static BOOL DebugInterpreter(THREADID tid, CONTEXT *ctxt, const string &cmd, string *result, VOID *)
{
TINFO_MAP::iterator it = ThreadInfos.find(tid);
if (it == ThreadInfos.end())
return FALSE;
TINFO *tinfo = it->second;
std::string line = TrimWhitespace(cmd);
*result = "";
if (line == "help")
{
result->append("mappings -- Mappings.\n");
return TRUE;
}
else if(line == "mappings")
{
tinfo->_os.str("");
tinfo->_os << "{"; //open JSON
for( IMG img= APP_ImgHead(); IMG_Valid(img); img = IMG_Next(img) )
{
const string& name = LEVEL_PINCLIENT::IMG_Name(img);
tinfo->_os <<"\""<< name << "\":{"; //open img
ADDRINT address = LEVEL_PINCLIENT::IMG_LowAddress(img);
tinfo->_os << "\"start\":" << address << ",";
address = LEVEL_PINCLIENT::IMG_HighAddress(img);
tinfo->_os << "\"end\":" << address << ",";
tinfo->_os << "\"sections\":" << "{"; //open sections
for( SEC sec = IMG_SecHead(img); SEC_Valid(sec); sec = SEC_Next(sec))
{
const string& name = LEVEL_PINCLIENT::SEC_Name(sec);
if(name != "")
{
tinfo->_os << "\"" << name <<"\":{"; //open section
ADDRINT address = LEVEL_PINCLIENT::SEC_Address(sec);
tinfo->_os << "\"start\":" << address << ",";
USIZE size = LEVEL_PINCLIENT::SEC_Size(sec);
if(SEC_Valid(SEC_Next(sec)))
{
tinfo->_os << "\"size\":" << size << "},"; //close section
}else
{
tinfo->_os << "\"size\":" << size << "}}"; //close section and sections
}
}
}
if(IMG_Valid(IMG_Next(img)))
{
tinfo->_os << "},"; //close img
}else
{
tinfo->_os << "}}"; //close img and json
}
}
*result = tinfo->_os.str();
return TRUE;
}
return FALSE; /* Unknown command */
}
BaseIRBuilder::BaseIRBuilder(__uint address, const std::string &dis) {
RTN rtn;
SEC sec;
IMG img;
this->address = address;
this->branchTaken = false;
this->branchTargetAddress = 0;
this->disas = dis;
this->needSetup = false;
this->nextAddress = 0;
this->imageName = "unknown";
this->sectionName = "unknown";
rtn = RTN_FindByAddress(address);
if (RTN_Valid(rtn)) {
sec = RTN_Sec(rtn);
if (SEC_Valid(sec)) {
this->sectionName = SEC_Name(sec);
img = SEC_Img(sec);
if (IMG_Valid(img)) {
this->baseAddress = IMG_LowAddress(img);
this->imageName = IMG_Name(img);
}
}
}
this->offset = this->address - this->baseAddress;
this->routineName = RTN_FindNameByAddress(address);
if (this->routineName.empty())
this->routineName = "unknown";
}
VOID MemWrite(THREADID tid, ADDRINT ea, ADDRINT eip )
{
IMG imgR;
string retName = "ANON", rR = "unknown";
thread_data_t *tdata = get_tls(tid);
list<ADDRINT>::const_iterator sp_iter;
for (sp_iter = tdata->data_sp.begin(); sp_iter != tdata->data_sp.end(); sp_iter++) {
if ( *sp_iter == ea )
break;
}
if ( sp_iter != tdata->data_sp.end() ) {
PIN_LockClient();
imgR = IMG_FindByAddress((ADDRINT)eip);
PIN_UnlockClient();
if ( IMG_Valid(imgR) ) {
retName = IMG_Name(imgR);
}
rR = RTN_FindNameByAddress((ADDRINT)eip);
OutFile[tid] << tid << hex << "return address overwrite!!! " << ea << " "
<< eip << " " << retName << " " << rR << endl;
}
}
static void Instruction(INS ins, void *v)
{
INS_InsertPredicatedCall(
ins, IPOINT_BEFORE,
(AFUNPTR)do_count,
IARG_END);
// Filters out non memory reference instructions.
if (!INS_IsMemoryRead(ins) && !INS_IsMemoryWrite(ins))
return;
// Filters out references to stack.
if (INS_IsStackRead(ins) || INS_IsStackWrite(ins))
return;
// Filters out instructions out of main executable.
