/**
* Test the renaming of variables.
*/
void
CfgTest::testRenameVars()
{
auto prog = Prog::open(FRONTIER_PENTIUM);
CPPUNIT_ASSERT(prog);
auto fe = prog->getFrontEnd();
Type::clearNamedTypes();
fe->decode();
UserProc *pProc = (UserProc *)prog->getProc(0);
Cfg *cfg = pProc->getCFG();
DataFlow *df = pProc->getDataFlow();
// Simplify expressions (e.g. m[ebp + -8] -> m[ebp - 8]
prog->finishDecode();
df->dominators(cfg);
df->placePhiFunctions(pProc);
pProc->numberStatements(); // After placing phi functions!
df->renameBlockVars(pProc, 0, 1); // Block 0, mem depth 1
// MIKE: something missing here?
delete prog;
}
/**
* Test the placing of phi functions.
*/
void
CfgTest::testPlacePhi()
{
auto prog = Prog::open(FRONTIER_PENTIUM);
CPPUNIT_ASSERT(prog);
auto fe = prog->getFrontEnd();
Type::clearNamedTypes();
fe->decode();
UserProc *pProc = (UserProc *)prog->getProc(0);
Cfg *cfg = pProc->getCFG();
// Simplify expressions (e.g. m[ebp + -8] -> m[ebp - 8]
prog->finishDecode();
DataFlow *df = pProc->getDataFlow();
df->dominators(cfg);
df->placePhiFunctions(pProc);
// m[r29 - 8] (x for this program)
Exp *e = Location::memOf(
new Binary(opMinus,
Location::regOf(29),
new Const(4)));
// A_phi[x] should be the set {7 8 10 15 20 21} (all the join points)
std::ostringstream ost;
std::set<int> &A_phi = df->getA_phi(e);
for (const auto &ii : A_phi)
ost << ii << " ";
std::string expected("7 8 10 15 20 21 ");
CPPUNIT_ASSERT_EQUAL(expected, ost.str());
delete prog;
}
/*==============================================================================
* FUNCTION: CfgTest::testRenameVars
* OVERVIEW: Test the renaming of variables
*============================================================================*/
void CfgTest::testRenameVars ()
{
BinaryFileFactory bff;
BinaryFile* pBF = bff.Load(FRONTIER_PENTIUM);
CPPUNIT_ASSERT(pBF != 0);
Prog* prog = new Prog;
FrontEnd* pFE = new PentiumFrontEnd(pBF, prog, &bff);
Type::clearNamedTypes();
prog->setFrontEnd(pFE);
pFE->decode(prog);
UserProc* pProc = (UserProc*) prog->getProc(0);
Cfg* cfg = pProc->getCFG();
DataFlow* df = pProc->getDataFlow();
// Simplify expressions (e.g. m[ebp + -8] -> m[ebp - 8]
prog->finishDecode();
df->dominators(cfg);
df->placePhiFunctions(pProc);
pProc->numberStatements(); // After placing phi functions!
df->renameBlockVars(pProc, 0, 1); // Block 0, mem depth 1
// MIKE: something missing here?
delete pFE;
}
/**
* Test the dominator frontier code.
*/
void
CfgTest::testDominators()
{
#define FRONTIER_FOUR 0x08048347
#define FRONTIER_FIVE 0x08048351
#define FRONTIER_TWELVE 0x080483b2
#define FRONTIER_THIRTEEN 0x080483b9
auto prog = Prog::open(FRONTIER_PENTIUM);
CPPUNIT_ASSERT(prog);
auto fe = prog->getFrontEnd();
Type::clearNamedTypes();
fe->decode();
bool gotMain;
ADDRESS addr = fe->getMainEntryPoint(gotMain);
CPPUNIT_ASSERT(addr != NO_ADDRESS);
UserProc *pProc = (UserProc *)prog->getProc(0);
Cfg *cfg = pProc->getCFG();
DataFlow *df = pProc->getDataFlow();
df->dominators(cfg);
// Find BB "5" (as per Appel, Figure 19.5).
