#include #include #include #include #include #include #include using namespace std; // Command line parsing #include // DyninstAPI includes #include "BPatch.h" #include "BPatch_binaryEdit.h" #include "BPatch_flowGraph.h" #include "BPatch_function.h" #include "BPatch_point.h" using namespace Dyninst; //cmd line options char *originalBinary; char *instrumentedBinary; bool verbose = false; Dyninst::Address entryPoint; set instrumentLibraries; set runtimeLibraries; int bbSkip = 0; bool skipMainModule = false; const char *instLibrary = "libAflDyninst.so"; static const char *OPT_STR = "i:o:l:e:vs:dr:"; static const char *USAGE = " -i -o -l -e
-s \n \ -i: Input binary \n \ -o: Output binary\n \ -d: Don't instrument the binary, only supplied libraries\n \ -l: Linked library to instrument (repeat for more than one)\n \ -r: Runtime library to instrument (path to, repeat for more than one)\n \ -e: Entry point address to patch (required for stripped binaries)\n \ -s: Number of basic blocks to skip\n \ -v: Verbose output\n"; bool parseOptions(int argc, char **argv) { int c; while ((c = getopt (argc, argv, OPT_STR)) != -1) { switch ((char) c) { case 'e': entryPoint = strtoul(optarg, NULL, 16);; break; case 'i': originalBinary = optarg; instrumentLibraries.insert(optarg); break; case 'o': instrumentedBinary = optarg; break; case 'l': instrumentLibraries.insert(optarg); break; case 'r': runtimeLibraries.insert(optarg); break; case 's': bbSkip = atoi(optarg); break; case 'd': skipMainModule = true; break; case 'v': verbose = true; break; default: cerr << "Usage: " << argv[0] << USAGE; return false; } } if(originalBinary == NULL) { cerr << "Input binary is required!"<< endl; cerr << "Usage: " << argv[0] << USAGE; return false; } if(instrumentedBinary == NULL) { cerr << "Output binary is required!" << endl; cerr << "Usage: " << argv[0] << USAGE; return false; } if(skipMainModule && instrumentLibraries.empty()) { cerr << "If using option -d , option -l is required." << endl; cerr << "Usage: " << argv[0] << USAGE; return false; } return true; } BPatch_function *findFuncByName (BPatch_image * appImage, char *funcName) { BPatch_Vector < BPatch_function * >funcs; if (NULL == appImage->findFunction (funcName, funcs) || !funcs.size () || NULL == funcs[0]) { cerr << "Failed to find " << funcName << " function." << endl; return NULL; } return funcs[0]; } // insert callback to initialization function in the instrumentation library // either at _init or at manualy specified entry point. bool insertCallToInit(BPatch_binaryEdit * appBin, BPatch_function * instIncFunc,BPatch_module * module, BPatch_function *funcInit) { /* Find the instrumentation points */ vector points; vector < BPatch_point * >*funcEntry = funcInit->findPoint (BPatch_entry); if (NULL == funcEntry) { cerr << "Failed to find entry for function. " << endl; return false; } cout << "Inserting init callback." << endl; BPatch_Vector < BPatch_snippet * >instArgs; // init has no args BPatch_funcCallExpr instIncExpr (*instIncFunc, instArgs); /* Insert the snippet at function entry */ BPatchSnippetHandle *handle = appBin->insertSnippet (instIncExpr, *funcEntry, BPatch_callBefore, BPatch_lastSnippet); if (!handle) { cerr << "Failed to insert init callback." << endl; return false; } return true; } // inserts a callback for each basic block assigning it an instrumentation // time 16bit random ID just as afl bool insertBBCallback(BPatch_binaryEdit * appBin, BPatch_function * curFunc, char *funcName, BPatch_function * instBBIncFunc,int *bbIndex) { BPatch_flowGraph *appCFG = curFunc->getCFG (); unsigned short randID; if (!appCFG) { cerr << "Failed to find CFG for function " << funcName << endl; return false; } BPatch_Set < BPatch_basicBlock * >allBlocks; if (!appCFG->getAllBasicBlocks (allBlocks)) { cerr << "Failed to find basic blocks for function " << funcName << endl; return false; } else if (allBlocks.size () == 0) { cerr << "No basic blocks for function " << funcName << endl; return false; } BPatch_Set < BPatch_basicBlock * >::iterator iter; for (iter = allBlocks.begin (); iter != allBlocks.end (); iter++) { if(*bbIndex < bbSkip) { // skip over first bbSkip bbs (*bbIndex)++; continue; } unsigned long address = (*iter)->getStartAddress (); randID = rand() % USHRT_MAX; if(verbose) { cout << "Instrumenting Basic Block 0x" << hex << address << " of " << funcName << " with random id " << randID << endl; } BPatch_Vector < BPatch_snippet * >instArgs; BPatch_constExpr bbId (randID); instArgs.push_back (&bbId); BPatch_point *bbEntry = (*iter)->findEntryPoint (); if (NULL == bbEntry) { // warn the user, but continue cerr << "Failed to find entry for basic block at 0x" << hex << address << endl; (*bbIndex)++; continue; } BPatch_funcCallExpr instIncExpr (*instBBIncFunc, instArgs); BPatchSnippetHandle *handle = appBin->insertSnippet (instIncExpr, *bbEntry, BPatch_callBefore, BPatch_lastSnippet); if (!handle) { // warn the user, but continue to next bb cerr << "Failed to insert instrumention in basic block at 0x" << hex << address << endl; (*bbIndex)++; continue; } (*bbIndex)++; } return true; } int main (int argc, char **argv) { if(!parseOptions(argc,argv)) { return EXIT_FAILURE; } BPatch bpatch; BPatch_binaryEdit *appBin = bpatch.openBinary (originalBinary, instrumentLibraries.size() != 1); if (appBin == NULL) { cerr << "Failed to open binary" << endl; return EXIT_FAILURE; } BPatch_image *appImage = appBin->getImage (); //get and iterate over all modules, instrumenting only the default and manualy specified ones vector < BPatch_module * >*modules = appImage->getModules (); vector < BPatch_module * >::iterator moduleIter; vector < BPatch_function * >* funcsInModule; BPatch_module *defaultModule = NULL; string defaultModuleName; // look for _init if(defaultModuleName.empty()){ for (moduleIter = modules->begin(); moduleIter != modules->end(); ++moduleIter){ funcsInModule = (*moduleIter)->getProcedures(); vector < BPatch_function * >::iterator funcsIterator; for (funcsIterator = funcsInModule->begin(); funcsIterator != funcsInModule->end(); ++funcsIterator){ char funcName[1024]; (*funcsIterator)->getName(funcName,1024); if(string(funcName) == string("_init")){ char moduleName[1024]; (*moduleIter)->getName(moduleName,1024); defaultModuleName = string(moduleName); if(verbose) { cout << "Found _init in " << moduleName<< endl; } break; } } if(!defaultModuleName.empty()) break; } } // last resort, by name of the binary if(defaultModuleName.empty()) defaultModuleName = string(originalBinary).substr(string(originalBinary).find_last_of("\\/")+1); if (!appBin->loadLibrary (instLibrary)) { cerr << "Failed to open instrumentation library." << endl; cerr << "It needs to be located in the current working directory." << endl; return EXIT_FAILURE; } appImage = appBin->getImage (); /* Find code coverage functions in the instrumentation library */ BPatch_function *initAflForkServer = findFuncByName (appImage, (char *) "initAflForkServer"); BPatch_function *bbCallback = findFuncByName (appImage, (char *) "bbCallback"); if (!initAflForkServer || !bbCallback ) { cerr << "Instrumentation library lacks callbacks!" << endl; return EXIT_FAILURE; } int