePattern = TuplePattern::create(C, SourceLoc(), {
TuplePatternElt(lhsElemPat), TuplePatternElt(rhsElemPat) },
SourceLoc());
caseTuplePattern->setImplicit();
auto labelItem = CaseLabelItem(caseTuplePattern);
// Generate a guard statement for each associated value in the payload,
// breaking out early if any pair is unequal. (This is done to avoid
// constructing long lists of autoclosure-wrapped conditions connected by
// &&, which the type checker has more difficulty processing.)
SmallVector<ASTNode, 6> statementsInCase;
for (size_t varIdx = 0; varIdx < lhsPayloadVars.size(); varIdx++) {
auto lhsVar = lhsPayloadVars[varIdx];
auto lhsExpr = new (C) DeclRefExpr(lhsVar, DeclNameLoc(),
/*implicit*/true);
auto rhsVar = rhsPayloadVars[varIdx];
auto rhsExpr = new (C) DeclRefExpr(rhsVar, DeclNameLoc(),
/*Implicit*/true);
auto guardStmt = returnIfNotEqualGuard(C, lhsExpr, rhsExpr);
statementsInCase.emplace_back(guardStmt);
}
// If none of the guard statements caused an early exit, then all the pairs
// were true.
// return true
auto trueExpr = new (C) BooleanLiteralExpr(true, SourceLoc(),
/*Implicit*/true);
auto returnStmt = new (C) ReturnStmt(SourceLoc(), trueExpr);
statementsInCase.push_back(returnStmt);
auto body = BraceStmt::create(C, SourceLoc(), statementsInCase,
SourceLoc());
cases.push_back(CaseStmt::create(C, SourceLoc(), labelItem, SourceLoc(),
SourceLoc(), body, caseBodyVarDecls));
}
// default: result = false
//
// We only generate this if the enum has more than one case. If it has exactly
// one case, then that single case statement is already exhaustive.
if (elementCount > 1) {
auto defaultPattern = new (C) AnyPattern(SourceLoc());
defaultPattern->setImplicit();
auto defaultItem = CaseLabelItem::getDefault(defaultPattern);
auto falseExpr = new (C) BooleanLiteralExpr(false, SourceLoc(),
/*implicit*/ true);
auto returnStmt = new (C) ReturnStmt(SourceLoc(), falseExpr);
auto body = BraceStmt::create(C, SourceLoc(), ASTNode(returnStmt),
SourceLoc());
cases.push_back(CaseStmt::create(C, SourceLoc(), defaultItem, SourceLoc(),
SourceLoc(), body,
/*case body var decls*/ None));
}
// switch (a, b) { <case statements> }
auto aRef = new (C) DeclRefExpr(aParam, DeclNameLoc(), /*implicit*/true);
auto bRef = new (C) DeclRefExpr(bParam, DeclNameLoc(), /*implicit*/true);
auto abExpr = TupleExpr::create(C, SourceLoc(), { aRef, bRef }, {}, {},
SourceLoc(), /*HasTrailingClosure*/ false,
/*implicit*/ true);
auto switchStmt = SwitchStmt::create(LabeledStmtInfo(), SourceLoc(), abExpr,
SourceLoc(), cases, SourceLoc(), C);
statements.push_back(switchStmt);
auto body = BraceStmt::create(C, SourceLoc(), statements, SourceLoc());
return { body, /*isTypeChecked=*/false };
}
/// Derive the body for an '==' operator for a struct.
static std::pair<BraceStmt *, bool>
deriveBodyEquatable_struct_eq(AbstractFunctionDecl *eqDecl, void *) {
auto parentDC = eqDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
auto args = eqDecl->getParameters();
auto aParam = args->get(0);
auto bParam = args->get(1);
auto structDecl = cast<StructDecl>(aParam->getType()->getAnyNominal());
SmallVector<ASTNode, 6> statements;
auto storedProperties = structDecl->getStoredProperties();
// For each stored property element, generate a guard statement that returns
// false if a property is not pairwise-equal.