IMG img = IMG_FindByAddress(INS_Address(ins));
if (!IMG_Valid(img) || !IMG_IsMainExecutable(img))
return;
unsigned i;
unsigned int mem_op = INS_MemoryOperandCount(ins);
for (i = 0; i < mem_op; i++) {
INS_InsertPredicatedCall(
ins, IPOINT_BEFORE,
(AFUNPTR)check_addr,
IARG_INST_PTR,
IARG_MEMORYOP_EA, i, IARG_END);
}
}
VOID Image(IMG img, VOID *v){
char szFilePath[260];
unsigned long index;
GetLock(&lock, 1);
if (process_start != 0){
ReleaseLock(&lock);
return;
}
if (IMG_Valid(img)){
memset(szFilePath, 0, sizeof(szFilePath));
strncpy(szFilePath, IMG_Name(img).c_str(), sizeof(szFilePath)-1);
index = 0;
while (szFilePath[index] != 0){
szFilePath[index] = tolower(szFilePath[index]);
index++;
}
if (strstr(szFilePath, KnobProcessToTrace.Value().c_str())){
process_start = IMG_LowAddress(img);
process_end = IMG_HighAddress(img);
}
}
ReleaseLock(&lock);
}
/* Image instrumentation */
static void IMG_Instrumentation(IMG img, void *v) {
/* Lock / Unlock the Analysis from a Entry point */
if (tracer::pintool::options::startAnalysisFromEntry) {
tracer::pintool::options::startAnalysisFromEntry = false;
/* IMG_LoadOffset(img) + IMG_Entry(img) for PIE binaries (see #524) */
tracer::pintool::options::startAnalysisFromAddress.insert(IMG_LoadOffset(img) + IMG_Entry(img));
}
/* Lock / Unlock the Analysis from a symbol */
if (tracer::pintool::options::startAnalysisFromSymbol != nullptr){
RTN targetRTN = RTN_FindByName(img, tracer::pintool::options::startAnalysisFromSymbol);
if (RTN_Valid(targetRTN)) {
RTN_Open(targetRTN);
RTN_InsertCall(targetRTN,
IPOINT_BEFORE,
(AFUNPTR) toggleWrapper,
IARG_BOOL, true,
IARG_END);
RTN_InsertCall(targetRTN,
IPOINT_AFTER,
(AFUNPTR) toggleWrapper,
IARG_BOOL, false,
IARG_END);
RTN_Close(targetRTN);
}
}
/* Callback on routine entry */
std::map<const char *, PyObject *>::iterator it;
for (it = tracer::pintool::options::callbackRoutineEntry.begin(); it != tracer::pintool::options::callbackRoutineEntry.end(); it++) {
RTN targetRTN = RTN_FindByName(img, it->first);
if (RTN_Valid(targetRTN)){
RTN_Open(targetRTN);
RTN_InsertCall(targetRTN, IPOINT_BEFORE, (AFUNPTR)callbackRoutineEntry, IARG_CONTEXT, IARG_THREAD_ID, IARG_PTR, it->second, IARG_END);
RTN_Close(targetRTN);
}
}
/* Callback on routine exit */
for (it = tracer::pintool::options::callbackRoutineExit.begin(); it != tracer::pintool::options::callbackRoutineExit.end(); it++) {
RTN targetRTN = RTN_FindByName(img, it->first);
if (RTN_Valid(targetRTN)){
RTN_Open(targetRTN);
RTN_InsertCall(targetRTN, IPOINT_AFTER, (AFUNPTR)callbackRoutineExit, IARG_CONTEXT, IARG_THREAD_ID, IARG_PTR, it->second, IARG_END);
RTN_Close(targetRTN);
}
}
/*
* Callback when a new image is loaded.
