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//===- ThreadSafetyTraverse.h -----------------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file defines a framework for doing generic traversals and rewriting
// operations over the Thread Safety TIL.
//
// UNDER CONSTRUCTION. USE AT YOUR OWN RISK.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYTRAVERSE_H
#define LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYTRAVERSE_H
#include "clang/AST/Decl.h"
#include "clang/Analysis/Analyses/ThreadSafetyTIL.h"
#include "clang/Analysis/Analyses/ThreadSafetyUtil.h"
#include "clang/Basic/LLVM.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/Support/Casting.h"
#include <cstdint>
#include <ostream>
namespace clang {
namespace threadSafety {
namespace til {
// Defines an interface used to traverse SExprs. Traversals have been made as
// generic as possible, and are intended to handle any kind of pass over the
// AST, e.g. visitors, copying, non-destructive rewriting, destructive
// (in-place) rewriting, hashing, typing, etc.
//
// Traversals implement the functional notion of a "fold" operation on SExprs.
// Each SExpr class provides a traverse method, which does the following:
// * e->traverse(v):
// // compute a result r_i for each subexpression e_i
// for (i = 1..n) r_i = v.traverse(e_i);
// // combine results into a result for e, where X is the class of e
// return v.reduceX(*e, r_1, .. r_n).
//
// A visitor can control the traversal by overriding the following methods:
// * v.traverse(e):
// return v.traverseByCase(e), which returns v.traverseX(e)
// * v.traverseX(e): (X is the class of e)
// return e->traverse(v).
// * v.reduceX(*e, r_1, .. r_n):
// compute a result for a node of type X
//
// The reduceX methods control the kind of traversal (visitor, copy, etc.).
// They are defined in derived classes.
//
// Class R defines the basic interface types (R_SExpr).
template <class Self, class R>
class Traversal {
public:
Self *self() { return static_cast<Self *>(this); }
// Traverse an expression -- returning a result of type R_SExpr.
// Override this method to do something for every expression, regardless
// of which kind it is.
// E is a reference, so this can be use for in-place updates.
// The type T must be a subclass of SExpr.
template <class T>
typename R::R_SExpr traverse(T* &E, typename R::R_Ctx Ctx) {
return traverseSExpr(E, Ctx);
}
// Override this method to do something for every expression.
// Does not allow in-place updates.
typename R::R_SExpr traverseSExpr(SExpr *E, typename R::R_Ctx Ctx) {
return traverseByCase(E, Ctx);
}
// Helper method to call traverseX(e) on the appropriate type.
typename R::R_SExpr traverseByCase(SExpr *E, typename R::R_Ctx Ctx) {
switch (E->opcode()) {
#define TIL_OPCODE_DEF(X) \
case COP_##X: \
return self()->traverse##X(cast<X>(E), Ctx);
#include "ThreadSafetyOps.def"
#undef TIL_OPCODE_DEF
}
return self()->reduceNull();
}
// Traverse e, by static dispatch on the type "X" of e.
// Override these methods to do something for a particular kind of term.
#define TIL_OPCODE_DEF(X) \
typename R::R_SExpr traverse##X(X *e, typename R::R_Ctx Ctx) { \
return e->traverse(*self(), Ctx); \
}
#include "ThreadSafetyOps.def"
#undef TIL_OPCODE_DEF
};
// Base class for simple reducers that don't much care about the context.
class SimpleReducerBase {
public:
enum TraversalKind {
// Ordinary subexpressions.
TRV_Normal,
// Declarations (e.g. function bodies).
TRV_Decl,
// Expressions that require lazy evaluation.
TRV_Lazy,
// Type expressions.
TRV_Type
};
// R_Ctx defines a "context" for the traversal, which encodes information
// about where a term appears. This can be used to encoding the
// "current continuation" for CPS transforms, or other information.
using R_Ctx = TraversalKind;
// Create context for an ordinary subexpression.
R_Ctx subExprCtx(R_Ctx Ctx) { return TRV_Normal; }
// Create context for a subexpression that occurs in a declaration position
// (e.g. function body).