for (auto propertyDecl : storedProperties) {
if (!propertyDecl->isUserAccessible())
continue;
auto aPropertyRef = new (C) DeclRefExpr(propertyDecl, DeclNameLoc(),
/*implicit*/ true);
auto aParamRef = new (C) DeclRefExpr(aParam, DeclNameLoc(),
/*implicit*/ true);
auto aPropertyExpr = new (C) DotSyntaxCallExpr(aPropertyRef, SourceLoc(),
aParamRef);
auto bPropertyRef = new (C) DeclRefExpr(propertyDecl, DeclNameLoc(),
/*implicit*/ true);
auto bParamRef = new (C) DeclRefExpr(bParam, DeclNameLoc(),
/*implicit*/ true);
auto bPropertyExpr = new (C) DotSyntaxCallExpr(bPropertyRef, SourceLoc(),
bParamRef);
auto guardStmt = returnIfNotEqualGuard(C, aPropertyExpr, bPropertyExpr);
statements.emplace_back(guardStmt);
}
// If none of the guard statements caused an early exit, then all the pairs
// were true.
// return true
auto trueExpr = new (C) BooleanLiteralExpr(true, SourceLoc(),
/*Implicit*/true);
auto returnStmt = new (C) ReturnStmt(SourceLoc(), trueExpr);
statements.push_back(returnStmt);
auto body = BraceStmt::create(C, SourceLoc(), statements, SourceLoc());
return { body, /*isTypeChecked=*/false };
}
/// Derive an '==' operator implementation for an enum or a struct.
static ValueDecl *
deriveEquatable_eq(
DerivedConformance &derived,
std::pair<BraceStmt *, bool> (*bodySynthesizer)(AbstractFunctionDecl *,
void *)) {
// enum SomeEnum<T...> {
// case A, B(Int), C(String, Int)
//
// @derived
// @_implements(Equatable, ==(_:_:))
// func __derived_enum_equals(a: SomeEnum<T...>,
// b: SomeEnum<T...>) -> Bool {
// switch (a, b) {
// case (.A, .A):
// return true
// case (.B(let l0), .B(let r0)):
// guard l0 == r0 else { return false }
// return true
// case (.C(let l0, let l1), .C(let r0, let r1)):
// guard l0 == r0 else { return false }
// guard l1 == r1 else { return false }
// return true
// default: return false
// }
// }
//
// struct SomeStruct<T...> {
// var x: Int
// var y: String
//
// @derived
// @_implements(Equatable, ==(_:_:))
// func __derived_struct_equals(a: SomeStruct<T...>,
// b: SomeStruct<T...>) -> Bool {
// guard a.x == b.x else { return false; }
// guard a.y == b.y else { return false; }
// return true;
// }
// }
ASTContext &C = derived.TC.Context;
auto parentDC = derived.getConformanceContext();
auto selfIfaceTy = parentDC->getDeclaredInterfaceType();
auto getParamDecl = [&](StringRef s) -> ParamDecl * {
auto *param = new (C) ParamDecl(ParamDecl::Specifier::Default, SourceLoc(),
SourceLoc(), Identifier(), SourceLoc(),
C.getIdentifier(s), parentDC);
param->setInterfaceType(selfIfaceTy);
return param;
};
ParameterList *params = ParameterList::create(C, {
getParamDecl("a"),
getParamDecl("b")
});
auto boolTy = C.getBoolDecl()->getDeclaredType();
Identifier generatedIdentifier;
if (parentDC->getParentModule()->isResilient()) {
generatedIdentifier = C.Id_EqualsOperator;
} else if (selfIfaceTy->getEnumOrBoundGenericEnum()) {
generatedIdentifier = C.Id_derived_enum_equals;
} else {
assert(selfIfaceTy->getStructOrBoundGenericStruct());
generatedIdentifier = C.Id_derived_struct_equals;
}
DeclName name(C, generatedIdentifier, params);
auto eqDecl =
FuncDecl::create(C, /*StaticLoc=*/SourceLoc(),
StaticSpellingKind::KeywordStatic,
/*FuncLoc=*/SourceLoc(), name, /*NameLoc=*/SourceLoc(),
/*Throws=*/false, /*ThrowsLoc=*/SourceLoc(),
/*GenericParams=*/nullptr,
params,
TypeLoc::withoutLoc(boolTy),
parentDC);
eqDecl->setImplicit();
eqDecl->setUserAccessible(false);
// Add the @_implements(Equatable, ==(_:_:)) attribute
if (generatedIdentifier != C.Id_EqualsOperator) {
auto equatableProto = C.getProtocol(KnownProtocolKind::Equatable);
auto equatableTy = equatableProto->getDeclaredType();
auto equatableTypeLoc = TypeLoc::withoutLoc(equatableTy);
SmallVector<Identifier, 2> argumentLabels = { Identifier(), Identifier() };
auto equalsDeclName = DeclName(C, DeclBaseName(C.Id_EqualsOperator),
argumentLabels);
eqDecl->getAttrs().add(new (C) ImplementsAttr(SourceLoc(),
SourceRange(),
equatableTypeLoc,
equalsDeclName,
DeclNameLoc()));
}
if (!C.getEqualIntDecl()) {
derived.TC.diagnose(derived.ConformanceDecl->getLoc(),
diag::no_equal_overload_for_int);
return nullptr;
}
eqDecl->setBodySynthesizer(bodySynthesizer);
// Compute the interface type.