* This callback must be called even outside the range analysis.
*/
if (IMG_Valid(img))
tracer::pintool::callbackImageLoad(img);
}
/*
* process_loaded_image: Called every time when new image is loaded.
*/
static VOID process_loaded_image(IMG image, VOID *value)
{
if ( !IMG_Valid(image) || foundFunc)
return;
DoReplacementFunc( image, "StdCallFunctionToBeReplacedByPin");
}
static void reportError(ADDRINT addr)
{
fprintf (stderr, "BAD Fetch from 0x%08x\n", addr);
for (IMG img= APP_ImgHead(); IMG_Valid(img); img = IMG_Next(img))
{
fprintf (stderr, "%-30s: 0x%08x:0x%08x\n", IMG_Name(img).c_str(),
IMG_LowAddress(img),IMG_HighAddress(img));
}
exit (-1);
}
static IMG FindNamedImg(const string& imgName)
{
// Visit every loaded image
for (IMG img= APP_ImgTail(); IMG_Valid(img); img = IMG_Prev(img))
{
if (IMG_Name(img) == imgName)
return img;
}
return IMG_Invalid();
}
bool Profiler::HandleIgnoreInstCount(IMG img) {
if (knob_->ValueBool("ignore_ic_pthread")) {
if (!IMG_Valid(img))
return false;
Image *image = sinfo_->FindImage(IMG_Name(img));
DEBUG_ASSERT(image);
if (image->IsPthread())
return true;
}
return false;
}
// Print the list of images currently loaded, with some information about each.
static VOID PrintImageList()
{
for (IMG img= APP_ImgHead(); IMG_Valid(img); img = IMG_Next(img))
{
ADDRESS_RANGE range = FindImageTextMargin(img);
fprintf (trace, " L %-40s %2d [0x%llx:0x%llx] offset 0x%llx %4d RTNs\n", IMG_Name(img).c_str(), (int)IMG_Id(img),
(unsigned long long)range._low, (unsigned long long)range._high, (unsigned long long)IMG_LoadOffset(img),
CountImageRtns (img));
}
}
static void InstrumentRtn(RTN rtn, VOID *)
{
ADDRINT a = RTN_Address(rtn);
IMG img = IMG_FindByAddress(a);
if (IMG_Valid(img) &&
IMG_IsMainExecutable(img)) {
RTN_Open(rtn);
RTN_InsertCall(rtn, IPOINT_BEFORE, AFUNPTR(FunctionHook), IARG_ADDRINT, a, IARG_END);
RTN_Close(rtn);
}
}
// Print the list of images currently loaded, with some information about each.
