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fuchsia / third_party / swift / refs/tags/swift-DEVELOPMENT-SNAPSHOT-2016-08-07-a / . / lib / SIL / SILPrinter.cpp
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//===--- SILPrinter.cpp - Pretty-printing of SIL Code ---------------------===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2016 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See http://swift.org/LICENSE.txt for license information
// See http://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//
///
/// \file
///
/// This file defines the logic to pretty-print SIL, Instructions, etc.
///
//===----------------------------------------------------------------------===//
#include "swift/Strings.h"
#include "swift/Basic/DemangleWrappers.h"
#include "swift/Basic/QuotedString.h"
#include "swift/SIL/SILPrintContext.h"
#include "swift/SIL/CFG.h"
#include "swift/SIL/SILFunction.h"
#include "swift/SIL/SILCoverageMap.h"
#include "swift/SIL/SILDebugScope.h"
#include "swift/SIL/SILDeclRef.h"
#include "swift/SIL/SILModule.h"
#include "swift/SIL/SILVisitor.h"
#include "swift/SIL/SILVTable.h"
#include "swift/AST/Decl.h"
#include "swift/AST/Expr.h"
#include "swift/AST/Module.h"
#include "swift/AST/PrintOptions.h"
#include "swift/AST/Types.h"
#include "swift/Basic/STLExtras.h"
#include "llvm/ADT/APFloat.h"
#include "llvm/ADT/APInt.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/PostOrderIterator.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/FormattedStream.h"
#include "llvm/Support/FileSystem.h"
using namespace swift;
using namespace demangle_wrappers;
llvm::cl::opt<bool>
SILPrintNoColor("sil-print-no-color", llvm::cl::init(""),
llvm::cl::desc("Don't use color when printing SIL"));
llvm::cl::opt<bool>
SILFullDemangle("sil-full-demangle", llvm::cl::init(false),
llvm::cl::desc("Fully demangle symbol names in SIL output"));
static std::string demangleSymbol(StringRef Name) {
if (SILFullDemangle)
return demangleSymbolAsString(Name);
return demangleSymbolAsString(Name,
Demangle::DemangleOptions::SimplifiedUIDemangleOptions());
}
struct ID {
enum ID_Kind {
SILBasicBlock, SILUndef, SSAValue
} Kind;
unsigned Number;
// A stable ordering of ID objects.
bool operator<(ID Other) const {
if (unsigned(Kind) < unsigned(Other.Kind))
return true;
if (Number < Other.Number)
return true;
return false;
}
};
enum SILColorKind {
SC_Type,
};
namespace {
/// RAII based coloring of SIL output.
class SILColor {
raw_ostream &OS;
enum raw_ostream::Colors Color;
public:
#define DEF_COL(NAME, RAW) case NAME: Color = raw_ostream::RAW; break;
explicit SILColor(raw_ostream &OS, SILColorKind K) : OS(OS) {
if (!OS.has_colors() || SILPrintNoColor)
return;
switch (K) {
DEF_COL(SC_Type, YELLOW)
}
OS.resetColor();
OS.changeColor(Color);
}
explicit SILColor(raw_ostream &OS, ID::ID_Kind K) : OS(OS) {
if (!OS.has_colors() || SILPrintNoColor)
return;
switch (K) {
DEF_COL(ID::SILUndef, RED)
DEF_COL(ID::SILBasicBlock, GREEN)
DEF_COL(ID::SSAValue, MAGENTA)
}
OS.resetColor();
OS.changeColor(Color);
}
~SILColor() {
if (!OS.has_colors() || SILPrintNoColor)
return;
// FIXME: instead of resetColor(), we can look into
// capturing the current active color and restoring it.
OS.resetColor();
}
#undef DEF_COL
};
}
static raw_ostream &operator<<(raw_ostream &OS, ID i) {
SILColor C(OS, i.Kind);
switch (i.Kind) {
case ID::SILUndef: OS << "undef"; return OS;
case ID::SILBasicBlock: OS << "bb"; break;
case ID::SSAValue: OS << '%'; break;
}
OS << i.Number;
return OS;
}
/// IDAndType - Used when a client wants to print something like "%0 : $Int".
struct IDAndType {
ID id;
SILType Ty;
};
/// Return the fully qualified dotted path for DeclContext.
static void printFullContext(const DeclContext *Context, raw_ostream &Buffer) {
if (!Context)
return;
switch (Context->getContextKind()) {
case DeclContextKind::Module:
if (Context == cast<Module>(Context)->getASTContext().TheBuiltinModule)
Buffer << cast<Module>(Context)->getName() << ".";
return;
case DeclContextKind::FileUnit:
// Ignore the file; just print the module.
printFullContext(Context->getParent(), Buffer);
return;
case DeclContextKind::Initializer:
// FIXME
Buffer << "<initializer>";
return;
case DeclContextKind::AbstractClosureExpr:
// FIXME
Buffer << "<anonymous function>";
return;
case DeclContextKind::SerializedLocal:
Buffer << "<serialized local context>";
return;
case DeclContextKind::GenericTypeDecl: {
auto *generic = cast<GenericTypeDecl>(Context);
printFullContext(generic->getDeclContext(), Buffer);
Buffer << generic->getName() << ".";
return;
}
case DeclContextKind::ExtensionDecl: {
Type Ty = cast<ExtensionDecl>(Context)->getExtendedType();
TypeBase *Base = Ty->getCanonicalType().getPointer();
const NominalTypeDecl *ExtNominal = 0;
switch (Base->getKind()) {
default:
llvm_unreachable("unhandled context kind in SILPrint!");
case TypeKind::Protocol:
ExtNominal = cast<ProtocolType>(Base)->getDecl();
break;
case TypeKind::Enum:
ExtNominal = cast<EnumType>(Base)->getDecl();
break;
case TypeKind::Struct:
ExtNominal = cast<StructType>(Base)->getDecl();
break;
case TypeKind::Class:
ExtNominal = cast<ClassType>(Base)->getDecl();
break;
case TypeKind::BoundGenericEnum:
ExtNominal = cast<BoundGenericEnumType>(Base)->getDecl();
break;
case TypeKind::BoundGenericStruct:
ExtNominal = cast<BoundGenericStructType>(Base)->getDecl();
break;
case TypeKind::BoundGenericClass:
ExtNominal = cast<BoundGenericClassType>(Base)->getDecl();
break;
}
printFullContext(ExtNominal->getDeclContext(), Buffer);
Buffer << ExtNominal->getName() << ".";
return;
}
case DeclContextKind::TopLevelCodeDecl:
// FIXME
Buffer << "<top level code>";
return;
case DeclContextKind::AbstractFunctionDecl:
// FIXME
Buffer << "<abstract function>";
return;
case DeclContextKind::SubscriptDecl:
// FIXME
Buffer << "<subscript>";
return;
}
llvm_unreachable("bad decl context");
}
static void printValueDecl(ValueDecl *Decl, raw_ostream &OS) {
printFullContext(Decl->getDeclContext(), OS);
assert(Decl->hasName());
if (Decl->isOperator())
OS << '"' << Decl->getName() << '"';
else
OS << Decl->getName();
}
/// SILDeclRef uses sigil "#" and prints the fully qualified dotted path.
void SILDeclRef::print(raw_ostream &OS) const {
OS << "#";
if (isNull()) {
OS << "<null>";
return;
}
bool isDot = true;
if (!hasDecl()) {
OS << "<anonymous function>";
} else if (kind == SILDeclRef::Kind::Func) {
auto *FD = cast<FuncDecl>(getDecl());
switch (FD->getAccessorKind()) {
case AccessorKind::IsWillSet:
printValueDecl(FD->getAccessorStorageDecl(), OS);
OS << "!willSet";
break;
case AccessorKind::IsDidSet:
printValueDecl(FD->getAccessorStorageDecl(), OS);
OS << "!didSet";
break;
case AccessorKind::NotAccessor:
printValueDecl(FD, OS);
isDot = false;
break;
case AccessorKind::IsGetter:
printValueDecl(FD->getAccessorStorageDecl(), OS);
OS << "!getter";
break;
case AccessorKind::IsSetter:
printValueDecl(FD->getAccessorStorageDecl(), OS);
OS << "!setter";
break;
case AccessorKind::IsMaterializeForSet:
printValueDecl(FD->getAccessorStorageDecl(), OS);
OS << "!materializeForSet";
break;
case AccessorKind::IsAddressor:
printValueDecl(FD->getAccessorStorageDecl(), OS);
OS << "!addressor";
break;
case AccessorKind::IsMutableAddressor:
printValueDecl(FD->getAccessorStorageDecl(), OS);
OS << "!mutableAddressor";
break;
}
} else {
printValueDecl(getDecl(), OS);
}
switch (kind) {
case SILDeclRef::Kind::Func:
break;
case SILDeclRef::Kind::Allocator:
OS << "!allocator";
break;
case SILDeclRef::Kind::Initializer:
OS << "!initializer";
break;
case SILDeclRef::Kind::EnumElement:
OS << "!enumelt";
break;
case SILDeclRef::Kind::Destroyer:
OS << "!destroyer";
break;
case SILDeclRef::Kind::Deallocator:
OS << "!deallocator";
break;
case SILDeclRef::Kind::IVarInitializer:
OS << "!ivarinitializer";
break;
case SILDeclRef::Kind::IVarDestroyer:
OS << "!ivardestroyer";
break;
case SILDeclRef::Kind::GlobalAccessor:
OS << "!globalaccessor";
break;
case SILDeclRef::Kind::GlobalGetter:
OS << "!globalgetter";
break;
case SILDeclRef::Kind::DefaultArgGenerator:
OS << "!defaultarg" << "." << defaultArgIndex;
break;
case SILDeclRef::Kind::StoredPropertyInitializer:
OS << "!propertyinit";
break;
}
if (uncurryLevel != 0)
OS << (isDot ? '.' : '!') << uncurryLevel;
if (isForeign)
OS << ((isDot || uncurryLevel != 0) ? '.' : '!') << "foreign";
if (isDirectReference)
OS << ((isDot || uncurryLevel != 0) ? '.' : '!') << "direct";
}
void SILDeclRef::dump() const {
print(llvm::errs());
llvm::errs() << '\n';
}
static void print(raw_ostream &OS, SILValueCategory category) {
switch (category) {
case SILValueCategory::Object: return;
case SILValueCategory::Address: OS << '*'; return;
}
llvm_unreachable("bad value category!");
}
static StringRef getCastConsumptionKindName(CastConsumptionKind kind) {
switch (kind) {
case CastConsumptionKind::TakeAlways: return "take_always";
case CastConsumptionKind::TakeOnSuccess: return "take_on_success";
case CastConsumptionKind::CopyOnSuccess: return "copy_on_success";
}
llvm_unreachable("bad cast consumption kind");
}
static void printSILTypeColorAndSigil(raw_ostream &OS, SILType t) {
SILColor C(OS, SC_Type);
OS << '$';
// Potentially add a leading sigil for the value category.