eqDecl->setGenericSignature(parentDC->getGenericSignatureOfContext());
eqDecl->computeType();
eqDecl->copyFormalAccessFrom(derived.Nominal, /*sourceIsParentContext*/ true);
C.addSynthesizedDecl(eqDecl);
// Add the operator to the parent scope.
derived.addMembersToConformanceContext({eqDecl});
return eqDecl;
}
bool DerivedConformance::canDeriveEquatable(DeclContext *DC,
NominalTypeDecl *type) {
ASTContext &ctx = DC->getASTContext();
auto equatableProto = ctx.getProtocol(KnownProtocolKind::Equatable);
if (!equatableProto) return false;
return canDeriveConformance(DC, type, equatableProto);
}
ValueDecl *DerivedConformance::deriveEquatable(ValueDecl *requirement) {
if (checkAndDiagnoseDisallowedContext(requirement))
return nullptr;
// Build the necessary decl.
if (requirement->getBaseName() == "==") {
if (auto ed = dyn_cast<EnumDecl>(Nominal)) {
auto bodySynthesizer =
!ed->hasCases()
? &deriveBodyEquatable_enum_uninhabited_eq
: ed->hasOnlyCasesWithoutAssociatedValues()
? &deriveBodyEquatable_enum_noAssociatedValues_eq
: &deriveBodyEquatable_enum_hasAssociatedValues_eq;
return deriveEquatable_eq(*this, bodySynthesizer);
} else if (isa<StructDecl>(Nominal))
return deriveEquatable_eq(*this, &deriveBodyEquatable_struct_eq);
else
llvm_unreachable("todo");
}
TC.diagnose(requirement->getLoc(), diag::broken_equatable_requirement);
return nullptr;
}
void DerivedConformance::tryDiagnoseFailedEquatableDerivation(
DeclContext *DC, NominalTypeDecl *nominal) {
ASTContext &ctx = DC->getASTContext();
auto *equatableProto = ctx.getProtocol(KnownProtocolKind::Equatable);
diagnoseFailedDerivation(DC, nominal, equatableProto);
}
/// Returns a new \c CallExpr representing
///
/// hasher.combine(hashable)
///
/// \param C The AST context to create the expression in.
///
/// \param hasher The parameter decl to make the call on.
///
/// \param hashable The parameter to the call.