static VOID PrintImageList()
{
for (IMG img= APP_ImgHead(); IMG_Valid(img); img = IMG_Next(img))
{
int nSecs;
int nRtns;
CountImageSecsAndRtns (img, &nSecs, &nRtns);
fprintf (trace, " L %-40s %2d [0x%lx:0x%lx] offset 0x%lx %2d SECs %4d RTNs\n", IMG_Name(img).c_str(), IMG_Id(img),
(unsigned long)IMG_LowAddress(img), (unsigned long)IMG_HighAddress(img), (unsigned long)IMG_LoadOffset(img), nSecs, nRtns);
}
}
bool Profiler::HandleIgnoreMemAccess(IMG img) {
if (!IMG_Valid(img))
return true;
Image *image = sinfo_->FindImage(IMG_Name(img));
DEBUG_ASSERT(image);
if (image->IsPthread())
return true;
if (knob_->ValueBool("ignore_lib")) {
if (image->IsCommonLib())
return true;
}
return false;
}
static BOOL traceFromExecutable(TRACE trace)
{
RTN rtn = TRACE_Rtn(trace);
if (!RTN_Valid(rtn))
return FALSE;
SEC sec = RTN_Sec(rtn);
if (!SEC_Valid(sec))
return FALSE;
IMG img = SEC_Img(sec);
if (!IMG_Valid(img))
return FALSE;
return IMG_IsMainExecutable(img);
}
static VOID Instruction(INS ins, VOID *v)
{
IMG img = IMG_FindByAddress(INS_Address(ins));
if (IMG_Valid(img))
{
numTimesImgFoundInInstrumentation++;
}
else
{
numTimesImgNotFoundInInstrumentation++;
}
INS_InsertCall(ins, IPOINT_BEFORE, (AFUNPTR)AnalysisFindImg, IARG_INST_PTR, IARG_END);
}
static VOID AnalysisFindImg (ADDRINT ip)
{
PIN_LockClient();
IMG img = IMG_FindByAddress(ip);
PIN_UnlockClient();
if (IMG_Valid(img))
{
numTimesImgFoundInAnalysis++;
}
else
{
numTimesImgNotFoundInAnalysis++;
}
}
std::string getImageName(triton::__uint address) {
RTN rtn;
SEC sec;
IMG img;
PIN_LockClient();
rtn = RTN_FindByAddress(address);
PIN_UnlockClient();
if (RTN_Valid(rtn)) {
sec = RTN_Sec(rtn);
if (SEC_Valid(sec)) {
img = SEC_Img(sec);
if (IMG_Valid(img)) {
return IMG_Name(img);
}
}
}
return "";
}
triton::__uint getBaseAddress(triton::__uint address) {
RTN rtn;
SEC sec;
IMG img;
PIN_LockClient();
rtn = RTN_FindByAddress(address);
PIN_UnlockClient();
if (RTN_Valid(rtn)) {
sec = RTN_Sec(rtn);
if (SEC_Valid(sec)) {
img = SEC_Img(sec);
if (IMG_Valid(img)) {
return IMG_LowAddress(img);
}
}
}
return 0;
}
VOID instrumentTrace(TRACE trace, VOID *v)
{
IMG img = IMG_FindByAddress(TRACE_Address(trace));
if (!IMG_Valid(img) || !IMG_IsMainExecutable(img))
return;
const char* imageName = IMG_Name(img).c_str();
for (BBL bbl = TRACE_BblHead(trace); BBL_Valid(bbl); bbl = BBL_Next(bbl))
{
for (INS ins = BBL_InsHead(bbl); INS_Valid(ins); ins = INS_Next(ins))
{
processMemoryWriteInstruction(ins, imageName);
processMemoryReadInstruction(ins, imageName);
}
}
}
/**
* Given an address, this function determines the name of the loaded module the
* address belongs to. If the address does not belong to any module, the empty
* string is returned.
**/
std::string getModule(ADDRINT address)
{
// To find the module name of an address, iterate over all sections of all
// modules until a section is found that contains the address.
for(IMG img=APP_ImgHead(); IMG_Valid(img); img = IMG_Next(img))
{
for(SEC sec=IMG_SecHead(img); SEC_Valid(sec); sec = SEC_Next(sec))
{
if (address >= SEC_Address(sec) && address < SEC_Address(sec) + SEC_Size(sec))
{
return extractFilename(IMG_Name(img));
}
}
}
return "";
}
/**
* Determines whether a given address belongs to a known module or not.
