// this will be an incremental search tool in the future. now it is just a memory region dump thing #include #include #include #include #include #include #include #include #include using namespace std; #ifndef LINUX_BUILD #define WINVER 0x0500 // this one prevents windows from infecting the global namespace with filth #define NOMINMAX #define WIN32_LEAN_AND_MEAN #include #endif #include #include #include #include //TODO: lots of optimization void searchLoop(DFHack::API & DF, vector & ranges, int size, int alignment) { int32_t test1; int32_t test2; vector found; vector newfound; found.reserve(100000); newfound.reserve(100000); //bool initial = 1; cout << "search ready - insert integers, 'p' for results" << endl; string select; while (1) { cout << ">>"; DF.Detach(); std::getline(cin, select); DF.Attach(); if(select == "p") { cout << "Found addresses:" << endl; for(int i = 0; i < found.size();i++) { cout << hex << "0x" << found[i] << endl; } } else if(sscanf(select.c_str(),"%d", &test1) == 1) { newfound.clear(); bool initial = found.empty(); if(initial) { // for each range for (int i = 0; i < ranges.size();i++) { // can't read? range is invalid to us if(!ranges[i].read) continue; //loop for(uint64_t offset = ranges[i].start;offset <= ranges[i].end - size; offset+=alignment) { DF.ReadRaw(offset, size, (uint8_t *) &test2); if(test1 == test2 ) found.push_back(offset); } } cout << "found " << found.size() << " addresses" << endl; } else { for(int j = 0; j < found.size();j++) { DF.ReadRaw(found[j], size, (uint8_t *) &test2); if(test1 == test2) { newfound.push_back(found[j]); } } cout << "matched " << newfound.size() << " addresses out of " << found.size() << endl; found = newfound; } } else break; } } int main (void) { string select; DFHack::API DF("Memory.xml"); if(!DF.Attach()) { cerr << "DF not found" << endl; return 1; } DFHack::Process * p = DF.getProcess(); vector ranges; vector selected_ranges; p->getMemRanges(ranges); cout << "Which range to search? (default is 1-4)" << endl; for(int i = 0; i< ranges.size();i++) { cout << dec << "(" << i << ") "; ranges[i].print(); } try_again_ranges: cout << ">>"; std::getline(cin, select); int start, end; if(select.empty()) { // empty input, assume default. observe the length of the memory range vector // these are hardcoded values, intended for my convenience only if(p->getDescriptor()->getOS() == DFHack::memory_info::OS_WINDOWS) { start = min(11, (int)ranges.size()); end = min(14, (int)ranges.size()); } else if(p->getDescriptor()->getOS() == DFHack::memory_info::OS_LINUX) { start = min(11, (int)ranges.size()); end = min(14, (int)ranges.size()); } else { start = 1; end = 1; } } // I like the C variants here. much less object clutter else if(sscanf(select.c_str(), "%d-%d", &start, &end) == 2) { start = min(start, (int)ranges.size()); end = min(end, (int)ranges.size()); } else { goto try_again_ranges; // yes, this is a goto. bite me. } end++; cout << "selected ranges:" <>"; std::getline(cin, select); int size; if(select.empty()) { size = 4; } else if( sscanf(select.c_str(), "%d", &size) == 1 ) { if(/*size != 8 &&*/ size != 4 && size != 2 && size != 1) { goto try_again_size; } } else { goto try_again_size; } // input / validation of variable alignment (default is to use the same alignment as size) try_again_align: cout << "Variable alignment (1,2,4 bytes, default is " << size << ")" << endl; cout << ">>"; std::getline(cin, select); int alignment = size; if(select.empty()) { alignment = size; } else if( sscanf(select.c_str(), "%d", &alignment) == 1 ) { if(/*alignment != 8 &&*/ alignment != 4 && alignment != 2 && alignment != 1) { goto try_again_align; } } else { goto try_again_align; } searchLoop(DF,selected_ranges, size, alignment); // initial value // cycle until you get only a few offsets (~10?) if(!DF.Detach()) { cerr << "Can't detach from DF" << endl; return 1; } #ifndef LINUX_BUILD cout << "Done. Press any key to continue" << endl; cin.ignore(); #endif return 0; }