::print(OS, t.getCategory());
}
void SILType::print(raw_ostream &OS) const {
printSILTypeColorAndSigil(OS, *this);
// Print other types as their Swift representation.
PrintOptions SubPrinter = PrintOptions::printSIL();
getSwiftRValueType().print(OS, SubPrinter);
}
void SILType::dump() const {
print(llvm::errs());
llvm::errs() << '\n';
}
namespace {
/// SILPrinter class - This holds the internal implementation details of
/// printing SIL structures.
class SILPrinter : public SILVisitor<SILPrinter> {
SILPrintContext &Ctx;
struct {
llvm::formatted_raw_ostream OS;
PrintOptions ASTOptions;
} PrintState;
SILValue subjectValue;
unsigned LastBufferID;
llvm::DenseMap<const SILBasicBlock *, unsigned> BlocksToIDMap;
llvm::DenseMap<const ValueBase *, unsigned> ValueToIDMap;
// Printers for the underlying stream.
#define SIMPLE_PRINTER(TYPE) \
SILPrinter &operator<<(TYPE value) { \
PrintState.OS << value; \
return *this; \
}
SIMPLE_PRINTER(char)
SIMPLE_PRINTER(unsigned)
SIMPLE_PRINTER(StringRef)
SIMPLE_PRINTER(Identifier)
SIMPLE_PRINTER(ID)
SIMPLE_PRINTER(QuotedString)
SIMPLE_PRINTER(SILDeclRef)
SIMPLE_PRINTER(APInt)
#undef SIMPLE_PRINTER
SILPrinter &operator<<(IDAndType i) {
SILColor C(PrintState.OS, SC_Type);
return *this << i.id << " : " << i.Ty;
}
SILPrinter &operator<<(Type t) {
// Print the type using our print options.
t.print(PrintState.OS, PrintState.ASTOptions);
return *this;
}
SILPrinter &operator<<(SILType t) {
printSILTypeColorAndSigil(PrintState.OS, t);
t.getSwiftRValueType().print(PrintState.OS, PrintState.ASTOptions);
return *this;
}
public:
SILPrinter(
SILPrintContext &PrintCtx,
llvm::DenseMap<CanType, Identifier> *AlternativeTypeNames = nullptr)
: Ctx(PrintCtx),
PrintState{{PrintCtx.OS()}, PrintOptions::printSIL()},
LastBufferID(0) {
PrintState.ASTOptions.AlternativeTypeNames = AlternativeTypeNames;
}
ID getID(const SILBasicBlock *B);
ID getID(SILValue V);
IDAndType getIDAndType(SILValue V) {
return { getID(V), V->getType() };
}
//===--------------------------------------------------------------------===//
// Big entrypoints.
void print(const SILFunction *F) {
// If we are asked to emit sorted SIL, print out our BBs in RPOT order.
if (Ctx.sortSIL()) {
std::vector<SILBasicBlock *> RPOT;
auto *UnsafeF = const_cast<SILFunction *>(F);
std::copy(po_begin(UnsafeF), po_end(UnsafeF),
std::back_inserter(RPOT));
std::reverse(RPOT.begin(), RPOT.end());
// Initialize IDs so our IDs are in RPOT as well. This is a hack.
for (unsigned Index : indices(RPOT))
BlocksToIDMap[RPOT[Index]] = Index;
interleave(RPOT,
[&](SILBasicBlock *B) { print(B); },
[&] { *this << '\n'; });
return;
}
interleave(*F,
[&](const SILBasicBlock &B) { print(&B); },
[&] { *this << '\n'; });
}
void print(const SILBasicBlock *BB) {
// Output uses for BB arguments.
if (!BB->bbarg_empty()) {
for (auto I = BB->bbarg_begin(), E = BB->bbarg_end(); I != E; ++I) {
SILValue V = *I;
if (V->use_empty())
continue;
*this << "// " << getID(V);
PrintState.OS.PadToColumn(50);
*this << "// user";
if (std::next(V->use_begin()) != V->use_end())
*this << 's';
*this << ": ";
llvm::SmallVector<ID, 32> UserIDs;
for (auto *Op : V->getUses())
UserIDs.push_back(getID(Op->getUser()));
// Display the user ids sorted to give a stable use order in the
// printer's output if we are asked to do so. This makes diffing large
// sections of SIL significantly easier at the expense of not showing
// the _TRUE_ order of the users in the use list.
if (Ctx.sortSIL()) {
std::sort(UserIDs.begin(), UserIDs.end());
}
interleave(UserIDs.begin(), UserIDs.end(),
[&] (ID id) { *this << id; },
[&] { *this << ", "; });
*this << '\n';
}
}
*this << getID(BB);
if (!BB->bbarg_empty()) {
*this << '(';
for (auto I = BB->bbarg_begin(), E = BB->bbarg_end(); I != E; ++I) {
if (I != BB->bbarg_begin()) *this << ", ";
*this << getIDAndType(*I);
}
*this << ')';
}
*this << ":";
if (!BB->pred_empty()) {
PrintState.OS.PadToColumn(50);
*this << "// Preds:";
llvm::SmallVector<ID, 32> PredIDs;
for (auto *BBI : BB->getPreds())
PredIDs.push_back(getID(BBI));
// Display the pred ids sorted to give a stable use order in the printer's
// output if we are asked to do so. This makes diffing large sections of
// SIL significantly easier at the expense of not showing the _TRUE_ order
// of the users in the use list.
if (Ctx.sortSIL()) {
std::sort(PredIDs.begin(), PredIDs.end());
}
for (auto Id : PredIDs)
*this << ' ' << Id;
}
*this << '\n';
for (const SILInstruction &I : *BB) {
Ctx.printInstructionCallBack(&I);
print(&I);
}
}
//===--------------------------------------------------------------------===//
// SILInstruction Printing Logic
/// Print out the users of the SILValue \p V. Return true if we printed out
/// either an id or a use list. Return false otherwise.
bool printUsersOfSILValue(SILValue V) {
if (!V->hasValue()) {
PrintState.OS.PadToColumn(50);
*this << "// id: " << getID(V);
return true;
}
if (V->use_empty())
return false;
PrintState.OS.PadToColumn(50);
*this << "// user";
if (std::next(V->use_begin()) != V->use_end())
*this << 's';
*this << ": ";
llvm::SmallVector<ID, 32> UserIDs;
for (auto *Op : V->getUses())
UserIDs.push_back(getID(Op->getUser()));
// If we are asked to, display the user ids sorted to give a stable use
// order in the printer's output. This makes diffing large sections of SIL
// significantly easier.
if (Ctx.sortSIL()) {
std::sort(UserIDs.begin(), UserIDs.end());
}
interleave(UserIDs.begin(), UserIDs.end(), [&](ID id) { *this << id; },
[&] { *this << ", "; });
return true;
}
void printDebugLocRef(SILLocation Loc, const SourceManager &SM,
bool PrintComma = true) {
auto DL = Loc.decodeDebugLoc(SM);
if (DL.Filename) {
if (PrintComma)
*this << ", ";
*this << "loc " << QuotedString(DL.Filename) << ':' << DL.Line << ':'
<< DL.Column;
}
}
void printDebugScope(const SILDebugScope *DS, const SourceManager &SM) {
if (!DS)
return;
if (!Ctx.hasScopeID(DS)) {
printDebugScope(DS->Parent.dyn_cast<const SILDebugScope *>(), SM);
printDebugScope(DS->InlinedCallSite, SM);
unsigned ID = Ctx.assignScopeID(DS);
*this << "sil_scope " << ID << " { ";
printDebugLocRef(DS->Loc, SM, false);
*this << " parent ";
if (auto *F = DS->Parent.dyn_cast<SILFunction *>())
*this << "@" << F->getName() << " : $" << F->getLoweredFunctionType();
else {
auto *PS = DS->Parent.get<const SILDebugScope *>();
*this << Ctx.getScopeID(PS);
}
if (auto *CS = DS->InlinedCallSite)
*this << " inlined_at " << Ctx.getScopeID(CS);
*this << " }\n";
}
}
void printDebugScopeRef(const SILDebugScope *DS, const SourceManager &SM,
bool PrintComma = true) {
if (DS) {
if (PrintComma)
*this << ", ";
*this << "scope " << Ctx.getScopeID(DS);
}
}
void printSILLocation(SILLocation L, SILModule &M, const SILDebugScope *DS,
bool printedSlashes) {
if (!L.isNull()) {
if (!printedSlashes) {
PrintState.OS.PadToColumn(50);
*this << "//";
}
*this << " ";
// To minimize output, only print the line and column number for
// everything but the first instruction.
