/* * Copyright (C) 2008 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. */ /* * Prepare a DEX file for use by the VM. Depending upon the VM options * we will attempt to verify and/or optimize the code, possibly appending * register maps. * * TODO: the format of the optimized header is currently "whatever we * happen to write", since the VM that writes it is by definition the same * as the VM that reads it. Still, it should be better documented and * more rigorously structured. */ #include "Dalvik.h" #include "libdex/OptInvocation.h" #include "analysis/RegisterMap.h" #include "analysis/Optimize.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* fwd */ static bool rewriteDex(u1* addr, int len, bool doVerify, bool doOpt, DexClassLookup** ppClassLookup, DvmDex** ppDvmDex); static bool loadAllClasses(DvmDex* pDvmDex); static void verifyAndOptimizeClasses(DexFile* pDexFile, bool doVerify, bool doOpt); static void verifyAndOptimizeClass(DexFile* pDexFile, ClassObject* clazz, const DexClassDef* pClassDef, bool doVerify, bool doOpt); static void updateChecksum(u1* addr, int len, DexHeader* pHeader); static int writeDependencies(int fd, u4 modWhen, u4 crc); static bool writeOptData(int fd, const DexClassLookup* pClassLookup,\ const RegisterMapBuilder* pRegMapBuilder); static bool computeFileChecksum(int fd, off_t start, size_t length, u4* pSum); /* * Get just the directory portion of the given path. Equivalent to dirname(3). */ static std::string saneDirName(const std::string& path) { size_t n = path.rfind('/'); if (n == std::string::npos) { return "."; } return path.substr(0, n); } /* * Helper for dvmOpenCacheDexFile() in a known-error case: Check to * see if the directory part of the given path (all but the last * component) exists and is writable. Complain to the log if not. */ static bool directoryIsValid(const std::string& fileName) { std::string dirName(saneDirName(fileName)); struct stat sb; if (stat(dirName.c_str(), &sb) < 0) { ALOGE("Could not stat dex cache directory '%s': %s", dirName.c_str(), strerror(errno)); return false; } if (!S_ISDIR(sb.st_mode)) { ALOGE("Dex cache directory isn't a directory: %s", dirName.c_str()); return false; } if (access(dirName.c_str(), W_OK) < 0) { ALOGE("Dex cache directory isn't writable: %s", dirName.c_str()); return false; } if (access(dirName.c_str(), R_OK) < 0) { ALOGE("Dex cache directory isn't readable: %s", dirName.c_str()); return false; } return true; } /* * Return the fd of an open file in the DEX file cache area. If the cache * file doesn't exist or is out of date, this will remove the old entry, * create a new one (writing only the file header), and return with the * "new file" flag set. * * It's possible to execute from an unoptimized DEX file directly, * assuming the byte ordering and structure alignment is correct, but * disadvantageous because some significant optimizations are not possible. * It's not generally possible to do the same from an uncompressed Jar * file entry, because we have to guarantee 32-bit alignment in the * memory-mapped file. * * For a Jar/APK file (a zip archive with "classes.dex" inside), "modWhen" * and "crc32" come from the Zip directory entry. For a stand-alone DEX * file, it's the modification date of the file and the Adler32 from the * DEX header (which immediately follows the magic). If these don't * match what's stored in the opt header, we reject the file immediately. * * On success, the file descriptor will be positioned just past the "opt" * file header, and will be locked with flock. "*pCachedName" will point * to newly-allocated storage. */ int dvmOpenCachedDexFile(const char* fileName, const char* cacheFileName, u4 modWhen, u4 crc, bool isBootstrap, bool* pNewFile, bool createIfMissing) { int fd, cc; struct stat fdStat, fileStat; bool readOnly = false; *pNewFile = false; retry: /* * Try to open the cache file. If we've been asked to, * create it if it doesn't exist. */ fd = createIfMissing ? open(cacheFileName, O_CREAT|O_RDWR, 0644) : -1; if (fd < 0) { fd = open(cacheFileName, O_RDONLY, 0); if (fd < 0) { if (createIfMissing) { // TODO: write an equivalent of strerror_r that returns a std::string. const std::string errnoString(strerror(errno)); if (directoryIsValid(cacheFileName)) { ALOGE("Can't open dex cache file '%s': %s", cacheFileName, errnoString.c_str()); } } return fd; } readOnly = true; } else { fchmod(fd, 0644); } /* * Grab an exclusive lock on the cache file. If somebody else is * working on it, we'll block here until they complete. Because * we're waiting on an external resource, we go into VMWAIT mode. */ ALOGV("DexOpt: locking cache file %s (fd=%d, boot=%d)", cacheFileName, fd, isBootstrap); ThreadStatus oldStatus = dvmChangeStatus(NULL, THREAD_VMWAIT); cc = flock(fd, LOCK_EX | LOCK_NB); if (cc != 0) { ALOGD("DexOpt: sleeping on flock(%s)", cacheFileName); cc = flock(fd, LOCK_EX); } dvmChangeStatus(NULL, oldStatus); if (cc != 0) { ALOGE("Can't lock dex cache '%s': %d", cacheFileName, cc); close(fd); return -1; } ALOGV("DexOpt: locked cache file"); /* * Check to see if the fd we opened and locked matches the file in * the filesystem. If they don't, then somebody else unlinked ours * and created a new file, and we need to use that one instead. (If * we caught them between the unlink