static CallExpr *createHasherCombineCall(ASTContext &C,
ParamDecl *hasher,
Expr *hashable) {
Expr *hasherExpr = new (C) DeclRefExpr(ConcreteDeclRef(hasher),
DeclNameLoc(), /*implicit*/ true);
DeclName name(C, C.Id_combine, {Identifier()});
// hasher.combine(_:)
auto *combineCall = new (C) UnresolvedDotExpr(hasherExpr, SourceLoc(),
name, DeclNameLoc(),
/*implicit*/ true);
// hasher.combine(hashable)
return CallExpr::createImplicit(C, combineCall, {hashable}, {Identifier()});
}
static FuncDecl *
deriveHashable_hashInto(
DerivedConformance &derived,
std::pair<BraceStmt *, bool> (*bodySynthesizer)(AbstractFunctionDecl *,
void *)) {
// @derived func hash(into hasher: inout Hasher)
ASTContext &C = derived.TC.Context;
auto parentDC = derived.getConformanceContext();
// Expected type: (Self) -> (into: inout Hasher) -> ()
// Constructed as:
// func type(input: Self,
// output: func type(input: inout Hasher,
// output: ()))
// Created from the inside out:
auto hasherDecl = C.getHasherDecl();
if (!hasherDecl) {
auto hashableProto = C.getProtocol(KnownProtocolKind::Hashable);
derived.TC.diagnose(hashableProto->getLoc(),
diag::broken_hashable_no_hasher);
return nullptr;
}
Type hasherType = hasherDecl->getDeclaredType();
// Params: self (implicit), hasher
auto *hasherParamDecl = new (C) ParamDecl(ParamDecl::Specifier::InOut,
SourceLoc(),
SourceLoc(), C.Id_into, SourceLoc(),
C.Id_hasher, parentDC);
hasherParamDecl->setInterfaceType(hasherType);
ParameterList *params = ParameterList::createWithoutLoc(hasherParamDecl);
// Return type: ()
auto returnType = TupleType::getEmpty(C);
// Func name: hash(into: inout Hasher) -> ()
DeclName name(C, C.Id_hash, params);
auto *hashDecl = FuncDecl::create(C,
SourceLoc(), StaticSpellingKind::None,
SourceLoc(), name, SourceLoc(),
/*Throws=*/false, SourceLoc(),
nullptr, params,
TypeLoc::withoutLoc(returnType),
parentDC);
hashDecl->setImplicit();
hashDecl->setBodySynthesizer(bodySynthesizer);
hashDecl->setGenericSignature(parentDC->getGenericSignatureOfContext());
hashDecl->computeType();
hashDecl->copyFormalAccessFrom(derived.Nominal);
C.addSynthesizedDecl(hashDecl);
derived.addMembersToConformanceContext({hashDecl});
return hashDecl;
}
/// Derive the body for the hash(into:) method when hashValue has a
/// user-supplied implementation.
static std::pair<BraceStmt *, bool>
deriveBodyHashable_compat_hashInto(AbstractFunctionDecl *hashIntoDecl, void *) {
// func hash(into hasher: inout Hasher) {
// hasher.combine(self.hashValue)
// }
auto parentDC = hashIntoDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
auto selfDecl = hashIntoDecl->getImplicitSelfDecl();
auto selfRef = new (C) DeclRefExpr(selfDecl, DeclNameLoc(),
/*implicit*/ true);
auto hashValueExpr = new (C) UnresolvedDotExpr(selfRef, SourceLoc(),
C.Id_hashValue, DeclNameLoc(),
/*implicit*/ true);
auto hasherParam = hashIntoDecl->getParameters()->get(0);
auto hasherExpr = createHasherCombineCall(C, hasherParam, hashValueExpr);
auto body = BraceStmt::create(C, SourceLoc(), {ASTNode(hasherExpr)},
SourceLoc(), /*implicit*/ true);
return { body, /*isTypeChecked=*/false };
}
/// Derive the body for the 'hash(into:)' method for an enum by using its raw
/// value.
static std::pair<BraceStmt *, bool>
deriveBodyHashable_enum_rawValue_hashInto(
AbstractFunctionDecl *hashIntoDecl, void *) {
// enum SomeEnum: Int {
// case A, B, C
// @derived func hash(into hasher: inout Hasher) {
// hasher.combine(self.rawValue)
// }
// }
ASTContext &C = hashIntoDecl->getASTContext();
// generate: self.rawValue
auto *selfRef = DerivedConformance::createSelfDeclRef(hashIntoDecl);
auto *rawValueRef = new (C) UnresolvedDotExpr(selfRef, SourceLoc(),
C.Id_rawValue, DeclNameLoc(),
/*Implicit=*/true);
// generate: hasher.combine(discriminator)
auto hasherParam = hashIntoDecl->getParameters()->get(0);
ASTNode combineStmt = createHasherCombineCall(C, hasherParam, rawValueRef);
auto body = BraceStmt::create(C, SourceLoc(), combineStmt, SourceLoc(),
/*implicit*/ true);
return { body, /*isTypeChecked=*/false };
}
/// Derive the body for the 'hash(into:)' method for an enum without associated
/// values.