L.getSourceLoc().printLineAndColumn(PrintState.OS,
M.getASTContext().SourceMgr);
// Print the type of location.
switch (L.getKind()) {
case SILLocation::NoneKind:
assert(L.isAutoGenerated() && "This kind shouldn't be printed.");
break;
case SILLocation::RegularKind:
break;
case SILLocation::ReturnKind:
*this << ":return";
break;
case SILLocation::ImplicitReturnKind:
*this << ":imp_return";
break;
case SILLocation::InlinedKind:
*this << ":inlined";
break;
case SILLocation::MandatoryInlinedKind:
*this << ":minlined";
break;
case SILLocation::CleanupKind:
*this << ":cleanup";
break;
case SILLocation::ArtificialUnreachableKind:
*this << ":art_unreach";
break;
}
if (L.isSILFile())
*this << ":sil";
if (L.isAutoGenerated())
*this << ":auto_gen";
if (L.isInPrologue())
*this << ":in_prologue";
}
if (L.isNull()) {
if (!printedSlashes) {
PrintState.OS.PadToColumn(50);
*this << "//";
}
if (L.isInTopLevel())
*this << " top_level";
else if (L.isAutoGenerated())
*this << " auto_gen";
else
*this << " no_loc";
if (L.isInPrologue())
*this << ":in_prologue";
}
// Print inlined-at location, if any.
if (DS) {
SILFunction *InlinedF = DS->getInlinedFunction();
auto InlineScopes = DS->flattenedInlineTree();
for (auto *CS : reversed(InlineScopes)) {
*this << ": ";
if (InlinedF) {
*this << demangleSymbol(InlinedF->getName());
} else {
*this << '?';
}
*this << " perf_inlined_at ";
auto CallSite = CS->Loc;
if (!CallSite.isNull() && CallSite.isASTNode())
CallSite.getSourceLoc().print(
PrintState.OS, M.getASTContext().SourceMgr, LastBufferID);
else
*this << "?";
InlinedF = CS->getInlinedFunction();
}
}
}
void print(SILValue V, bool PrintScopes = false) {
// Lazily print any debug locations used in this value.
if (PrintScopes)
if (auto *I = dyn_cast<SILInstruction>(V)) {
auto &SM = I->getModule().getASTContext().SourceMgr;
printDebugScope(I->getDebugScope(), SM);
}
if (auto *FRI = dyn_cast<FunctionRefInst>(V))
*this << " // function_ref "
<< demangleSymbol(FRI->getReferencedFunction()->getName())
<< "\n";
*this << " ";
// Print result.
if (V->hasValue()) {
ID Name = getID(V);
*this << Name << " = ";
}
// Print the value.
visit(V);
if (auto *I = dyn_cast<SILInstruction>(V)) {
auto &SM = I->getModule().getASTContext().SourceMgr;
printDebugLocRef(I->getLoc(), SM);
printDebugScopeRef(I->getDebugScope(), SM);
}
// Print users, or id for valueless instructions.
bool printedSlashes = printUsersOfSILValue(V);
// Print SIL location.
if (Ctx.printVerbose()) {
if (auto *I = dyn_cast<SILInstruction>(V)) {
printSILLocation(I->getLoc(), I->getModule(), I->getDebugScope(),
printedSlashes);
}
}
*this << '\n';
}
void printInContext(SILValue V) {
subjectValue = V;
auto sortByID = [&](SILValue a, SILValue b) {
return getID(a).Number < getID(b).Number;
};
if (auto *I = dyn_cast<SILInstruction>(V)) {
auto operands = map<SmallVector<SILValue,4>>(I->getAllOperands(),
[](Operand const &o) {
return o.get();
});
std::sort(operands.begin(), operands.end(), sortByID);
for (auto &operand : operands) {
*this << " ";
print(operand);
}
}
*this << "-> ";
print(V);
auto users = map<SmallVector<SILValue,4>>(V->getUses(),
[](Operand *o) {
return o->getUser();
});
std::sort(users.begin(), users.end(), sortByID);
for (auto &user : users) {
*this << " ";
print(user);
}
}
void visitSILArgument(SILArgument *A) {
// This should really only happen during debugging.
*this << "argument of " << getID(A->getParent()) << " : "
<< A->getType();
}
void visitSILUndef(SILUndef *A) {
// This should really only happen during debugging.
*this << "undef<" << A->getType() << ">";
}
void printDebugVar(SILDebugVariable Var) {
if (Var.Name.empty())
return;
if (Var.Constant)
*this << ", let";
else
*this << ", var";
*this << ", name \"" << Var.Name << '"';
if (Var.ArgNo)
*this << ", argno " << Var.ArgNo;
}
void visitAllocStackInst(AllocStackInst *AVI) {
*this << "alloc_stack " << AVI->getElementType();
printDebugVar(AVI->getVarInfo());
}
void visitAllocRefInst(AllocRefInst *ARI) {
*this << "alloc_ref ";
if (ARI->isObjC())
*this << "[objc] ";
if (ARI->canAllocOnStack())
*this << "[stack] ";
*this << ARI->getType();
}
void visitAllocRefDynamicInst(AllocRefDynamicInst *ARDI) {
*this << "alloc_ref_dynamic ";
if (ARDI->isObjC())
*this << "[objc] ";
*this << getIDAndType(ARDI->getOperand());
*this << ", " << ARDI->getType();
}
void visitAllocValueBufferInst(AllocValueBufferInst *AVBI) {
*this << "alloc_value_buffer " << AVBI->getValueType()
<< " in " << getIDAndType(AVBI->getOperand());
}
void visitAllocBoxInst(AllocBoxInst *ABI) {
*this << "alloc_box " << ABI->getElementType();
printDebugVar(ABI->getVarInfo());
}
void printSubstitutions(ArrayRef<Substitution> Subs) {
if (Subs.empty())
return;
*this << '<';
interleave(Subs,
[&](const Substitution &s) { *this << s.getReplacement(); },
[&] { *this << ", "; });
*this << '>';
}
void visitApplyInst(ApplyInst *AI) {
*this << "apply ";
if (AI->isNonThrowing())
*this << "[nothrow] ";
*this << getID(AI->getCallee());
printSubstitutions(AI->getSubstitutions());
*this << '(';
interleave(AI->getArguments(),
[&](const SILValue &arg) { *this << getID(arg); },
[&] { *this << ", "; });
*this << ") : " << AI->getCallee()->getType();
}
void visitTryApplyInst(TryApplyInst *AI) {
*this << "try_apply ";
*this << getID(AI->getCallee());
printSubstitutions(AI->getSubstitutions());
*this << '(';
interleave(AI->getArguments(),
[&](const SILValue &arg) { *this << getID(arg); },
[&] { *this << ", "; });
*this << ") : " << AI->getCallee()->getType();
*this << ", normal " << getID(AI->getNormalBB());
*this << ", error " << getID(AI->getErrorBB());
}
void visitPartialApplyInst(PartialApplyInst *CI) {
*this << "partial_apply ";
*this << getID(CI->getCallee());
printSubstitutions(CI->getSubstitutions());
*this << '(';
interleave(CI->getArguments(),
[&](const SILValue &arg) { *this << getID(arg); },
[&] { *this << ", "; });
*this << ") : " << CI->getCallee()->getType();
}
void visitFunctionRefInst(FunctionRefInst *FRI) {
*this << "function_ref ";
FRI->getReferencedFunction()->printName(PrintState.OS);
*this << " : " << FRI->getType();
}
void visitBuiltinInst(BuiltinInst *BI) {
*this << "builtin " << QuotedString(BI->getName().str());
printSubstitutions(BI->getSubstitutions());
*this << "(";
interleave(BI->getArguments(), [&](SILValue v) {
*this << getIDAndType(v);
}, [&]{
*this << ", ";
});
*this << ") : ";
*this << BI->getType();
}
void visitAllocGlobalInst(AllocGlobalInst *AGI) {
*this << "alloc_global ";
if (AGI->getReferencedGlobal()) {
AGI->getReferencedGlobal()->printName(PrintState.OS);
} else {
*this << "<<placeholder>>";
}
}
void visitGlobalAddrInst(GlobalAddrInst *GAI) {
*this << "global_addr ";
if (GAI->getReferencedGlobal()) {
GAI->getReferencedGlobal()->printName(PrintState.OS);
} else {
*this << "<<placeholder>>";
}
*this << " : " << GAI->getType();
}
void visitIntegerLiteralInst(IntegerLiteralInst *ILI) {
const auto &lit = ILI->getValue();
*this << "integer_literal " << ILI->getType() << ", " << lit;
}
void visitFloatLiteralInst(FloatLiteralInst *FLI) {
*this << "float_literal " << FLI->getType() << ", 0x";
APInt bits = FLI->getBits();
*this << bits.toString(16, /*Signed*/ false);
llvm::SmallString<12> decimal;
FLI->getValue().toString(decimal);
*this << " // " << decimal;
}
static StringRef getStringEncodingName(StringLiteralInst::Encoding kind) {
switch (kind) {
case StringLiteralInst::Encoding::UTF8: return "utf8 ";
case StringLiteralInst::Encoding::UTF16: return "utf16 ";
case StringLiteralInst::Encoding::ObjCSelector: return "objc_selector ";
}
llvm_unreachable("bad string literal encoding");
}
void visitStringLiteralInst(StringLiteralInst *SLI) {
*this << "string_literal " << getStringEncodingName(SLI->getEncoding())
<< QuotedString(SLI->getValue());
}
void visitLoadInst(LoadInst *LI) {
*this << "load " << getIDAndType(LI->getOperand());
}
void visitStoreInst(StoreInst *SI) {
*this << "store " << getID(SI->getSrc()) << " to "
<< getIDAndType(SI->getDest());
}
void visitAssignInst(AssignInst *AI) {
*this << "assign " << getID(AI->getSrc()) << " to "
<< getIDAndType(AI->getDest());
}
void visitMarkUninitializedInst(MarkUninitializedInst *MU) {
*this << "mark_uninitialized ";
switch (MU->getKind()) {
case MarkUninitializedInst::Var: *this << "[var] "; break;
case MarkUninitializedInst::RootSelf: *this << "[rootself] "; break;
case MarkUninitializedInst::DerivedSelf: *this << "[derivedself] "; break;
case MarkUninitializedInst::DerivedSelfOnly:
*this << "[derivedselfonly] ";
break;
case MarkUninitializedInst::DelegatingSelf: *this << "[delegatingself] ";break;
