//===--- SILGenPattern.cpp - Pattern matching codegen ---------------------===// // // 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 // //===----------------------------------------------------------------------===// #define DEBUG_TYPE "patternmatch-silgen" #include "Cleanup.h" #include "ExitableFullExpr.h" #include "Initialization.h" #include "LValue.h" #include "RValue.h" #include "SILGen.h" #include "Scope.h" #include "swift/AST/ASTWalker.h" #include "swift/AST/DiagnosticsSIL.h" #include "swift/AST/Pattern.h" #include "swift/AST/SILOptions.h" #include "swift/AST/SubstitutionMap.h" #include "swift/AST/Types.h" #include "swift/Basic/Defer.h" #include "swift/Basic/ProfileCounter.h" #include "swift/Basic/STLExtras.h" #include "swift/SIL/DynamicCasts.h" #include "swift/SIL/SILArgument.h" #include "swift/SIL/SILUndef.h" #include "swift/SIL/TypeLowering.h" #include "llvm/ADT/MapVector.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Debug.h" #include "llvm/Support/FormattedStream.h" using namespace swift; using namespace Lowering; //===----------------------------------------------------------------------===// // Pattern Utilities //===----------------------------------------------------------------------===// // TODO: These routines should probably be refactored into their own file since // they have nothing to do with the implementation of SILGenPattern // specifically. /// Shallow-dump a pattern node one level deep for debug purposes. static void dumpPattern(const Pattern *p, llvm::raw_ostream &os) { if (!p) { // We use null to represent a synthetic wildcard. os << '_'; return; } p = p->getSemanticsProvidingPattern(); switch (p->getKind()) { case PatternKind::Any: os << '_'; return; case PatternKind::Expr: os << ""; return; case PatternKind::Named: os << "var " << cast(p)->getBoundName(); return; case PatternKind::Tuple: { unsigned numFields = cast(p)->getNumElements(); if (numFields == 0) os << "()"; else if (numFields == 1) os << "(_)"; else { os << '('; for (unsigned i = 0; i < numFields - 1; ++i) os << ','; os << ')'; } return; } case PatternKind::Is: os << "is "; cast(p)->getCastTypeLoc().getType()->print(os); break; case PatternKind::EnumElement: { auto eep = cast(p); os << '.' << eep->getName(); return; } case PatternKind::OptionalSome: os << ".some"; return; case PatternKind::Bool: os << (cast(p)->getValue() ? "true" : "false"); return; case PatternKind::Paren: case PatternKind::Typed: case PatternKind::Var: llvm_unreachable("not semantic"); } } /// Is the given specializable pattern directly refutable, as opposed /// to containing some refutability in a nested position? static bool isDirectlyRefutablePattern(const Pattern *p) { if (!p) return false; switch (p->getKind()) { case PatternKind::Any: case PatternKind::Named: case PatternKind::Expr: llvm_unreachable("non-specializable patterns"); // Tuple and nominal-type patterns are not themselves directly refutable. case PatternKind::Tuple: return false; // isa and enum-element patterns are refutable, at least in theory. case PatternKind::Is: case PatternKind::EnumElement: case PatternKind::OptionalSome: case PatternKind::Bool: return true; // Recur into simple wrapping patterns. case PatternKind::Paren: case PatternKind::Typed: case PatternKind::Var: return isDirectlyRefutablePattern(p->getSemanticsProvidingPattern()); } llvm_unreachable("bad pattern"); } const unsigned AlwaysRefutable = ~0U; /// Return the number of times a pattern must be specialized /// before becoming irrefutable. /// /// \return AlwaysRefutable if the pattern is never irrefutable static unsigned getNumSpecializationsRecursive(const Pattern *p, unsigned n) { // n is partially here to make simple cases tail-recursive, but it // also gives us a simple opportunity to bail out early when we see // an always-refutable pattern. if (n == AlwaysRefutable) return n; switch (p->getKind()) { // True wildcards. case PatternKind::Any: case PatternKind::Named: return n; // Expressions are always-refutable wildcards. case PatternKind::Expr: return AlwaysRefutable; // Tuple and nominal-type patterns are not themselves directly refutable. case PatternKind::Tuple: { auto tuple = cast(p); for (auto &elt : tuple->getElements()) n = getNumSpecializationsRecursive(elt.getPattern(), n); return n; } // isa and enum-element patterns are refutable, at least in theory. case PatternKind::Is: { auto isa = cast(p); n++; if (auto sub = isa->getSubPattern()) return getNumSpecializationsRecursive(sub, n); return n; } case PatternKind::EnumElement: { auto en = cast(p); n++; if (en->hasSubPattern()) n = getNumSpecializationsRecursive(en->getSubPattern(), n); return n; } case PatternKind::OptionalSome: { auto en = cast(p); return getNumSpecializationsRecursive(en->getSubPattern(), n+1); } case PatternKind::Bool: return n+1; // Recur into simple wrapping patterns. case PatternKind::Paren: case PatternKind::Typed: case PatternKind::Var: return getNumSpecializationsRecursive(p->getSemanticsProvidingPattern(), n); } llvm_unreachable("bad pattern"); } /// Return the number of times a pattern must be specialized /// before becoming irrefutable. /// /// \return AlwaysRefutable if the pattern is never irrefutable static unsigned getNumSpecializations(const Pattern *p) { return (p ? getNumSpecializationsRecursive(p, 0) : 0); } /// True if a pattern is a wildcard, meaning it matches any value. '_' and /// variable patterns are wildcards. We also consider ExprPatterns to be /// wildcards; we test the match expression as a guard outside of the normal /// pattern clause matrix. When destructuring wildcard patterns, we also use /// nullptr to represent newly-constructed wildcards. static bool isWildcardPattern(const Pattern *p) { if (!p) return true; switch (p->getKind()) { // Simple wildcards. case PatternKind::Any: case PatternKind::Expr: case PatternKind::Named: return true; // Non-wildcards. case PatternKind::Tuple: case PatternKind::Is: case PatternKind::EnumElement: case PatternKind::OptionalSome: case PatternKind::Bool: return false; // Recur into simple wrapping patterns. case PatternKind::Paren: case PatternKind::Typed: case PatternKind::Var: return isWildcardPattern(p->getSemanticsProvidingPattern()); } llvm_unreachable("Unhandled PatternKind in switch."); } /// Check to see if the given pattern is a specializing pattern, /// and return a semantic pattern for it. Pattern *getSpecializingPattern(Pattern *p) { // Empty entries are basically AnyPatterns. if (!p) return nullptr; p = p->getSemanticsProvidingPattern(); return (isWildcardPattern(p) ? nullptr : p); } /// Given a pattern stored in a clause matrix, check to see whether it /// can be specialized the same way as the first one. static Pattern *getSimilarSpecializingPattern(Pattern *p, Pattern *first) { // Empty entries are basically AnyPatterns. if (!p) return nullptr; assert(first && getSpecializingPattern(first) == first); // Map down to the semantics-providing pattern. p = p->getSemanticsProvidingPattern(); // If the patterns are exactly the same kind, we might be able to treat them // similarly. switch (p->getKind()) { case PatternKind::EnumElement: case PatternKind::OptionalSome: { // If one is an OptionalSomePattern and one is an EnumElementPattern, then // they are the same since the OptionalSomePattern is just sugar for // .Some(x). if ((isa(p) && isa(first)) || (isa(first) && isa(p))) return p; LLVM_FALLTHROUGH; } case PatternKind::Tuple: case PatternKind::Named: case PatternKind::Any: case PatternKind::Bool: case PatternKind::Expr: { // These kinds are only similar to the same kind. if (p->getKind() == first->getKind()) return p; return nullptr; } case PatternKind::Is: { auto pIs = cast(p); // 'is' patterns are only similar to matches to the same type. if (auto firstIs = dyn_cast(first)) { if (firstIs->getCastTypeLoc().getType() ->isEqual(pIs->getCastTypeLoc().getType())) return p; } return nullptr; } case PatternKind::Paren: case PatternKind::Var: case PatternKind::Typed: llvm_unreachable("not semantic"); } llvm_unreachable("Unhandled PatternKind in switch."); } //===----------------------------------------------------------------------===// // SILGenPattern Emission //===----------------------------------------------------------------------===// namespace { /// A row which we intend to specialize. struct RowToSpecialize { /// The pattern from this row which we are specializing upon. Pattern *Pattern; /// The index of the target row. unsigned RowIndex; /// Whether the row will be irrefutable after this specialization. bool Irrefutable; /// Profile Count of hte row we intend to specialize. ProfileCounter Count; }; /// Changes that we wish to apply to a row which we have specialized. struct SpecializedRow { /// The patterns which should replace the specialized pattern. SmallVector Patterns; /// The index of the target row. unsigned RowIndex; }; /// An array of arguments. using ArgArray = ArrayRef; /// A callback which dispatches a failure case. using FailureHandler = std::function; /// A callback which redispatches a set of specialized rows. using SpecializationHandler = std::function rowChanges, const FailureHandler &contDest)>; class ClauseMatrix; class ClauseRow; /// A class controlling the emission of the decision tree for a pattern match /// statement (switch, if/let, or while/let condition). /// /// The value cleanup rules during pattern match emission are complicated /// because we're trying to allow as much borrowing/forwarding of /// values as possible, so that we only need to actually copy/retain /// values as late as possible. This means we end up having to do /// a pretty delicate dance to manage the active set of cleanups. /// /// We split values into three categories: /// - TakeAlways (which are owned by the current portion of the /// decision tree) /// - CopyOnSuccess (which are not owned at all by the current /// portion of the decision tree) /// - TakeOnSuccess (which are owned only if the decision tree /// actually passes all guards and enters a case block) /// In particular, it is important that a TakeOnSuccess value not be /// destructively modified unless success is assured. /// /// Whenever the decision tree branches, it must forward values down /// correctly. A TakeAlways value becomes TakeOnSuccess for all but /// last branch of the tree. /// /// Values should be forwarded down the decision tree with the /// appropriate cleanups. CopyOnSuccess values should not have /// attached cleanups. TakeAlways or TakeOnSuccess values should have /// cleanups when their types are non-trivial. When a value is /// forwarded down into a branch of the decision tree, its cleanup /// might be deactivated within that subtree; to protect against the /// cleanup being removed when this happens, the cleanup must be first /// put in the PersistentlyActive state before the emission of the /// subtree, then restored to its current state when the subtree is /// finished. /// /// The set of active cleanups should always be instantaneously /// consistent: that is, there should always be exactly one cleanup /// tracking a +1 value. It's okay to deactivate a cleanup for a /// TakeOnSuccess value and then introduce new cleanups for all of its /// subobjects. Jumps outside of the decision tree entirely will be /// fine: the jump will simply destroy the subobjects instead of the /// aggregate. However, jumps to somewhere else within the decision /// tree require careful attention if the jump could lead to a /// cleanups depth outside the subobject cleanups (causing them to be /// run) but inside the old cleanup (in which case it will be /// reactivated). Therefore, such borrowings must be "unforwarded" /// during the emission of such jumps by disabling the new cleanups /// and re-enabling the outer cleanup. It's okay to re-enable /// cleanups like this because these jumps only occur when a branch of /// the decision tree fails with a non-exhaustive match, which means /// the value should have been passed down as TakeOnSuccess, and the /// decision tree is not allowed to destructively modify objects that /// are TakeOnSuccess when failure is still a possibility. class PatternMatchEmission { PatternMatchEmission(const PatternMatchEmission &) = delete; PatternMatchEmission &operator=(const PatternMatchEmission &) = delete; SILGenFunction &SGF; /// PatternMatchStmt - The 'switch', or do-catch statement that we're emitting /// this pattern match for. Stmt *PatternMatchStmt; CleanupsDepth PatternMatchStmtDepth; llvm::MapVector> SharedCases; llvm::DenseMap Temporaries; using CompletionHandlerTy = llvm::function_ref; CompletionHandlerTy CompletionHandler; public: PatternMatchEmission(SILGenFunction &SGF, Stmt *S, CompletionHandlerTy completionHandler) : SGF(SGF), PatternMatchStmt(S), CompletionHandler(completionHandler) {} Optional getSubjectLocationOverride(SILLocation loc) const { if (auto *Switch = dyn_cast(PatternMatchStmt)) if (!Switch->isImplicit()) return SILLocation(Switch->getSubjectExpr()); return None; } void emitDispatch(ClauseMatrix &matrix, ArgArray args, const FailureHandler &failure); void initSharedCaseBlockDest(CaseStmt *caseBlock, bool hasFallthroughTo); void emitAddressOnlyAllocations(); void emitAddressOnlyInitialization(VarDecl *dest, SILValue value); JumpDest getSharedCaseBlockDest(CaseStmt *caseStmt); void emitSharedCaseBlocks(); void emitCaseBody(CaseStmt *caseBlock); SILValue getAddressOnlyTemporary(VarDecl *decl) { auto found = Temporaries.find(decl); assert(found != Temporaries.end()); return found->second; } private: void emitWildcardDispatch(ClauseMatrix &matrix, ArgArray args, unsigned row, const FailureHandler &failure); void bindRefutablePatterns(const ClauseRow &row, ArgArray args, const FailureHandler &failure); void emitGuardBranch(SILLocation loc, Expr *guard, const FailureHandler &failure); void bindIrrefutablePatterns(const ClauseRow &row, ArgArray args, bool forIrrefutableRow, bool hasMultipleItems); void bindVariable(Pattern *pattern, VarDecl *var, ConsumableManagedValue value, bool isIrrefutable, bool hasMultipleItems); void emitSpecializedDispatch(ClauseMatrix &matrix, ArgArray args, unsigned &lastRow, unsigned column, const FailureHandler &failure); void emitTupleObjectDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleSpec, const FailureHandler &failure); void emitTupleDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleSpec, const FailureHandler &failure); void emitIsDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleSpec, const FailureHandler &failure); void emitEnumElementObjectDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleSpec, const FailureHandler &failure, ProfileCounter defaultCaseCount); void emitEnumElementDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleSpec, const FailureHandler &failure, ProfileCounter defaultCaseCount); void emitBoolDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleSpec, const FailureHandler &failure); }; /// A handle to a row in a clause matrix. Does not own memory; use of the /// ClauseRow must be dominated by its originating ClauseMatrix. /// /// TODO: This should be refactored into a more general formulation that uses a /// child template pattern to inject our logic. This will then allow us to /// inject "mock" objects in a unittest file. class ClauseRow { friend class ClauseMatrix; Stmt *ClientData; Pattern *CasePattern; Expr *CaseGuardExpr; /// HasFallthroughTo - True if there is a fallthrough into this case. bool HasFallthroughTo; /// The number of remaining specializations until this row becomes /// irrefutable. unsigned NumRemainingSpecializations; SmallVector Columns; public: ClauseRow(Stmt *clientData, Pattern *CasePattern, Expr *CaseGuardExpr, bool HasFallthroughTo) : ClientData(clientData), CasePattern(CasePattern), CaseGuardExpr(CaseGuardExpr), HasFallthroughTo(HasFallthroughTo) { Columns.push_back(CasePattern); if (CaseGuardExpr) NumRemainingSpecializations = AlwaysRefutable; else NumRemainingSpecializations = getNumSpecializations(Columns[0]); } template T *getClientData() const { return static_cast(ClientData); } Pattern *getCasePattern() const { return CasePattern; } Expr *getCaseGuardExpr() const { return CaseGuardExpr; } bool hasFallthroughTo() const { return HasFallthroughTo; } ArrayRef getColumns() const { return Columns; } MutableArrayRef getColumns() { return Columns; } /// Specialize the given column to the given array of new columns. /// /// Places the new columns using the column-specialization algorithm. void specializeInPlace(unsigned column, ArrayRef newColumns) { // We assume that this method always removes one level of pattern // and replacing it with its direct sub-patterns. Therefore, we // can adjust the number of remaining specializations very easily. // // We don't need to test whether NumRemainingSpecializations is // AlwaysRefutable before decrementing because we only ever test // this value against zero. if (isDirectlyRefutablePattern(Columns[column])) NumRemainingSpecializations--; if (newColumns.size() == 1) { Columns[column] = newColumns[0]; } else if (newColumns.empty()) { if (column + 1 == Columns.size()) { Columns.pop_back(); } else { Columns[column] = Columns.pop_back_val(); } } else { Columns[column] = newColumns[0]; Columns.append(newColumns.begin() + 1, newColumns.end()); } } /// Is this row currently irrefutable? bool isIrrefutable() const { return NumRemainingSpecializations == 0; } /// Will this row be irrefutable after we single-step specialize the /// given column? bool isIrrefutableAfterSpecializing(unsigned column) const { if (NumRemainingSpecializations == 1) return isDirectlyRefutablePattern(Columns[column]); return NumRemainingSpecializations == 0; } Pattern * const *begin() const { return getColumns().begin(); } Pattern * const *end() const { return getColumns().end(); } Pattern **begin() { return getColumns().begin(); } Pattern **end() { return getColumns().end(); } Pattern *operator[](unsigned column) const { return getColumns()[column]; } Pattern *&operator[](unsigned column) { return getColumns()[column]; } unsigned columns() const { return Columns.size(); } LLVM_ATTRIBUTE_USED void dump() const { return print(llvm::errs()); } void print(llvm::raw_ostream &out) const; }; /// A clause matrix. This matrix associates subpattern rows to their /// corresponding guard expressions, and associates destination basic block /// and columns to their associated subject value. class ClauseMatrix { SmallVector Rows; ClauseMatrix(const ClauseMatrix &) = delete; ClauseMatrix &operator=(const ClauseMatrix &) = delete; ClauseMatrix() = default; public: /// Create a clause matrix from the given pattern-row storage. /// (actively matched values) and enough initial capacity for the /// given number of rows. The clause matrix will be initialized with zero rows /// and a column for every occurrence. Rows can be added using addRows. explicit ClauseMatrix(MutableArrayRef rows) { for (ClauseRow &row : rows) { Rows.push_back(&row); } } ClauseMatrix(ClauseMatrix &&) = default; ClauseMatrix &operator=(ClauseMatrix &&) = default; unsigned rows() const { return Rows.size(); } ClauseRow &operator[](unsigned row) { return *Rows[row]; } const ClauseRow &operator[](unsigned row) const { return *Rows[row]; } /// Destructively specialize the rows of this clause matrix. The /// rows should not be used in this matrix afterwards. ClauseMatrix specializeRowsInPlace(unsigned column, ArrayRef newRows) { assert(!newRows.empty() && "specializing for an empty set of rows?"); ClauseMatrix innerMatrix; for (unsigned i = 0, e = newRows.size(); i != e; ++i) { assert((i == 0 || newRows[i - 1].RowIndex < newRows[i].RowIndex) && "specialized rows are out of order?"); ClauseRow *rowData = Rows[newRows[i].RowIndex]; rowData->specializeInPlace(column, newRows[i].Patterns); innerMatrix.Rows.push_back(rowData); } return innerMatrix; } LLVM_ATTRIBUTE_USED void dump() const { return print(llvm::errs()); } void print(llvm::raw_ostream &out) const; }; } // end anonymous namespace void ClauseRow::print(llvm::raw_ostream &out) const { out << "[ "; for (const Pattern *column : *this) { dumpPattern(column, out); out << ' '; } out << "]\n"; } void ClauseMatrix::print(llvm::raw_ostream &out) const { if (Rows.empty()) { return; } // Tabulate the strings for each column, row-major. // We need to pad the strings out like a real matrix. SmallVector, 4> patternStrings; SmallVector columnSizes; patternStrings.resize(Rows.size()); llvm::formatted_raw_ostream fos(out); for (unsigned r = 0, rend = rows(); r < rend; ++r) { const ClauseRow &row = (*this)[r]; auto &rowStrings = patternStrings[r]; // Make sure that column sizes has an entry for all our columns. if (row.columns() > columnSizes.size()) columnSizes.resize(row.columns(), 0); rowStrings.reserve(row.columns()); for (unsigned c = 0, cend = row.columns(); c < cend; ++c) { rowStrings.push_back(""); std::string &str = rowStrings.back(); { llvm::raw_string_ostream ss(str); dumpPattern(row[c], ss); ss.flush(); } columnSizes[c] = std::max(columnSizes[c], str.size()); } } for (unsigned r = 0, rend = rows(); r < rend; ++r) { fos << "[ "; for (unsigned c = 0, cend = patternStrings[r].size(); c < cend; ++c) { unsigned start = fos.getColumn(); fos << patternStrings[r][c]; fos.PadToColumn(start + columnSizes[c] + 1); } fos << "]\n"; } fos.flush(); } /// Forward a value down into a branch of the decision tree that may /// fail and lead back to other branch(es). /// /// Essentially equivalent to forwardIntoIrrefutableSubtree, except it /// converts AlwaysTake to TakeOnSuccess. static ConsumableManagedValue forwardIntoSubtree(SILGenFunction &SGF, SILLocation loc, CleanupStateRestorationScope &scope, ConsumableManagedValue outerCMV) { ManagedValue outerMV = outerCMV.getFinalManagedValue(); if (!outerMV.hasCleanup()) return outerCMV; auto consumptionKind = outerCMV.getFinalConsumption(); (void)consumptionKind; // If we have an object and it is take always, we need to borrow the value // since our subtree does not own the value. if (outerMV.getType().isObject()) { assert(consumptionKind == CastConsumptionKind::TakeAlways && "Object without cleanup that is not take_always?!"); return {outerMV.borrow(SGF, loc), CastConsumptionKind::BorrowAlways}; } // Only address only values use TakeOnSuccess. assert(outerMV.getType().isAddressOnly(SGF.F) && "TakeOnSuccess can only be used with address only values"); assert((consumptionKind == CastConsumptionKind::TakeAlways || consumptionKind == CastConsumptionKind::TakeOnSuccess) && "non-+1 consumption with a cleanup?"); scope.pushCleanupState(outerMV.getCleanup(), CleanupState::PersistentlyActive); // Success means that we won't end up in the other branch, // but failure doesn't. return {outerMV, CastConsumptionKind::TakeOnSuccess}; } /// Forward a value down into an irrefutable branch of the decision tree. /// /// Essentially equivalent to forwardIntoSubtree, except it preserves /// AlwaysTake consumption. static void forwardIntoIrrefutableSubtree(SILGenFunction &SGF, CleanupStateRestorationScope &scope, ConsumableManagedValue outerCMV) { ManagedValue outerMV = outerCMV.getFinalManagedValue(); if (!outerMV.hasCleanup()) return; assert(outerCMV.getFinalConsumption() != CastConsumptionKind::CopyOnSuccess && "copy-on-success value with cleanup?"); scope.pushCleanupState(outerMV.getCleanup(), CleanupState::PersistentlyActive); } namespace { class ArgForwarderBase { SILGenFunction &SGF; CleanupStateRestorationScope Scope; protected: ArgForwarderBase(SILGenFunction &SGF) : SGF(SGF), Scope(SGF.Cleanups) {} ConsumableManagedValue forward(ConsumableManagedValue value, SILLocation loc) { return forwardIntoSubtree(SGF, loc, Scope, value); } void forwardIntoIrrefutable(ConsumableManagedValue value) { return