static std::pair<BraceStmt *, bool>
deriveBodyHashable_enum_noAssociatedValues_hashInto(
AbstractFunctionDecl *hashIntoDecl, void *) {
// enum SomeEnum {
// case A, B, C
// @derived func hash(into hasher: inout Hasher) {
// let discriminator: Int
// switch self {
// case A:
// discriminator = 0
// case B:
// discriminator = 1
// case C:
// discriminator = 2
// }
// hasher.combine(discriminator)
// }
// }
auto parentDC = hashIntoDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
auto enumDecl = parentDC->getSelfEnumDecl();
auto selfDecl = hashIntoDecl->getImplicitSelfDecl();
// generate: switch self {...}
SmallVector<ASTNode, 3> stmts;
auto discriminatorExpr = convertEnumToIndex(stmts, parentDC, enumDecl,
selfDecl, hashIntoDecl,
"discriminator");
// generate: hasher.combine(discriminator)
auto hasherParam = hashIntoDecl->getParameters()->get(0);
auto combineStmt = createHasherCombineCall(C, hasherParam, discriminatorExpr);
stmts.push_back(combineStmt);
auto body = BraceStmt::create(C, SourceLoc(), stmts, SourceLoc(),
/*implicit*/ true);
return { body, /*isTypeChecked=*/false };
}
/// Derive the body for the 'hash(into:)' method for an enum with associated
/// values.
static std::pair<BraceStmt *, bool>
deriveBodyHashable_enum_hasAssociatedValues_hashInto(
AbstractFunctionDecl *hashIntoDecl, void *) {
// enum SomeEnumWithAssociatedValues {
// case A, B(Int), C(String, Int)
// @derived func hash(into hasher: inout Hasher) {
// switch self {
// case A:
// hasher.combine(0)
// case B(let a0):
// hasher.combine(1)
// hasher.combine(a0)
// case C(let a0, let a1):
// hasher.combine(2)
// hasher.combine(a0)
// hasher.combine(a1)
// }
// }
// }
auto parentDC = hashIntoDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
auto enumDecl = parentDC->getSelfEnumDecl();
auto selfDecl = hashIntoDecl->getImplicitSelfDecl();
Type enumType = selfDecl->getType();
// Extract the decl for the hasher parameter.
auto hasherParam = hashIntoDecl->getParameters()->get(0);
unsigned index = 0;
SmallVector<ASTNode, 4> cases;
// For each enum element, generate a case statement that binds the associated
// values so that they can be fed to the hasher.
for (auto elt : enumDecl->getAllElements()) {
// case .<elt>(let a0, let a1, ...):
SmallVector<VarDecl*, 3> payloadVars;
SmallVector<ASTNode, 3> statements;
auto payloadPattern = enumElementPayloadSubpattern(elt, 'a', hashIntoDecl,
payloadVars);
auto pat = new (C) EnumElementPattern(TypeLoc::withoutLoc(enumType),
SourceLoc(), SourceLoc(),
elt->getName(), elt, payloadPattern);
pat->setImplicit();
auto labelItem = CaseLabelItem(pat);
// If the enum has no associated values, we use the ordinal as the single
// hash component, because that is sufficient for a good distribution. If
// any case does have associated values, then the ordinal is used as the
// first term fed into the hasher.
{
// Generate: hasher.combine(<ordinal>)
auto ordinalExpr = IntegerLiteralExpr::createFromUnsigned(C, index++);
auto combineExpr = createHasherCombineCall(C, hasherParam, ordinalExpr);
statements.emplace_back(ASTNode(combineExpr));
}
// Generate a sequence of statements that feed the payloads into hasher.