BasicBlock *bb = nullptr;
for (const auto &b : *cfg) {
if (b->getLowAddr() == FRONTIER_FIVE) {
bb = b;
break;
}
}
CPPUNIT_ASSERT(bb);
std::ostringstream expected, actual;
#if 0
expected << std::hex
<< FRONTIER_FIVE << " "
<< FRONTIER_THIRTEEN << " "
<< FRONTIER_TWELVE << " "
<< FRONTIER_FOUR << " "
<< std::dec;
#endif
expected << std::hex
<< FRONTIER_THIRTEEN << " "
<< FRONTIER_FOUR << " "
<< FRONTIER_TWELVE << " "
<< FRONTIER_FIVE << " "
<< std::dec;
int n5 = df->pbbToNode(bb);
std::set<int> &DFset = df->getDF(n5);
for (const auto &ii : DFset)
actual << std::hex << (unsigned)df->nodeToBB(ii)->getLowAddr() << std::dec << " ";
CPPUNIT_ASSERT_EQUAL(expected.str(), actual.str());
delete prog;
}
/*==============================================================================
* FUNCTION: CfgTest::testPlacePhi2
* OVERVIEW: Test a case where a phi function is not needed
*============================================================================*/
void CfgTest::testPlacePhi2 ()
{
BinaryFileFactory bff;
BinaryFile* pBF = bff.Load(IFTHEN_PENTIUM);
CPPUNIT_ASSERT(pBF != 0);
Prog* prog = new Prog;
FrontEnd* pFE = new PentiumFrontEnd(pBF, prog, &bff);
Type::clearNamedTypes();
prog->setFrontEnd(pFE);
pFE->decode(prog);
UserProc* pProc = (UserProc*) prog->getProc(0);
Cfg* cfg = pProc->getCFG();
DataFlow* df = pProc->getDataFlow();
// Simplify expressions (e.g. m[ebp + -8] -> m[ebp - 8]
prog->finishDecode();
df->dominators(cfg);
df->placePhiFunctions(pProc);
// In this program, x is allocated at [ebp-4], a at [ebp-8], and
// b at [ebp-12]
// We check that A_phi[ m[ebp-8] ] is 4, and that
// A_phi A_phi[ m[ebp-8] ] is null
// (block 4 comes out with n=4)
std::string expected = "4 ";
std::ostringstream actual;
// m[r29 - 8]
Exp* e = new Unary(opMemOf,
new Binary(opMinus,
Location::regOf(29),
new Const(8)));
std::set<int>& s = df->getA_phi(e);
std::set<int>::iterator pp;
for (pp = s.begin(); pp != s.end(); pp++)
actual << *pp << " ";
CPPUNIT_ASSERT_EQUAL(expected, actual.str());
delete e;
expected = "";
std::ostringstream actual2;
// m[r29 - 12]
e = new Unary(opMemOf,
new Binary(opMinus,
Location::regOf(29),
new Const(12)));
std::set<int>& s2 = df->getA_phi(e);
for (pp = s2.begin(); pp != s2.end(); pp++)
actual2 << *pp << " ";
CPPUNIT_ASSERT_EQUAL(expected, actual2.str());
delete e;
delete pFE;
}
/**
* Test a case where semi dominators are different to dominators.
*/
void
CfgTest::testSemiDominators()
{
#define SEMI_L 0x80483b0
#define SEMI_M 0x80483e2
#define SEMI_B 0x8048345
#define SEMI_D 0x8048354
#define SEMI_M 0x80483e2
auto prog = Prog::open(SEMI_PENTIUM);
CPPUNIT_ASSERT(prog);
auto fe = prog->getFrontEnd();
Type::clearNamedTypes();
fe->decode();
bool gotMain;
ADDRESS addr = fe->getMainEntryPoint(gotMain);
CPPUNIT_ASSERT(addr != NO_ADDRESS);
UserProc *pProc = (UserProc *)prog->getProc(0);
Cfg *cfg = pProc->getCFG();
DataFlow *df = pProc->getDataFlow();
df->dominators(cfg);
// Find BB "L (6)" (as per Appel, Figure 19.8).