}
*this << getIDAndType(MU->getOperand());
}
void visitMarkUninitializedBehaviorInst(MarkUninitializedBehaviorInst *MU) {
*this << "mark_uninitialized_behavior "
<< getID(MU->getInitStorageFunc());
printSubstitutions(MU->getInitStorageSubstitutions());
*this << '(' << getID(MU->getStorage()) << ") : "
<< MU->getInitStorageFunc()->getType() << ", "
<< getID(MU->getSetterFunc());
printSubstitutions(MU->getSetterSubstitutions());
*this << '(' << getID(MU->getSelf()) << ") : "
<< MU->getSetterFunc()->getType();
}
void visitMarkFunctionEscapeInst(MarkFunctionEscapeInst *MFE) {
*this << "mark_function_escape ";
interleave(MFE->getElements(),
[&](SILValue Var) {
*this << getIDAndType(Var);
},
[&] { *this << ", "; });
}
void visitDebugValueInst(DebugValueInst *DVI) {
*this << "debug_value " << getIDAndType(DVI->getOperand());
printDebugVar(DVI->getVarInfo());
}
void visitDebugValueAddrInst(DebugValueAddrInst *DVAI) {
*this << "debug_value_addr " << getIDAndType(DVAI->getOperand());
printDebugVar(DVAI->getVarInfo());
}
void visitLoadUnownedInst(LoadUnownedInst *LI) {
*this << "load_unowned ";
if (LI->isTake())
*this << "[take] ";
*this << getIDAndType(LI->getOperand());
}
void visitStoreUnownedInst(StoreUnownedInst *SI) {
*this << "store_unowned " << getID(SI->getSrc()) << " to ";
if (SI->isInitializationOfDest())
*this << "[initialization] ";
*this << getIDAndType(SI->getDest());
}
void visitLoadWeakInst(LoadWeakInst *LI) {
*this << "load_weak ";
if (LI->isTake())
*this << "[take] ";
*this << getIDAndType(LI->getOperand());
}
void visitStoreWeakInst(StoreWeakInst *SI) {
*this << "store_weak " << getID(SI->getSrc()) << " to ";
if (SI->isInitializationOfDest())
*this << "[initialization] ";
*this << getIDAndType(SI->getDest());
}
void visitCopyAddrInst(CopyAddrInst *CI) {
*this << "copy_addr ";
if (CI->isTakeOfSrc())
*this << "[take] ";
*this << getID(CI->getSrc()) << " to ";
if (CI->isInitializationOfDest())
*this << "[initialization] ";
*this << getIDAndType(CI->getDest());
}
void visitBindMemoryInst(BindMemoryInst *BI) {
*this << "bind_memory ";
*this << getIDAndType(BI->getBase()) << ", ";
*this << getIDAndType(BI->getIndex()) << " to ";
*this << BI->getBoundType();
}
void printUncheckedConversionInst(ConversionInst *CI, SILValue operand,
StringRef name) {
*this << name << " " << getIDAndType(operand) << " to " << CI->getType();
}
void visitUnconditionalCheckedCastInst(UnconditionalCheckedCastInst *CI) {
*this << "unconditional_checked_cast "
<< getIDAndType(CI->getOperand())
<< " to " << CI->getType();
}
void visitCheckedCastBranchInst(CheckedCastBranchInst *CI) {
*this << "checked_cast_br ";
if (CI->isExact()) *this << "[exact] ";
*this << getIDAndType(CI->getOperand())
<< " to " << CI->getCastType() << ", "
<< getID(CI->getSuccessBB()) << ", " << getID(CI->getFailureBB());
}
void visitUnconditionalCheckedCastAddrInst(UnconditionalCheckedCastAddrInst *CI) {
*this << "unconditional_checked_cast_addr "
<< getCastConsumptionKindName(CI->getConsumptionKind())
<< ' ' << CI->getSourceType() << " in " << getIDAndType(CI->getSrc())
<< " to " << CI->getTargetType() << " in " << getIDAndType(CI->getDest());
}
void visitCheckedCastAddrBranchInst(CheckedCastAddrBranchInst *CI) {
*this << "checked_cast_addr_br "
<< getCastConsumptionKindName(CI->getConsumptionKind())
<< ' ' << CI->getSourceType() << " in " << getIDAndType(CI->getSrc())
<< " to " << CI->getTargetType() << " in " << getIDAndType(CI->getDest())
<< ", " << getID(CI->getSuccessBB()) << ", " << getID(CI->getFailureBB());
}
void visitConvertFunctionInst(ConvertFunctionInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "convert_function");
}
void visitThinFunctionToPointerInst(ThinFunctionToPointerInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(),
"thin_function_to_pointer");
}
void visitPointerToThinFunctionInst(PointerToThinFunctionInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(),
"pointer_to_thin_function");
}
void visitUpcastInst(UpcastInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "upcast");
}
void visitAddressToPointerInst(AddressToPointerInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "address_to_pointer");
}
void visitPointerToAddressInst(PointerToAddressInst *CI) {
*this << "pointer_to_address " << getIDAndType(CI->getOperand()) << " to ";
if (CI->isStrict())
*this << "[strict] ";
*this << CI->getType();
}
void visitUncheckedRefCastInst(UncheckedRefCastInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "unchecked_ref_cast");
}
void visitUncheckedRefCastAddrInst(UncheckedRefCastAddrInst *CI) {
*this << "unchecked_ref_cast_addr "
<< ' ' << CI->getSourceType() << " in " << getIDAndType(CI->getSrc())
<< " to " << CI->getTargetType() << " in " << getIDAndType(CI->getDest());
}
void visitUncheckedAddrCastInst(UncheckedAddrCastInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "unchecked_addr_cast");
}
void visitUncheckedTrivialBitCastInst(UncheckedTrivialBitCastInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "unchecked_trivial_bit_cast");
}
void visitUncheckedBitwiseCastInst(UncheckedBitwiseCastInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(),
"unchecked_bitwise_cast");
}
void visitRefToRawPointerInst(RefToRawPointerInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "ref_to_raw_pointer");
}
void visitRawPointerToRefInst(RawPointerToRefInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "raw_pointer_to_ref");
}
void visitRefToUnownedInst(RefToUnownedInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "ref_to_unowned");
}
void visitUnownedToRefInst(UnownedToRefInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "unowned_to_ref");
}
void visitRefToUnmanagedInst(RefToUnmanagedInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "ref_to_unmanaged");
}
void visitUnmanagedToRefInst(UnmanagedToRefInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(), "unmanaged_to_ref");
}
void visitThinToThickFunctionInst(ThinToThickFunctionInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(),"thin_to_thick_function");
}
void visitThickToObjCMetatypeInst(ThickToObjCMetatypeInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(),"thick_to_objc_metatype");
}
void visitObjCToThickMetatypeInst(ObjCToThickMetatypeInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(),"objc_to_thick_metatype");
}
void visitObjCMetatypeToObjectInst(ObjCMetatypeToObjectInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(),
"objc_metatype_to_object");
}
void visitObjCExistentialMetatypeToObjectInst(
ObjCExistentialMetatypeToObjectInst *CI) {
printUncheckedConversionInst(CI, CI->getOperand(),
"objc_existential_metatype_to_object");
}
void visitObjCProtocolInst(ObjCProtocolInst *CI) {
*this << "objc_protocol #" << CI->getProtocol()->getName()
<< " : " << CI->getType();
}
void visitRefToBridgeObjectInst(RefToBridgeObjectInst *I) {
*this << "ref_to_bridge_object " << getIDAndType(I->getConverted())
<< ", " << getIDAndType(I->getBitsOperand());
}
void visitBridgeObjectToRefInst(BridgeObjectToRefInst *I) {
printUncheckedConversionInst(I, I->getOperand(), "bridge_object_to_ref");
}
void visitBridgeObjectToWordInst(BridgeObjectToWordInst *I) {
printUncheckedConversionInst(I, I->getOperand(), "bridge_object_to_word");
}
void visitIsNonnullInst(IsNonnullInst *I) {
*this << "is_nonnull " << getIDAndType(I->getOperand());
}
void visitRetainValueInst(RetainValueInst *I) {
visitRefCountingInst(I, "retain_value");
}
void visitReleaseValueInst(ReleaseValueInst *I) {
visitRefCountingInst(I, "release_value");
}
void visitAutoreleaseValueInst(AutoreleaseValueInst *I) {
visitRefCountingInst(I, "autorelease_value");
}
void visitSetDeallocatingInst(SetDeallocatingInst *I) {
visitRefCountingInst(I, "set_deallocating");
}
void visitStructInst(StructInst *SI) {
*this << "struct " << SI->getType() << " (";
interleave(SI->getElements(),
[&](const SILValue &V) { *this << getIDAndType(V); },
[&] { *this << ", "; });
*this << ')';
}
void visitTupleInst(TupleInst *TI) {
*this << "tuple ";
// Check to see if the type of the tuple can be inferred accurately from the
// elements.
bool SimpleType = true;
for (auto &Elt : TI->getType().castTo<TupleType>()->getElements()) {
if (Elt.hasName() || Elt.isVararg()) {
SimpleType = false;
break;
}
}
// If the type is simple, just print the tuple elements.
if (SimpleType) {
*this << '(';
interleave(TI->getElements(),
[&](const SILValue &V){ *this << getIDAndType(V); },
[&] { *this << ", "; });
*this << ')';
} else {
// Otherwise, print the type, then each value.