and the create, we'll get an * ENOENT from the file stat.) */ cc = fstat(fd, &fdStat); if (cc != 0) { ALOGE("Can't stat open file '%s'", cacheFileName); LOGVV("DexOpt: unlocking cache file %s", cacheFileName); goto close_fail; } cc = stat(cacheFileName, &fileStat); if (cc != 0 || fdStat.st_dev != fileStat.st_dev || fdStat.st_ino != fileStat.st_ino) { ALOGD("DexOpt: our open cache file is stale; sleeping and retrying"); LOGVV("DexOpt: unlocking cache file %s", cacheFileName); flock(fd, LOCK_UN); close(fd); usleep(250 * 1000); /* if something is hosed, don't peg machine */ goto retry; } /* * We have the correct file open and locked. If the file size is zero, * then it was just created by us, and we want to fill in some fields * in the "opt" header and set "*pNewFile". Otherwise, we want to * verify that the fields in the header match our expectations, and * reset the file if they don't. */ if (fdStat.st_size == 0) { if (readOnly) { ALOGW("DexOpt: file has zero length and isn't writable"); goto close_fail; } cc = dexOptCreateEmptyHeader(fd); if (cc != 0) goto close_fail; *pNewFile = true; ALOGV("DexOpt: successfully initialized new cache file"); } else { bool expectVerify, expectOpt; if (gDvm.classVerifyMode == VERIFY_MODE_NONE) { expectVerify = false; } else if (gDvm.classVerifyMode == VERIFY_MODE_REMOTE) { expectVerify = !isBootstrap; } else /*if (gDvm.classVerifyMode == VERIFY_MODE_ALL)*/ { expectVerify = true; } if (gDvm.dexOptMode == OPTIMIZE_MODE_NONE) { expectOpt = false; } else if (gDvm.dexOptMode == OPTIMIZE_MODE_VERIFIED || gDvm.dexOptMode == OPTIMIZE_MODE_FULL) { expectOpt = expectVerify; } else /*if (gDvm.dexOptMode == OPTIMIZE_MODE_ALL)*/ { expectOpt = true; } ALOGV("checking deps, expecting vfy=%d opt=%d", expectVerify, expectOpt); if (!dvmCheckOptHeaderAndDependencies(fd, true, modWhen, crc, expectVerify, expectOpt)) { if (readOnly) { /* * We could unlink and rewrite the file if we own it or * the "sticky" bit isn't set on the directory. However, * we're not able to truncate it, which spoils things. So, * give up now. */ if (createIfMissing) { ALOGW("Cached DEX '%s' (%s) is stale and not writable", fileName, cacheFileName); } goto close_fail; } /* * If we truncate the existing file before unlinking it, any * process that has it mapped will fail when it tries to touch * the pages. * * This is very important. The zygote process will have the * boot DEX files (core, framework, etc.) mapped early. If * (say) core.dex gets updated, and somebody launches an app * that uses App.dex, then App.dex gets reoptimized because it's * dependent upon the boot classes. However, dexopt will be * using the *new* core.dex to do the optimizations, while the * app will actually be running against the *old* core.dex * because it starts from zygote. * * Even without zygote, it's still possible for a class loader * to pull in an APK that was optimized against an older set * of DEX files. We must ensure that everything fails when a * boot DEX gets updated, and for general "why aren't my * changes doing anything" purposes its best if we just make * everything crash when a DEX they're using gets updated. */ ALOGD("ODEX file is stale or bad; removing and retrying (%s)", cacheFileName); if (ftruncate(fd, 0) != 0) { ALOGW("Warning: unable to truncate cache file '%s': %s", cacheFileName, strerror(errno)); /* keep going */ } if (unlink(cacheFileName) != 0) { ALOGW("Warning: unable to remove cache file '%s': %d %s", cacheFileName, errno, strerror(errno)); /* keep going; permission failure should probably be fatal */ } LOGVV("DexOpt: unlocking cache file %s", cacheFileName); flock(fd, LOCK_UN); close(fd); goto retry; } else { ALOGV("DexOpt: good deps in cache file"); } } assert(fd >= 0); return fd; close_fail: flock(fd, LOCK_UN); close(fd); return -1; } /* * Unlock the file descriptor. * * Returns "true" on success. */ bool dvmUnlockCachedDexFile(int fd) { LOGVV("DexOpt: unlocking cache file fd=%d", fd); return (flock(fd, LOCK_UN) == 0); } /* * Given a descriptor for a file with DEX data in it, produce an * optimized version. * * The file pointed to by "fd" is expected to be a locked shared resource * (or private); we make no efforts to enforce multi-process correctness * here. * * "fileName" is only used for debug output. "modWhen" and "crc" are stored * in the dependency set. * * The "isBootstrap" flag determines how the optimizer and verifier handle * package-scope access checks. When optimizing, we only load the bootstrap * class DEX files and the target DEX, so the flag determines whether the * target DEX classes are given a (synthetic) non-NULL classLoader pointer. * This only really matters if the target DEX contains classes that claim to * be in the same package as bootstrap classes. * * The optimizer will need to load every class in the target DEX file. * This is generally undesirable, so we start a subprocess to do the * work and wait for it to complete. * * Returns "true" on success. All data will have been written to "fd". */ bool dvmOptimizeDexFile(int fd, off_t dexOffset, long dexLength, const char* fileName, u4 modWhen, u4 crc, bool isBootstrap) { const char* lastPart = strrchr(fileName, '/'); if (lastPart != NULL) lastPart++; else lastPart = fileName; ALOGD("DexOpt: --- BEGIN '%s' (bootstrap=%d) ---", lastPart, isBootstrap); pid_t pid; /* * This could happen if something in our bootclasspath, which we thought * was all optimized, got rejected. */ if (gDvm.optimizing) { ALOGW("Rejecting recursive optimization attempt on '%s'", fileName); return false; } pid = fork(); if (pid == 0) { static const int kUseValgrind = 0; static const char* kDexOptBin = "/bin/dexopt"; static const char* kValgrinder = "/usr/bin/valgrind"; static const int kFixedArgCount = 10; static const int kValgrindArgCount = 5; static const int kMaxIntLen = 12; // '-'+10dig+'\0' -OR- 0x+8dig int bcpSize = dvmGetBootPathSize(); int argc = kFixedArgCount + bcpSize + (kValgrindArgCount * kUseValgrind); const char* argv[argc+1]; // last entry is NULL char values[argc][kMaxIntLen]; char* execFile; const char* androidRoot; int flags; /* change process groups, so we don't clash with ProcessManager */ setpgid(0, 0); /* full path to optimizer */ androidRoot = getenv("ANDROID_ROOT"); if (androidRoot == NULL) { ALOGW("ANDROID_ROOT not set, defaulting to /system"); androidRoot = "/system"; } execFile = (char*)alloca(strlen(androidRoot) + strlen(kDexOptBin) + 1); strcpy(execFile, androidRoot); strcat(execFile, kDexOptBin); /* * Create arg vector. */ int curArg = 0; if (kUseValgrind) { /* probably shouldn't ship the hard-coded path */ argv[curArg++] = (char*)kValgrinder; argv[curArg++] = "--tool=memcheck"; argv[curArg++] = "--leak-check=yes"; // check for leaks too argv[curArg++] = "--leak-resolution=med"; // increase from 2 to 4 argv[curArg++] = "--num-callers=16"; // default is 12 assert(curArg == kValgrindArgCount); } argv[curArg++] = execFile; argv[curArg++] = "--dex"; sprintf(values[2], "%d", DALVIK_VM_BUILD); argv[curArg++] = values[2]; sprintf(values[3], "%d", fd); argv[curArg++] = values[3]; sprintf(values[4], "%d", (int) dexOffset); argv[curArg++] = values[4]; sprintf(values[5], "%d", (int) dexLength); argv[curArg++] = values[5]; argv[curArg++] = (char*)fileName; sprintf(values[7], "%d", (int) modWhen); argv[curArg++] = values[7]; sprintf(values[8], "%d", (int) crc); argv[curArg++] = values[8]; flags = 0; if (gDvm.dexOptMode != OPTIMIZE_MODE_NONE) { flags |= DEXOPT_OPT_ENABLED; if (gDvm.dexOptMode == OPTIMIZE_MODE_ALL) flags |= DEXOPT_OPT_ALL; } if (gDvm.classVerifyMode != VERIFY_MODE_NONE) { flags |= DEXOPT_VERIFY_ENABLED; if (gDvm.classVerifyMode == VERIFY_MODE_ALL) flags |= DEXOPT_VERIFY_ALL; } if (isBootstrap) flags |= DEXOPT_IS_BOOTSTRAP; if (gDvm.generateRegisterMaps) flags |= DEXOPT_GEN_REGISTER_MAPS; sprintf(values[9], "%d", flags); argv[curArg++] = values[9]; assert(((!kUseValgrind && curArg == kFixedArgCount) || ((kUseValgrind && curArg == kFixedArgCount+kValgrindArgCount)))); ClassPathEntry* cpe; for (cpe = gDvm.bootClassPath; cpe->ptr != NULL; cpe++) { argv[curArg++] = cpe->fileName; } assert(curArg == argc); argv[curArg] = NULL; if (kUseValgrind) execv(kValgrinder, const_cast(argv)); else execv(execFile, const_cast(argv)); ALOGE("execv '%s'%s failed: %s", execFile, kUseValgrind ? " [valgrind]" : "", strerror(errno)); exit(1); } else { ALOGV("DexOpt: waiting for verify+opt, pid=%d", (int) pid); int status; pid_t gotPid; /* * Wait for the optimization process to finish. We go into VMWAIT * mode here so GC suspension won't have to wait for us. */ ThreadStatus oldStatus = dvmChangeStatus(NULL, THREAD_VMWAIT); while (true) { gotPid = waitpid(pid, &status, 0); if (gotPid == -1 && errno == EINTR) { ALOGD("waitpid interrupted, retrying"); } else { break; } } dvmChangeStatus(NULL, oldStatus); if (gotPid != pid) { ALOGE("waitpid failed: wanted %d, got %d: %s", (int) pid, (int) gotPid, strerror(errno)); return false; } if (WIFEXITED(status) && WEXITSTATUS(status) == 0) { ALOGD("DexOpt: --- END '%s' (success) ---", lastPart); return true; } else { ALOGW("DexOpt: --- END '%s' --- status=0x%04x, process failed", lastPart, status); return false; } } } /* * Do the actual optimization. This is executed in the dexopt process. * * For best use of disk/memory, we want to extract once and perform * optimizations in place. If the file has to expand or contract * to match local structure padding/alignment expectations, we want * to do the rewrite as part of the extract, rather than extracting * into a temp file and slurping it back out. (The structure alignment * is currently correct for all platforms, and this isn't expected to * change, so we should be okay with having it already extracted.) * * Returns "true" on success. */ bool dvmContinueOptimization(int fd, off_t dexOffset, long dexLength, const char* fileName, u4 modWhen, u4 crc, bool isBootstrap) { DexClassLookup* pClassLookup = NULL; RegisterMapBuilder* pRegMapBuilder = NULL; assert(gDvm.optimizing); ALOGV("Continuing optimization (%s, isb=%d)", fileName, isBootstrap); assert(dexOffset >= 0); /* quick test so we don't blow up on empty file */ if (dexLength < (int) sizeof(DexHeader)) { ALOGE("too small to be DEX"); return false; } if (dexOffset < (int) sizeof(DexOptHeader)) { ALOGE("not enough room for opt header"); return false; } bool result = false; /* * Drop this into a global so we don't have to pass it around. We could * also add a field to DexFile, but since it only pertains to DEX * creation that probably doesn't make sense. */ gDvm.optimizingBootstrapClass = isBootstrap; { /* * Map the entire file (so we don't have to worry about page * alignment). The expectation is that the output file contains * our DEX data plus room for a small header. */ bool success; void* mapAddr; mapAddr = mmap(NULL, dexOffset + dexLength, PROT_READ|PROT_WRITE, MAP_SHARED, fd, 0); if (mapAddr == MAP_FAILED) { ALOGE("unable to mmap DEX cache: %s", strerror(errno)); goto bail; } bool doVerify, doOpt; if (gDvm.classVerifyMode == VERIFY_MODE_NONE) { doVerify = false; } else if (gDvm.classVerifyMode == VERIFY_MODE_REMOTE) { doVerify = !gDvm.optimizingBootstrapClass; } else /*if (gDvm.classVerifyMode == VERIFY_MODE_ALL)*/ { doVerify = true; } if (gDvm.dexOptMode == OPTIMIZE_MODE_NONE) { doOpt = false; } else if (gDvm.dexOptMode == OPTIMIZE_MODE_VERIFIED || gDvm.dexOptMode == OPTIMIZE_MODE_FULL) { doOpt = doVerify; } else /*if (gDvm.dexOptMode == OPTIMIZE_MODE_ALL)*/ { doOpt = true; } /* * Rewrite the file. Byte reordering, structure realigning, * class verification, and bytecode optimization are all performed * here. * * In theory the file could change size and bits could shift around. * In practice this would be annoying to deal with, so the file * layout is designed so that it can always be rewritten in place. * * This creates the class lookup table as part of doing the processing. */ success = rewriteDex(((u1*) mapAddr) + dexOffset, dexLength, doVerify, doOpt, &pClassLookup, NULL); if (success) { DvmDex* pDvmDex = NULL; u1* dexAddr = ((u1*) mapAddr) + dexOffset; if (dvmDexFileOpenPartial(dexAddr, dexLength, &pDvmDex) != 0) { ALOGE("Unable to create DexFile"); success = false; } else { /* * If configured to do so, generate register map output * for all verified classes. The register maps were * generated during verification, and will now be serialized. */ if (gDvm.generateRegisterMaps) { pRegMapBuilder = dvmGenerateRegisterMaps(pDvmDex); if (pRegMapBuilder == NULL) { ALOGE("Failed generating register maps"); success = false; } } DexHeader* pHeader = (DexHeader*)pDvmDex->pHeader; updateChecksum(dexAddr, dexLength, pHeader); dvmDexFileFree(pDvmDex); } } /* unmap the read-write version, forcing writes to disk */ if (msync(mapAddr, dexOffset + dexLength, MS_SYNC) != 0) { ALOGW("msync failed: %s", strerror(errno)); // weird, but keep going } #if 1 /* * This causes clean shutdown to fail, because we have loaded classes * that point into it. For the optimizer this isn't a problem, * because it's more efficient for the process to simply exit. * Exclude this code when doing clean shutdown for valgrind. */ if (munmap(mapAddr, dexOffset + dexLength) != 0) { ALOGE("munmap failed: %s", strerror(errno)); goto bail; } #endif if (!success) goto bail; } /* get start offset, and adjust deps start for 64-bit alignment */ off_t depsOffset, optOffset, endOffset, adjOffset; int depsLength, optLength; u4 optChecksum; depsOffset = lseek(fd, 0, SEEK_END); if (depsOffset < 0) { ALOGE("lseek to EOF failed: %s", strerror(errno)); goto bail; } adjOffset = (depsOffset + 7) & ~(0x07); if (adjOffset != depsOffset) { ALOGV("Adjusting deps start from %d to %d", (int) depsOffset, (int) adjOffset); depsOffset = adjOffset; lseek(fd, depsOffset, SEEK_SET); } /* * Append the dependency list. */ if (writeDependencies(fd, modWhen, crc) != 0) { ALOGW("Failed writing dependencies"); goto bail; } /* compute deps length, then adjust opt start for 64-bit alignment */ optOffset = lseek(fd, 0, SEEK_END); depsLength = optOffset - depsOffset; adjOffset = (optOffset + 7) & ~(0x07); if (adjOffset != optOffset) { ALOGV("Adjusting opt start from %d to %d", (int) optOffset, (int) adjOffset); optOffset = adjOffset; lseek(fd, optOffset, SEEK_SET); } /* * Append any optimized pre-computed data structures. */ if (!writeOptData(fd, pClassLookup, pRegMapBuilder)) { ALOGW("Failed writing opt data"); goto bail; } endOffset = lseek(fd, 0, SEEK_END); optLength = endOffset - optOffset; /* compute checksum from start of deps to end of opt area */ if (!computeFileChecksum(fd, depsOffset, (optOffset+optLength) - depsOffset, &optChecksum)) { goto bail; } /* * Output the "opt" header with all values filled in and a correct * magic number. */ DexOptHeader optHdr; memset(&optHdr, 0xff, sizeof(optHdr)); memcpy(optHdr.magic, DEX_OPT_MAGIC, 4); memcpy(optHdr.magic+4, DEX_OPT_MAGIC_VERS, 4); optHdr.dexOffset = (u4) dexOffset; optHdr.dexLength = (u4) dexLength; optHdr.depsOffset = (u4) depsOffset; optHdr.depsLength = (u4) depsLength; optHdr.optOffset = (u4) optOffset; optHdr.optLength = (u4) optLength; #if __BYTE_ORDER != __LITTLE_ENDIAN optHdr.flags = DEX_OPT_FLAG_BIG; #else optHdr.flags = 0; #endif optHdr.checksum = optChecksum; fsync(fd); /* ensure previous writes go before header is written */ lseek(fd, 0, SEEK_SET); if (sysWriteFully(fd, &optHdr, sizeof(optHdr), "DexOpt opt header") != 0) goto bail; ALOGV("Successfully wrote DEX header"); result = true; //dvmRegisterMapDumpStats(); bail: dvmFreeRegisterMapBuilder(pRegMapBuilder); free(pClassLookup); return result; } /* * Prepare an in-memory DEX file. * * The data was presented to the VM as a byte array rather than a file. * We want to do the same basic set of operations, but we can just leave * them in memory instead of writing them out to a cached optimized DEX file. */ bool dvmPrepareDexInMemory(u1* addr, size_t