BasicBlock *bb = nullptr;
for (const auto &b : *cfg) {
if (b->getLowAddr() == SEMI_L) {
bb = b;
break;
}
}
CPPUNIT_ASSERT(bb);
int nL = df->pbbToNode(bb);
// The dominator for L should be B, where the semi dominator is D
// (book says F)
unsigned actual_dom = (unsigned)df->nodeToBB(df->getIdom(nL))->getLowAddr();
unsigned actual_semi = (unsigned)df->nodeToBB(df->getSemi(nL))->getLowAddr();
CPPUNIT_ASSERT_EQUAL((unsigned)SEMI_B, actual_dom);
CPPUNIT_ASSERT_EQUAL((unsigned)SEMI_D, actual_semi);
// Check the final dominator frontier as well; should be M and B
std::ostringstream expected, actual;
#if 0
expected << std::hex << SEMI_M << " " << SEMI_B << " " << std::dec;
#endif
expected << std::hex << SEMI_B << " " << SEMI_M << " " << std::dec;
std::set<int> &DFset = df->getDF(nL);
for (const auto &ii : DFset)
actual << std::hex << (unsigned)df->nodeToBB(ii)->getLowAddr() << std::dec << " ";
CPPUNIT_ASSERT_EQUAL(expected.str(), actual.str());
delete prog;
}
/**
* Test a case where a phi function is not needed.
*/
void
CfgTest::testPlacePhi2()
{
auto prog = Prog::open(IFTHEN_PENTIUM);
CPPUNIT_ASSERT(prog);
auto fe = prog->getFrontEnd();
Type::clearNamedTypes();
fe->decode();
UserProc *pProc = (UserProc *)prog->getProc(0);
Cfg *cfg = pProc->getCFG();
DataFlow *df = pProc->getDataFlow();
// Simplify expressions (e.g. m[ebp + -8] -> m[ebp - 8]
prog->finishDecode();
df->dominators(cfg);
df->placePhiFunctions(pProc);
// In this program, x is allocated at [ebp-4], a at [ebp-8], and
// b at [ebp-12]
// We check that A_phi[ m[ebp-8] ] is 4, and that
// A_phi A_phi[ m[ebp-8] ] is null
// (block 4 comes out with n=4)
std::string expected = "4 ";
std::ostringstream actual;
// m[r29 - 8]
Exp *e = Location::memOf(
new Binary(opMinus,
Location::regOf(29),
new Const(8)));
std::set<int> &s = df->getA_phi(e);
for (const auto &pp : s)
actual << pp << " ";
CPPUNIT_ASSERT_EQUAL(expected, actual.str());
delete e;
expected = "";
std::ostringstream actual2;
// m[r29 - 12]
e = Location::memOf(
new Binary(opMinus,
Location::regOf(29),
new Const(12)));
std::set<int> &s2 = df->getA_phi(e);
for (const auto &pp : s2)
actual2 << pp << " ";
CPPUNIT_ASSERT_EQUAL(expected, actual2.str());
delete e;
delete prog;
}
void CfgTest::testSemiDominators ()
{
BinaryFileFactory bff;
BinaryFile* pBF = bff.Load(SEMI_PENTIUM);
CPPUNIT_ASSERT(pBF != 0);
Prog* prog = new Prog;
FrontEnd* pFE = new PentiumFrontEnd(pBF, prog, &bff);
Type::clearNamedTypes();
prog->setFrontEnd(pFE);
pFE->decode(prog);
bool gotMain;
ADDRESS addr = pFE->getMainEntryPoint(gotMain);
CPPUNIT_ASSERT (addr != NO_ADDRESS);
UserProc* pProc = (UserProc*) prog->getProc(0);
Cfg* cfg = pProc->getCFG();
DataFlow* df = pProc->getDataFlow();
df->dominators(cfg);
// Find BB "L (6)" (as per Appel, Figure 19.8).