bbIndex = 0; for (moduleIter = modules->begin (); moduleIter != modules->end (); ++moduleIter) { char moduleName[1024]; (*moduleIter)->getName (moduleName, 1024); if ((*moduleIter)->isSharedLib ()) { if (instrumentLibraries.find (moduleName) == instrumentLibraries.end ()) { cout << "Skipping library: " << moduleName << endl; continue; } } if (string (moduleName).find (defaultModuleName) != string::npos) { defaultModule = (*moduleIter); if(skipMainModule) continue; } cout << "Instrumenting module: " << moduleName << endl; vector < BPatch_function * >*allFunctions = (*moduleIter)->getProcedures (); vector < BPatch_function * >::iterator funcIter; // iterate over all functions in the module for (funcIter = allFunctions->begin (); funcIter != allFunctions->end (); ++funcIter) { BPatch_function *curFunc = *funcIter; char funcName[1024]; curFunc->getName (funcName, 1024); if(string (funcName) == string("_start")) continue; // here's a bug on hlt insertBBCallback (appBin, curFunc, funcName, bbCallback, &bbIndex); } } //if entrypoint set ,find function , else find _init BPatch_function *funcToPatch = NULL; if(!entryPoint) { BPatch_Vector funcs; defaultModule->findFunction("_init", funcs); if(!funcs.size()) { cerr << "Couldn't locate _init, specify entry point manualy. "<< endl; return EXIT_FAILURE; } // there should really be only one funcToPatch = funcs[0]; } else { funcToPatch = defaultModule->findFunctionByEntry(entryPoint); } if(!funcToPatch) { cerr << "Couldn't locate function at given entry point. "<< endl; return EXIT_FAILURE; } if(!insertCallToInit (appBin, initAflForkServer,defaultModule,funcToPatch)){ cerr << "Could not insert init callback at given entry point." << endl; return EXIT_FAILURE; } cout << "Saving the instrumented binary to " << instrumentedBinary << "..." << endl; // Output the instrumented binary if (!appBin->writeFile (instrumentedBinary)) { cerr << "Failed to write output file: " << instrumentedBinary << endl; return EXIT_FAILURE; } if(!runtimeLibraries.empty()) { cout << "Instrumenting runtime libraries." << endl; set::iterator rtLibIter ; for(rtLibIter = runtimeLibraries.begin(); rtLibIter != runtimeLibraries.end(); rtLibIter++) { BPatch_binaryEdit *libBin = bpatch.openBinary ((*rtLibIter).c_str(), false); printf("I sad otvara %s\n",(*rtLibIter).c_str()); if (libBin == NULL) { cerr << "Failed to open binary "<< *rtLibIter << endl; return EXIT_FAILURE; } BPatch_image *libImg = libBin->getImage (); vector < BPatch_module * >*modules = libImg->getModules (); libBin->loadLibrary (instLibrary); moduleIter = modules->begin (); for ( ; moduleIter != modules->end (); ++moduleIter) { char moduleName[1024]; (*moduleIter)->getName (moduleName, 1024); cout << "Instrumenting module: " << moduleName << endl; vector < BPatch_function * >*allFunctions = (*moduleIter)->getProcedures (); vector < BPatch_function * >::iterator funcIter; // iterate over all functions in the module for (funcIter = allFunctions->begin (); funcIter != allFunctions->end (); ++funcIter) { BPatch_function *curFunc = *funcIter; char funcName[1024]; curFunc->getName (funcName, 1024); if(string (funcName) == string("_start")) continue; insertBBCallback (libBin, curFunc, funcName, bbCallback, &bbIndex); } } if (!libBin->writeFile ((*rtLibIter + ".ins").c_str())) { cerr << "Failed to write output file: " <<(*rtLibIter + ".ins").c_str() << endl; return EXIT_FAILURE; } else { cout << "Saved the instrumented library to " << (*rtLibIter + ".ins").c_str() << "." << endl; } } } cout << "All done! Happy fuzzing!" << endl; return EXIT_SUCCESS; }