len, DvmDex** ppDvmDex) { DexClassLookup* pClassLookup = NULL; /* * Byte-swap, realign, verify basic DEX file structure. * * We could load + verify + optimize here as well, but that's probably * not desirable. * * (The bulk-verification code is currently only setting the DEX * file's "verified" flag, not updating the ClassObject. This would * also need to be changed, or we will try to verify the class twice, * and possibly reject it when optimized opcodes are encountered.) */ if (!rewriteDex(addr, len, false, false, &pClassLookup, ppDvmDex)) { return false; } (*ppDvmDex)->pDexFile->pClassLookup = pClassLookup; return true; } /* * Perform in-place rewrites on a memory-mapped DEX file. * * If this is called from a short-lived child process (dexopt), we can * go nutty with loading classes and allocating memory. When it's * called to prepare classes provided in a byte array, we may want to * be more conservative. * * If "ppClassLookup" is non-NULL, a pointer to a newly-allocated * DexClassLookup will be returned on success. * * If "ppDvmDex" is non-NULL, a newly-allocated DvmDex struct will be * returned on success. */ static bool rewriteDex(u1* addr, int len, bool doVerify, bool doOpt, DexClassLookup** ppClassLookup, DvmDex** ppDvmDex) { DexClassLookup* pClassLookup = NULL; u8 prepWhen, loadWhen, verifyOptWhen; DvmDex* pDvmDex = NULL; bool result = false; const char* msgStr = "???"; /* if the DEX is in the wrong byte order, swap it now */ if (dexSwapAndVerify(addr, len) != 0) goto bail; /* * Now that the DEX file can be read directly, create a DexFile struct * for it. */ if (dvmDexFileOpenPartial(addr, len, &pDvmDex) != 0) { ALOGE("Unable to create DexFile"); goto bail; } /* * Create the class lookup table. This will eventually be appended * to the end of the .odex. * * We create a temporary link from the DexFile for the benefit of * class loading, below. */ pClassLookup = dexCreateClassLookup(pDvmDex->pDexFile); if (pClassLookup == NULL) goto bail; pDvmDex->pDexFile->pClassLookup = pClassLookup; /* * If we're not going to attempt to verify or optimize the classes, * there's no value in loading them, so bail out early. */ if (!doVerify && !doOpt) { result = true; goto bail; } prepWhen = dvmGetRelativeTimeUsec(); /* * Load all classes found in this DEX file. If they fail to load for * some reason, they won't get verified (which is as it should be). */ if (!loadAllClasses(pDvmDex)) goto bail; loadWhen = dvmGetRelativeTimeUsec(); /* * Create a data structure for use by the bytecode optimizer. * We need to look up methods in a few classes, so this may cause * a bit of class loading. We usually do this during VM init, but * for dexopt on core.jar the order of operations gets a bit tricky, * so we defer it to here. */ if (!dvmCreateInlineSubsTable()) goto bail; /* * Verify and optimize all classes in the DEX file (command-line * options permitting). * * This is best-effort, so there's really no way for dexopt to * fail at this point. */ verifyAndOptimizeClasses(pDvmDex->pDexFile, doVerify, doOpt); verifyOptWhen = dvmGetRelativeTimeUsec(); if (doVerify && doOpt) msgStr = "verify+opt"; else if (doVerify) msgStr = "verify"; else if (doOpt) msgStr = "opt"; ALOGD("DexOpt: load %dms, %s %dms, %d bytes", (int) (loadWhen - prepWhen) / 1000, msgStr, (int) (verifyOptWhen - loadWhen) / 1000, gDvm.pBootLoaderAlloc->curOffset); result = true; bail: /* * On success, return the pieces that the caller asked for. */ if (pDvmDex != NULL) { /* break link between the two */ pDvmDex->pDexFile->pClassLookup = NULL; } if (ppDvmDex == NULL || !result) { dvmDexFileFree(pDvmDex); } else { *ppDvmDex = pDvmDex; } if (ppClassLookup == NULL || !result) { free(pClassLookup); } else { *ppClassLookup = pClassLookup; } return result; } /* * Try to load all classes in the specified DEX. If they have some sort * of broken dependency, e.g. their superclass lives in a different DEX * that wasn't previously loaded into the bootstrap class path, loading * will fail. This is the desired behavior. * * We have no notion of class loader at this point, so we load all of * the classes with the bootstrap class loader. It turns out this has * exactly the behavior we want, and has no ill side effects because we're * running in a separate process and anything we load here will be forgotten. * * We set the CLASS_MULTIPLE_DEFS flag here if we see multiple definitions. * This works because we only call here as part of optimization / pre-verify, * not during verification as part of loading a class into a running VM. * * This returns "false" if the world is too screwed up to do anything * useful at all. */ static bool loadAllClasses(DvmDex* pDvmDex) { u4 count = pDvmDex->pDexFile->pHeader->classDefsSize; u4 idx; int loaded = 0; ALOGV("DexOpt: +++ trying to load %d classes", count); dvmSetBootPathExtraDex(pDvmDex); /* * At this point, it is safe -- and necessary! -- to look up the * VM's required classes and members, even when what we are in the * process of processing is the core library that defines these * classes itself. (The reason it is necessary is that in the act * of initializing the class Class, below, the system will end up * referring to many of the class references that got set up by * this call.) */ if (!dvmFindRequiredClassesAndMembers()) { return