forwardIntoIrrefutableSubtree(SGF, Scope, value); } }; /// A RAII-ish object for forwarding a bunch of arguments down to one /// side of a branch. class ArgForwarder : private ArgForwarderBase { ArgArray OuterArgs; SmallVector ForwardedArgsBuffer; public: ArgForwarder(SILGenFunction &SGF, ArgArray outerArgs, SILLocation loc, bool isFinalUse) : ArgForwarderBase(SGF), OuterArgs(outerArgs) { // If this is a final use along this path, we don't need to change // any of the args. However, we do need to make sure that the // cleanup state gets restored later, because being final on this // path isn't the same as being final along all paths. if (isFinalUse) { for (auto &outerArg : outerArgs) forwardIntoIrrefutable(outerArg); } else { ForwardedArgsBuffer.reserve(outerArgs.size()); for (auto &outerArg : outerArgs) ForwardedArgsBuffer.push_back(forward(outerArg, loc)); } } ArgArray getForwardedArgs() const { if (didForwardArgs()) return ForwardedArgsBuffer; return OuterArgs; } private: bool didForwardArgs() const { return !ForwardedArgsBuffer.empty(); } }; /// A RAII-ish object for forwarding a bunch of arguments down to one /// side of a branch. class SpecializedArgForwarder : private ArgForwarderBase { ArgArray OuterArgs; bool IsFinalUse; SmallVector ForwardedArgsBuffer; public: /// Construct a specialized arg forwarder for a (locally) successful /// dispatch. SpecializedArgForwarder(SILGenFunction &SGF, ArgArray outerArgs, unsigned column, ArgArray newArgs, SILLocation loc, bool isFinalUse) : ArgForwarderBase(SGF), OuterArgs(outerArgs), IsFinalUse(isFinalUse) { assert(column < outerArgs.size()); ForwardedArgsBuffer.reserve(outerArgs.size() - 1 + newArgs.size()); // Place the new columns with the column-specialization algorithm: // - place the first new column (if any) in the same position as the // original column; // - if there are no new columns, and the removed column was not // the last column, the last column is moved to the removed column. // The outer columns before the specialized column. for (unsigned i = 0, e = column; i != e; ++i) ForwardedArgsBuffer.push_back(forward(outerArgs[i], loc)); // The specialized column. if (!newArgs.empty()) { ForwardedArgsBuffer.push_back(newArgs[0]); newArgs = newArgs.slice(1); } else if (column + 1 < outerArgs.size()) { ForwardedArgsBuffer.push_back(forward(outerArgs.back(), loc)); outerArgs = outerArgs.slice(0, outerArgs.size() - 1); } // The rest of the outer columns. for (unsigned i = column + 1, e = outerArgs.size(); i != e; ++i) ForwardedArgsBuffer.push_back(forward(outerArgs[i], loc)); // The rest of the new args. ForwardedArgsBuffer.append(newArgs.begin(), newArgs.end()); } /// Returns the forward arguments. The new rows are placed using /// the column-specialization algorithm. ArgArray getForwardedArgs() const { return ForwardedArgsBuffer; } private: ConsumableManagedValue forward(ConsumableManagedValue value, SILLocation loc) { if (IsFinalUse) { ArgForwarderBase::forwardIntoIrrefutable(value); return value; } else { return ArgForwarderBase::forward(value, loc); } } }; /// A RAII-ish object for undoing the forwarding of cleanups along a /// failure path. class ArgUnforwarder { SILGenFunction &SGF; CleanupStateRestorationScope Scope; public: ArgUnforwarder(SILGenFunction &SGF) : SGF(SGF), Scope(SGF.Cleanups) {} static bool requiresUnforwarding(SILGenFunction &SGF, ConsumableManagedValue operand) { return operand.hasCleanup() && operand.getFinalConsumption() == CastConsumptionKind::TakeOnSuccess; } /// Given that an aggregate was divided into a set of borrowed /// values which are now being tracked individually, temporarily /// disable all of the borrowed-value cleanups and restore the /// aggregate cleanup. void unforwardBorrowedValues(ConsumableManagedValue aggregate, ArgArray subobjects) { if (!requiresUnforwarding(SGF, aggregate)) return; Scope.pushCleanupState(aggregate.getCleanup(), CleanupState::Active); for (auto &subobject : subobjects) { if (subobject.hasCleanup()) Scope.pushCleanupState(subobject.getCleanup(), CleanupState::Dormant); } } }; } // end anonymous namespace /// Return the dispatchable length of the given column. static unsigned getConstructorPrefix(const ClauseMatrix &matrix, unsigned firstRow, unsigned column) { assert(firstRow < matrix.rows() && "getting column constructor prefix in matrix with no rows remaining?"); // Require the first row to be a non-wildcard. auto first = getSpecializingPattern(matrix[firstRow][column]); if (!first) return 0; // Then count the number of rows with the same kind of pattern. unsigned row = firstRow + 1; for (unsigned rend = matrix.rows(); row < rend; ++row) { if (!getSimilarSpecializingPattern(matrix[row][column], first)) break; } return row - firstRow; } /// Select the "necessary column", Maranget's term for the column /// most likely to give an optimal decision tree. /// /// \return None if we didn't find a meaningful necessary column static Optional chooseNecessaryColumn(const ClauseMatrix &matrix, unsigned firstRow) { assert(firstRow < matrix.rows() && "choosing necessary column of matrix with no rows remaining?"); // First of all, if we have zero or one columns, this is trivial // to decide. auto numColumns = matrix[firstRow].columns(); if (numColumns <= 1) { if (numColumns == 1 && !isWildcardPattern(matrix[firstRow][0])) { return 0; } return None; } // Use the "constructor prefix" heuristic from Maranget to pick the // necessary column. The column with the most pattern nodes prior to a // wildcard turns out to be a good and cheap-to-calculate heuristic for // generating an optimal decision tree. We ignore patterns that aren't // similar to the head pattern. Optional bestColumn; unsigned longestConstructorPrefix = 0; for (unsigned c = 0; c != numColumns; ++c) { unsigned constructorPrefix = getConstructorPrefix(matrix, firstRow, c); if (constructorPrefix > longestConstructorPrefix) { longestConstructorPrefix = constructorPrefix; bestColumn = c; } } return bestColumn; } /// Recursively emit a decision tree from the given pattern matrix. void PatternMatchEmission::emitDispatch(ClauseMatrix &clauses, ArgArray args, const FailureHandler &outerFailure) { if (clauses.rows() == 0) { SGF.B.createUnreachable(SILLocation(PatternMatchStmt)); return; } unsigned firstRow = 0; while (true) { // If there are no rows remaining, then we fail. if (firstRow == clauses.rows()) { outerFailure(clauses[clauses.rows() - 1].getCasePattern()); return; } // Try to find a "necessary column". Optional column = chooseNecessaryColumn(clauses, firstRow); // Emit the subtree in its own scope. ExitableFullExpr scope(SGF, CleanupLocation(PatternMatchStmt)); auto innerFailure = [&](SILLocation loc) { if (firstRow == clauses.rows()) return outerFailure(loc); SGF.Cleanups.emitBranchAndCleanups(scope.getExitDest(), loc); }; // If there is no necessary column, just emit the first row. if (!column) { unsigned wildcardRow = firstRow++; emitWildcardDispatch(clauses, args, wildcardRow, innerFailure); } else { // Otherwise, specialize on the necessary column. emitSpecializedDispatch(clauses, args, firstRow, column.getValue(), innerFailure); } assert(!SGF.B.hasValidInsertionPoint()); SILBasicBlock *contBB = scope.exit(); // If the continuation block has no uses, ... if (contBB->pred_empty()) { // If we have no more rows to emit, clear the IP and destroy the // continuation block. if (firstRow == clauses.rows()) { SGF.B.clearInsertionPoint(); SGF.eraseBasicBlock(contBB); return; } // Otherwise, if there is no fallthrough, then the next row is // unreachable: emit a dead code diagnostic. if (!clauses[firstRow].hasFallthroughTo()) { SourceLoc Loc; bool isDefault = false; if (auto *S = clauses[firstRow].getClientData()) { Loc = S->getStartLoc(); if (auto *CS = dyn_cast(S)) isDefault = CS->isDefault(); } else { Loc = clauses[firstRow].getCasePattern()->getStartLoc(); } SGF.SGM.diagnose(Loc, diag::unreachable_case, isDefault); } } } } /// Emit the decision tree for a row containing only non-specializing /// patterns. /// /// \param matrixArgs - appropriate for the entire clause matrix, not /// just this one row void PatternMatchEmission::emitWildcardDispatch(ClauseMatrix &clauses, ArgArray matrixArgs, unsigned row, const FailureHandler &failure) { // Get appropriate arguments. ArgForwarder forwarder(SGF, matrixArgs, clauses[row].getCasePattern(), /*isFinalUse*/ row + 1 == clauses.rows()); ArgArray args = forwarder.getForwardedArgs(); // Bind all the refutable patterns first. We want to do this first // so that we can treat the rest of the bindings as inherently // successful if we don't have a guard. This approach assumes that // expression patterns can't refer to bound arguments. bindRefutablePatterns(clauses[row], args, failure); // Okay, the rest of the bindings are irrefutable if there isn't a guard. Expr *guardExpr = clauses[row].getCaseGuardExpr(); bool hasGuard = guardExpr != nullptr; assert(!hasGuard || !clauses[row].isIrrefutable()); auto stmt = clauses[row].getClientData(); assert(isa(stmt) || isa(stmt)); auto *caseStmt = dyn_cast(stmt); bool hasMultipleItems = caseStmt && (clauses[row].hasFallthroughTo() || caseStmt->getCaseLabelItems().size() > 1); // Bind the rest of the patterns. bindIrrefutablePatterns(clauses[row], args, !hasGuard, hasMultipleItems); // Emit the guard branch, if it exists. if (guardExpr) { this->emitGuardBranch(guardExpr, guardExpr, failure); } // Enter the row. CompletionHandler(*this, args, clauses[row]); assert(!SGF.B.hasValidInsertionPoint()); } /// Bind all the refutable patterns in the given row. void PatternMatchEmission:: bindRefutablePatterns(const ClauseRow &row, ArgArray args, const FailureHandler &failure) { assert(row.columns() == args.size()); for (unsigned i = 0, e = args.size(); i != e; ++i) { if (!row[i]) // We use null patterns to mean artificial AnyPatterns continue; Pattern *pattern = row[i]->getSemanticsProvidingPattern(); switch (pattern->getKind()) { // Irrefutable patterns that we'll handle in a later pass. case PatternKind::Any: break; case PatternKind::Named: break; case PatternKind::Expr: { ExprPattern *exprPattern = cast(pattern); DebugLocOverrideRAII LocOverride{SGF.B, getSubjectLocationOverride(pattern)}; FullExpr scope(SGF.Cleanups, CleanupLocation(pattern)); bindVariable(pattern, exprPattern->getMatchVar(), args[i], /*isForSuccess*/ false, /* hasMultipleItems */ false); emitGuardBranch(pattern, exprPattern->getMatchExpr(), failure); break; } default: llvm_unreachable("bad pattern kind"); } } } /// Bind all the irrefutable patterns in the given row, which is nothing /// but wildcard patterns. /// /// Note that forIrrefutableRow can be true even if !row.isIrrefutable() /// because we might have already bound all the refutable parts. void PatternMatchEmission::bindIrrefutablePatterns(const ClauseRow &row, ArgArray args, bool forIrrefutableRow, bool hasMultipleItems) { assert(row.columns() == args.size()); for (unsigned i = 0, e = args.size(); i != e; ++i) { if (!row[i]) // We use null patterns to mean artificial AnyPatterns continue; Pattern *pattern = row[i]->getSemanticsProvidingPattern(); switch (pattern->getKind()) { case PatternKind::Any: // We can just drop Any values. break; case PatternKind::Expr: // Ignore expression patterns, which we should have // bound in an earlier pass. break; case PatternKind::Named: { NamedPattern *named = cast(pattern); bindVariable(pattern, named->getDecl(), args[i], forIrrefutableRow, hasMultipleItems); break; } default: llvm_unreachable("bad pattern kind"); } } } /// Should we take control of the mang static bool shouldTake(ConsumableManagedValue value, bool isIrrefutable) { switch (value.getFinalConsumption()) { case CastConsumptionKind::TakeAlways: return true; case CastConsumptionKind::TakeOnSuccess: return isIrrefutable; case CastConsumptionKind::CopyOnSuccess: return false; case CastConsumptionKind::BorrowAlways: return false; } llvm_unreachable("bad consumption kind"); } /// Bind a variable into the current scope. void PatternMatchEmission::bindVariable(Pattern *pattern, VarDecl *var, ConsumableManagedValue value, bool isIrrefutable, bool hasMultipleItems) { // If this binding is one of multiple patterns, each individual binding // will just be let, and then the chosen value will get forwarded into // a var box in the final shared case block. bool immutable = var->isLet() || hasMultipleItems; // Initialize the variable value. InitializationPtr init = SGF.emitInitializationForVarDecl(var, immutable); auto mv = value.getFinalManagedValue(); if (shouldTake(value, isIrrefutable)) { mv.forwardInto(SGF, pattern, init.get()); } else { mv.copyInto(SGF, pattern, init.get()); } } /// Evaluate a guard expression and, if it returns false, branch to /// the given destination. void PatternMatchEmission::emitGuardBranch(SILLocation loc, Expr *guard, const FailureHandler &failure) { SILBasicBlock *falseBB = SGF.B.splitBlockForFallthrough(); SILBasicBlock *trueBB = SGF.B.splitBlockForFallthrough(); // Emit the match test. SILValue testBool; { FullExpr scope(SGF.Cleanups, CleanupLocation(guard)); testBool = SGF.emitRValueAsSingleValue(guard).getUnmanagedValue(); } // Extract the i1 from the Bool struct. auto i1Value = SGF.emitUnwrapIntegerResult(loc, testBool); SGF.B.createCondBranch(loc, i1Value, trueBB, falseBB); SGF.B.setInsertionPoint(falseBB); failure(loc); SGF.B.setInsertionPoint(trueBB); } /// Perform specialized dispatch on the particular column. /// /// \param matrixArgs - appropriate for the entire clause matrix, not /// just these specific rows void PatternMatchEmission::emitSpecializedDispatch(ClauseMatrix &clauses, ArgArray matrixArgs, unsigned &lastRow, unsigned column, const FailureHandler &failure) { // HEY! LISTEN! // // When a pattern specializes its submatrix (like an 'as' or enum element // pattern), it *must* chain the FailureHandler for its inner submatrixes // through our `failure` handler if it manipulates any cleanup state. // Here's an example from emitEnumElementDispatch: // // const FailureHandler *innerFailure = &failure; // FailureHandler specializedFailure = [&](SILLocation loc) { // ArgUnforwarder unforwarder(SGF); // unforwarder.unforwardBorrowedValues(src, origCMV); // failure(loc); // }; // // if (ArgUnforwarder::requiresUnforwarding(src)) // innerFailure = &specializedFailure; // // Note that the inner failure handler either is exactly the outer failure // or performs the work necessary to clean up after the failed specialized // decision tree immediately before chaining onto the outer failure. // It is specifically NOT correct to do something like this: // // /* DON'T DO THIS */ // ExitableFullExpr scope; // FailureHandler innerFailure = [&](SILLocation loc) { // emitBranchAndCleanups(scope, loc); // }; // ... // /* DON'T DO THIS */ // scope.exit(); // ArgUnforwarder unforwarder(SGF); // unforwarder.unforwardBorrowedValues(src, origCMV); // failure(loc); // /* DON'T DO THIS */ // // since the cleanup state changes performed by ArgUnforwarder will // occur too late. unsigned firstRow = lastRow; // Collect the rows to specialize. SmallVector rowsToSpecialize; auto addRowToSpecialize = [&](Pattern *pattern, unsigned rowIndex) { assert(getSpecializingPattern(clauses[rowIndex][column]) == pattern); bool irrefutable = clauses[rowIndex].isIrrefutableAfterSpecializing(column); auto caseBlock = clauses[rowIndex].getClientData(); ProfileCounter count = ProfileCounter(); if (caseBlock) { count = SGF.loadProfilerCount(caseBlock); } rowsToSpecialize.push_back({pattern, rowIndex, irrefutable, count}); }; ProfileCounter defaultCaseCount = ProfileCounter(); Pattern *firstSpecializer = getSpecializingPattern(clauses[firstRow][column]); assert(firstSpecializer && "specializing unspecializable row?"); addRowToSpecialize(firstSpecializer, firstRow); // Take a prefix of rows that share the same semantic kind of pattern. for (++lastRow; lastRow != clauses.rows(); ++lastRow) { Pattern *specializer = getSimilarSpecializingPattern(clauses[lastRow][column], firstSpecializer); if (!specializer) { auto caseBlock = clauses[lastRow].getClientData(); if (caseBlock) { defaultCaseCount = SGF.loadProfilerCount(caseBlock); } break; } addRowToSpecialize(specializer, lastRow); } assert(lastRow - firstRow == rowsToSpecialize.size()); // Forward just the specialized argument right now. We'll forward // the rest in the handler. bool isFinalUse = (lastRow == clauses.rows()); ArgForwarder outerForwarder(SGF, matrixArgs[column], firstSpecializer, isFinalUse); auto arg = outerForwarder.getForwardedArgs()[0]; SpecializationHandler handler = [&](ArrayRef newArgs, ArrayRef rows, const FailureHandler &innerFailure) { // These two operations must follow the same rules for column // placement because 'arguments' are parallel to the matrix columns. // We use the column-specialization algorithm described in // specializeInPlace. ClauseMatrix innerClauses = clauses.specializeRowsInPlace(column, rows); SpecializedArgForwarder innerForwarder(SGF, matrixArgs, column, newArgs, firstSpecializer, isFinalUse); ArgArray innerArgs = innerForwarder.getForwardedArgs(); emitDispatch(innerClauses, innerArgs, innerFailure); }; switch (firstSpecializer->getKind()) { case PatternKind::Any: case PatternKind::Expr: case PatternKind::Named: llvm_unreachable("cannot specialize wildcard pattern"); case PatternKind::Paren: case PatternKind::Typed: case PatternKind::Var: llvm_unreachable("non-semantic pattern kind!"); case PatternKind::Tuple: return emitTupleDispatch(rowsToSpecialize, arg, handler, failure); case PatternKind::Is: return emitIsDispatch(rowsToSpecialize, arg, handler, failure); case PatternKind::EnumElement: case PatternKind::OptionalSome: return emitEnumElementDispatch(rowsToSpecialize, arg, handler, failure, defaultCaseCount); case PatternKind::Bool: return emitBoolDispatch(rowsToSpecialize, arg, handler, failure); } llvm_unreachable("bad pattern kind"); }; /// Given that we've broken down a source value into this subobject, /// and that we were supposed to use the given consumption rules on /// it, construct an appropriate managed value. static ConsumableManagedValue getManagedSubobject(SILGenFunction &SGF, SILValue value, const TypeLowering &valueTL, CastConsumptionKind consumption) { switch (consumption) { case CastConsumptionKind::BorrowAlways: case CastConsumptionKind::CopyOnSuccess: return {ManagedValue::forUnmanaged(value), consumption}; case CastConsumptionKind::TakeAlways: case CastConsumptionKind::TakeOnSuccess: return {SGF.emitManagedRValueWithCleanup(value, valueTL), consumption}; } llvm_unreachable("covered switch"); } static ConsumableManagedValue emitReabstractedSubobject(SILGenFunction &SGF, SILLocation loc, ConsumableManagedValue value, const TypeLowering &valueTL, AbstractionPattern abstraction, CanType substFormalType) { // Return if there's no abstraction. (The first condition is just // a fast path.) if (value.getType().getASTType() == substFormalType || value.getType() == SGF.getLoweredType(substFormalType)) return value; // Otherwise, turn to +1 and re-abstract. ManagedValue mv = SGF.getManagedValue(loc, value); return ConsumableManagedValue::forOwned( SGF.emitOrigToSubstValue(loc, mv, abstraction, substFormalType)); } void PatternMatchEmission::emitTupleObjectDispatch( ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleCase, const FailureHandler &outerFailure) { // Construct the specialized rows. SmallVector specializedRows; specializedRows.resize(rows.size()); for (unsigned i = 0, e = rows.size(); i != e; ++i) { specializedRows[i].RowIndex = rows[i].RowIndex; auto pattern = cast(rows[i].Pattern); for (auto &elt : pattern->getElements()) { specializedRows[i].Patterns.push_back(elt.getPattern()); } } auto firstPat = rows[0].Pattern; SILLocation loc = firstPat; // Final consumption here will be either BorrowAlways or TakeAlways. ManagedValue v = src.getFinalManagedValue(); SmallVector destructured; SGF.B.emitDestructureValueOperation( loc, v, [&](unsigned index, ManagedValue v) { destructured.push_back({v, src.getFinalConsumption()}); }); // Since we did all of our work at +0, we just send down the outer failure. handleCase(destructured, specializedRows, outerFailure); } /// Perform specialized dispatch for tuples. /// /// This is simple; all the tuples have the same structure. void PatternMatchEmission:: emitTupleDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleCase, const FailureHandler &outerFailure) { auto firstPat = rows[0].Pattern; SILLocation loc = firstPat; // If our source is an address that is loadable, perform a load_borrow. if (src.getType().isAddress() && src.getType().isLoadable(SGF.F)) { // We should only see take_on_success if we have a base type that is address // only. assert(src.getFinalConsumption() != CastConsumptionKind::TakeOnSuccess && "Can only occur if base type is address only?!"); src = {SGF.B.createLoadBorrow(loc, src.getFinalManagedValue()), CastConsumptionKind::BorrowAlways}; } // Then if we have an object... if (src.getType().isObject()) { // Make sure that if we have a copy_on_success, non-trivial value that we do // not have a value with @owned ownership. assert((!src.getType().isTrivial(SGF.F) || src.getFinalConsumption() != CastConsumptionKind::CopyOnSuccess || src.getOwnershipKind() != ValueOwnershipKind::Owned) && "@owned value without cleanup + copy_on_success"); // We should only see take_on_success if we have a base type that is address // only. assert(src.getFinalConsumption() != CastConsumptionKind::TakeOnSuccess && "Can only occur if base type is address only?!"); // Then perform a forward or reborrow destructure on the object. return emitTupleObjectDispatch(rows, src, handleCase, outerFailure); } // Construct the specialized rows. SmallVector specializedRows; specializedRows.resize(rows.size()); for (unsigned i = 0, e = rows.size(); i != e; ++i) { specializedRows[i].RowIndex = rows[i].RowIndex; auto pattern = cast(rows[i].Pattern); for (auto &elt : pattern->getElements()) { specializedRows[i].Patterns.push_back(elt.getPattern()); } } // At this point we know that we must have an address only type, since we // would have loaded it earlier. SILValue v = src.getFinalManagedValue().forward(SGF); assert(v->getType().isAddressOnly(SGF.F) && "Loadable values were handled earlier"); // The destructured tuple that we pass off to our sub pattern. This may // contain values that we have performed a load_borrow from subsequent to // "performing a SILGenPattern borrow". SmallVector subPatternArgs; // An array of values that have the same underlying values as our // subPatternArgs, but may have a different cleanup and final consumption // kind. These are at +1 and are unforwarded. SmallVector unforwardArgs; // Break down the values. auto tupleSILTy = v->getType(); for (unsigned i : range(tupleSILTy.castTo()->getNumElements())) { SILType fieldTy = tupleSILTy.getTupleElementType(i); auto &fieldTL = SGF.getTypeLowering(fieldTy); SILValue member = SGF.B.createTupleElementAddr(loc, v, i, fieldTy); // Inline constructor. auto memberCMV = ([&]() -> ConsumableManagedValue { if (!fieldTL.isLoadable()) { // If we have an address only type, just get the managed // subobject. return getManagedSubobject(SGF, member, fieldTL, src.getFinalConsumption()); } // If we have a loadable type, then we have a loadable sub-type of the // underlying address only tuple. auto memberMV = ManagedValue::forUnmanaged(member); switch (src.getFinalConsumption()) { case CastConsumptionKind::TakeAlways: { // If our original source value is take always, perform a load [take]. return {SGF.B.createLoadTake(loc, memberMV), CastConsumptionKind::TakeAlways}; } case CastConsumptionKind::TakeOnSuccess: { // If we have a take_on_success, we propagate down the member