**/
bool isUnknownAddress(ADDRINT address)
{
// An address belongs to a known module, if the address belongs to any
// section of any module in the target address space.
for(IMG img=APP_ImgHead(); IMG_Valid(img); img = IMG_Next(img))
{
for(SEC sec=IMG_SecHead(img); SEC_Valid(sec); sec = SEC_Next(sec))
{
if (address >= SEC_Address(sec) && address < SEC_Address(sec) + SEC_Size(sec))
{
return false;
}
}
}
return true;
}
static VOID tpss_on_module_loading(IMG img, VOID *data)
{
unsigned long origAttrs = 0;
if (IMG_Valid(img))
{
if (IMG_IsMainExecutable(img))
{
g_tpss_entry_point =
(void(*)())RTN_ReplaceProbed(
RTN_FindByAddress(IMG_Entry(img)),
(AFUNPTR)tpss_mainStartup);
}
else
{
tpss_instrument_module(img, data);
}
}
}
VOID Trace(TRACE trace, VOID *v)
{
const RTN rtn = TRACE_Rtn(trace);
if (! RTN_Valid(rtn))
return;
const SEC sec = RTN_Sec(rtn);
ASSERTX(SEC_Valid(sec));
const IMG img = SEC_Img(sec);
ASSERTX(IMG_Valid(img));
if ( KnobNoSharedLibs.Value() && IMG_Type(img) == IMG_TYPE_SHAREDLIB)
return;
for (BBL bbl = TRACE_BblHead(trace); BBL_Valid(bbl); bbl = BBL_Next(bbl))
{
// Record the registers into a dummy buffer so we can count them
#define MAX_STATS_PER_BLOCK (128*1024)
UINT16 buffer[MAX_STATS_PER_BLOCK];
INT32 count = RecordRegisters(bbl, buffer, MAX_STATS_PER_BLOCK);
ASSERTX(count < MAX_STATS_PER_BLOCK);
// Summarize the stats for the bbl in a 0 terminated list
// This is done at instrumentation time
UINT16 * stats = new UINT16[count];
memcpy(stats, buffer, count * sizeof(UINT16));
// Insert instrumentation to count the number of times the bbl is executed
BBLSTATS * bblstats = new BBLSTATS(stats);
INS_InsertCall(BBL_InsHead(bbl), IPOINT_BEFORE, AFUNPTR(docount),
IARG_PTR, bblstats->_counter,
IARG_THREAD_ID,
IARG_END);
// Remember the counter and stats so we can compute a summary at the end
statsList.push_back(bblstats);
}
}
VOID PIN_FAST_ANALYSIS_CALL LogBBL(ADDRINT addr)
{
PIN_LockClient();
IMG img = IMG_FindByAddress(addr);
PIN_UnlockClient();
if (IMG_Valid(img)){
std::set<ADDRINT> *s = bbls[IMG_Name(img)];
if (s == NULL){
s = new std::set<ADDRINT> ();
bbls[IMG_Name(img)] = s;
}
s->insert(addr - IMG_LowAddress(img));
}
}
int main(INT32 argc, CHAR **argv)
{
PIN_InitSymbols();
if (PIN_Init(argc,argv))
return 1;
IMG img = IMG_Open(KnobInputFile);
if (!IMG_Valid(img))
{
std::cout << "Could not open " << KnobInputFile.Value() << endl;
return 1;
}
RTN_FindNameByAddress(0x123);
PIN_LockClient();
PIN_UnlockClient();
IMG_Close(img);
return 0;
}
int main(INT32 argc, CHAR **argv)
{
PIN_InitSymbols();
if( PIN_Init(argc,argv) )
{
return Usage();
}
IMG img = IMG_Open(KnobInputFile);
if (!IMG_Valid(img))
{
std::cout << "Could not open " << KnobInputFile.Value() << endl;
exit(1);
}
std::cout << hex;
rtnInternalRangeList.clear();
for (SEC sec = IMG_SecHead(img); SEC_Valid(sec); sec = SEC_Next(sec))
{
std::cout << "Section: " << setw(8) << SEC_Address(sec) << " " << SEC_Name(sec) << endl;
for (RTN rtn = SEC_RtnHead(sec); RTN_Valid(rtn); rtn = RTN_Next(rtn))
{