BB_IT it;
PBB bb = cfg->getFirstBB(it);
while (bb && bb->getLowAddr() != SEMI_L)
{
bb = cfg->getNextBB(it);
}
CPPUNIT_ASSERT(bb);
int nL = df->pbbToNode(bb);
// The dominator for L should be B, where the semi dominator is D
// (book says F)
unsigned actual_dom = (unsigned)df->nodeToBB(df->getIdom(nL))->getLowAddr();
unsigned actual_semi = (unsigned)df->nodeToBB(df->getSemi(nL))->getLowAddr();
CPPUNIT_ASSERT_EQUAL((unsigned)SEMI_B, actual_dom);
CPPUNIT_ASSERT_EQUAL((unsigned)SEMI_D, actual_semi);
// Check the final dominator frontier as well; should be M and B
std::ostringstream expected, actual;
//expected << std::hex << SEMI_M << " " << SEMI_B << " ";
expected << std::hex << SEMI_B << " " << SEMI_M << " ";
std::set<int>::iterator ii;
std::set<int>& DFset = df->getDF(nL);
for (ii=DFset.begin(); ii != DFset.end(); ii++)
actual << std::hex << (unsigned)df->nodeToBB(*ii)->getLowAddr() << " ";
CPPUNIT_ASSERT_EQUAL(expected.str(), actual.str());
delete pFE;
}
void CfgTest::testDominators ()
{
BinaryFileFactory bff;
BinaryFile *pBF = bff.Load(FRONTIER_PENTIUM);
CPPUNIT_ASSERT(pBF != 0);
Prog* prog = new Prog;
FrontEnd *pFE = new PentiumFrontEnd(pBF, prog, &bff);
Type::clearNamedTypes();
prog->setFrontEnd(pFE);
pFE->decode(prog);
bool gotMain;
ADDRESS addr = pFE->getMainEntryPoint(gotMain);
CPPUNIT_ASSERT (addr != NO_ADDRESS);
UserProc* pProc = (UserProc*) prog->getProc(0);
Cfg* cfg = pProc->getCFG();
DataFlow* df = pProc->getDataFlow();
df->dominators(cfg);
// Find BB "5" (as per Appel, Figure 19.5).
BB_IT it;
PBB bb = cfg->getFirstBB(it);
while (bb && bb->getLowAddr() != FRONTIER_FIVE)
{
bb = cfg->getNextBB(it);
}
CPPUNIT_ASSERT(bb);
std::ostringstream expected, actual;
//expected << std::hex << FRONTIER_FIVE << " " << FRONTIER_THIRTEEN << " " << FRONTIER_TWELVE << " " <<
// FRONTIER_FOUR << " ";
expected << std::hex << FRONTIER_THIRTEEN << " " << FRONTIER_FOUR << " " << FRONTIER_TWELVE << " " <<
FRONTIER_FIVE << " ";
int n5 = df->pbbToNode(bb);
std::set<int>::iterator ii;
std::set<int>& DFset = df->getDF(n5);
for (ii=DFset.begin(); ii != DFset.end(); ii++)
actual << std::hex << (unsigned)df->nodeToBB(*ii)->getLowAddr() << " ";
CPPUNIT_ASSERT_EQUAL(expected.str(), actual.str());
pBF->UnLoad();
delete pFE;
}
/*==============================================================================
* FUNCTION: CfgTest::testPlacePhi
* OVERVIEW: Test the placing of phi functions
*============================================================================*/
void CfgTest::testPlacePhi ()
{
BinaryFileFactory bff;
BinaryFile* pBF = bff.Load(FRONTIER_PENTIUM);
CPPUNIT_ASSERT(pBF != 0);
Prog* prog = new Prog;
FrontEnd* pFE = new PentiumFrontEnd(pBF, prog, &bff);
Type::clearNamedTypes();
prog->setFrontEnd(pFE);
pFE->decode(prog);
UserProc* pProc = (UserProc*) prog->getProc(0);
Cfg* cfg = pProc->getCFG();
// Simplify expressions (e.g. m[ebp + -8] -> m[ebp - 8]
prog->finishDecode();
DataFlow* df = pProc->getDataFlow();
df->dominators(cfg);
df->placePhiFunctions(pProc);
// m[r29 - 8] (x for this program)
Exp* e = new Unary(opMemOf,
new Binary(opMinus,
Location::regOf(29),
new Const(4)));
// A_phi[x] should be the set {7 8 10 15 20 21} (all the join points)
std::ostringstream ost;
std::set<int>::iterator ii;
std::set<int>& A_phi = df->getA_phi(e);
for (ii = A_phi.begin(); ii != A_phi.end(); ++ii)
ost << *ii << " ";
std::string expected("7 8 10 15 20 21 ");
CPPUNIT_ASSERT_EQUAL(expected, ost.str());
delete pFE;
}