as a +1 // address value and do not load. // // DISCUSSION: Unforwarding objects violates ownership since // unforwarding relies on forwarding an aggregate into subvalues and // on failure disabling the subvalue cleanups and re-enabling the // cleanup for the aggregate (which was already destroyed). So we are // forced to use an address here so we can forward/unforward this // value. We maintain our invariants that loadable types are always // loaded and are never take on success by passing down to our // subPattern a borrow of this value. See below. return getManagedSubobject(SGF, member, fieldTL, src.getFinalConsumption()); } case CastConsumptionKind::CopyOnSuccess: { // We translate copy_on_success => borrow_always. auto memberMV = ManagedValue::forUnmanaged(member); return {SGF.B.createLoadBorrow(loc, memberMV), CastConsumptionKind::BorrowAlways}; } case CastConsumptionKind::BorrowAlways: { llvm_unreachable( "Borrow always can only occur along object only code paths"); } } llvm_unreachable("covered switch"); }()); // If we aren't loadable, add to the unforward array. if (!fieldTL.isLoadable()) { unforwardArgs.push_back(memberCMV); } else { // If we have a loadable type that we didn't load, we must have had a // take_on_success address. This means that our parent cleanup is // currently persistently active, so we needed to propagate an active +1 // cleanup on our address so we can take if we actually succeed. That // being said, we do not want to pass objects with take_on_success into // the actual subtree. So we perform a load_borrow at this point. This // will ensure that we will always finish the end_borrow before we jumped // to a failure point, but at the same time the original +1 value will be // appropriately destroyed/forwarded around. if (memberCMV.getType().isAddress()) { unforwardArgs.push_back(memberCMV); auto val = memberCMV.getFinalManagedValue(); memberCMV = {SGF.B.createLoadBorrow(loc, val), CastConsumptionKind::BorrowAlways}; } } subPatternArgs.push_back(memberCMV); } // Maybe revert to the original cleanups during failure branches. const FailureHandler *innerFailure = &outerFailure; FailureHandler specializedFailure = [&](SILLocation loc) { ArgUnforwarder unforwarder(SGF); unforwarder.unforwardBorrowedValues(src, unforwardArgs); outerFailure(loc); }; if (ArgUnforwarder::requiresUnforwarding(SGF, src)) innerFailure = &specializedFailure; // Recurse. handleCase(subPatternArgs, specializedRows, *innerFailure); } static CanType getTargetType(const RowToSpecialize &row) { auto type = cast(row.Pattern)->getCastTypeLoc().getType(); return type->getCanonicalType(); } static ConsumableManagedValue emitCastOperand(SILGenFunction &SGF, SILLocation loc, ConsumableManagedValue src, CanType sourceType, CanType targetType, SmallVectorImpl &borrowedValues) { // Reabstract to the most general abstraction, and put it into a // temporary if necessary. // Figure out if we need the value to be in a temporary. bool requiresAddress = !canUseScalarCheckedCastInstructions(SGF.SGM.M, sourceType, targetType); AbstractionPattern abstraction = SGF.SGM.M.Types.getMostGeneralAbstraction(); auto &srcAbstractTL = SGF.getTypeLowering(abstraction, sourceType); bool hasAbstraction = (src.getType() != srcAbstractTL.getLoweredType()); // Fast path: no re-abstraction required. if (!hasAbstraction && (!requiresAddress || src.getType().isAddress())) { return src; } // We know that we must have a loadable type at this point since address only // types do not need reabstraction and are addresses. So we should have exited // above already. assert(src.getType().isLoadable(SGF.F) && "Should have a loadable value at this point"); // Since our finalValue is loadable, we could not have had a take_on_success // here. assert(src.getFinalConsumption() != CastConsumptionKind::TakeOnSuccess && "Loadable types can not have take_on_success?!"); std::unique_ptr init; SGFContext ctx; if (requiresAddress) { init = SGF.emitTemporary(loc, srcAbstractTL); ctx = SGFContext(init.get()); } // This will always produce a +1 take always value no matter what src's // ownership is. ManagedValue finalValue = SGF.getManagedValue(loc, src); if (hasAbstraction) { // Reabstract the value if we need to. This should produce a +1 value as // well. finalValue = SGF.emitSubstToOrigValue(loc, finalValue, abstraction, sourceType, ctx); } assert(finalValue.isPlusOne(SGF)); // If we at this point do not require an address, return final value. We know // that it is a +1 take always value. if (!requiresAddress) { return ConsumableManagedValue::forOwned(finalValue); } // At this point, we know that we have a non-address only type since we are // materializing an object into memory and addresses can not be stored into // memory. SGF.B.emitStoreValueOperation(loc, finalValue.forward(SGF), init->getAddress(), StoreOwnershipQualifier::Init); init->finishInitialization(SGF); // We know that either our initial value was already take_always or we made a // copy of the underlying value. In either case, we now have a take_always +1 // value. return ConsumableManagedValue::forOwned(init->getManagedAddress()); } /// Perform specialized dispatch for a sequence of IsPatterns. void PatternMatchEmission::emitIsDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleCase, const FailureHandler &failure) { CanType sourceType = rows[0].Pattern->getType()->getCanonicalType(); CanType targetType = getTargetType(rows[0]); // Make any abstraction modifications necessary for casting. SmallVector borrowedValues; ConsumableManagedValue operand = emitCastOperand( SGF, rows[0].Pattern, src, sourceType, targetType, borrowedValues); // Emit the 'is' check. // Build the specialized-rows array. SmallVector specializedRows; specializedRows.reserve(rows.size()); for (auto &row : rows) { assert(getTargetType(row) == targetType && "can only specialize on one type at a time"); auto is = cast(row.Pattern); specializedRows.push_back({}); specializedRows.back().RowIndex = row.RowIndex; specializedRows.back().Patterns.push_back(is->getSubPattern()); } SILLocation loc = rows[0].Pattern; ConsumableManagedValue castOperand = operand.asBorrowedOperand(SGF, loc); // Chain inner failures onto the outer failure. const FailureHandler *innerFailure = &failure; FailureHandler specializedFailure = [&](SILLocation loc) { ArgUnforwarder unforwarder(SGF); unforwarder.unforwardBorrowedValues(src, borrowedValues); failure(loc); }; if (ArgUnforwarder::requiresUnforwarding(SGF, src)) innerFailure = &specializedFailure; // Perform a conditional cast branch. SGF.emitCheckedCastBranch( loc, castOperand, sourceType, targetType, SGFContext(), // Success block: recurse. [&](ManagedValue castValue) { handleCase(ConsumableManagedValue::forOwned(castValue), specializedRows, *innerFailure); assert(!SGF.B.hasValidInsertionPoint() && "did not end block"); }, // Failure block: branch out to the continuation block. [&](Optional mv) { (*innerFailure)(loc); }, rows[0].Count); } namespace { struct CaseInfo { SmallVector SpecializedRows; Pattern *FirstMatcher; bool Irrefutable = false; }; class CaseBlocks { // These vectors are completely parallel, but the switch instructions want // only the first two, so we split them up. SmallVector, 4> CaseBBs; SmallVector CaseCounts; SmallVector CaseInfos; SILBasicBlock *DefaultBB = nullptr; public: /// Create destination blocks for switching over the cases in an enum /// defined by \p rows. CaseBlocks(SILGenFunction &SGF, ArrayRef rows, CanType sourceType, SILBasicBlock *curBB); ArrayRef> getCaseBlocks() const { return CaseBBs; } ArrayRef getCounts() const { return CaseCounts; } SILBasicBlock *getDefaultBlock() const { return DefaultBB; } void forEachCase(llvm::function_ref op) const { for_each(CaseBBs, CaseInfos, [op](std::pair casePair, const CaseInfo &info) { op(casePair.first, casePair.second, info); }); } bool hasAnyRefutableCase() const { return llvm::any_of(CaseInfos, [](const CaseInfo &info) { return !info.Irrefutable; }); } }; } // end anonymous namespace CaseBlocks::CaseBlocks( SILGenFunction &SGF, ArrayRef rows, CanType sourceType, SILBasicBlock *curBB) { CaseBBs.reserve(rows.size()); CaseInfos.reserve(rows.size()); CaseCounts.reserve(rows.size()); auto enumDecl = sourceType.getEnumOrBoundGenericEnum(); llvm::SmallDenseMap caseToIndex; for (auto &row : rows) { EnumElementDecl *formalElt; Pattern *subPattern = nullptr; if (auto eep = dyn_cast(row.Pattern)) { formalElt = eep->getElementDecl(); subPattern = eep->getSubPattern(); } else { auto *osp = cast(row.Pattern); formalElt = osp->getElementDecl(); subPattern = osp->getSubPattern(); } assert(formalElt->getParentEnum() == enumDecl); unsigned index = CaseInfos.size(); auto insertionResult = caseToIndex.insert({formalElt, index}); if (!insertionResult.second) { index = insertionResult.first->second; } else { curBB = SGF.createBasicBlockAfter(curBB); CaseBBs.push_back({formalElt, curBB}); CaseInfos.push_back(CaseInfo()); CaseInfos.back().FirstMatcher = row.Pattern; CaseCounts.push_back(row.Count); } assert(caseToIndex[formalElt] == index); assert(CaseBBs[index].first == formalElt); auto &info = CaseInfos[index]; info.Irrefutable = (info.Irrefutable || row.Irrefutable); info.SpecializedRows.push_back(SpecializedRow()); auto &specRow = info.SpecializedRows.back(); specRow.RowIndex = row.RowIndex; // Use the row pattern, if it has one. if (subPattern) { specRow.Patterns.push_back(subPattern); // It's also legal to write: // case .Some { ... } // which is an implicit wildcard. } else { specRow.Patterns.push_back(nullptr); } } assert(CaseBBs.size() == CaseInfos.size()); // Check to see if the enum may have values beyond the cases we can see // at compile-time. This includes future cases (for resilient enums) and // random values crammed into C enums. bool canAssumeExhaustive = enumDecl->isEffectivelyExhaustive(SGF.getModule().getSwiftModule(), SGF.F.getResilienceExpansion()); if (canAssumeExhaustive) { // Check that Sema didn't let any cases slip through. canAssumeExhaustive = llvm::all_of(enumDecl->getAllElements(), [&](const EnumElementDecl *elt) { return caseToIndex.count(elt); }); } if (!canAssumeExhaustive) DefaultBB = SGF.createBasicBlockAfter(curBB); } /// Perform specialized dispatch for a sequence of EnumElementPattern or an /// OptionalSomePattern. void PatternMatchEmission::emitEnumElementObjectDispatch( ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleCase, const FailureHandler &outerFailure, ProfileCounter defaultCastCount) { assert(src.getFinalConsumption() != CastConsumptionKind::TakeOnSuccess && "SIL ownership does not support TakeOnSuccess"); CanType sourceType = rows[0].Pattern->getType()->getCanonicalType(); // Collect the cases and specialized rows. CaseBlocks blocks{SGF, rows, sourceType, SGF.B.getInsertionBB()}; SILLocation loc = PatternMatchStmt; loc.setDebugLoc(rows[0].Pattern); bool isPlusZero = src.getFinalConsumption() == CastConsumptionKind::BorrowAlways; SILValue srcValue = src.getFinalManagedValue().forward(SGF); SGF.B.createSwitchEnum(loc, srcValue, blocks.getDefaultBlock(), blocks.getCaseBlocks(), blocks.getCounts(), defaultCastCount); // Okay, now emit all the cases. blocks.forEachCase([&](EnumElementDecl *elt, SILBasicBlock *caseBB, const CaseInfo &caseInfo) { SILLocation loc = caseInfo.FirstMatcher; auto &specializedRows = caseInfo.SpecializedRows; SGF.B.setInsertionPoint(caseBB); // We're in conditionally-executed code; enter a scope. Scope scope(SGF.Cleanups, CleanupLocation::get(loc)); // Create a BB argument or 'unchecked_take_enum_data_addr' // instruction to receive the enum case data if it has any. SILType eltTy; bool hasNonVoidAssocValue = false; bool hasAssocValue = elt->hasAssociatedValues(); if (hasAssocValue) { eltTy = src.getType().getEnumElementType(elt, SGF.SGM.M); hasNonVoidAssocValue = !eltTy.getASTType()->isVoid(); } ConsumableManagedValue