R_Ctx declCtx(R_Ctx Ctx) { return TRV_Decl; }
// Create context for a subexpression that occurs in a position that
// should be reduced lazily. (e.g. code body).
R_Ctx lazyCtx(R_Ctx Ctx) { return TRV_Lazy; }
// Create context for a subexpression that occurs in a type position.
R_Ctx typeCtx(R_Ctx Ctx) { return TRV_Type; }
};
// Base class for traversals that rewrite an SExpr to another SExpr.
class CopyReducerBase : public SimpleReducerBase {
public:
// R_SExpr is the result type for a traversal.
// A copy or non-destructive rewrite returns a newly allocated term.
using R_SExpr = SExpr *;
using R_BasicBlock = BasicBlock *;
// Container is a minimal interface used to store results when traversing
// SExprs of variable arity, such as Phi, Goto, and SCFG.
template <class T> class Container {
public:
// Allocate a new container with a capacity for n elements.
Container(CopyReducerBase &S, unsigned N) : Elems(S.Arena, N) {}
// Push a new element onto the container.
void push_back(T E) { Elems.push_back(E); }
SimpleArray<T> Elems;
};
CopyReducerBase(MemRegionRef A) : Arena(A) {}
protected:
MemRegionRef Arena;
};
// Base class for visit traversals.
class VisitReducerBase : public SimpleReducerBase {
public:
// A visitor returns a bool, representing success or failure.
using R_SExpr = bool;
using R_BasicBlock = bool;
// A visitor "container" is a single bool, which accumulates success.
template <class T> class Container {
public:
bool Success = true;
Container(VisitReducerBase &S, unsigned N) {}
void push_back(bool E) { Success = Success && E; }
};
};
// Implements a traversal that visits each subexpression, and returns either
// true or false.
template <class Self>
class VisitReducer : public Traversal<Self, VisitReducerBase>,
public VisitReducerBase {
public:
VisitReducer() = default;
public:
R_SExpr reduceNull() { return true; }
R_SExpr reduceUndefined(Undefined &Orig) { return true; }
R_SExpr reduceWildcard(Wildcard &Orig) { return true; }
R_SExpr reduceLiteral(Literal &Orig) { return true; }
template<class T>
R_SExpr reduceLiteralT(LiteralT<T> &Orig) { return true; }
R_SExpr reduceLiteralPtr(Literal &Orig) { return true; }
R_SExpr reduceFunction(Function &Orig, Variable *Nvd, R_SExpr E0) {
return Nvd && E0;
}
R_SExpr reduceSFunction(SFunction &Orig, Variable *Nvd, R_SExpr E0) {
return Nvd && E0;
}
R_SExpr reduceCode(Code &Orig, R_SExpr E0, R_SExpr E1) {
return E0 && E1;
}
R_SExpr reduceField(Field &Orig, R_SExpr E0, R_SExpr E1) {
return E0 && E1;
}
R_SExpr reduceApply(Apply &Orig, R_SExpr E0, R_SExpr E1) {
return E0 && E1;
}
R_SExpr reduceSApply(SApply &Orig, R_SExpr E0, R_SExpr E1) {
return E0 && E1;
}
R_SExpr reduceProject(Project &Orig, R_SExpr E0) { return E0; }
R_SExpr reduceCall(Call &Orig, R_SExpr E0) { return E0; }
R_SExpr reduceAlloc(Alloc &Orig, R_SExpr E0) { return E0; }
R_SExpr reduceLoad(Load &Orig, R_SExpr E0) { return E0; }
R_SExpr reduceStore(Store &Orig, R_SExpr E0, R_SExpr E1) { return E0 && E1; }
R_SExpr reduceArrayIndex(Store &Orig, R_SExpr E0, R_SExpr E1) {
return E0 && E1;
}
R_SExpr reduceArrayAdd(Store &Orig, R_SExpr E0, R_SExpr E1) {
return E0 && E1;
}
R_SExpr reduceUnaryOp(UnaryOp &Orig, R_SExpr E0) { return E0; }