*this << TI->getType() << " (";
interleave(TI->getElements(),
[&](const SILValue &V){ *this << getID(V); },
[&] { *this << ", "; });
*this << ')';
}
}
void visitEnumInst(EnumInst *UI) {
*this << "enum " << UI->getType() << ", "
<< SILDeclRef(UI->getElement(), SILDeclRef::Kind::EnumElement);
if (UI->hasOperand()) {
*this << ", " << getIDAndType(UI->getOperand());
}
}
void visitInitEnumDataAddrInst(InitEnumDataAddrInst *UDAI) {
*this << "init_enum_data_addr "
<< getIDAndType(UDAI->getOperand()) << ", "
<< SILDeclRef(UDAI->getElement(), SILDeclRef::Kind::EnumElement);
}
void visitUncheckedEnumDataInst(UncheckedEnumDataInst *UDAI) {
*this << "unchecked_enum_data "
<< getIDAndType(UDAI->getOperand()) << ", "
<< SILDeclRef(UDAI->getElement(), SILDeclRef::Kind::EnumElement);
}
void visitUncheckedTakeEnumDataAddrInst(UncheckedTakeEnumDataAddrInst *UDAI) {
*this << "unchecked_take_enum_data_addr "
<< getIDAndType(UDAI->getOperand()) << ", "
<< SILDeclRef(UDAI->getElement(), SILDeclRef::Kind::EnumElement);
}
void visitInjectEnumAddrInst(InjectEnumAddrInst *IUAI) {
*this << "inject_enum_addr "
<< getIDAndType(IUAI->getOperand()) << ", "
<< SILDeclRef(IUAI->getElement(), SILDeclRef::Kind::EnumElement);
}
void visitTupleExtractInst(TupleExtractInst *EI) {
*this << "tuple_extract " << getIDAndType(EI->getOperand()) << ", "
<< EI->getFieldNo();
}
void visitTupleElementAddrInst(TupleElementAddrInst *EI) {
*this << "tuple_element_addr " << getIDAndType(EI->getOperand()) << ", "
<< EI->getFieldNo();
}
void visitStructExtractInst(StructExtractInst *EI) {
*this << "struct_extract " << getIDAndType(EI->getOperand()) << ", #";
printFullContext(EI->getField()->getDeclContext(), PrintState.OS);
*this << EI->getField()->getName().get();
}
void visitStructElementAddrInst(StructElementAddrInst *EI) {
*this << "struct_element_addr " << getIDAndType(EI->getOperand()) << ", #";
printFullContext(EI->getField()->getDeclContext(), PrintState.OS);
*this << EI->getField()->getName().get();
}
void visitRefElementAddrInst(RefElementAddrInst *EI) {
*this << "ref_element_addr " << getIDAndType(EI->getOperand()) << ", #";
printFullContext(EI->getField()->getDeclContext(), PrintState.OS);
*this << EI->getField()->getName().get();
}
void printMethodInst(MethodInst *I, SILValue Operand, StringRef Name) {
*this << Name << " ";
if (I->isVolatile())
*this << "[volatile] ";
*this << getIDAndType(Operand) << ", " << I->getMember();
}
void visitClassMethodInst(ClassMethodInst *AMI) {
printMethodInst(AMI, AMI->getOperand(), "class_method");
*this << " : " << AMI->getMember().getDecl()->getInterfaceType();
*this << " , ";
*this << AMI->getType();
}
void visitSuperMethodInst(SuperMethodInst *AMI) {
printMethodInst(AMI, AMI->getOperand(), "super_method");
*this << " : " << AMI->getMember().getDecl()->getInterfaceType();
*this << " , ";
*this << AMI->getType();
}
void visitWitnessMethodInst(WitnessMethodInst *WMI) {
*this << "witness_method ";
if (WMI->isVolatile())
*this << "[volatile] ";
*this << "$" << WMI->getLookupType() << ", " << WMI->getMember();
if (!WMI->getOpenedArchetypeOperands().empty()) {
*this << ", ";
*this << getIDAndType(WMI->getOpenedArchetypeOperands()[0].get());
}
*this << " : " << WMI->getType();
}
void visitDynamicMethodInst(DynamicMethodInst *DMI) {
printMethodInst(DMI, DMI->getOperand(), "dynamic_method");
*this << " : " << DMI->getMember().getDecl()->getInterfaceType();
*this << ", ";
*this << DMI->getType();
}
void visitOpenExistentialAddrInst(OpenExistentialAddrInst *OI) {
*this << "open_existential_addr " << getIDAndType(OI->getOperand())
<< " to " << OI->getType();
}
void visitOpenExistentialRefInst(OpenExistentialRefInst *OI) {
*this << "open_existential_ref " << getIDAndType(OI->getOperand())
<< " to " << OI->getType();
}
void visitOpenExistentialMetatypeInst(OpenExistentialMetatypeInst *OI) {
*this << "open_existential_metatype " << getIDAndType(OI->getOperand())
<< " to " << OI->getType();
}
void visitOpenExistentialBoxInst(OpenExistentialBoxInst *OI) {
*this << "open_existential_box " << getIDAndType(OI->getOperand())
<< " to " << OI->getType();
}
void visitInitExistentialAddrInst(InitExistentialAddrInst *AEI) {
*this << "init_existential_addr " << getIDAndType(AEI->getOperand()) << ", $"
<< AEI->getFormalConcreteType();
}
void visitInitExistentialRefInst(InitExistentialRefInst *AEI) {
*this << "init_existential_ref " << getIDAndType(AEI->getOperand())
<< " : $" << AEI->getFormalConcreteType()
<< ", " << AEI->getType();
}
void visitInitExistentialMetatypeInst(InitExistentialMetatypeInst *AEI) {
*this << "init_existential_metatype " << getIDAndType(AEI->getOperand())
<< ", " << AEI->getType();
}
void visitAllocExistentialBoxInst(AllocExistentialBoxInst *AEBI) {
*this << "alloc_existential_box " << AEBI->getExistentialType()
<< ", $" << AEBI->getFormalConcreteType();
}
void visitDeinitExistentialAddrInst(DeinitExistentialAddrInst *DEI) {
*this << "deinit_existential_addr " << getIDAndType(DEI->getOperand());
}
void visitDeallocExistentialBoxInst(DeallocExistentialBoxInst *DEI) {
*this << "dealloc_existential_box " << getIDAndType(DEI->getOperand())
<< ", $" << DEI->getConcreteType();
}
void visitProjectBlockStorageInst(ProjectBlockStorageInst *PBSI) {
*this << "project_block_storage " << getIDAndType(PBSI->getOperand());
}
void visitInitBlockStorageHeaderInst(InitBlockStorageHeaderInst *IBSHI) {
*this << "init_block_storage_header " << getIDAndType(IBSHI->getBlockStorage())
<< ", invoke " << getID(IBSHI->getInvokeFunction());
printSubstitutions(IBSHI->getSubstitutions());
*this << " : " << IBSHI->getInvokeFunction()->getType()
<< ", type " << IBSHI->getType();
}
void visitValueMetatypeInst(ValueMetatypeInst *MI) {
*this << "value_metatype " << MI->getType() << ", "
<< getIDAndType(MI->getOperand());
}
void visitExistentialMetatypeInst(ExistentialMetatypeInst *MI) {
*this << "existential_metatype " << MI->getType() << ", "
<< getIDAndType(MI->getOperand());
}
void visitMetatypeInst(MetatypeInst *MI) {
*this << "metatype " << MI->getType();
}
void visitFixLifetimeInst(FixLifetimeInst *RI) {
*this << "fix_lifetime " << getIDAndType(RI->getOperand());
}
void visitMarkDependenceInst(MarkDependenceInst *MDI) {
*this << "mark_dependence " << getIDAndType(MDI->getValue())
<< " on " << getIDAndType(MDI->getBase());
}
void visitCopyBlockInst(CopyBlockInst *RI) {
*this << "copy_block " << getIDAndType(RI->getOperand());
}
void visitRefCountingInst(RefCountingInst *I, StringRef InstName) {
*this << InstName << " ";
if (I->isNonAtomic())
*this << "[nonatomic] ";
*this << getIDAndType(I->getOperand(0));
}
void visitStrongRetainInst(StrongRetainInst *RI) {
visitRefCountingInst(RI, "strong_retain");
}
void visitStrongReleaseInst(StrongReleaseInst *RI) {
visitRefCountingInst(RI, "strong_release");
}
void visitStrongPinInst(StrongPinInst *PI) {
visitRefCountingInst(PI, "strong_pin");
}
void visitStrongUnpinInst(StrongUnpinInst *UI) {
visitRefCountingInst(UI, "strong_unpin");
}
void visitStrongRetainUnownedInst(StrongRetainUnownedInst *RI) {