false; } /* * We have some circularity issues with Class and Object that are * most easily avoided by ensuring that Object is never the first * thing we try to find-and-initialize. The call to * dvmFindSystemClass() here takes care of that situation. (We * only need to do this when loading classes from the DEX file * that contains Object, and only when Object comes first in the * list, but it costs very little to do it in all cases.) */ if (!dvmInitClass(gDvm.classJavaLangClass)) { ALOGE("ERROR: failed to initialize the class Class!"); return false; } for (idx = 0; idx < count; idx++) { const DexClassDef* pClassDef; const char* classDescriptor; ClassObject* newClass; pClassDef = dexGetClassDef(pDvmDex->pDexFile, idx); classDescriptor = dexStringByTypeIdx(pDvmDex->pDexFile, pClassDef->classIdx); ALOGV("+++ loading '%s'", classDescriptor); //newClass = dvmDefineClass(pDexFile, classDescriptor, // NULL); newClass = dvmFindSystemClassNoInit(classDescriptor); if (newClass == NULL) { ALOGV("DexOpt: failed loading '%s'", classDescriptor); dvmClearOptException(dvmThreadSelf()); } else if (newClass->pDvmDex != pDvmDex) { /* * We don't load the new one, and we tag the first one found * with the "multiple def" flag so the resolver doesn't try * to make it available. */ ALOGD("DexOpt: '%s' has an earlier definition; blocking out", classDescriptor); SET_CLASS_FLAG(newClass, CLASS_MULTIPLE_DEFS); } else { loaded++; } } ALOGV("DexOpt: +++ successfully loaded %d classes", loaded); dvmSetBootPathExtraDex(NULL); return true; } /* * Verify and/or optimize all classes that were successfully loaded from * this DEX file. */ static void verifyAndOptimizeClasses(DexFile* pDexFile, bool doVerify, bool doOpt) { u4 count = pDexFile->pHeader->classDefsSize; u4 idx; for (idx = 0; idx < count; idx++) { const DexClassDef* pClassDef; const char* classDescriptor; ClassObject* clazz; pClassDef = dexGetClassDef(pDexFile, idx); classDescriptor = dexStringByTypeIdx(pDexFile, pClassDef->classIdx); /* all classes are loaded into the bootstrap class loader */ clazz = dvmLookupClass(classDescriptor, NULL, false); if (clazz != NULL) { verifyAndOptimizeClass(pDexFile, clazz, pClassDef, doVerify, doOpt); } else { // TODO: log when in verbose mode ALOGV("DexOpt: not optimizing unavailable class '%s'", classDescriptor); } } #ifdef VERIFIER_STATS ALOGI("Verifier stats:"); ALOGI(" methods examined : %u", gDvm.verifierStats.methodsExamined); ALOGI(" monitor-enter methods : %u", gDvm.verifierStats.monEnterMethods); ALOGI(" instructions examined : %u", gDvm.verifierStats.instrsExamined); ALOGI(" instructions re-examined: %u", gDvm.verifierStats.instrsReexamined); ALOGI(" copying of register sets: %u", gDvm.verifierStats.copyRegCount); ALOGI(" merging of register sets: %u", gDvm.verifierStats.mergeRegCount); ALOGI(" ...that caused changes : %u", gDvm.verifierStats.mergeRegChanged); ALOGI(" uninit searches : %u", gDvm.verifierStats.uninitSearches); ALOGI(" max memory required : %u", gDvm.verifierStats.biggestAlloc); #endif } /* * Verify and/or optimize a specific class. */ static void verifyAndOptimizeClass(DexFile* pDexFile, ClassObject* clazz, const DexClassDef* pClassDef, bool doVerify, bool doOpt) { const char* classDescriptor; bool verified = false; if (clazz->pDvmDex->pDexFile != pDexFile) { /* * The current DEX file defined a class that is also present in the * bootstrap class path. The class loader favored the bootstrap * version, which means that we have a pointer to a class that is * (a) not the one we want to examine, and (b) mapped read-only, * so we will seg fault if we try to rewrite instructions inside it. */ ALOGD("DexOpt: not verifying/optimizing '%s': multiple definitions", clazz->descriptor); return; } classDescriptor = dexStringByTypeIdx(pDexFile, pClassDef->classIdx); /* * First, try to verify it. */ if (doVerify) { if (dvmVerifyClass(clazz)) { /* * Set the "is preverified" flag in the DexClassDef. We * do it here, rather than in the ClassObject structure, * because the DexClassDef is part of the odex file. */ assert((clazz->accessFlags & JAVA_FLAGS_MASK) == pClassDef->accessFlags); ((DexClassDef*)pClassDef)->accessFlags |= CLASS_ISPREVERIFIED; verified = true; } else { // TODO: log when in verbose mode ALOGV("DexOpt: '%s' failed verification", classDescriptor); } } if (doOpt) { bool needVerify = (gDvm.dexOptMode == OPTIMIZE_MODE_VERIFIED || gDvm.dexOptMode == OPTIMIZE_MODE_FULL); if (!verified && needVerify) { ALOGV("DexOpt: not optimizing '%s': not verified", classDescriptor); } else { dvmOptimizeClass(clazz, false); /* set the flag whether or not we actually changed anything */ ((DexClassDef*)pClassDef)->accessFlags |= CLASS_ISOPTIMIZED; } } } /* * Get the cache file name from a ClassPathEntry. */ static const char* getCacheFileName(const ClassPathEntry* cpe) { switch (cpe->kind) { case kCpeJar: return dvmGetJarFileCacheFileName((JarFile*) cpe->ptr); case kCpeDex: return dvmGetRawDexFileCacheFileName((RawDexFile*) cpe->ptr); default: ALOGE("DexOpt: unexpected cpe kind %d", cpe->kind); dvmAbort(); return NULL; } } /* * Get the SHA-1 signature. */ static const u1* getSignature(const ClassPathEntry* cpe) { DvmDex* pDvmDex; switch (cpe->kind) { case kCpeJar: pDvmDex = dvmGetJarFileDex((JarFile*) cpe->ptr); break; case