for (auto payloadVar : payloadVars) {
auto payloadVarRef = new (C) DeclRefExpr(payloadVar, DeclNameLoc(),
/*implicit*/ true);
// Generate: hasher.combine(<payloadVar>)
auto combineExpr = createHasherCombineCall(C, hasherParam, payloadVarRef);
statements.emplace_back(ASTNode(combineExpr));
}
auto hasBoundDecls = !payloadVars.empty();
Optional<MutableArrayRef<VarDecl *>> caseBodyVarDecls;
if (hasBoundDecls) {
auto copy = C.Allocate<VarDecl *>(payloadVars.size());
for (unsigned i : indices(payloadVars)) {
auto *vOld = payloadVars[i];
auto *vNew = new (C) VarDecl(
/*IsStatic*/ false, vOld->getIntroducer(), false /*IsCaptureList*/,
vOld->getNameLoc(), vOld->getName(), vOld->getDeclContext());
vNew->setHasNonPatternBindingInit();
vNew->setImplicit();
copy[i] = vNew;
}
caseBodyVarDecls.emplace(copy);
}
auto body = BraceStmt::create(C, SourceLoc(), statements, SourceLoc());
cases.push_back(CaseStmt::create(C, SourceLoc(), labelItem, SourceLoc(),
SourceLoc(), body, caseBodyVarDecls,
/*implicit*/ true));
}
// generate: switch enumVar { }
auto enumRef = new (C) DeclRefExpr(selfDecl, DeclNameLoc(),
/*implicit*/true);
auto switchStmt = SwitchStmt::create(LabeledStmtInfo(), SourceLoc(), enumRef,
SourceLoc(), cases, SourceLoc(), C);
auto body = BraceStmt::create(C, SourceLoc(), {ASTNode(switchStmt)},
SourceLoc());
return { body, /*isTypeChecked=*/false };
}
/// Derive the body for the 'hash(into:)' method for a struct.
static std::pair<BraceStmt *, bool>
deriveBodyHashable_struct_hashInto(AbstractFunctionDecl *hashIntoDecl, void *) {
// struct SomeStruct {
// var x: Int
// var y: String
// @derived func hash(into hasher: inout Hasher) {
// hasher.combine(x)
// hasher.combine(y)
// }
// }
auto parentDC = hashIntoDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
auto structDecl = parentDC->getSelfStructDecl();
SmallVector<ASTNode, 6> statements;
auto selfDecl = hashIntoDecl->getImplicitSelfDecl();
// Extract the decl for the hasher parameter.
auto hasherParam = hashIntoDecl->getParameters()->get(0);
auto storedProperties = structDecl->getStoredProperties();
// Feed each stored property into the hasher.
for (auto propertyDecl : storedProperties) {
if (!propertyDecl->isUserAccessible())
continue;
auto propertyRef = new (C) DeclRefExpr(propertyDecl, DeclNameLoc(),
/*implicit*/ true);
auto selfRef = new (C) DeclRefExpr(selfDecl, DeclNameLoc(),
/*implicit*/ true);
auto selfPropertyExpr = new (C) DotSyntaxCallExpr(propertyRef, SourceLoc(),
selfRef);
// Generate: hasher.combine(self.<property>)
auto combineExpr = createHasherCombineCall(C, hasherParam, selfPropertyExpr);
statements.emplace_back(ASTNode(combineExpr));
}
auto body = BraceStmt::create(C, SourceLoc(), statements,
SourceLoc(), /*implicit*/ true);
return { body, /*isTypeChecked=*/false };
}
/// Derive the body for the 'hashValue' getter.
static std::pair<BraceStmt *, bool>
deriveBodyHashable_hashValue(AbstractFunctionDecl *hashValueDecl, void *) {
auto parentDC = hashValueDecl->getDeclContext();
ASTContext &C = parentDC->getASTContext();
// return _hashValue(for: self)
// 'self'
auto selfDecl = hashValueDecl->getImplicitSelfDecl();
Type selfType = selfDecl->getType();
auto selfRef = new (C) DeclRefExpr(selfDecl, DeclNameLoc(),
/*implicit*/ true,
AccessSemantics::Ordinary,
selfType);
// _hashValue(for:)
auto *hashFunc = C.getHashValueForDecl();
auto substitutions = SubstitutionMap::get(
hashFunc->getGenericSignature(),
[&](SubstitutableType *dependentType) {
if (auto gp = dyn_cast<GenericTypeParamType>(dependentType)) {
if (gp->getDepth() == 0 && gp->getIndex() == 0)
return selfType;
}
return Type(dependentType);
},
LookUpConformanceInModule(hashValueDecl->getModuleContext()));
ConcreteDeclRef hashFuncRef(hashFunc, substitutions);
Type hashFuncType = hashFunc->getInterfaceType().subst(substitutions);
auto hashExpr = new (C) DeclRefExpr(hashFuncRef, DeclNameLoc(),
/*implicit*/ true,
AccessSemantics::Ordinary,
hashFuncType);
Type hashFuncResultType =
hashFuncType->castTo<AnyFunctionType>()->getResult();
auto callExpr = CallExpr::createImplicit(C, hashExpr,
{ selfRef }, { C.Id_for });
callExpr->setType(hashFuncResultType);
auto returnStmt = new (C) ReturnStmt(SourceLoc(), callExpr);
auto body = BraceStmt::create(C, SourceLoc(), {returnStmt}, SourceLoc(),
/*implicit*/ true);
return { body, /*isTypeChecked=*/true };
}
/// Derive a 'hashValue' implementation.
