/* * 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. */ #define LOG_TAG "ResourceType" //#define LOG_NDEBUG 0 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef __ANDROID__ #include #endif #ifndef INT32_MAX #define INT32_MAX ((int32_t)(2147483647)) #endif namespace android { #ifdef HAVE_WINSOCK #undef nhtol #undef htonl #define ntohl(x) ( ((x) << 24) | (((x) >> 24) & 255) | (((x) << 8) & 0xff0000) | (((x) >> 8) & 0xff00) ) #define htonl(x) ntohl(x) #define ntohs(x) ( (((x) << 8) & 0xff00) | (((x) >> 8) & 255) ) #define htons(x) ntohs(x) #endif #define IDMAP_MAGIC 0x504D4449 #define IDMAP_CURRENT_VERSION 0x00000001 #define APP_PACKAGE_ID 0x7f #define CMSDK_PACKAGE_ID 0x3f #define SYS_PACKAGE_ID 0x01 #define OVERLAY_CMSDK_PACKAGE_ID 0x63 #define OVERLAY_APP_PACKAGE_ID 0x61 #define OVERLAY_SYS_PACKAGE_ID 0x60 #define OVERLAY_COMMON_PACKAGE_ID 0x5f // Define attributes from android.R.attr to protect from theme changes #define ATTR_WINDOW_NO_TITLE 0x01010056 // windowNoTitle #define ATTR_WINDOW_ACTION_BAR 0x010102cd // windowActionBar static const bool kDebugStringPoolNoisy = false; static const bool kDebugXMLNoisy = false; static const bool kDebugTableNoisy = false; static const bool kDebugTableGetEntry = false; static const bool kDebugTableSuperNoisy = false; static const bool kDebugLoadTableNoisy = false; static const bool kDebugLoadTableSuperNoisy = false; static const bool kDebugTableTheme = false; static const bool kDebugResXMLTree = false; static const bool kDebugLibNoisy = false; // TODO: This code uses 0xFFFFFFFF converted to bag_set* as a sentinel value. This is bad practice. // Standard C isspace() is only required to look at the low byte of its input, so // produces incorrect results for UTF-16 characters. For safety's sake, assume that // any high-byte UTF-16 code point is not whitespace. inline int isspace16(char16_t c) { return (c < 0x0080 && isspace(c)); } template inline static T max(T a, T b) { return a > b ? a : b; } // range checked; guaranteed to NUL-terminate within the stated number of available slots // NOTE: if this truncates the dst string due to running out of space, no attempt is // made to avoid splitting surrogate pairs. static void strcpy16_dtoh(char16_t* dst, const uint16_t* src, size_t avail) { char16_t* last = dst + avail - 1; while (*src && (dst < last)) { char16_t s = dtohs(static_cast(*src)); *dst++ = s; src++; } *dst = 0; } static status_t validate_chunk(const ResChunk_header* chunk, size_t minSize, const uint8_t* dataEnd, const char* name) { const uint16_t headerSize = dtohs(chunk->headerSize); const uint32_t size = dtohl(chunk->size); if (headerSize >= minSize) { if (headerSize <= size) { if (((headerSize|size)&0x3) == 0) { if ((size_t)size <= (size_t)(dataEnd-((const uint8_t*)chunk))) { return NO_ERROR; } ALOGW("%s data size 0x%x extends beyond resource end %p.", name, size, (void*)(dataEnd-((const uint8_t*)chunk))); return BAD_TYPE; } ALOGW("%s size 0x%x or headerSize 0x%x is not on an integer boundary.", name, (int)size, (int)headerSize); return BAD_TYPE; } ALOGW("%s size 0x%x is smaller than header size 0x%x.", name, size, headerSize); return BAD_TYPE; } ALOGW("%s header size 0x%04x is too small.", name, headerSize); return BAD_TYPE; } static void fill9patchOffsets(Res_png_9patch* patch) { patch->xDivsOffset = sizeof(Res_png_9patch); patch->yDivsOffset = patch->xDivsOffset + (patch->numXDivs * sizeof(int32_t)); patch->colorsOffset = patch->yDivsOffset + (patch->numYDivs * sizeof(int32_t)); } inline void Res_value::copyFrom_dtoh(const Res_value& src) { size = dtohs(src.size); res0 = src.res0; dataType = src.dataType; data = dtohl(src.data); } void Res_png_9patch::deviceToFile() { int32_t* xDivs = getXDivs(); for (int i = 0; i < numXDivs; i++) { xDivs[i] = htonl(xDivs[i]); } int32_t* yDivs = getYDivs(); for (int i = 0; i < numYDivs; i++) { yDivs[i] = htonl(yDivs[i]); } paddingLeft = htonl(paddingLeft); paddingRight = htonl(paddingRight); paddingTop = htonl(paddingTop); paddingBottom = htonl(paddingBottom); uint32_t* colors = getColors(); for (int i=0; i(outData)); } static bool assertIdmapHeader(const void* idmap, size_t size) { if (reinterpret_cast(idmap) & 0x03) { ALOGE("idmap: header is not word aligned"); return false; } if (size < ResTable::IDMAP_HEADER_SIZE_BYTES) { ALOGW("idmap: header too small (%d bytes)", (uint32_t) size); return false; } const uint32_t magic = htodl(*reinterpret_cast(idmap)); if (magic != IDMAP_MAGIC) { ALOGW("idmap: no magic found in header (is 0x%08x, expected 0x%08x)", magic, IDMAP_MAGIC); return false; } const uint32_t version = htodl(*(reinterpret_cast(idmap) + 1)); if (version != IDMAP_CURRENT_VERSION) { // We are strict about versions because files with this format are // auto-generated and don't need backwards compatibility. ALOGW("idmap: version mismatch in header (is 0x%08x, expected 0x%08x)", version, IDMAP_CURRENT_VERSION); return false; } return true; } class IdmapEntries { public: IdmapEntries() : mData(NULL) {} bool hasEntries() const { if (mData == NULL) { return false; } return (dtohs(*mData) > 0); } size_t byteSize() const { if (mData == NULL) { return 0; } uint16_t entryCount = dtohs(mData[2]); return (sizeof(uint16_t) * 4) + (sizeof(uint32_t) * static_cast(entryCount)); } uint8_t targetTypeId() const { if (mData == NULL) { return 0; } return dtohs(mData[0]); } uint8_t overlayTypeId() const { if (mData == NULL) { return 0; } return dtohs(mData[1]); } status_t setTo(const void* entryHeader, size_t size) { if (reinterpret_cast(entryHeader) & 0x03) { ALOGE("idmap: entry header is not word aligned"); return UNKNOWN_ERROR; } if (size < sizeof(uint16_t) * 4) { ALOGE("idmap: entry header is too small (%u bytes)", (uint32_t) size); return UNKNOWN_ERROR; } const uint16_t* header = reinterpret_cast(entryHeader); const uint16_t targetTypeId = dtohs(header[0]); const uint16_t overlayTypeId = dtohs(header[1]); if (targetTypeId == 0 || overlayTypeId == 0 || targetTypeId > 255 || overlayTypeId > 255) { ALOGE("idmap: invalid type map (%u -> %u)", targetTypeId, overlayTypeId); return UNKNOWN_ERROR; } uint16_t entryCount = dtohs(header[2]); if (size < sizeof(uint32_t) * (entryCount + 2)) { ALOGE("idmap: too small (%u bytes) for the number of entries (%u)", (uint32_t) size, (uint32_t) entryCount); return UNKNOWN_ERROR; } mData = header; return NO_ERROR; } status_t lookup(uint16_t entryId, uint16_t* outEntryId) const { uint16_t entryCount = dtohs(mData[2]); uint16_t offset = dtohs(mData[3]); if (entryId < offset) { // The entry is not present in this idmap return BAD_INDEX; } entryId -= offset; if (entryId >= entryCount) { // The entry is not present in this idmap return BAD_INDEX; } // It is safe to access the type here without checking the size because // we have checked this when it was first loaded. const