visitRefCountingInst(RI, "strong_retain_unowned");
}
void visitUnownedRetainInst(UnownedRetainInst *RI) {
visitRefCountingInst(RI, "unowned_retain");
}
void visitUnownedReleaseInst(UnownedReleaseInst *RI) {
visitRefCountingInst(RI, "unowned_release");
}
void visitIsUniqueInst(IsUniqueInst *CUI) {
*this << "is_unique " << getIDAndType(CUI->getOperand());
}
void visitIsUniqueOrPinnedInst(IsUniqueOrPinnedInst *CUI) {
*this << "is_unique_or_pinned " << getIDAndType(CUI->getOperand());
}
void visitDeallocStackInst(DeallocStackInst *DI) {
*this << "dealloc_stack " << getIDAndType(DI->getOperand());
}
void visitDeallocRefInst(DeallocRefInst *DI) {
*this << "dealloc_ref ";
if (DI->canAllocOnStack())
*this << "[stack] ";
*this << getIDAndType(DI->getOperand());
}
void visitDeallocPartialRefInst(DeallocPartialRefInst *DPI) {
*this << "dealloc_partial_ref ";
*this << getIDAndType(DPI->getInstance());
*this << ", ";
*this << getIDAndType(DPI->getMetatype());
}
void visitDeallocValueBufferInst(DeallocValueBufferInst *DVBI) {
*this << "dealloc_value_buffer " << DVBI->getValueType()
<< " in " << getIDAndType(DVBI->getOperand());
}
void visitDeallocBoxInst(DeallocBoxInst *DI) {
*this << "dealloc_box " << getIDAndType(DI->getOperand());
}
void visitDestroyAddrInst(DestroyAddrInst *DI) {
*this << "destroy_addr " << getIDAndType(DI->getOperand());
}
void visitProjectValueBufferInst(ProjectValueBufferInst *PVBI) {
*this << "project_value_buffer " << PVBI->getValueType()
<< " in " << getIDAndType(PVBI->getOperand());
}
void visitProjectBoxInst(ProjectBoxInst *PBI) {
*this << "project_box " << getIDAndType(PBI->getOperand());
}
void visitProjectExistentialBoxInst(ProjectExistentialBoxInst *PEBI) {
*this << "project_existential_box " << PEBI->getValueType()
<< " in " << getIDAndType(PEBI->getOperand());
}
void visitCondFailInst(CondFailInst *FI) {
*this << "cond_fail " << getIDAndType(FI->getOperand());
}
void visitIndexAddrInst(IndexAddrInst *IAI) {
*this << "index_addr " << getIDAndType(IAI->getBase()) << ", "
<< getIDAndType(IAI->getIndex());
}
void visitIndexRawPointerInst(IndexRawPointerInst *IAI) {
*this << "index_raw_pointer " << getIDAndType(IAI->getBase()) << ", "
<< getIDAndType(IAI->getIndex());
}
void visitUnreachableInst(UnreachableInst *UI) {
*this << "unreachable";
}
void visitReturnInst(ReturnInst *RI) {
*this << "return " << getIDAndType(RI->getOperand());
}
void visitThrowInst(ThrowInst *TI) {
*this << "throw " << getIDAndType(TI->getOperand());
}
void visitSwitchValueInst(SwitchValueInst *SII) {
*this << "switch_value " << getIDAndType(SII->getOperand());
for (unsigned i = 0, e = SII->getNumCases(); i < e; ++i) {
SILValue value;
SILBasicBlock *dest;
std::tie(value, dest) = SII->getCase(i);
*this << ", case " << getID(value) << ": " << getID(dest);
}
if (SII->hasDefault())
*this << ", default " << getID(SII->getDefaultBB());
}
void printSwitchEnumInst(SwitchEnumInstBase *SOI) {
*this << getIDAndType(SOI->getOperand());
for (unsigned i = 0, e = SOI->getNumCases(); i < e; ++i) {
EnumElementDecl *elt;
SILBasicBlock *dest;
std::tie(elt, dest) = SOI->getCase(i);
*this << ", case " << SILDeclRef(elt, SILDeclRef::Kind::EnumElement)
<< ": " << getID(dest);
}
if (SOI->hasDefault())
*this << ", default " << getID(SOI->getDefaultBB());
}
void visitSwitchEnumInst(SwitchEnumInst *SOI) {
*this << "switch_enum ";
printSwitchEnumInst(SOI);
}
void visitSwitchEnumAddrInst(SwitchEnumAddrInst *SOI) {
*this << "switch_enum_addr ";
printSwitchEnumInst(SOI);
}
void printSelectEnumInst(SelectEnumInstBase *SEI) {
*this << getIDAndType(SEI->getEnumOperand());
for (unsigned i = 0, e = SEI->getNumCases(); i < e; ++i) {
EnumElementDecl *elt;
SILValue result;
std::tie(elt, result) = SEI->getCase(i);
*this << ", case " << SILDeclRef(elt, SILDeclRef::Kind::EnumElement)
<< ": " << getID(result);
}
if (SEI->hasDefault())
*this << ", default " << getID(SEI->getDefaultResult());
*this << " : " << SEI->getType();
}
void visitSelectEnumInst(SelectEnumInst *SEI) {
*this << "select_enum ";
printSelectEnumInst(SEI);
}
void visitSelectEnumAddrInst(SelectEnumAddrInst *SEI) {
*this << "select_enum_addr ";
printSelectEnumInst(SEI);
}
void visitSelectValueInst(SelectValueInst *SVI) {
*this << "select_value ";
*this << getIDAndType(SVI->getOperand());
for (unsigned i = 0, e = SVI->getNumCases(); i < e; ++i) {
SILValue casevalue;
SILValue result;
std::tie(casevalue, result) = SVI->getCase(i);
*this << ", case " << getID(casevalue)
<< ": " << getID(result);
}
if (SVI->hasDefault())
*this << ", default " << getID(SVI->getDefaultResult());
*this << " : " << SVI->getType();
}
void visitDynamicMethodBranchInst(DynamicMethodBranchInst *DMBI) {
*this << "dynamic_method_br " << getIDAndType(DMBI->getOperand()) << ", "
<< DMBI->getMember()
<< ", " << getID(DMBI->getHasMethodBB()) << ", "
<< getID(DMBI->getNoMethodBB());
}
void printBranchArgs(OperandValueArrayRef args) {
if (args.empty()) return;
*this << '(';
interleave(args,
[&](SILValue v) { *this << getIDAndType(v); },
[&] { *this << ", "; });
*this << ')';
}
void visitBranchInst(BranchInst *UBI) {
*this << "br " << getID(UBI->getDestBB());
printBranchArgs(UBI->getArgs());
}
void visitCondBranchInst(CondBranchInst *CBI) {
*this << "cond_br " << getID(CBI->getCondition()) << ", "
<< getID(CBI->getTrueBB());
printBranchArgs(CBI->getTrueArgs());
*this << ", " << getID(CBI->getFalseBB());
printBranchArgs(CBI->getFalseArgs());
}
};
} // end anonymous namespace
ID SILPrinter::getID(const SILBasicBlock *Block) {
// Lazily initialize the Blocks-to-IDs mapping.
if (BlocksToIDMap.empty()) {
unsigned idx = 0;
for (const SILBasicBlock &B : *Block->getParent())
BlocksToIDMap[&B] = idx++;
}
ID R = { ID::SILBasicBlock, BlocksToIDMap[Block] };
return R;
}
ID SILPrinter::getID(SILValue V) {
if (isa<SILUndef>(V))
return { ID::SILUndef, 0 };
// Lazily initialize the instruction -> ID mapping.
if (ValueToIDMap.empty()) {
V->getParentBB()->getParent()->numberValues(ValueToIDMap);
}
ID R = { ID::SSAValue, ValueToIDMap[V] };
return R;
}
void SILBasicBlock::printAsOperand(raw_ostream &OS, bool PrintType) {
SILPrintContext Ctx(OS);
OS << SILPrinter(Ctx).getID(this);
}
//===----------------------------------------------------------------------===//
// Printing for SILInstruction, SILBasicBlock, SILFunction, and SILModule
//===----------------------------------------------------------------------===//
void ValueBase::dump() const {
print(llvm::errs());
}
void ValueBase::print(raw_ostream &OS) const {
SILPrintContext Ctx(OS);
SILPrinter(Ctx).print(this);
}
/// Pretty-print the SILBasicBlock to errs.
void SILBasicBlock::dump() const {
print(llvm::errs());
}
/// Pretty-print the SILBasicBlock to the designated stream.
void SILBasicBlock::print(raw_ostream &OS) const {
SILPrintContext Ctx(OS);
SILPrinter(Ctx).print(this);
}
/// Pretty-print the SILFunction to errs.
void SILFunction::dump(bool Verbose) const {
SILPrintContext Ctx(llvm::errs(), Verbose);
print(Ctx);
}
// This is out of line so the debugger can find it.