R_SExpr reduceBinaryOp(BinaryOp &Orig, R_SExpr E0, R_SExpr E1) {
return E0 && E1;
}
R_SExpr reduceCast(Cast &Orig, R_SExpr E0) { return E0; }
R_SExpr reduceSCFG(SCFG &Orig, Container<BasicBlock *> Bbs) {
return Bbs.Success;
}
R_BasicBlock reduceBasicBlock(BasicBlock &Orig, Container<R_SExpr> &As,
Container<R_SExpr> &Is, R_SExpr T) {
return (As.Success && Is.Success && T);
}
R_SExpr reducePhi(Phi &Orig, Container<R_SExpr> &As) {
return As.Success;
}
R_SExpr reduceGoto(Goto &Orig, BasicBlock *B) {
return true;
}
R_SExpr reduceBranch(Branch &O, R_SExpr C, BasicBlock *B0, BasicBlock *B1) {
return C;
}
R_SExpr reduceReturn(Return &O, R_SExpr E) {
return E;
}
R_SExpr reduceIdentifier(Identifier &Orig) {
return true;
}
R_SExpr reduceIfThenElse(IfThenElse &Orig, R_SExpr C, R_SExpr T, R_SExpr E) {
return C && T && E;
}
R_SExpr reduceLet(Let &Orig, Variable *Nvd, R_SExpr B) {
return Nvd && B;
}
Variable *enterScope(Variable &Orig, R_SExpr E0) { return &Orig; }
void exitScope(const Variable &Orig) {}
void enterCFG(SCFG &Cfg) {}
void exitCFG(SCFG &Cfg) {}
void enterBasicBlock(BasicBlock &BB) {}
void exitBasicBlock(BasicBlock &BB) {}
Variable *reduceVariableRef(Variable *Ovd) { return Ovd; }
BasicBlock *reduceBasicBlockRef(BasicBlock *Obb) { return Obb; }
public:
bool traverse(SExpr *E, TraversalKind K = TRV_Normal) {
Success = Success && this->traverseByCase(E);
return Success;
}
static bool visit(SExpr *E) {
Self Visitor;
return Visitor.traverse(E, TRV_Normal);
}
private:
bool Success;
};
// Basic class for comparison operations over expressions.
template <typename Self>
class Comparator {
protected:
Self *self() { return reinterpret_cast<Self *>(this); }
public:
bool compareByCase(const SExpr *E1, const SExpr* E2) {
switch (E1->opcode()) {
#define TIL_OPCODE_DEF(X) \
case COP_##X: \
return cast<X>(E1)->compare(cast<X>(E2), *self());
#include "ThreadSafetyOps.def"
#undef TIL_OPCODE_DEF
}
return false;
}
};
class EqualsComparator : public Comparator<EqualsComparator> {
public:
// Result type for the comparison, e.g. bool for simple equality,
// or int for lexigraphic comparison (-1, 0, 1). Must have one value which
// denotes "true".
using CType = bool;
CType trueResult() { return true; }
bool notTrue(CType ct) { return !ct; }
bool compareIntegers(unsigned i, unsigned j) { return i == j; }
bool compareStrings (StringRef s, StringRef r) { return s == r; }
bool comparePointers(const void* P, const void* Q) { return P == Q; }
bool compare(const SExpr *E1, const SExpr* E2) {
if (E1->opcode() != E2->opcode())
return false;
return compareByCase(E1, E2);
}
// TODO -- handle alpha-renaming of variables
void enterScope(const Variable *V1, const Variable *V2) {}
void leaveScope() {}
bool compareVariableRefs(const Variable *V1, const Variable *V2) {
return V1 == V2;
}
static bool compareExprs(const SExpr *E1, const SExpr* E2) {
EqualsComparator Eq;
return Eq.compare(E1, E2);
}
};
class MatchComparator : public Comparator<MatchComparator> {
public:
// Result type for the comparison, e.g. bool for simple equality,
// or int for lexigraphic comparison (-1, 0, 1). Must have one value which
// denotes "true".