kCpeDex: pDvmDex = dvmGetRawDexFileDex((RawDexFile*) cpe->ptr); break; default: ALOGE("unexpected cpe kind %d", cpe->kind); dvmAbort(); pDvmDex = NULL; // make gcc happy } assert(pDvmDex != NULL); return pDvmDex->pDexFile->pHeader->signature; } /* * Dependency layout: * 4b Source file modification time, in seconds since 1970 UTC * 4b CRC-32 from Zip entry, or Adler32 from source DEX header * 4b Dalvik VM build number * 4b Number of dependency entries that follow * Dependency entries: * 4b Name length (including terminating null) * var Full path of cache entry (null terminated) * 20b SHA-1 signature from source DEX file * * If this changes, update DEX_OPT_MAGIC_VERS. */ static const size_t kMinDepSize = 4 * 4; static const size_t kMaxDepSize = 4 * 4 + 2048; // sanity check /* * Read the "opt" header, verify it, then read the dependencies section * and verify that data as well. * * If "sourceAvail" is "true", this will verify that "modWhen" and "crc" * match up with what is stored in the header. If they don't, we reject * the file so that it can be recreated from the updated original. If * "sourceAvail" isn't set, e.g. for a .odex file, we ignore these arguments. * * On successful return, the file will be seeked immediately past the * "opt" header. */ bool dvmCheckOptHeaderAndDependencies(int fd, bool sourceAvail, u4 modWhen, u4 crc, bool expectVerify, bool expectOpt) { DexOptHeader optHdr; u1* depData = NULL; const u1* magic; off_t posn; int result = false; ssize_t actual; /* * Start at the start. The "opt" header, when present, will always be * the first thing in the file. */ if (lseek(fd, 0, SEEK_SET) != 0) { ALOGE("DexOpt: failed to seek to start of file: %s", strerror(errno)); goto bail; } /* * Read and do trivial verification on the opt header. The header is * always in host byte order. */ actual = read(fd, &optHdr, sizeof(optHdr)); if (actual < 0) { ALOGE("DexOpt: failed reading opt header: %s", strerror(errno)); goto bail; } else if (actual != sizeof(optHdr)) { ALOGE("DexOpt: failed reading opt header (got %d of %zd)", (int) actual, sizeof(optHdr)); goto bail; } magic = optHdr.magic; if (memcmp(magic, DEX_MAGIC, 4) == 0) { /* somebody probably pointed us at the wrong file */ ALOGD("DexOpt: expected optimized DEX, found unoptimized"); goto bail; } else if (memcmp(magic, DEX_OPT_MAGIC, 4) != 0) { /* not a DEX file, or previous attempt was interrupted */ ALOGD("DexOpt: incorrect opt magic number (0x%02x %02x %02x %02x)", magic[0], magic[1], magic[2], magic[3]); goto bail; } if (memcmp(magic+4, DEX_OPT_MAGIC_VERS, 4) != 0) { ALOGW("DexOpt: stale opt version (0x%02x %02x %02x %02x)", magic[4], magic[5], magic[6], magic[7]); goto bail; } if (optHdr.depsLength < kMinDepSize || optHdr.depsLength > kMaxDepSize) { ALOGW("DexOpt: weird deps length %d, bailing", optHdr.depsLength); goto bail; } /* * Do the header flags match up with what we want? * * The only thing we really can't handle is incorrect byte ordering. */ { const u4 matchMask = DEX_OPT_FLAG_BIG; u4 expectedFlags = 0; #if __BYTE_ORDER != __LITTLE_ENDIAN expectedFlags |= DEX_OPT_FLAG_BIG; #endif if ((expectedFlags & matchMask) != (optHdr.flags & matchMask)) { ALOGI("DexOpt: header flag mismatch (0x%02x vs 0x%02x, mask=0x%02x)", expectedFlags, optHdr.flags, matchMask); goto bail; } } posn = lseek(fd, optHdr.depsOffset, SEEK_SET); if (posn < 0) { ALOGW("DexOpt: seek to deps failed: %s", strerror(errno)); goto bail; } /* * Read all of the dependency stuff into memory. */ depData = (u1*) malloc(optHdr.depsLength); if (depData == NULL) { ALOGW("DexOpt: unable to allocate %d bytes for deps", optHdr.depsLength); goto bail; } actual = read(fd, depData, optHdr.depsLength); if (actual < 0) { ALOGW("DexOpt: failed reading deps: %s", strerror(errno)); goto bail; } else if (actual != (ssize_t) optHdr.depsLength) { ALOGW("DexOpt: failed reading deps: got %d of %d", (int) actual, optHdr.depsLength); goto bail; } /* * Verify simple items. */ const u1* ptr; u4 val; ptr = depData; val = read4LE(&ptr); if (sourceAvail && val != modWhen) { ALOGI("DexOpt: source file mod time mismatch (%08x vs %08x)", val, modWhen); goto bail; } val = read4LE(&ptr); if (sourceAvail && val != crc) { ALOGI("DexOpt: source file CRC mismatch (%08x vs %08x)", val, crc); goto bail; } val = read4LE(&ptr); if (val != DALVIK_VM_BUILD) { ALOGD("DexOpt: VM build version mismatch (%d vs %d)", val, DALVIK_VM_BUILD); goto bail; } /* * Verify dependencies on other cached DEX files. It must match * exactly with what is currently defined in the bootclasspath. */ ClassPathEntry* cpe; u4 numDeps; numDeps = read4LE(&ptr); ALOGV("+++ DexOpt: numDeps = %d", numDeps); for (cpe = gDvm.bootClassPath; cpe->ptr != NULL; cpe++) { const char* cacheFileName = dvmPathToAbsolutePortion(getCacheFileName(cpe)); assert(cacheFileName != NULL); /* guaranteed by Class.c */ const u1* signature = getSignature(cpe); size_t len = strlen(cacheFileName) +1; u4 storedStrLen; if (numDeps == 0) { /* more entries in bootclasspath than in deps list */ ALOGI("DexOpt: not all deps represented"); goto bail; } storedStrLen = read4LE(&ptr); if (len != storedStrLen || strcmp(cacheFileName, (const char*) ptr) != 0) { ALOGI("DexOpt: mismatch dep name: '%s' vs. '%s'", cacheFileName, ptr); goto bail; } ptr += storedStrLen; if (memcmp(signature, ptr, kSHA1DigestLen) != 0) { ALOGI("DexOpt: mismatch dep signature for '%s'", cacheFileName); goto bail; } ptr += kSHA1DigestLen; ALOGV("DexOpt: dep match on '%s'", cacheFileName); numDeps--; } if (numDeps != 0) { /* more entries in deps list than in classpath */ ALOGI("DexOpt: Some deps went away"); goto bail; } // consumed all data and no more? if (ptr != depData + optHdr.depsLength) { ALOGW("DexOpt: Spurious dep data? %d vs %d", (int) (ptr - depData), optHdr.depsLength); assert(false); } result = true; bail: free(depData); return result; } /* * Write the dependency info to "fd" at the current file position. */ static int writeDependencies(int fd, u4 modWhen, u4 crc) { u1* buf = NULL; int result = -1; ssize_t bufLen; ClassPathEntry* cpe; int numDeps; /* * Count up the number of completed entries in the bootclasspath. */ numDeps = 0; bufLen = 0; for (cpe = gDvm.bootClassPath; cpe->ptr != NULL; cpe++) { const char* cacheFileName = dvmPathToAbsolutePortion(getCacheFileName(cpe)); assert(cacheFileName != NULL); /* guaranteed by Class.c */ ALOGV("+++ DexOpt: found dep '%s'", cacheFileName); numDeps++; bufLen += strlen(cacheFileName) +1; } bufLen += 4*4 + numDeps * (4+kSHA1DigestLen); buf = (u1*)malloc(bufLen); set4LE(buf+0, modWhen); set4LE(buf+4, crc); set4LE(buf+8, DALVIK_VM_BUILD); set4LE(buf+12, numDeps); // TODO: do we want to add dvmGetInlineOpsTableLength() here? Won't // help us if somebody replaces an existing entry, but it'd catch // additions/removals. u1* ptr = buf + 4*4; for (cpe = gDvm.bootClassPath; cpe->ptr != NULL; cpe++) { const char* cacheFileName = dvmPathToAbsolutePortion(getCacheFileName(cpe)); assert(cacheFileName != NULL); /* guaranteed by Class.c */ const u1* signature = getSignature(cpe); int len = strlen(cacheFileName) +1; if (ptr + 4 + len + kSHA1DigestLen > buf + bufLen) { ALOGE("DexOpt: overran buffer"); dvmAbort(); } set4LE(ptr, len); ptr += 4; memcpy(ptr, cacheFileName, len); ptr += len; memcpy(ptr, signature, kSHA1DigestLen); ptr += kSHA1DigestLen; } assert(ptr == buf + bufLen); result = sysWriteFully(fd, buf, bufLen, "DexOpt dep info"); free(buf); return result; } /* * Write a block of data in "chunk" format. * * The chunk header fields are always in "native" byte order. If "size" * is not a multiple of 8 bytes, the data area is padded out. */ static bool writeChunk(int fd, u4 type, const void* data, size_t size) { union { /* save a syscall by grouping these together */ char raw[8]; struct { u4 type; u4 size; } ts; } header; assert(sizeof(header) == 8); ALOGV("Writing chunk, type=%.4s size=%d", (char*) &type, size); header.ts.type = type; header.ts.size = (u4) size; if (sysWriteFully(fd, &header, sizeof(header), "DexOpt opt chunk header write") != 0) { return false; } if (size > 0) { if (sysWriteFully(fd, data, size, "DexOpt opt chunk write") != 0) return false; } /* if necessary, pad to 64-bit alignment */ if ((size & 7) != 0) { int padSize = 8 - (size & 7); ALOGV("size was %d, inserting %d pad bytes", size, padSize); lseek(fd, padSize, SEEK_CUR); } assert( ((int)lseek(fd, 0, SEEK_CUR) & 7) == 0); return true; } /* * Write opt data. * * We have different pieces, some of which may be optional. To make the * most effective use of space, we use a "chunk" format, with a 4-byte * type and a 4-byte length. We guarantee 64-bit alignment for the data, * so it can be used directly when the file is mapped for reading. */ static bool writeOptData(int fd, const DexClassLookup* pClassLookup, const RegisterMapBuilder* pRegMapBuilder) { /* pre-computed class lookup hash table */ if (!writeChunk(fd, (u4) kDexChunkClassLookup, pClassLookup, pClassLookup->size)) { return false; } /* register maps (optional) */ if (pRegMapBuilder != NULL) { if (!writeChunk(fd, (u4) kDexChunkRegisterMaps, pRegMapBuilder->data, pRegMapBuilder->size)) { return false; } } /* write the end marker */ if (!writeChunk(fd, (u4) kDexChunkEnd, NULL, 0)) { return false; } return true; } /* * Compute a checksum on a piece of an open file. * * File will be positioned at end of checksummed area. * * Returns "true" on success. */ static bool computeFileChecksum(int fd, off_t start, size_t length, u4* pSum) { unsigned char readBuf[8192]; ssize_t actual; uLong adler; if (lseek(fd, start, SEEK_SET) != start) { ALOGE("Unable to seek to start of checksum area (%ld): %s", (long) start, strerror(errno)); return false; } adler = adler32(0L, Z_NULL, 0); while (length != 0) { size_t wanted = (length < sizeof(readBuf)) ? length : sizeof(readBuf); actual = read(fd, readBuf, wanted); if (actual <= 0) { ALOGE("Read failed (%d) while computing checksum (len=%zu): %s", (int) actual, length, strerror(errno)); return false; } adler = adler32(adler, readBuf, actual); length -= actual; } *pSum = adler; return true; } /* * Update the Adler-32 checksum stored in the DEX file. This covers the * swapped and optimized DEX data, but does not include the opt header * or optimized data. */ static void updateChecksum(u1* addr, int len, DexHeader* pHeader) { /* * Rewrite the checksum. We leave the SHA-1 signature alone. */ uLong adler = adler32(0L, Z_NULL, 0); const int nonSum = sizeof(pHeader->magic) + sizeof(pHeader->checksum); adler = adler32(adler, addr + nonSum, len - nonSum); pHeader->checksum = adler; }