void SILFunction::dump() const {
dump(false);
}
void SILFunction::dump(const char *FileName) const {
std::error_code EC;
llvm::raw_fd_ostream os(FileName, EC, llvm::sys::fs::OpenFlags::F_None);
print(os);
}
static StringRef getLinkageString(SILLinkage linkage) {
switch (linkage) {
case SILLinkage::Public: return "public ";
case SILLinkage::Hidden: return "hidden ";
case SILLinkage::Shared: return "shared ";
case SILLinkage::Private: return "private ";
case SILLinkage::PublicExternal: return "public_external ";
case SILLinkage::HiddenExternal: return "hidden_external ";
case SILLinkage::SharedExternal: return "shared_external ";
case SILLinkage::PrivateExternal: return "private_external ";
}
llvm_unreachable("bad linkage");
}
static void printLinkage(llvm::raw_ostream &OS, SILLinkage linkage,
bool isDefinition) {
if ((isDefinition && linkage == SILLinkage::DefaultForDefinition) ||
(!isDefinition && linkage == SILLinkage::DefaultForDeclaration))
return;
OS << getLinkageString(linkage);
}
/// Pretty-print the SILFunction to the designated stream.
void SILFunction::print(SILPrintContext &PrintCtx) const {
auto &SM = getModule().getASTContext().SourceMgr;
llvm::raw_ostream &OS = PrintCtx.OS();
for (auto &BB : *this)
for (auto &I : BB) {
SILPrinter P(PrintCtx);
P.printDebugScope(I.getDebugScope(), SM);
}
OS << "\n";
OS << "// " << demangleSymbol(getName()) << '\n';
OS << "sil ";
printLinkage(OS, getLinkage(), isDefinition());
if (isTransparent())
OS << "[transparent] ";
if (isFragile())
OS << "[fragile] ";
switch (isThunk()) {
case IsNotThunk: break;
case IsThunk: OS << "[thunk] "; break;
case IsReabstractionThunk: OS << "[reabstraction_thunk] "; break;
}
if (isGlobalInit())
OS << "[global_init] ";
switch (getInlineStrategy()) {
case NoInline: OS << "[noinline] "; break;
case AlwaysInline: OS << "[always_inline] "; break;
case InlineDefault: break;
}
if (getEffectsKind() == EffectsKind::ReadOnly)
OS << "[readonly] ";
else if (getEffectsKind() == EffectsKind::ReadNone)
OS << "[readnone] ";
if (getEffectsKind() == EffectsKind::ReadWrite)
OS << "[readwrite] ";
for (auto &Attr : getSemanticsAttrs())
OS << "[_semantics \"" << Attr << "\"] ";
for (auto *Attr : getSpecializeAttrs()) {
OS << "[_specialize "; Attr->print(OS); OS << "] ";
}
// TODO: Handle clang node owners which don't have a name.
if (hasClangNode() && getClangNodeOwner()->hasName()) {
OS << "[clang ";
printValueDecl(getClangNodeOwner(), OS);
OS << "] ";
}
printName(OS);
OS << " : $";
// Print the type by substituting our context parameter names for the dependent
// parameters. In SIL, we may end up with multiple generic parameters that
// have the same name from different contexts, for instance, a generic
// protocol requirement with a generic method parameter <T>, which is
// witnessed by a generic type that has a generic type parameter also named
// <T>, so we may need to introduce disambiguating aliases.
llvm::DenseMap<CanType, Identifier> Aliases;
llvm::DenseSet<Identifier> UsedNames;
auto params = ContextGenericParams;
llvm::SmallString<16> disambiguatedNameBuf;
unsigned disambiguatedNameCounter = 1;
while (params) {
for (ArchetypeType *param : params->getPrimaryArchetypes()) {
Identifier name = param->getName();
while (!UsedNames.insert(name).second) {
disambiguatedNameBuf.clear();
{
llvm::raw_svector_ostream names(disambiguatedNameBuf);
names << param->getName() << disambiguatedNameCounter++;
}
name = getASTContext().getIdentifier(disambiguatedNameBuf);
}
if (name != param->getName())
Aliases[CanType(param)] = name;
}
params = params->getOuterParameters();
}
{
PrintOptions withContextGenericParams = PrintOptions::printSIL();
withContextGenericParams.ContextGenericParams = ContextGenericParams;
withContextGenericParams.AlternativeTypeNames =
Aliases.empty() ? nullptr : &Aliases;
LoweredType->print(OS, withContextGenericParams);
}
if (!isExternalDeclaration()) {
OS << " {\n";
SILPrinter(PrintCtx, (Aliases.empty() ? nullptr : &Aliases))
.print(this);
OS << "}";
}
OS << "\n\n";
}
/// Pretty-print the SILFunction's name using SIL syntax,
/// '@function_mangled_name'.
void SILFunction::printName(raw_ostream &OS) const {
OS << "@" << Name;
}
/// Pretty-print a global variable to the designated stream.
void SILGlobalVariable::print(llvm::raw_ostream &OS, bool Verbose) const {
OS << "// " << demangleSymbol(getName()) << '\n';
OS << "sil_global ";
printLinkage(OS, getLinkage(), isDefinition());
if (isFragile())
OS << "[fragile] ";
if (isLet())
OS << "[let] ";
printName(OS);
OS << " : " << LoweredType;
if (getInitializer()) {
OS << ", ";
getInitializer()->printName(OS);
OS << " : " << getInitializer()->getLoweredType();
}
OS << "\n\n";
}
void SILGlobalVariable::dump(bool Verbose) const {
print(llvm::errs(), Verbose);
}
void SILGlobalVariable::printName(raw_ostream &OS) const {
OS << "@" << Name;
}
/// Pretty-print the SILModule to errs.
void SILModule::dump(bool Verbose) const {
SILPrintContext Ctx(llvm::errs(), Verbose);
print(Ctx);
}
void SILModule::dump(const char *FileName, bool Verbose,
bool PrintASTDecls) const {
std::error_code EC;
llvm::raw_fd_ostream os(FileName, EC, llvm::sys::fs::OpenFlags::F_None);
SILPrintContext Ctx(os, Verbose);
print(Ctx, getSwiftModule(), PrintASTDecls);
}
static void printSILGlobals(SILPrintContext &Ctx,
const SILModule::GlobalListType &Globals) {
if (!Ctx.sortSIL()) {
for (const SILGlobalVariable &g : Globals)
g.print(Ctx.OS(), Ctx.printVerbose());
return;
}
std::vector<const SILGlobalVariable *> globals;
globals.reserve(Globals.size());
for (const SILGlobalVariable &g : Globals)
globals.push_back(&g);
std::sort(globals.begin(), globals.end(),
[] (const SILGlobalVariable *g1, const SILGlobalVariable *g2) -> bool {
return g1->getName().compare(g2->getName()) == -1;
}
);
for (const SILGlobalVariable *g : globals)
g->print(Ctx.OS(), Ctx.printVerbose());
}
static void printSILFunctions(SILPrintContext &Ctx,
const SILModule::FunctionListType &Functions) {
if (!Ctx.sortSIL()) {
for (const SILFunction &f : Functions)
f.print(Ctx);
return;
}
std::vector<const SILFunction *> functions;
functions.reserve(Functions.size());
for (const SILFunction &f : Functions)
functions.push_back(&f);
std::sort(functions.begin(), functions.end(),
[] (const SILFunction *f1, const SILFunction *f2) -> bool {
return f1->getName().compare(f2->getName()) == -1;
}
);
for (const SILFunction *f : functions)
f->print(Ctx);
}
static void printSILVTables(SILPrintContext &Ctx,
const SILModule::VTableListType &VTables) {
if (!Ctx.sortSIL()) {
for (const SILVTable &vt : VTables)
vt.print(Ctx.OS(), Ctx.printVerbose());
return;
}
std::vector<const SILVTable *> vtables;
vtables.reserve(VTables.size());
for (const SILVTable &vt : VTables)
vtables.push_back(&vt);
std::sort(vtables.begin(), vtables.end(),
[] (const SILVTable *v1, const SILVTable *v2) -> bool {
StringRef Name1 = v1->getClass()->getName().str();
StringRef Name2 = v2->getClass()->getName().str();
return Name1.compare(Name2) == -1;
}
);
for (const SILVTable *vt : vtables)
vt->print(Ctx.OS(), Ctx.printVerbose());
}
static void
printSILWitnessTables(SILPrintContext &Ctx,
const SILModule::WitnessTableListType &WTables) {
if (!Ctx.sortSIL()) {
for (const SILWitnessTable &wt : WTables)
wt.print(Ctx.OS(), Ctx.printVerbose());
return;
}
std::vector<const SILWitnessTable *> witnesstables;
witnesstables.reserve(WTables.size());
for (const SILWitnessTable &wt : WTables)
witnesstables.push_back(&wt);
std::sort(witnesstables.begin(), witnesstables.end(),
[] (const SILWitnessTable *w1, const SILWitnessTable *w2) -> bool {
return w1->getName().compare(w2->getName()) == -1;
}
);
for (const SILWitnessTable *wt : witnesstables)
wt->print(Ctx.OS(), Ctx.printVerbose());
}
static void
printSILDefaultWitnessTables(SILPrintContext &Ctx,
const SILModule::DefaultWitnessTableListType &WTables) {
if (!Ctx.sortSIL()) {
for (const SILDefaultWitnessTable &wt : WTables)
wt.print(Ctx.OS(), Ctx.printVerbose());
return;
}
std::vector<const SILDefaultWitnessTable *> witnesstables;
witnesstables.reserve(WTables.size());
for (const SILDefaultWitnessTable &wt : WTables)
witnesstables.push_back(&wt);
std::sort(witnesstables.begin(), witnesstables.end(),
[] (const SILDefaultWitnessTable *w1,
const SILDefaultWitnessTable *w2) -> bool {
return w1->getProtocol()->getName()
.compare(w2->getProtocol()->getName()) == -1;
}
);
for (const SILDefaultWitnessTable *wt : witnesstables)
wt->print(Ctx.OS(), Ctx.printVerbose());
}
static void
printSILCoverageMaps(SILPrintContext &Ctx,
const SILModule::CoverageMapListType &CoverageMaps) {
if (!Ctx.sortSIL()) {
for (const SILCoverageMap &M : CoverageMaps)
M.print(Ctx);
return;
}
std::vector<const SILCoverageMap *> Maps;
Maps.reserve(CoverageMaps.size());
for (const SILCoverageMap &M : CoverageMaps)
Maps.push_back(&M);
std::sort(Maps.begin(), Maps.end(),
[](const SILCoverageMap *LHS, const SILCoverageMap *RHS) -> bool {
return LHS->getName().compare(RHS->getName()) == -1;
});
for (const SILCoverageMap *M : Maps)
M->print(Ctx);
}
/// Pretty-print the SILModule to the designated stream.