using CType = bool;
CType trueResult() { return true; }
bool notTrue(CType ct) { return !ct; }
bool compareIntegers(unsigned i, unsigned j) { return i == j; }
bool compareStrings (StringRef s, StringRef r) { return s == r; }
bool comparePointers(const void *P, const void *Q) { return P == Q; }
bool compare(const SExpr *E1, const SExpr *E2) {
// Wildcards match anything.
if (E1->opcode() == COP_Wildcard || E2->opcode() == COP_Wildcard)
return true;
// otherwise normal equality.
if (E1->opcode() != E2->opcode())
return false;
return compareByCase(E1, E2);
}
// TODO -- handle alpha-renaming of variables
void enterScope(const Variable* V1, const Variable* V2) {}
void leaveScope() {}
bool compareVariableRefs(const Variable* V1, const Variable* V2) {
return V1 == V2;
}
static bool compareExprs(const SExpr *E1, const SExpr* E2) {
MatchComparator Matcher;
return Matcher.compare(E1, E2);
}
};
// inline std::ostream& operator<<(std::ostream& SS, StringRef R) {
// return SS.write(R.data(), R.size());
// }
// Pretty printer for TIL expressions
template <typename Self, typename StreamType>
class PrettyPrinter {
private:
// Print out additional information.
bool Verbose;
// Omit redundant decls.
bool Cleanup;
// Print exprs in C-like syntax.
bool CStyle;
public:
PrettyPrinter(bool V = false, bool C = true, bool CS = true)
: Verbose(V), Cleanup(C), CStyle(CS) {}
static void print(const SExpr *E, StreamType &SS) {
Self printer;
printer.printSExpr(E, SS, Prec_MAX);
}
protected:
Self *self() { return reinterpret_cast<Self *>(this); }
void newline(StreamType &SS) {
SS << "\n";
}
// TODO: further distinguish between binary operations.
static const unsigned Prec_Atom = 0;
static const unsigned Prec_Postfix = 1;
static const unsigned Prec_Unary = 2;
static const unsigned Prec_Binary = 3;
static const unsigned Prec_Other = 4;
static const unsigned Prec_Decl = 5;
static const unsigned Prec_MAX = 6;
// Return the precedence of a given node, for use in pretty printing.
unsigned precedence(const SExpr *E) {
switch (E->opcode()) {
case COP_Future: return Prec_Atom;
case COP_Undefined: return Prec_Atom;
case COP_Wildcard: return Prec_Atom;
case COP_Literal: return Prec_Atom;
case COP_LiteralPtr: return Prec_Atom;
case COP_Variable: return Prec_Atom;
case COP_Function: return Prec_Decl;
case COP_SFunction: return Prec_Decl;
case COP_Code: return Prec_Decl;
case COP_Field: return Prec_Decl;
case COP_Apply: return Prec_Postfix;
case COP_SApply: return Prec_Postfix;
case COP_Project: return Prec_Postfix;
case COP_Call: return Prec_Postfix;
case COP_Alloc: return Prec_Other;
case COP_Load: return Prec_Postfix;
case COP_Store: return Prec_Other;
case COP_ArrayIndex: return Prec_Postfix;
case COP_ArrayAdd: return Prec_Postfix;
case COP_UnaryOp: return Prec_Unary;
case COP_BinaryOp: return Prec_Binary;
case COP_Cast: return Prec_Atom;
case COP_SCFG: return Prec_Decl;
case COP_BasicBlock: return Prec_MAX;
case COP_Phi: return Prec_Atom;
case COP_Goto: return Prec_Atom;
case COP_Branch: return Prec_Atom;
case COP_Return: return Prec_Other;
case COP_Identifier: return Prec_Atom;
case COP_IfThenElse: return Prec_Other;
case COP_Let: return Prec_Decl;
}
return Prec_MAX;
}
void printBlockLabel(StreamType & SS, const BasicBlock *BB, int index) {
if (!BB) {
SS << "BB_null";
return;
}
SS << "BB_";
SS << BB->blockID();
if (index >= 0) {
SS << ":";
SS << index;
}
}
void printSExpr(const SExpr *E, StreamType &SS, unsigned P, bool Sub=true) {
if (!E) {
self()->printNull(SS);
return;
}
if (Sub && E->block() && E->opcode() != COP_Variable) {
SS << "_x" << E->id();
return;
}
if (self()->precedence(E) > P) {
// Wrap expr in () if necessary.