static ValueDecl *deriveHashable_hashValue(DerivedConformance &derived) {
// @derived var hashValue: Int {
// return _hashValue(for: self)
// }
auto &tc = derived.TC;
ASTContext &C = tc.Context;
auto parentDC = derived.getConformanceContext();
Type intType = C.getIntDecl()->getDeclaredType();
// We can't form a Hashable conformance if Int isn't Hashable or
// ExpressibleByIntegerLiteral.
if (!TypeChecker::conformsToProtocol(intType,
C.getProtocol(KnownProtocolKind::Hashable),
parentDC, None)) {
derived.ConformanceDecl->diagnose(diag::broken_int_hashable_conformance);
return nullptr;
}
ProtocolDecl *intLiteralProto =
C.getProtocol(KnownProtocolKind::ExpressibleByIntegerLiteral);
if (!TypeChecker::conformsToProtocol(intType, intLiteralProto,
parentDC, None)) {
derived.ConformanceDecl->diagnose(
diag::broken_int_integer_literal_convertible_conformance);
return nullptr;
}
VarDecl *hashValueDecl =
new (C) VarDecl(/*IsStatic*/false, VarDecl::Introducer::Var,
/*IsCaptureList*/false, SourceLoc(),
C.Id_hashValue, parentDC);
hashValueDecl->setType(intType);
ParameterList *params = ParameterList::createEmpty(C);
AccessorDecl *getterDecl = AccessorDecl::create(C,
/*FuncLoc=*/SourceLoc(), /*AccessorKeywordLoc=*/SourceLoc(),
AccessorKind::Get, hashValueDecl,
/*StaticLoc=*/SourceLoc(), StaticSpellingKind::None,
/*Throws=*/false, /*ThrowsLoc=*/SourceLoc(),
/*GenericParams=*/nullptr, params,
TypeLoc::withoutLoc(intType), parentDC);
getterDecl->setImplicit();
getterDecl->setBodySynthesizer(&deriveBodyHashable_hashValue);
getterDecl->setIsTransparent(false);
// Compute the interface type of hashValue().
getterDecl->setGenericSignature(parentDC->getGenericSignatureOfContext());
getterDecl->computeType();
getterDecl->copyFormalAccessFrom(derived.Nominal,
/*sourceIsParentContext*/ true);
// Finish creating the property.
hashValueDecl->setImplicit();
hashValueDecl->setInterfaceType(intType);
hashValueDecl->setImplInfo(StorageImplInfo::getImmutableComputed());
hashValueDecl->setAccessors(SourceLoc(), {getterDecl}, SourceLoc());
hashValueDecl->copyFormalAccessFrom(derived.Nominal,
/*sourceIsParentContext*/ true);
Pattern *hashValuePat = new (C) NamedPattern(hashValueDecl, /*implicit*/true);
hashValuePat->setType(intType);
hashValuePat = TypedPattern::createImplicit(C, hashValuePat, intType);
hashValuePat->setType(intType);
auto *patDecl = PatternBindingDecl::createImplicit(
C, StaticSpellingKind::None, hashValuePat, /*InitExpr*/ nullptr,
parentDC);
C.addSynthesizedDecl(hashValueDecl);
C.addSynthesizedDecl(getterDecl);
derived.addMembersToConformanceContext({hashValueDecl, patDecl});
return hashValueDecl;
}
static ValueDecl *
getHashValueRequirement(ASTContext &C) {
auto hashableProto = C.getProtocol(KnownProtocolKind::Hashable);
for (auto member: hashableProto->getMembers()) {
if (auto fd = dyn_cast<VarDecl>(member)) {
if (fd->getBaseName() == C.Id_hashValue)
return fd;
}
}
return nullptr;
}
static ProtocolConformance *
getHashableConformance(Decl *parentDecl) {
ASTContext &C = parentDecl->getASTContext();
auto DC = cast<DeclContext>(parentDecl);
auto hashableProto = C.getProtocol(KnownProtocolKind::Hashable);
for (auto conformance: DC->getLocalConformances()) {
if (conformance->getProtocol() == hashableProto) {
return conformance;
}
}
return nullptr;
}
bool DerivedConformance::canDeriveHashable(NominalTypeDecl *type) {
if (!isa<EnumDecl>(type) && !isa<StructDecl>(type) && !isa<ClassDecl>(type))
return false;
// FIXME: This is not actually correct. We cannot promise to always
// provide a witness here in all cases. Unfortunately, figuring out
// whether this is actually possible requires a parent decl context.