eltCMV, origCMV; // Void (i.e. empty) cases. // if (!hasNonVoidAssocValue) { // Inline constructor. eltCMV = [&]() -> ConsumableManagedValue { // If we have an associated value, rather than no payload at all, we // still need to create the argument. So do that instead of creating the // empty-tuple. Otherwise, we need to create undef or the empty-tuple. if (hasAssocValue) { return {SGF.B.createOwnedPhiArgument(eltTy), CastConsumptionKind::TakeAlways}; } // Otherwise, try to avoid making an empty tuple value if it's obviously // going to be ignored. This assumes that we won't even try to touch the // value in such cases, although we may touch the cleanup (enough to see // that it's not present). bool hasNonAny = llvm::any_of(specializedRows, [&](const SpecializedRow &row) { auto *p = row.Patterns[0]; return p && !isa(p->getSemanticsProvidingPattern()); }); if (hasNonAny) { return ConsumableManagedValue::forUnmanaged(SGF.emitEmptyTuple(loc)); } return ConsumableManagedValue::forUnmanaged( SILUndef::get(SGF.SGM.Types.getEmptyTupleType(), SGF.F)); }(); // Okay, specialize on the argument. } else { auto *eltTL = &SGF.getTypeLowering(eltTy); SILValue eltValue; if (isPlusZero) { origCMV = {SGF.B.createGuaranteedPhiArgument(eltTy), CastConsumptionKind::BorrowAlways}; } else { origCMV = {SGF.B.createOwnedPhiArgument(eltTy), CastConsumptionKind::TakeAlways}; } eltCMV = origCMV; // If the payload is boxed, project it. if (elt->isIndirect() || elt->getParentEnum()->isIndirect()) { ManagedValue boxedValue = SGF.B.createProjectBox(loc, origCMV.getFinalManagedValue(), 0); eltTL = &SGF.getTypeLowering(boxedValue.getType()); if (eltTL->isLoadable()) { boxedValue = SGF.B.createLoadBorrow(loc, boxedValue); eltCMV = {boxedValue, CastConsumptionKind::BorrowAlways}; } else { // Otherwise, we have an address only payload and we use // copy on success instead. eltCMV = {boxedValue, CastConsumptionKind::CopyOnSuccess}; } } // Reabstract to the substituted type, if needed. CanType substEltTy = sourceType ->getTypeOfMember(SGF.SGM.M.getSwiftModule(), elt, elt->getArgumentInterfaceType()) ->getCanonicalType(); AbstractionPattern origEltTy = (elt->getParentEnum()->isOptionalDecl() ? AbstractionPattern(substEltTy) : SGF.SGM.M.Types.getAbstractionPattern(elt)); // If we reabstracted, we may have a +1 value returned. We are ok with // that as long as it is TakeAlways. eltCMV = emitReabstractedSubobject(SGF, loc, eltCMV, *eltTL, origEltTy, substEltTy); } handleCase(eltCMV, specializedRows, outerFailure); assert(!SGF.B.hasValidInsertionPoint() && "did not end block"); }); // Emit the default block if we needed one. if (SILBasicBlock *defaultBB = blocks.getDefaultBlock()) { SGF.B.setInsertionPoint(defaultBB); if (isPlusZero) { SGF.B.createGuaranteedPhiArgument(src.getType()); } else { SGF.B.createOwnedPhiArgument(src.getType()); } outerFailure(rows.back().Pattern); } } /// Perform specialized dispatch for a sequence of EnumElementPattern or an /// OptionalSomePattern. void PatternMatchEmission::emitEnumElementDispatch( ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleCase, const FailureHandler &outerFailure, ProfileCounter defaultCaseCount) { // Why do we need to do this here (I just cargo culted this). SILLocation loc = PatternMatchStmt; loc.setDebugLoc(rows[0].Pattern); // If our source is an address that is loadable, perform a load_borrow. if (src.getType().isAddress() && src.getType().isLoadable(SGF.F)) { assert(src.getFinalConsumption() != CastConsumptionKind::TakeOnSuccess && "Can only have take_on_success with address only values"); src = {SGF.B.createLoadBorrow(loc, src.getFinalManagedValue()), CastConsumptionKind::BorrowAlways}; } // If we have an object... if (src.getType().isObject()) { // Do a quick assert that we do not have take_on_success. This should only // be passed take_on_success if src is an address only type. assert(src.getFinalConsumption() != CastConsumptionKind::TakeOnSuccess && "Can only have take_on_success with address only values"); // Finally perform the enum element dispatch. return emitEnumElementObjectDispatch(rows, src, handleCase, outerFailure, defaultCaseCount); } // After this point we now that we must have an address only type. assert(src.getType().isAddressOnly(SGF.F) && "Should have an address only type here"); CanType sourceType = rows[0].Pattern->getType()->getCanonicalType(); // Collect the cases and specialized rows. CaseBlocks blocks{SGF, rows, sourceType, SGF.B.getInsertionBB()}; // We lack a SIL instruction to nondestructively project data from an // address-only enum, so we can only do so in place if we're allowed to take // the source always. Copy the source if we can't. switch (src.getFinalConsumption()) { case CastConsumptionKind::TakeAlways: case CastConsumptionKind::CopyOnSuccess: case CastConsumptionKind::BorrowAlways: // No change to src necessary. break; case CastConsumptionKind::TakeOnSuccess: // If any of the specialization cases is refutable, we must copy. if (!blocks.hasAnyRefutableCase()) break; src = ConsumableManagedValue(ManagedValue::forUnmanaged(src.getValue()), CastConsumptionKind::CopyOnSuccess); break; } // Emit the switch_enum_addr instruction. SILValue srcValue = src.getFinalManagedValue().forward(SGF); SGF.B.createSwitchEnumAddr(loc, srcValue, blocks.getDefaultBlock(), blocks.getCaseBlocks(), blocks.getCounts(), defaultCaseCount); // Okay, now emit all the cases. blocks.forEachCase([&](EnumElementDecl *elt, SILBasicBlock *caseBB, const CaseInfo &caseInfo) { SILLocation loc = caseInfo.FirstMatcher; auto &specializedRows = caseInfo.SpecializedRows; SGF.B.setInsertionPoint(caseBB); // We're in conditionally-executed code; enter a scope. Scope scope(SGF.Cleanups, CleanupLocation::get(loc)); // Create a BB argument or 'unchecked_take_enum_data_addr' // instruction to receive the enum case data if it has any. SILType eltTy; bool hasElt = false; if (elt->hasAssociatedValues()) { eltTy = src.getType().getEnumElementType(elt, SGF.SGM.M); hasElt = !eltTy.getASTType()->isVoid(); } ConsumableManagedValue eltCMV, origCMV; // Empty cases. Try to avoid making an empty tuple value if it's // obviously going to be ignored. This assumes that we won't even // try to touch the value in such cases, although we may touch the // cleanup (enough to see that it's not present). if (!hasElt) { bool hasNonAny = false; for (auto &specRow : specializedRows) { auto pattern = specRow.Patterns[0]; if (pattern && !isa(pattern->getSemanticsProvidingPattern())) { hasNonAny = true; break; } } SILValue result; if (hasNonAny) { result = SGF.emitEmptyTuple(loc); } else { result = SILUndef::get(SGF.SGM.Types.getEmptyTupleType(), SGF.F); } origCMV = ConsumableManagedValue::forUnmanaged(result); eltCMV = origCMV; // Okay, specialize on the argument. } else { auto *eltTL = &SGF.getTypeLowering(eltTy); // Normally we'd just use the consumption of the source // because the difference between TakeOnSuccess and TakeAlways // doesn't matter for irrefutable rows. But if we need to // re-abstract, we'll see a lot of benefit from figuring out // that we can use TakeAlways here. auto eltConsumption = src.getFinalConsumption(); if (caseInfo.Irrefutable && eltConsumption == CastConsumptionKind::TakeOnSuccess) { eltConsumption = CastConsumptionKind::TakeAlways; } SILValue eltValue; // We can only project destructively from an address-only enum, so // copy the value if we can't consume it. // TODO: Should have a more efficient way to copy payload // nondestructively from an enum. switch (eltConsumption) { case CastConsumptionKind::TakeAlways: eltValue = SGF.B.createUncheckedTakeEnumDataAddr(loc, srcValue, elt, eltTy); break; case CastConsumptionKind::BorrowAlways: // If we reach this point, we know that we have a loadable // element type from an enum with mixed address // only/loadable cases. Since we had an address only type, // we assume that we will not have BorrowAlways since // address only types do not support BorrowAlways. llvm_unreachable("not allowed"); case CastConsumptionKind::CopyOnSuccess: { auto copy = SGF.emitTemporaryAllocation(loc, srcValue->getType()); SGF.B.createCopyAddr(loc, srcValue, copy, IsNotTake, IsInitialization); // We can always take from the copy. eltConsumption = CastConsumptionKind::TakeAlways; eltValue = SGF.B.createUncheckedTakeEnumDataAddr(loc, copy, elt, eltTy); break; } // We can't conditionally take, since UncheckedTakeEnumDataAddr // invalidates the enum. case CastConsumptionKind::TakeOnSuccess: llvm_unreachable("not allowed"); } // If we have a loadable payload despite the enum being address only, load // the value. This invariant makes it easy to specialize code for // ownership. if (eltTL->isLoadable()) { // If we do not have a loadable value, just use getManagedSubObject // Load a loadable data value. auto managedEltValue = ManagedValue::forUnmanaged(eltValue); if (eltConsumption == CastConsumptionKind::CopyOnSuccess) { managedEltValue = SGF.B.createLoadBorrow(loc, managedEltValue); eltConsumption = CastConsumptionKind::BorrowAlways; } else { assert(eltConsumption == CastConsumptionKind::TakeAlways); managedEltValue = SGF.B.createLoadTake(loc, managedEltValue); } origCMV = {managedEltValue, eltConsumption}; } else { origCMV = getManagedSubobject(SGF, eltValue, *eltTL, eltConsumption); } eltCMV = origCMV; // If the payload is boxed, project it. if (elt->isIndirect() || elt->getParentEnum()->isIndirect()) { ManagedValue boxedValue = SGF.B.createProjectBox(loc, origCMV.getFinalManagedValue(), 0); eltTL = &SGF.getTypeLowering(boxedValue.getType()); if (eltTL->isLoadable()) { boxedValue = SGF.B.createLoadBorrow(loc, boxedValue); eltCMV = {boxedValue, CastConsumptionKind::BorrowAlways}; } else { // The boxed value may be shared, so we always have to copy it. eltCMV = getManagedSubobject(SGF, boxedValue.getValue(), *eltTL, CastConsumptionKind::CopyOnSuccess); } } // Reabstract to the substituted type, if needed. CanType substEltTy = sourceType->getTypeOfMember(SGF.SGM.M.getSwiftModule(), elt, elt->getArgumentInterfaceType()) ->getCanonicalType(); AbstractionPattern origEltTy = (elt->getParentEnum()->isOptionalDecl() ? AbstractionPattern(substEltTy) : SGF.SGM.M.Types.getAbstractionPattern(elt)); eltCMV = emitReabstractedSubobject(SGF, loc, eltCMV, *eltTL, origEltTy, substEltTy); } const FailureHandler *innerFailure = &outerFailure; FailureHandler specializedFailure = [&](SILLocation loc) { ArgUnforwarder unforwarder(SGF); unforwarder.unforwardBorrowedValues(src, origCMV); outerFailure(loc); }; if (ArgUnforwarder::requiresUnforwarding(SGF, src)) innerFailure = &specializedFailure; handleCase(eltCMV, specializedRows, *innerFailure); assert(!SGF.B.hasValidInsertionPoint() && "did not end block"); }); // Emit the default block if we needed one. if (SILBasicBlock *defaultBB = blocks.getDefaultBlock()) { SGF.B.setInsertionPoint(defaultBB); outerFailure(rows.back().Pattern); } } /// Perform specialized dispatch for a sequence of EnumElementPattern or an /// OptionalSomePattern. void PatternMatchEmission:: emitBoolDispatch(ArrayRef rows, ConsumableManagedValue src, const SpecializationHandler &handleCase, const FailureHandler &outerFailure) { struct CaseInfo { Pattern *FirstMatcher; bool Irrefutable = false; SmallVector SpecializedRows; }; SILBasicBlock *curBB = SGF.B.getInsertionBB(); auto &Context = SGF.getASTContext(); // Collect the cases and specialized rows. // // These vectors are completely parallel, but the switch // instructions want only the first information, so we split them up. SmallVector, 4> caseBBs; SmallVector caseInfos; SILBasicBlock *defaultBB = nullptr; caseBBs.reserve(rows.size()); caseInfos.reserve(rows.size()); // Create destination blocks for all the cases. unsigned caseToIndex[2] = { ~0U, ~0U }; for (auto &row : rows) { bool isTrue = cast(row.Pattern)->getValue(); unsigned index = caseInfos.size(); if (caseToIndex[isTrue] != ~0U) { // We already had an entry for this bool value. index = caseToIndex[isTrue]; } else { caseToIndex[isTrue] = index; curBB = SGF.createBasicBlockAfter(curBB); auto *IL = SGF.B.createIntegerLiteral(PatternMatchStmt, SILType::getBuiltinIntegerType(1, Context), isTrue ? 