std::cout << " Rtn: " << setw(8) << hex << RTN_Address(rtn) << " " << RTN_Name(rtn) << endl;
string path;
INT32 line;
PIN_GetSourceLocation(RTN_Address(rtn), NULL, &line, &path);
if (path != "")
{
std::cout << "File " << path << " Line " << line << endl;
}
RTN_Open(rtn);
if (!INS_Valid(RTN_InsHead(rtn)))
{
RTN_Close(rtn);
continue;
}
RTN_INTERNAL_RANGE rtnInternalRange;
rtnInternalRange.start = INS_Address(RTN_InsHead(rtn));
rtnInternalRange.end
= INS_Address(RTN_InsHead(rtn)) + INS_Size(RTN_InsHead(rtn));
INS lastIns = INS_Invalid();
for (INS ins = RTN_InsHead(rtn); INS_Valid(ins); ins = INS_Next(ins))
{
std::cout << " " << setw(8) << hex << INS_Address(ins) << " " << INS_Disassemble(ins) << endl;
if (INS_Valid(lastIns))
{
if ((INS_Address(lastIns) + INS_Size(lastIns)) == INS_Address(ins))
{
rtnInternalRange.end = INS_Address(ins)+INS_Size(ins);
}
else
{
rtnInternalRangeList.push_back(rtnInternalRange);
std::cout << " rtnInternalRangeList.push_back " << setw(8) << hex << rtnInternalRange.start << " " << setw(8) << hex << rtnInternalRange.end << endl;
// make sure this ins has not already appeared in this RTN
for (vector<RTN_INTERNAL_RANGE>::iterator ri = rtnInternalRangeList.begin(); ri != rtnInternalRangeList.end(); ri++)
{
if ((INS_Address(ins) >= ri->start) && (INS_Address(ins)<ri->end))
{
std::cout << "***Error - above instruction already appeared in this RTN\n";
std::cout << " in rtnInternalRangeList " << setw(8) << hex << ri->start << " " << setw(8) << hex << ri->end << endl;
exit (1);
}
}
rtnInternalRange.start = INS_Address(ins);
rtnInternalRange.end = INS_Address(ins) + INS_Size(ins);
}
}
lastIns = ins;
}
RTN_Close(rtn);
rtnInternalRangeList.clear();
}
}
IMG_Close(img);
}
// Replay the image log.
// We run this before the each instruction of the code as an analysis routine.
// So we eat up the image loads one instruction at a time!
// We can also call it before PIN_StartProgram, to check that queuing
// the replay calls up works.
//
static void ReplayImageEntry()
{
if (feof(imgLog))
return;
char tag = fgetc(imgLog);
switch (tag)
{
case 'L':
{
string imageName;
ADDRINT startAddr;
ADDRINT offset;
USIZE size;
BOOL mainExe;
vector<RTN_INFO> rtns;
ParseImageLoadLine(imageName, &startAddr, &size, &offset, &mainExe, &rtns);
if (KnobVerbose)
fprintf (stderr, "Replaying load for %s, address: %llx offset: %llx, size: %lx\n", imageName.c_str(), (unsigned long long)startAddr, (unsigned long long)offset, (long)size);
// Create a temporary IMG object
IMG img = IMG_CreateAt(imageName.c_str(), startAddr, size, offset, mainExe);
ASSERT(IMG_Valid(img), "IMG_CreateAt for " + imageName + " is invalid");
// Populate the IMG object with recorded RTNs
PIN_LockClient();
for (vector<RTN_INFO>::iterator it = rtns.begin(); it < rtns.end(); it++)
{
RTN rtn = RTN_CreateAt(it->startAddr, it->name);
ASSERT(RTN_Valid(rtn), "Failed to create RTN " + it->name + " at address " + hexstr(it->startAddr));
}
// And, finally, inform Pin that it is all there, which will invoke
// image load callbacks.