SS << "(";
self()->printSExpr(E, SS, Prec_MAX);
SS << ")";
return;
}
switch (E->opcode()) {
#define TIL_OPCODE_DEF(X) \
case COP_##X: \
self()->print##X(cast<X>(E), SS); \
return;
#include "ThreadSafetyOps.def"
#undef TIL_OPCODE_DEF
}
}
void printNull(StreamType &SS) {
SS << "#null";
}
void printFuture(const Future *E, StreamType &SS) {
self()->printSExpr(E->maybeGetResult(), SS, Prec_Atom);
}
void printUndefined(const Undefined *E, StreamType &SS) {
SS << "#undefined";
}
void printWildcard(const Wildcard *E, StreamType &SS) {
SS << "*";
}
template<class T>
void printLiteralT(const LiteralT<T> *E, StreamType &SS) {
SS << E->value();
}
void printLiteralT(const LiteralT<uint8_t> *E, StreamType &SS) {
SS << "'" << E->value() << "'";
}
void printLiteral(const Literal *E, StreamType &SS) {
if (E->clangExpr()) {
SS << getSourceLiteralString(E->clangExpr());
return;
}
else {
ValueType VT = E->valueType();
switch (VT.Base) {
case ValueType::BT_Void:
SS << "void";
return;
case ValueType::BT_Bool:
if (E->as<bool>().value())
SS << "true";
else
SS << "false";
return;
case ValueType::BT_Int:
switch (VT.Size) {
case ValueType::ST_8:
if (VT.Signed)
printLiteralT(&E->as<int8_t>(), SS);
else
printLiteralT(&E->as<uint8_t>(), SS);
return;
case ValueType::ST_16:
if (VT.Signed)
printLiteralT(&E->as<int16_t>(), SS);
else
printLiteralT(&E->as<uint16_t>(), SS);
return;
case ValueType::ST_32:
if (VT.Signed)
printLiteralT(&E->as<int32_t>(), SS);
else
printLiteralT(&E->as<uint32_t>(), SS);
return;
case ValueType::ST_64:
if (VT.Signed)
printLiteralT(&E->as<int64_t>(), SS);
else
printLiteralT(&E->as<uint64_t>(), SS);
return;
default:
break;
}
break;
case ValueType::BT_Float:
switch (VT.Size) {
case ValueType::ST_32:
printLiteralT(&E->as<float>(), SS);
return;
case ValueType::ST_64:
printLiteralT(&E->as<double>(), SS);
return;
default:
break;
}
break;
case ValueType::BT_String:
SS << "\"";
printLiteralT(&E->as<StringRef>(), SS);
SS << "\"";
return;
case ValueType::BT_Pointer:
SS << "#ptr";
return;
case ValueType::BT_ValueRef:
SS << "#vref";
return;
}
}
SS << "#lit";
}
void printLiteralPtr(const LiteralPtr *E, StreamType &SS) {
SS << E->clangDecl()->getNameAsString();
}
void printVariable(const Variable *V, StreamType &SS, bool IsVarDecl=false) {
if (CStyle && V->kind() == Variable::VK_SFun)
SS << "this";
else
SS << V->name() << V->id();
}
void printFunction(const Function *E, StreamType &SS, unsigned sugared = 0) {
switch (sugared) {
default:
SS << "\\("; // Lambda
break;
case 1:
SS << "("; // Slot declarations
break;
case 2:
SS << ", "; // Curried functions
break;
}
self()->printVariable(E->variableDecl(), SS, true);
SS << ": ";
self()->printSExpr(E->variableDecl()->definition(), SS, Prec_MAX);
const SExpr *B = E->body();
if (B && B->opcode() == COP_Function)
self()->printFunction(cast<Function>(B), SS, 2);
else {
SS << ")";
self()->printSExpr(B, SS, Prec_Decl);
}
}
void printSFunction(const SFunction *E, StreamType &SS) {
SS << "@";
self()->printVariable(E->variableDecl(), SS, true);