1 : 0); caseBBs.push_back({SILValue(IL), curBB}); caseInfos.resize(caseInfos.size() + 1); caseInfos.back().FirstMatcher = row.Pattern; } auto &info = caseInfos[index]; info.Irrefutable = (info.Irrefutable || row.Irrefutable); info.SpecializedRows.resize(info.SpecializedRows.size() + 1); auto &specRow = info.SpecializedRows.back(); specRow.RowIndex = row.RowIndex; specRow.Patterns.push_back(nullptr); } assert(caseBBs.size() == caseInfos.size()); // Check to see if we need a default block. if (caseBBs.size() < 2) defaultBB = SGF.createBasicBlockAfter(curBB); // Emit the switch_value SILLocation loc = PatternMatchStmt; loc.setDebugLoc(rows[0].Pattern); SILValue srcValue = src.getFinalManagedValue().forward(SGF); // Extract the i1 from the Bool struct. auto i1Value = SGF.emitUnwrapIntegerResult(loc, srcValue); SGF.B.createSwitchValue(loc, i1Value, defaultBB, caseBBs); // Okay, now emit all the cases. for (unsigned i = 0, e = caseInfos.size(); i != e; ++i) { auto &caseInfo = caseInfos[i]; auto &specializedRows = caseInfo.SpecializedRows; SILBasicBlock *caseBB = caseBBs[i].second; SGF.B.setInsertionPoint(caseBB); // We're in conditionally-executed code; enter a scope. Scope scope(SGF.Cleanups, CleanupLocation::get(loc)); SILValue result = SILUndef::get(SGF.SGM.Types.getEmptyTupleType(), SGF.F); ConsumableManagedValue CMV = ConsumableManagedValue::forUnmanaged(result); handleCase(CMV, specializedRows, outerFailure); assert(!SGF.B.hasValidInsertionPoint() && "did not end block"); } // Emit the default block if we needed one. if (defaultBB) { SGF.B.setInsertionPoint(defaultBB); outerFailure(rows.back().Pattern); } } /// Emit the body of a case statement at the current insertion point. void PatternMatchEmission::emitCaseBody(CaseStmt *caseBlock) { SGF.emitStmt(caseBlock->getBody()); // Implicitly break out of the pattern match statement. if (SGF.B.hasValidInsertionPoint()) { // Case blocks without trailing braces have a line location of the last // instruction in the case block. SILLocation cleanupLoc = RegularLocation::getAutoGeneratedLocation(caseBlock->getEndLoc()); if (auto *braces = dyn_cast(caseBlock->getBody())) if (braces->getNumElements() == 1 && dyn_cast_or_null(braces->getElement(0).dyn_cast())) cleanupLoc = CleanupLocation(caseBlock); SGF.emitBreakOutOf(cleanupLoc, PatternMatchStmt); } } void PatternMatchEmission::initSharedCaseBlockDest(CaseStmt *caseBlock, bool hasFallthroughTo) { auto result = SharedCases.insert({caseBlock, {nullptr, hasFallthroughTo}}); assert(result.second); auto *block = SGF.createBasicBlock(); result.first->second.first = block; // Add args for any pattern variables if we have any. for (auto *vd : caseBlock->getCaseBodyVariablesOrEmptyArray()) { if (!vd->hasName()) continue; // We don't pass address-only values in basic block arguments. SILType ty = SGF.getLoweredType(vd->getType()); if (ty.isAddressOnly(SGF.F)) continue; block->createPhiArgument(ty, ValueOwnershipKind::Owned, vd); } } /// Retrieve the jump destination for a shared case block. JumpDest PatternMatchEmission::getSharedCaseBlockDest(CaseStmt *caseBlock) { auto result = SharedCases.find(caseBlock); assert(result != SharedCases.end()); auto *block = result->second.first; assert(block); return JumpDest(block, PatternMatchStmtDepth, CleanupLocation(PatternMatchStmt)); } void PatternMatchEmission::emitAddressOnlyAllocations() { for (auto &entry : SharedCases) { CaseStmt *caseBlock = entry.first; // If we have a shared case with bound decls, setup the arguments for the // shared block by emitting the temporary allocation used for the arguments // of the shared block. for (auto *vd : caseBlock->getCaseBodyVariablesOrEmptyArray()) { if (!vd->hasName()) continue; SILType ty = SGF.getLoweredType(vd->getType()); if (!ty.isAddressOnly(SGF.F)) continue; assert(!Temporaries[vd]); Temporaries[vd] = SGF.emitTemporaryAllocation(vd, ty); } } // Now we have all of our cleanups entered, so we can record the // depth. PatternMatchStmtDepth = SGF.getCleanupsDepth(); } void PatternMatchEmission:: emitAddressOnlyInitialization(VarDecl *dest, SILValue value) { auto found = Temporaries.find(dest); assert(found != Temporaries.end()); SGF.B.createCopyAddr(dest, value, found->second, IsNotTake, IsInitialization); } /// Emit all the shared case statements. void PatternMatchEmission::emitSharedCaseBlocks() { for (auto &entry : SharedCases) { CaseStmt *caseBlock = entry.first; SILBasicBlock *caseBB = entry.second.first; bool hasFallthroughTo = entry.second.second; assert(caseBB->empty()); // If this case can only have one predecessor, then merge it into that // predecessor. We rely on the SIL CFG here, because unemitted shared case // blocks might fallthrough into this one. if (!hasFallthroughTo && caseBlock->getCaseLabelItems().size() == 1) { SILBasicBlock *predBB = caseBB->getSinglePredecessorBlock(); assert(predBB && "Should only have 1 predecessor because it isn't shared"); assert(isa(predBB->getTerminator()) && "Should have uncond branch to shared block"); predBB->getTerminator()->eraseFromParent(); caseBB->eraseFromParent(); // Emit the case body into the predecessor's block. SGF.B.setInsertionPoint(predBB); } else { // If we did not need a shared case block, we shouldn't have emitted one. assert(!caseBB->pred_empty() && "Shared case block without predecessors?!"); // Otherwise, move the block to after the first predecessor. auto predBB = *caseBB->pred_begin(); caseBB->moveAfter(predBB); // Then emit the case body into the caseBB. SGF.B.setInsertionPoint(caseBB); } // Make sure that before/after we emit the case body we have emitted all // cleanups we created within. assert(SGF.getCleanupsDepth() == PatternMatchStmtDepth); SWIFT_DEFER { assert(SGF.getCleanupsDepth() == PatternMatchStmtDepth); }; if (!caseBlock->hasCaseBodyVariables()) { emitCaseBody(caseBlock); continue; } // If we have a shared case with bound decls, then the case stmt pattern has // the order of variables that are the incoming BB arguments. Setup the // VarLocs to point to the incoming args and setup initialization so any // args needing Cleanup will get that as well. Scope scope(SGF.Cleanups, CleanupLocation(caseBlock)); unsigned argIndex = 0; for (auto *vd : caseBlock->getCaseBodyVariables()) { if (!vd->hasName()) continue; SILType ty = SGF.getLoweredType(vd->getType()); // Initialize mv at +1. We always pass values in at +1 for today into // shared blocks. ManagedValue mv; if (ty.isAddressOnly(SGF.F)) { // There's no basic block argument, since we don't allow basic blocks // to have address arguments. // // Instead, we map the variable to a temporary alloc_stack in // emitAddressOnlyAllocations(), and store into it at each // predecessor block. // // There's nothing to do here, since the value should already have // been initialized on entry. auto found = Temporaries.find(vd); assert(found != Temporaries.end()); mv = SGF.emitManagedRValueWithCleanup(found->second); } else { SILValue arg = caseBB->getArgument(argIndex++); assert(arg.getOwnershipKind() == ValueOwnershipKind::Owned || arg.getOwnershipKind() == ValueOwnershipKind::Any); mv = SGF.emitManagedRValueWithCleanup(arg); } if (vd->isLet()) { // Just emit a let and leave the cleanup alone. SGF.VarLocs[vd].value = mv.getValue(); continue; } // Otherwise, the pattern variables were all emitted as lets and one got // passed in. Since we have a var, alloc a box for the var and forward in // the chosen value. SGF.VarLocs.erase(vd); auto newVar = SGF.emitInitializationForVarDecl(vd, vd->isLet()); newVar->copyOrInitValueInto(SGF, vd, mv, /*isInit*/ true); newVar->finishInitialization(SGF); } // Now that we have setup all of the VarLocs correctly, emit the shared case // body. emitCaseBody(caseBlock); } } /// Context info used to emit FallthroughStmts. /// Since fallthrough-able case blocks must not bind variables, they are always /// emitted in the outermost scope of the switch. class Lowering::PatternMatchContext { public: PatternMatchEmission &Emission; }; namespace { struct UnexpectedEnumCaseInfo { CanType subjectTy; ManagedValue metatype; ManagedValue rawValue; NullablePtr singleObjCEnum; UnexpectedEnumCaseInfo(CanType subjectTy, ManagedValue metatype, ManagedValue rawValue, const EnumDecl *singleObjCEnum) : subjectTy(subjectTy), metatype(metatype), rawValue(rawValue), singleObjCEnum(singleObjCEnum) { assert(isa(metatype)); assert(bool(rawValue) && isa(rawValue)); assert(singleObjCEnum->hasRawType()); } UnexpectedEnumCaseInfo(CanType subjectTy, ManagedValue valueMetatype) : subjectTy(subjectTy), metatype(valueMetatype), rawValue(), singleObjCEnum() { assert(isa(valueMetatype)); } bool isSingleObjCEnum() const { return singleObjCEnum.isNonNull(); } void cleanupInstsIfUnused() { auto f = [](SILValue v) { if (!v->use_empty()) return; cast(v)->eraseFromParent(); }; f(metatype.getValue()); if (rawValue) f(rawValue.getValue()); } }; } // end anonymous namespace static void emitDiagnoseOfUnexpectedEnumCaseValue(SILGenFunction &SGF, SILLocation loc, UnexpectedEnumCaseInfo ueci) { ASTContext &ctx = SGF.getASTContext(); auto diagnoseFailure = ctx.getDiagnoseUnexpectedEnumCaseValue(); if (!diagnoseFailure) { SGF.B.createBuiltinTrap(loc); return; } auto genericSig = diagnoseFailure->getGenericSignature(); auto subs = SubstitutionMap::get( genericSig, [&](SubstitutableType *type) -> Type { auto genericParam = cast(type); assert(genericParam->getDepth() == 0); assert(genericParam->getIndex() < 2); switch (genericParam->getIndex()) { case 0: return ueci.subjectTy; case 1: return ueci.singleObjCEnum.get()->getRawType(); default: llvm_unreachable("wrong generic signature for expected case value"); } }, LookUpConformanceInSignature(*genericSig)); SGF.emitApplyOfLibraryIntrinsic( loc, diagnoseFailure, subs, {ueci.metatype, ueci.rawValue.materialize(SGF, loc)}, SGFContext()); } static void emitDiagnoseOfUnexpectedEnumCase(SILGenFunction &SGF, SILLocation loc, UnexpectedEnumCaseInfo ueci) { ASTContext &ctx = SGF.getASTContext(); auto diagnoseFailure = ctx.getDiagnoseUnexpectedEnumCase(); if (!diagnoseFailure) { SGF.B.createBuiltinTrap(loc); return; } auto diagnoseSignature = diagnoseFailure->getGenericSignature(); auto genericArgsMap = SubstitutionMap::get( diagnoseSignature, [&](SubstitutableType *type) -> Type { return ueci.subjectTy; }, LookUpConformanceInSignature(*diagnoseSignature)); SGF.emitApplyOfLibraryIntrinsic(loc, diagnoseFailure, genericArgsMap, ueci.metatype, SGFContext()); } static void switchCaseStmtSuccessCallback(SILGenFunction &SGF, PatternMatchEmission &emission, ArgArray argArray, ClauseRow &row) { auto caseBlock = row.getClientData(); SGF.emitProfilerIncrement(caseBlock); // Certain case statements can be entered along multiple paths, either because // they have multiple labels or because of fallthrough. When we need multiple // entrance path, we factor the paths with a shared block. // // If we don't have a fallthrough or a multi-pattern 'case', we can emit the // body inline. Emit the statement here and bail early. if (!row.hasFallthroughTo() && caseBlock->getCaseLabelItems().size() == 1) { // If we have case body vars, set them up to point at the matching var // decls. if (caseBlock->hasCaseBodyVariables()) { // Since we know that we only have one case label item, grab its pattern // vars and use that to update expected with the right SILValue. // // TODO: Do we need a copy here? SmallVector patternVars; row.getCasePattern()->collectVariables(patternVars); for (auto *expected : caseBlock->getCaseBodyVariables()) { if (!expected->hasName()) continue; for (auto *vd : patternVars) { if (!vd->hasName() || vd->getName() != expected->getName()) { continue; } // Ok, we found a match. Update the VarLocs for the case block. auto v = SGF.VarLocs[vd]; SGF.VarLocs[expected] = v; } } } emission.emitCaseBody(caseBlock); return; } // Ok, at this point we know that we have a multiple entrance block. Grab our // shared destination in preperation for branching to it. // // NOTE: We do not emit anything yet, since we will emit the shared block // later. JumpDest sharedDest = emission.getSharedCaseBlockDest(caseBlock); // If we do not have any bound decls, we do not need to setup any // variables. Just jump to the shared destination. if (!caseBlock->hasCaseBodyVariables()) { // Don't emit anything yet, we emit it at the cleanup level of the switch // statement. JumpDest sharedDest = emission.getSharedCaseBlockDest(caseBlock); SGF.Cleanups.emitBranchAndCleanups(sharedDest, caseBlock); return; } // Generate the arguments from this row's pattern in the case block's expected // order, and keep those arguments from being cleaned up, as we're passing the // +1 along to the shared case block dest. (The cleanups still happen, as they // are threaded through here messily, but the explicit retains here counteract // them, and then the retain/release pair gets optimized out.) SmallVector args; SmallVector patternVars; row.getCasePattern()->collectVariables(patternVars); for (auto *expected : caseBlock->getCaseBodyVariables()) { if (!expected->hasName()) continue; for (auto *var : patternVars) { if (!var->hasName() || var->getName() != expected->getName()) continue; SILValue value = SGF.VarLocs[var].value; SILType type = value->getType(); // If we have an address-only type, initialize the temporary // allocation. We're not going to pass the address as a block // argument. if (type.isAddressOnly(SGF.F)) { emission.emitAddressOnlyInitialization(expected, value); break; } // If we have a loadable address, perform a load [copy]. if (type.isAddress()) { value = SGF.B.emitLoadValueOperation(SGF.CurrentSILLoc, value, LoadOwnershipQualifier::Copy); args.push_back(value); break; } value = SGF.B.emitCopyValueOperation(SGF.CurrentSILLoc, value); args.push_back(value); break; } } // Now that we have initialized our arguments, branch to the shared dest. SGF.Cleanups.emitBranchAndCleanups(sharedDest, caseBlock, args); } void SILGenFunction::emitSwitchStmt(SwitchStmt *S) { LLVM_DEBUG(llvm::dbgs() << "emitting switch stmt\n"; S->dump(llvm::dbgs()); llvm::dbgs() << '\n'); auto subjectTy = S->getSubjectExpr()->getType(); // If the subject expression is uninhabited, we're already dead. // Emit an unreachable in place of the switch statement. if (subjectTy->isStructurallyUninhabited()) { emitIgnoredExpr(S->getSubjectExpr()); B.createUnreachable(S); return; } auto completionHandler = [this](PatternMatchEmission &emission, ArgArray argArray, ClauseRow &row) { return switchCaseStmtSuccessCallback(*this, emission, argArray, row); }; PatternMatchEmission emission(*this, S, completionHandler); // Add a row for each label of each case. SmallVector clauseRows; clauseRows.reserve(S->getRawCases().size()); bool hasFallthrough = false; for (auto caseBlock : S->getCases()) { // If the previous block falls through into this block or we have multiple // case label itmes, create a shared case block to generate the shared // block. if (hasFallthrough || caseBlock->getCaseLabelItems().size() > 1) { emission.initSharedCaseBlockDest(caseBlock, hasFallthrough); } for (auto &labelItem : caseBlock->getCaseLabelItems()) { clauseRows.emplace_back(caseBlock, const_cast(labelItem.getPattern()), const_cast(labelItem.getGuardExpr()), hasFallthrough); } hasFallthrough = caseBlock->hasFallthroughDest(); } // Emit alloc_stacks for address-only variables appearing in // multiple-entry case blocks. emission.emitAddressOnlyAllocations(); SILBasicBlock *contBB = createBasicBlock(); emitProfilerIncrement(S); JumpDest contDest(contBB, Cleanups.getCleanupsDepth(), CleanupLocation(S)); Scope switchScope(Cleanups, CleanupLocation(S)); // Enter a break/continue scope. If we wanted a continue // destination, it would probably be out here. BreakContinueDestStack.push_back({S, contDest, JumpDest(S)}); PatternMatchContext switchContext = { emission }; SwitchStack.push_back(&switchContext); // Emit the subject value. If at +1, dispatching will consume it. If it is at // +0, we just forward down borrows. ManagedValue subjectMV = emitRValueAsSingleValue( S->getSubjectExpr(), SGFContext::AllowGuaranteedPlusZero); // Inline constructor for subject. auto subject = ([&]() -> ConsumableManagedValue { // If we have a plus one value... if (subjectMV.isPlusOne(*this)) { // And we have an address that is loadable, perform a load [take]. if (subjectMV.getType().isAddress() && subjectMV.getType().isLoadable(F)) { subjectMV = B.createLoadTake(S, subjectMV); } return {subjectMV, CastConsumptionKind::TakeAlways}; } // If we have a loadable address and +0, perform a load borrow. if (subjectMV.getType().isAddress() && subjectMV.getType().isLoadable(F)) { subjectMV = B.createLoadBorrow(S, subjectMV); } // If then we have an object, return it at +0. if (subjectMV.getType().isObject()) { return {subjectMV, CastConsumptionKind::BorrowAlways}; } // If we have an address only type returned without a cleanup, we // need to do a copy just to be safe. So for efficiency we pass it // down take_always. return {subjectMV.copy(*this, S), CastConsumptionKind::TakeAlways}; }()); // If we need to diagnose an unexpected enum case or unexpected enum case // value, we need access to a value metatype for the subject. Emit this state // now before we emit the actual switch to ensure that the subject has not // been consumed. auto unexpectedEnumCaseInfo = ([&]() -> UnexpectedEnumCaseInfo { SILLocation loc = RegularLocation::getAutoGeneratedLocation(); CanType canSubjectTy = subjectTy->getCanonicalType(); CanType metatypeType = MetatypeType::get(canSubjectTy)->getCanonicalType(); SILType loweredMetatypeType = getLoweredType(AbstractionPattern::getOpaque(), metatypeType); ManagedValue value = subject.getFinalManagedValue(); if (auto *singleEnumDecl = canSubjectTy->getEnumOrBoundGenericEnum()) { if (singleEnumDecl->isObjC()) { auto metatype = ManagedValue::forUnmanaged( B.createMetatype(loc, loweredMetatypeType)); // Bitcast the enum value to its raw type. (This is only safe for @objc // enums.) SILType loweredRawType = getLoweredType(singleEnumDecl->getRawType()); assert(loweredRawType.isTrivial(F)); assert(loweredRawType.isObject()); auto rawValue = B.createUncheckedTrivialBitCast(loc, value, loweredRawType); return {canSubjectTy, metatype, rawValue, singleEnumDecl}; } } return {canSubjectTy, B.createValueMetatype(loc, loweredMetatypeType, value)}; }()); auto failure = [&](SILLocation location) { // If we fail to match anything, we trap. This can happen with a switch // over an @objc enum, which may contain any value of its underlying type, // or a switch over a non-frozen Swift enum when the user hasn't written a // catch-all case. SWIFT_DEFER { B.createUnreachable(location); }; // Special case: if it's a single @objc enum, we can print the raw value. if (unexpectedEnumCaseInfo.isSingleObjCEnum()) { emitDiagnoseOfUnexpectedEnumCaseValue(*this, location, unexpectedEnumCaseInfo); return; } emitDiagnoseOfUnexpectedEnumCase(*this, location, unexpectedEnumCaseInfo); }; // Set up an initial clause matrix. ClauseMatrix clauses(clauseRows); // Recursively specialize and emit the clause matrix. emission.emitDispatch(clauses, subject, failure); assert(!B.hasValidInsertionPoint()); switchScope.pop(); // Then emit the case blocks shared by multiple pattern cases. emission.emitSharedCaseBlocks(); // Bookkeeping. SwitchStack.pop_back(); BreakContinueDestStack.pop_back(); // If the continuation block has no predecessors, this // point is not reachable. if (contBB->pred_empty()) { eraseBasicBlock(contBB); } else { B.emitBlock(contBB); } // Now that we have emitted everything, see if our unexpected enum case info // metatypes were actually used. If not, delete them. unexpectedEnumCaseInfo.cleanupInstsIfUnused(); } void SILGenFunction::emitSwitchFallthrough(FallthroughStmt *S) { assert(!SwitchStack.empty() && "fallthrough outside of switch?!"); PatternMatchContext *context = SwitchStack.back(); // Get the destination block. CaseStmt *destCaseStmt = S->getFallthroughDest(); JumpDest sharedDest = context->Emission.getSharedCaseBlockDest(destCaseStmt); // If our destination case doesn't have any bound decls, there is no rebinding // to do. Just jump to the shared dest. if (!destCaseStmt->hasCaseBodyVariables()) { Cleanups.emitBranchAndCleanups(sharedDest, S); return; } // Generate branch args to pass along current vars to fallthrough case. SmallVector args; CaseStmt *fallthroughSourceStmt = S->getFallthroughSource(); for (auto *expected : destCaseStmt->getCaseBodyVariables()) { if (!expected->hasName()) continue; // The type checker enforces that if our destination case has variables then // our fallthrough source must as well. for (auto *var : fallthroughSourceStmt->getCaseBodyVariables()) { if (!var->hasName() || var->getName() != expected->getName()) { continue; } auto varLoc = VarLocs[var]; SILValue value = varLoc.value; if (value->getType().isAddressOnly(F)) { context->Emission.emitAddressOnlyInitialization(expected, value); break; } if (varLoc.box) { SILValue argValue = B.emitLoadValueOperation( CurrentSILLoc, value, LoadOwnershipQualifier::Copy); args.push_back(argValue); break; } auto argValue = B.emitCopyValueOperation(CurrentSILLoc, value); args.push_back(argValue); break; } } Cleanups.emitBranchAndCleanups(sharedDest, S, args); } /// Emit a sequence of catch clauses. void SILGenFunction::emitCatchDispatch(DoCatchStmt *S, ManagedValue exn, ArrayRef clauses, JumpDest catchFallthroughDest) { auto completionHandler = [&](PatternMatchEmission &emission, ArgArray argArray, ClauseRow &row) { auto clause = row.getClientData(); emitProfilerIncrement(clause->getBody()); emitStmt(clause->getBody()); // If we fell out of the catch clause, branch to the fallthrough dest. if (B.hasValidInsertionPoint()) { Cleanups.emitBranchAndCleanups(catchFallthroughDest, clause->getBody()); } }; PatternMatchEmission emission(*this, S, completionHandler); // Add a row for each clause. std::vector clauseRows; clauseRows.reserve(clauses.size()); for (CatchStmt *clause : clauses) { clauseRows.emplace_back(clause, clause->getErrorPattern(), clause->getGuardExpr(), /*hasFallthroughTo*/false); } // Set up an initial clause matrix. ClauseMatrix clauseMatrix(clauseRows); assert(exn.getType().isObject() && "Error is special and should always be an object"); // Our model is that sub-cases get the exception at +0 and the throw (if we // need to rethrow the exception) gets the exception at +1 since we need to // trampoline it's ownership to our caller. ConsumableManagedValue subject = {exn.borrow(*this, S), CastConsumptionKind::BorrowAlways}; auto failure = [&](SILLocation location) { // If we fail to match anything, just rethrow the exception. // If the throw destination is not valid, then the PatternMatchEmission // logic is emitting an unreachable block but didn't prune the failure BB. // Mark it as such. if (!ThrowDest.isValid()) { B.createUnreachable(S); return; } // Since we borrowed exn before sending it to our subcases, we know that it // must be at +1 at this point. That being said, SILGenPattern will // potentially invoke this for each of the catch statements, so we need to // copy before we pass it into the throw. CleanupStateRestorationScope scope(Cleanups); if (exn.hasCleanup()) { scope.pushCleanupState(exn.getCleanup(), CleanupState::PersistentlyActive); } emitThrow(S, exn); }; // Recursively specialize and emit the clause matrix. emission.emitDispatch(clauseMatrix, subject, failure); assert(!B.hasValidInsertionPoint()); }