IMG_ReplayImageLoad(img);
PIN_UnlockClient();
break;
}
case 'U':
{
string imageName;
ParseImageUnloadLine(imageName);
IMG img = FindNamedImg(imageName);
if (KnobVerbose)
fprintf (stderr, "Replaying unload for %s\n", imageName.c_str());
// And, finally, inform Pin that it has gone, which will invoke
// image unload callbacks.
PIN_LockClient();
PIN_ReplayImageUnload(img);
PIN_UnlockClient();
break;
}
default:
fprintf (trace, "Unexpected line in log file starting with '%c'\n", tag);
exit(1);
}
}
// -------------------------------------------------------------
// STool_LibraryNameByID
// -------------------------------------------------------------
// Return pointer to the name of the library with the given ID,
// or <unknown_library>, if the ID is invalid.
// Note: the user should *not* deallocate the returned pointer
const char* STool_LibraryNameByID(UINT32 libID) {
IMG img = IMG_FindImgById(libID);
if( IMG_Valid(img) && strlen(IMG_Name(img).c_str()) > 0 )
return IMG_Name(img).c_str();
else return "<unknown_library>";
}
// Pin calls this function before a code sequence is executed for the first time
VOID TraceCalls(INS ins, VOID *v)
{
// If we don't have a proper config, we cannot instrument anything
if (config == NULL)
{
return;
}
ADDRINT addr = INS_Address(ins);
IMG img = IMG_FindByAddress(addr);
// We are interested only calls from the JITted code. That code is not part of any valid image
if (IMG_Valid(img) && img != config->img)
{
return;
}
// We don't know the origins of the calls (only the targets) so we need to instrument every call
if (INS_IsCall(ins))
{
bool ok = false;
if (INS_RegRContain(ins, REG_EAX) || INS_RegRContain(ins, REG_EDX))
{
ok = true;
}
else if (INS_IsDirectCall(ins))
{
ADDRINT target_addr = INS_DirectBranchOrCallTargetAddress(ins);
IMG target_img = IMG_FindByAddress(target_addr);
if (!IMG_Valid(img) || img == config->img)
{
ok = true;
}
}
if (ok)
{
// Select which call analysis function to use depending on whether we are in fast mode
AFUNPTR analysisFunc = (AFUNPTR)MethodCallAnalysis;
if (KnobFast.Value())
{
analysisFunc = (AFUNPTR)MethodCallAnalysisFast;
}
ADDRINT ret_addr = INS_NextAddress(ins);
INS_InsertIfCall(ins, IPOINT_BEFORE, (AFUNPTR)ShouldCallBeAnalyzed, IARG_FUNCARG_CALLSITE_REFERENCE, 0, IARG_ADDRINT, ret_addr, IARG_BRANCH_TARGET_ADDR, IARG_END);
INS_InsertThenCall(ins, IPOINT_BEFORE, analysisFunc, IARG_FUNCARG_CALLSITE_REFERENCE, 0, IARG_ADDRINT, ret_addr, IARG_BRANCH_TARGET_ADDR, IARG_END);
returnAddressToInstument[ret_addr] = true;
return;
}
}
if (returnAddressToInstument.find(addr) != returnAddressToInstument.end())
{
// Select which call analysis function to use depending on whether we are in fast mode
AFUNPTR analysisFuncIf = (AFUNPTR)ShouldReturnAddressBeAnalyzed;
AFUNPTR analysisFuncThen = (AFUNPTR)ReturnValueAnalysis;
if (KnobFast.Value())
{
analysisFuncIf = (AFUNPTR)ShouldReturnAddressBeAnalyzedFast;
analysisFuncThen = (AFUNPTR)ReturnValueAnalysisFast;
}
INS_InsertIfCall(ins, IPOINT_BEFORE, analysisFuncIf, IARG_ADDRINT, addr, IARG_END);
INS_InsertThenCall(ins, IPOINT_BEFORE, analysisFuncThen, IARG_ADDRINT, addr, IARG_REG_VALUE, REG_EAX, IARG_FUNCARG_CALLSITE_REFERENCE, 0, IARG_END);
return;
}
}