SS << " ";
self()->printSExpr(E->body(), SS, Prec_Decl);
}
void printCode(const Code *E, StreamType &SS) {
SS << ": ";
self()->printSExpr(E->returnType(), SS, Prec_Decl-1);
SS << " -> ";
self()->printSExpr(E->body(), SS, Prec_Decl);
}
void printField(const Field *E, StreamType &SS) {
SS << ": ";
self()->printSExpr(E->range(), SS, Prec_Decl-1);
SS << " = ";
self()->printSExpr(E->body(), SS, Prec_Decl);
}
void printApply(const Apply *E, StreamType &SS, bool sugared = false) {
const SExpr *F = E->fun();
if (F->opcode() == COP_Apply) {
printApply(cast<Apply>(F), SS, true);
SS << ", ";
} else {
self()->printSExpr(F, SS, Prec_Postfix);
SS << "(";
}
self()->printSExpr(E->arg(), SS, Prec_MAX);
if (!sugared)
SS << ")$";
}
void printSApply(const SApply *E, StreamType &SS) {
self()->printSExpr(E->sfun(), SS, Prec_Postfix);
if (E->isDelegation()) {
SS << "@(";
self()->printSExpr(E->arg(), SS, Prec_MAX);
SS << ")";
}
}
void printProject(const Project *E, StreamType &SS) {
if (CStyle) {
// Omit the this->
if (const auto *SAP = dyn_cast<SApply>(E->record())) {
if (const auto *V = dyn_cast<Variable>(SAP->sfun())) {
if (!SAP->isDelegation() && V->kind() == Variable::VK_SFun) {
SS << E->slotName();
return;
}
}
}
if (isa<Wildcard>(E->record())) {
// handle existentials
SS << "&";
SS << E->clangDecl()->getQualifiedNameAsString();
return;
}
}
self()->printSExpr(E->record(), SS, Prec_Postfix);
if (CStyle && E->isArrow())
SS << "->";
else
SS << ".";
SS << E->slotName();
}
void printCall(const Call *E, StreamType &SS) {
const SExpr *T = E->target();
if (T->opcode() == COP_Apply) {
self()->printApply(cast<Apply>(T), SS, true);
SS << ")";
}
else {
self()->printSExpr(T, SS, Prec_Postfix);
SS << "()";
}
}
void printAlloc(const Alloc *E, StreamType &SS) {
SS << "new ";
self()->printSExpr(E->dataType(), SS, Prec_Other-1);
}
void printLoad(const Load *E, StreamType &SS) {
self()->printSExpr(E->pointer(), SS, Prec_Postfix);
if (!CStyle)
SS << "^";
}
void printStore(const Store *E, StreamType &SS) {
self()->printSExpr(E->destination(), SS, Prec_Other-1);
SS << " := ";
self()->printSExpr(E->source(), SS, Prec_Other-1);
}
void printArrayIndex(const ArrayIndex *E, StreamType &SS) {
self()->printSExpr(E->array(), SS, Prec_Postfix);
SS << "[";
self()->printSExpr(E->index(), SS, Prec_MAX);
SS << "]";
}
void printArrayAdd(const ArrayAdd *E, StreamType &SS) {
self()->printSExpr(E->array(), SS, Prec_Postfix);
SS << " + ";
self()->printSExpr(E->index(), SS, Prec_Atom);
}
void printUnaryOp(const UnaryOp *E, StreamType &SS) {
SS << getUnaryOpcodeString(E->unaryOpcode());
self()->printSExpr(E->expr(), SS, Prec_Unary);
}
void printBinaryOp(const BinaryOp *E, StreamType &SS) {
self()->printSExpr(E->expr0(), SS, Prec_Binary-1);
SS << " " << getBinaryOpcodeString(E->binaryOpcode()) << " ";
self()->printSExpr(E->expr1(), SS, Prec_Binary-1);
}
void printCast(const Cast *E, StreamType &SS) {
if (!CStyle) {
SS << "cast[";
switch (E->castOpcode()) {
case CAST_none:
SS << "none";
break;
case CAST_extendNum:
SS << "extendNum";
break;
case CAST_truncNum:
SS << "truncNum";
break;
case CAST_toFloat:
SS << "toFloat";
break;
case CAST_toInt:
SS << "toInt";
break;
case CAST_objToPtr:
SS << "objToPtr";
break;
}
SS << "](";
self()->printSExpr(E->expr(), SS, Prec_Unary);
SS << ")";
return;
}
self()->printSExpr(E->expr(), SS, Prec_Unary);
}
void printSCFG(const SCFG *E, StreamType &SS) {
SS << "CFG {\n";
for (const auto *BBI : *E)
printBasicBlock(BBI, SS);
SS << "}";
newline(SS);
}
void printBBInstr(const SExpr *E, StreamType &SS) {
bool Sub = false;
if (E->opcode() == COP_Variable) {
const auto *V = cast<Variable>(E);
SS << "let " << V->name() << V->id() << " = ";
E = V->definition();
Sub = true;
}
else if (E->opcode() != COP_Store) {
SS << "let _x" << E->id() << " = ";
}
self()->printSExpr(E, SS, Prec_MAX, Sub);
SS << ";";
newline(SS);
}
void printBasicBlock(const BasicBlock *E, StreamType &SS) {
SS << "BB_" << E->blockID() << ":";
if (E->parent())
SS << " BB_" << E->parent()->blockID();
newline(SS);
for (const auto *A : E->arguments())
printBBInstr(A, SS);
for (const auto *I : E->instructions())
printBBInstr(I, SS);
const SExpr *T = E->terminator();
if (T) {
self()->printSExpr(T, SS, Prec_MAX, false);
SS << ";";
newline(SS);
}
newline(SS);
}
void printPhi(const Phi *E, StreamType &SS) {
SS << "phi(";
if (E->status() == Phi::PH_SingleVal)
self()->printSExpr(E->values()[0], SS, Prec_MAX);
else {
unsigned i = 0;
for (const auto *V : E->values()) {
if (i++ > 0)
SS << ", ";
self()->printSExpr(V, SS, Prec_MAX);
}
}
SS << ")";
}
void printGoto(const Goto *E, StreamType &SS) {
SS << "goto ";
printBlockLabel(SS, E->targetBlock(), E->index());
}
void printBranch(const Branch *E, StreamType &SS) {
SS << "branch (";
self()->printSExpr(E->condition(), SS, Prec_MAX);
SS << ") ";
printBlockLabel(SS, E->thenBlock(), -1);
SS << " ";
printBlockLabel(SS, E->elseBlock(), -1);
}
void printReturn(const Return *E, StreamType &SS) {
SS << "return ";
self()->printSExpr(E->returnValue(), SS, Prec_Other);
}
void printIdentifier(const Identifier *E, StreamType &SS) {
SS << E->name();
}
void printIfThenElse(const IfThenElse *E, StreamType &SS) {
if (CStyle) {
printSExpr(E->condition(), SS, Prec_Unary);
SS << " ? ";
printSExpr(E->thenExpr(), SS, Prec_Unary);
SS << " : ";
printSExpr(E->elseExpr(), SS, Prec_Unary);
return;
}
SS << "if (";
printSExpr(E->condition(), SS, Prec_MAX);
SS << ") then ";
printSExpr(E->thenExpr(), SS, Prec_Other);
SS << " else ";
printSExpr(E->elseExpr(), SS, Prec_Other);
}
void printLet(const Let *E, StreamType &SS) {
SS << "let ";
printVariable(E->variableDecl(), SS, true);
SS << " = ";
printSExpr(E->variableDecl()->definition(), SS, Prec_Decl-1);
SS << "; ";
printSExpr(E->body(), SS, Prec_Decl-1);
}
};
class StdPrinter : public PrettyPrinter<StdPrinter, std::ostream> {};
} // namespace til
} // namespace threadSafety
} // namespace clang
#endif // LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYTRAVERSE_H