/* * Copyright (C) 2015 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * Implementation file of the dexlist utility. * * This is a re-implementation of the original dexlist utility that was * based on Dalvik functions in libdex into a new dexlist that is now * based on Art functions in libart instead. The output is identical to * the original for correct DEX files. Error messages may differ, however. * * List all methods in all concrete classes in one or more DEX files. */ #include #include #include "dex_file-inl.h" #include "mem_map.h" #include "runtime.h" namespace art { static const char* gProgName = "dexlist"; /* Command-line options. */ static struct { char* argCopy; const char* classToFind; const char* methodToFind; const char* outputFileName; } gOptions; /* * Output file. Defaults to stdout. */ static FILE* gOutFile = stdout; /* * Data types that match the definitions in the VM specification. */ typedef uint8_t u1; typedef uint32_t u4; typedef uint64_t u8; /* * Returns a newly-allocated string for the "dot version" of the class * name for the given type descriptor. That is, The initial "L" and * final ";" (if any) have been removed and all occurrences of '/' * have been changed to '.'. */ static std::unique_ptr descriptorToDot(const char* str) { size_t len = strlen(str); if (str[0] == 'L') { len -= 2; // Two fewer chars to copy (trims L and ;). str++; // Start past 'L'. } std::unique_ptr newStr(new char[len + 1]); for (size_t i = 0; i < len; i++) { newStr[i] = (str[i] == '/') ? '.' : str[i]; } newStr[len] = '\0'; return newStr; } /* * Positions table callback; we just want to catch the number of the * first line in the method, which *should* correspond to the first * entry from the table. (Could also use "min" here.) */ static bool positionsCb(void* context, const DexFile::PositionInfo& entry) { int* pFirstLine = reinterpret_cast(context); if (*pFirstLine == -1) { *pFirstLine = entry.line_; } return 0; } /* * Dumps a method. */ static void dumpMethod(const DexFile* pDexFile, const char* fileName, u4 idx, u4 flags ATTRIBUTE_UNUSED, const DexFile::CodeItem* pCode, u4 codeOffset) { // Abstract and native methods don't get listed. if (pCode == nullptr || codeOffset == 0) { return; } // Method information. const DexFile::MethodId& pMethodId = pDexFile->GetMethodId(idx); const char* methodName = pDexFile->StringDataByIdx(pMethodId.name_idx_); const char* classDescriptor = pDexFile->StringByTypeIdx(pMethodId.class_idx_); std::unique_ptr className(descriptorToDot(classDescriptor)); const u4 insnsOff = codeOffset + 0x10; // Don't list methods that do not match a particular query. if (gOptions.methodToFind != nullptr && (strcmp(gOptions.classToFind, className.get()) != 0 || strcmp(gOptions.methodToFind, methodName) != 0)) { return; } // If the filename is empty, then set it to something printable. if (fileName == nullptr || fileName[0] == 0) { fileName = "(none)"; } // Find the first line. int firstLine = -1; pDexFile->DecodeDebugPositionInfo(pCode, positionsCb, &firstLine); // Method signature. const Signature signature = pDexFile->GetMethodSignature(pMethodId); char* typeDesc = strdup(signature.ToString().c_str()); // Dump actual method information. fprintf(gOutFile, "0x%08x %d %s %s %s %s %d\n", insnsOff, pCode->insns_size_in_code_units_ * 2, className.get(), methodName, typeDesc, fileName, firstLine); free(typeDesc); } /* * Runs through all direct and virtual methods in the class. */ void dumpClass(const DexFile* pDexFile, u4 idx) { const DexFile::ClassDef& pClassDef = pDexFile->GetClassDef(idx); const char* fileName; if (!pClassDef.source_file_idx_.IsValid()) { fileName = nullptr; } else { fileName = pDexFile->StringDataByIdx(pClassDef.source_file_idx_); } const u1* pEncodedData = pDexFile->GetClassData(pClassDef); if (pEncodedData != nullptr) { ClassDataItemIterator pClassData(*pDexFile, pEncodedData); // Skip the fields. for (; pClassData.HasNextStaticField(); pClassData.Next()) {} for (; pClassData.HasNextInstanceField(); pClassData.Next()) {} // Direct methods. for (; pClassData.HasNextDirectMethod(); pClassData.Next()) { dumpMethod(pDexFile, fileName, pClassData.GetMemberIndex(), pClassData.GetRawMemberAccessFlags(), pClassData.GetMethodCodeItem(), pClassData.GetMethodCodeItemOffset()); } // Virtual methods. for (; pClassData.HasNextVirtualMethod(); pClassData.Next()) { dumpMethod(pDexFile, fileName, pClassData.GetMemberIndex(), pClassData.GetRawMemberAccessFlags(), pClassData.GetMethodCodeItem(), pClassData.GetMethodCodeItemOffset()); } } } /* * Processes a single file (either direct .dex or indirect .zip/.jar/.apk). */ static int processFile(const char* fileName) { // If the file is not a .dex file, the function tries .zip/.jar/.apk files, // all of which are Zip archives with "classes.dex" inside. static constexpr bool kVerifyChecksum = true; std::string error_msg; std::vector> dex_files; if (!DexFile::Open(fileName, fileName, kVerifyChecksum, &error_msg, &dex_files)) { fputs(error_msg.c_str(), stderr); fputc('\n', stderr); return -1; } // Success. Iterate over all dex files found in given file. fprintf(gOutFile, "#%s\n", fileName); for (size_t i = 0; i < dex_files.size(); i++) { // Iterate over all classes in one dex file. const DexFile* pDexFile = dex_files[i].get(); const u4 classDefsSize = pDexFile->GetHeader().class_defs_size_; for (u4 idx = 0; idx < classDefsSize; idx++) { dumpClass(pDexFile, idx); } } return 0; } /* * Shows usage. */ static void usage(void) { fprintf(stderr, "Copyright (C) 2007 The Android Open Source Project\n\n"); fprintf(stderr, "%s: [-m p.c.m] [-o outfile] dexfile...\n", gProgName); fprintf(stderr, "\n"); } /* * Main driver of the dexlist utility. */ int dexlistDriver(int argc, char** argv) { // Art specific set up. InitLogging(argv, Runtime::Aborter); MemMap::Init(); // Reset options. bool wantUsage = false; memset(&gOptions, 0, sizeof(gOptions)); // Parse all arguments. while (1) { const int ic = getopt(argc, argv, "o:m:"); if (ic < 0) { break; // done } switch (ic) { case 'o': // output file gOptions.outputFileName = optarg; break; case 'm': // If -m p.c.m is given, then find all instances of the // fully-qualified method name. This isn't really what // dexlist is for, but it's easy to do it here. { gOptions.argCopy = strdup(optarg); char* meth = strrchr(gOptions.argCopy, '.'); if (meth == nullptr) { fprintf(stderr, "Expected: package.Class.method\n"); wantUsage = true; } else { *meth = '\0'; gOptions.classToFind = gOptions.argCopy; gOptions.methodToFind = meth + 1; } } break; default: wantUsage = true; break; } // switch } // while // Detect early problems. if (optind == argc) { fprintf(stderr, "%s: no file specified\n", gProgName); wantUsage = true; } if (wantUsage) { usage(); free(gOptions.argCopy); return 2; } // Open alternative output file. if (gOptions.outputFileName) { gOutFile = fopen(gOptions.outputFileName, "w"); if (!gOutFile) { fprintf(stderr, "Can't open %s\n", gOptions.outputFileName); free(gOptions.argCopy); return 1; } } // Process all files supplied on command line. If one of them fails we // continue on, only returning a failure at the end. int result = 0; while (optind < argc) { result |= processFile(argv[optind++]); } // while free(gOptions.argCopy); return result != 0; } } // namespace art int main(int argc, char** argv) { return art::dexlistDriver(argc, argv); }