// When the answer is no, DerivedConformance::deriveHashable will output
// its own diagnostics.
return true;
}
void DerivedConformance::tryDiagnoseFailedHashableDerivation(
DeclContext *DC, NominalTypeDecl *nominal) {
ASTContext &ctx = DC->getASTContext();
auto *hashableProto = ctx.getProtocol(KnownProtocolKind::Hashable);
diagnoseFailedDerivation(DC, nominal, hashableProto);
}
ValueDecl *DerivedConformance::deriveHashable(ValueDecl *requirement) {
ASTContext &C = ConformanceDecl->getASTContext();
// var hashValue: Int
if (requirement->getBaseName() == C.Id_hashValue) {
// We always allow hashValue to be synthesized; invalid cases are diagnosed
// during hash(into:) synthesis.
return deriveHashable_hashValue(*this);
}
// Hashable.hash(into:)
if (requirement->getBaseName() == C.Id_hash) {
// Start by resolving hashValue conformance.
auto hashValueReq = getHashValueRequirement(C);
auto conformance = getHashableConformance(ConformanceDecl);
auto hashValueDecl = conformance->getWitnessDecl(hashValueReq);
if (!hashValueDecl) {
// We won't derive hash(into:) if hashValue cannot be resolved.
// The hashValue failure will produce a diagnostic elsewhere.
return nullptr;
}
if (hashValueDecl->isImplicit()) {
// Neither hashValue nor hash(into:) is explicitly defined; we need to do
// a full Hashable derivation.
// Refuse to synthesize Hashable if type isn't a struct or enum, or if it
// has non-Hashable stored properties/associated values.
auto hashableProto = C.getProtocol(KnownProtocolKind::Hashable);
if (!canDeriveConformance(getConformanceContext(), Nominal,
hashableProto)) {
ConformanceDecl->diagnose(diag::type_does_not_conform,
Nominal->getDeclaredType(),
hashableProto->getDeclaredType());
// Ideally, this would be diagnosed in
// ConformanceChecker::resolveWitnessViaLookup. That doesn't work for
// Hashable because DerivedConformance::canDeriveHashable returns true
// even if the conformance can't be derived. See the note there for
// details.
auto *dc = ConformanceDecl->getDeclContext();
tryDiagnoseFailedHashableDerivation(dc, Nominal);
return nullptr;
}
if (checkAndDiagnoseDisallowedContext(requirement))
return nullptr;
if (auto ED = dyn_cast<EnumDecl>(Nominal)) {
std::pair<BraceStmt *, bool> (*bodySynthesizer)(
AbstractFunctionDecl *, void *);
if (ED->isObjC())
bodySynthesizer = deriveBodyHashable_enum_rawValue_hashInto;
else if (ED->hasOnlyCasesWithoutAssociatedValues())
bodySynthesizer = deriveBodyHashable_enum_noAssociatedValues_hashInto;
else
bodySynthesizer=deriveBodyHashable_enum_hasAssociatedValues_hashInto;
return deriveHashable_hashInto(*this, bodySynthesizer);
} else if (isa<StructDecl>(Nominal))
return deriveHashable_hashInto(*this,
&deriveBodyHashable_struct_hashInto);
else // This should've been caught by canDeriveHashable above.
llvm_unreachable("Attempt to derive Hashable for a type other "
"than a struct or enum");
} else {
// hashValue has an explicit implementation, but hash(into:) doesn't.
// Emit a deprecation warning, then derive hash(into:) in terms of
// hashValue.
hashValueDecl->diagnose(diag::hashvalue_implementation,
Nominal->getDeclaredType());
return deriveHashable_hashInto(*this,
&deriveBodyHashable_compat_hashInto);
}
}
requirement->diagnose(diag::broken_hashable_requirement);
return nullptr;
}