void SILModule::print(SILPrintContext &PrintCtx, Module *M,
bool PrintASTDecls) const {
llvm::raw_ostream &OS = PrintCtx.OS();
OS << "sil_stage ";
switch (Stage) {
case SILStage::Raw:
OS << "raw";
break;
case SILStage::Canonical:
OS << "canonical";
break;
}
OS << "\n\nimport Builtin\nimport " << STDLIB_NAME
<< "\nimport SwiftShims" << "\n\n";
// Print the declarations and types from the origin module, unless we're not
// in whole-module mode.
if (M && AssociatedDeclContext == M && PrintASTDecls) {
PrintOptions Options = PrintOptions::printSIL();
Options.TypeDefinitions = true;
Options.VarInitializers = true;
// FIXME: ExplodePatternBindingDecls is incompatible with VarInitializers!
Options.ExplodePatternBindingDecls = true;
Options.SkipImplicit = false;
Options.PrintGetSetOnRWProperties = true;
Options.PrintInSILBody = false;
Options.PrintDefaultParameterPlaceholder = false;
SmallVector<Decl *, 32> topLevelDecls;
M->getTopLevelDecls(topLevelDecls);
for (const Decl *D : topLevelDecls) {
if ((isa<ValueDecl>(D) || isa<OperatorDecl>(D) ||
isa<ExtensionDecl>(D)) &&
!D->isImplicit()) {
if (auto *FD = dyn_cast<FuncDecl>(D))
if (FD->isAccessor())
continue;
D->print(OS, Options);
OS << "\n\n";
}
}
}
printSILGlobals(PrintCtx, getSILGlobalList());
printSILFunctions(PrintCtx, getFunctionList());
printSILVTables(PrintCtx, getVTableList());
printSILWitnessTables(PrintCtx, getWitnessTableList());
printSILDefaultWitnessTables(PrintCtx, getDefaultWitnessTableList());
printSILCoverageMaps(PrintCtx, getCoverageMapList());
OS << "\n\n";
}
void ValueBase::dumpInContext() const {
printInContext(llvm::errs());
}
void ValueBase::printInContext(llvm::raw_ostream &OS) const {
SILPrintContext Ctx(OS);
SILPrinter(Ctx).printInContext(this);
}
void SILVTable::print(llvm::raw_ostream &OS, bool Verbose) const {
OS << "sil_vtable " << getClass()->getName() << " {\n";
for (auto &entry : getEntries()) {
OS << " ";
entry.first.print(OS);
OS << ": " << entry.second->getName()
<< "\t// " << demangleSymbol(entry.second->getName()) << "\n";
}
OS << "}\n\n";
}
void SILVTable::dump() const {
print(llvm::errs());
}
void SILWitnessTable::print(llvm::raw_ostream &OS, bool Verbose) const {
PrintOptions Options = PrintOptions::printSIL();
OS << "sil_witness_table ";
printLinkage(OS, getLinkage(), /*isDefinition*/ isDefinition());
if (isFragile())
OS << "[fragile] ";
getConformance()->printName(OS, Options);
if (isDeclaration()) {
OS << "\n\n";
return;
}
OS << " {\n";
for (auto &witness : getEntries()) {
OS << " ";
switch (witness.getKind()) {
case Invalid:
llvm_unreachable("invalid witness?!");
case Method: {
// method #declref: @function
auto &methodWitness = witness.getMethodWitness();
OS << "method ";
methodWitness.Requirement.print(OS);
OS << ": ";
if (methodWitness.Witness) {
methodWitness.Witness->printName(OS);
OS << "\t// "
<< demangleSymbol(methodWitness.Witness->getName());
} else {
OS << "nil";
}
break;
}
case AssociatedType: {
// associated_type AssociatedTypeName: ConformingType
auto &assocWitness = witness.getAssociatedTypeWitness();
OS << "associated_type ";
OS << assocWitness.Requirement->getName() << ": ";
assocWitness.Witness->print(OS, PrintOptions::printSIL());
break;
}
case AssociatedTypeProtocol: {
// associated_type_protocol (AssociatedTypeName: Protocol): <conformance>
auto &assocProtoWitness = witness.getAssociatedTypeProtocolWitness();
OS << "associated_type_protocol ("
<< assocProtoWitness.Requirement->getName() << ": "
<< assocProtoWitness.Protocol->getName() << "): ";
if (assocProtoWitness.Witness.isConcrete())
assocProtoWitness.Witness.getConcrete()->printName(OS, Options);
else
OS << "dependent";
break;
}
case BaseProtocol: {
// base_protocol Protocol: <conformance>
auto &baseProtoWitness = witness.getBaseProtocolWitness();
OS << "base_protocol "
<< baseProtoWitness.Requirement->getName() << ": ";
baseProtoWitness.Witness->printName(OS, Options);
break;
}
case MissingOptional: {
// optional requirement 'declref': <<not present>>
OS << "optional requirement '"
<< witness.getMissingOptionalWitness().Witness->getName()
<< "': <<not present>>";
break;
}
}
OS << '\n';
}
OS << "}\n\n";
}
void SILWitnessTable::dump() const {
print(llvm::errs());
}
void SILDefaultWitnessTable::print(llvm::raw_ostream &OS, bool Verbose) const {
// sil_default_witness_table [<Linkage>] <Protocol> <MinSize>
OS << "sil_default_witness_table ";
printLinkage(OS, getLinkage(), ForDefinition);
OS << getProtocol()->getName() << " {\n";
for (auto &witness : getEntries()) {
if (!witness.isValid()) {
OS << " no_default\n";
continue;
}
// method #declref: @function
OS << " method ";
witness.getRequirement().print(OS);
OS << ": ";
witness.getWitness()->printName(OS);
OS << "\t// "
<< demangleSymbolAsString(witness.getWitness()->getName());
OS << '\n';
}
OS << "}\n\n";
}
void SILDefaultWitnessTable::dump() const {
print(llvm::errs());
}
void SILCoverageMap::print(SILPrintContext &PrintCtx) const {
llvm::raw_ostream &OS = PrintCtx.OS();
OS << "sil_coverage_map " << QuotedString(getFile()) << " " << getName()
<< " " << getHash() << " {\t// " << demangleSymbol(getName())
<< "\n";
if (PrintCtx.sortSIL())
std::sort(MappedRegions, MappedRegions + NumMappedRegions,
[](const MappedRegion &LHS, const MappedRegion &RHS) {
return std::tie(LHS.StartLine, LHS.StartCol, LHS.EndLine, LHS.EndCol) <
std::tie(RHS.StartLine, RHS.StartCol, RHS.EndLine, RHS.EndCol);
});
for (auto &MR : getMappedRegions()) {
OS << " " << MR.StartLine << ":" << MR.StartCol << " -> " << MR.EndLine
<< ":" << MR.EndCol << " : ";
printCounter(OS, MR.Counter);
OS << "\n";
}
OS << "}\n\n";
}
void SILCoverageMap::dump() const {
print(llvm::errs());
}
void SILDebugScope::flatten(const SILDebugScope *DS,
SILDebugScope::InlineScopeList &List) {
if (DS) {
if (auto *CS = DS->InlinedCallSite) {
flatten(CS->Parent.dyn_cast<const SILDebugScope *>(), List);
List.push_back(CS);
}
flatten(DS->Parent.dyn_cast<const SILDebugScope *>(), List);
}
}
void SILDebugScope::dump(SourceManager &SM, llvm::raw_ostream &OS,
unsigned Indent) const {
OS << "{\n";
OS.indent(Indent);
if (Loc.isASTNode())
Loc.getSourceLoc().print(OS, SM);
OS << "\n";
OS.indent(Indent + 2);
OS << " parent: ";
if (auto *P = Parent.dyn_cast<const SILDebugScope *>()) {
P->dump(SM, OS, Indent + 2);
OS.indent(Indent + 2);
}
else if (auto *F = Parent.dyn_cast<SILFunction *>())
OS << "@" << F->getName();
else
OS << "nullptr";
OS << "\n";
OS.indent(Indent + 2);
if (auto *CS = InlinedCallSite) {
OS << "inlinedCallSite: ";
CS->dump(SM, OS, Indent + 2);
OS.indent(Indent + 2);
}
OS << "}\n";
}
void SILSpecializeAttr::print(llvm::raw_ostream &OS) const {
SILPrintContext Ctx(OS);
SILPrinter(Ctx).printSubstitutions(getSubstitutions());
}
//===----------------------------------------------------------------------===//
// SILPrintContext members
//===----------------------------------------------------------------------===//
SILPrintContext::~SILPrintContext() {
}
void SILPrintContext::printInstructionCallBack(const SILInstruction *I) {
}