uint32_t* entries = reinterpret_cast(mData) + 2; uint32_t mappedEntry = dtohl(entries[entryId]); if (mappedEntry == 0xffffffff) { // This entry is not present in this idmap return BAD_INDEX; } *outEntryId = static_cast(mappedEntry); return NO_ERROR; } private: const uint16_t* mData; }; status_t parseIdmap(const void* idmap, size_t size, uint8_t* outPackageId, KeyedVector* outMap) { if (!assertIdmapHeader(idmap, size)) { return UNKNOWN_ERROR; } size -= ResTable::IDMAP_HEADER_SIZE_BYTES; if (size < sizeof(uint16_t) * 2) { ALOGE("idmap: too small to contain any mapping"); return UNKNOWN_ERROR; } const uint16_t* data = reinterpret_cast( reinterpret_cast(idmap) + ResTable::IDMAP_HEADER_SIZE_BYTES); uint16_t targetPackageId = dtohs(*(data++)); if (targetPackageId == 0 || targetPackageId > 255) { ALOGE("idmap: target package ID is invalid (%02x)", targetPackageId); return UNKNOWN_ERROR; } uint16_t mapCount = dtohs(*(data++)); if (mapCount == 0) { ALOGE("idmap: no mappings"); return UNKNOWN_ERROR; } if (mapCount > 255) { ALOGW("idmap: too many mappings. Only 255 are possible but %u are present", (uint32_t) mapCount); } while (size > sizeof(uint16_t) * 4) { IdmapEntries entries; status_t err = entries.setTo(data, size); if (err != NO_ERROR) { return err; } ssize_t index = outMap->add(entries.overlayTypeId(), entries); if (index < 0) { return NO_MEMORY; } data += entries.byteSize() / sizeof(uint16_t); size -= entries.byteSize(); } if (outPackageId != NULL) { *outPackageId = static_cast(targetPackageId); } return NO_ERROR; } Res_png_9patch* Res_png_9patch::deserialize(void* inData) { Res_png_9patch* patch = reinterpret_cast(inData); patch->wasDeserialized = true; fill9patchOffsets(patch); return patch; } // -------------------------------------------------------------------- // -------------------------------------------------------------------- // -------------------------------------------------------------------- ResStringPool::ResStringPool() : mError(NO_INIT), mOwnedData(NULL), mHeader(NULL), mCache(NULL) { } ResStringPool::ResStringPool(const void* data, size_t size, bool copyData) : mError(NO_INIT), mOwnedData(NULL), mHeader(NULL), mCache(NULL) { setTo(data, size, copyData); } ResStringPool::~ResStringPool() { uninit(); } void ResStringPool::setToEmpty() { uninit(); mOwnedData = calloc(1, sizeof(ResStringPool_header)); ResStringPool_header* header = (ResStringPool_header*) mOwnedData; mSize = 0; mEntries = NULL; mStrings = NULL; mStringPoolSize = 0; mEntryStyles = NULL; mStyles = NULL; mStylePoolSize = 0; mHeader = (const ResStringPool_header*) header; } status_t ResStringPool::setTo(const void* data, size_t size, bool copyData) { if (!data || !size) { return (mError=BAD_TYPE); } uninit(); const bool notDeviceEndian = htods(0xf0) != 0xf0; if (copyData || notDeviceEndian) { mOwnedData = malloc(size); if (mOwnedData == NULL) { return (mError=NO_MEMORY); } memcpy(mOwnedData, data, size); data = mOwnedData; } mHeader = (const ResStringPool_header*)data; if (notDeviceEndian) { ResStringPool_header* h = const_cast(mHeader); h->header.headerSize = dtohs(mHeader->header.headerSize); h->header.type = dtohs(mHeader->header.type); h->header.size = dtohl(mHeader->header.size); h->stringCount = dtohl(mHeader->stringCount); h->styleCount = dtohl(mHeader->styleCount); h->flags = dtohl(mHeader->flags); h->stringsStart = dtohl(mHeader->stringsStart); h->stylesStart = dtohl(mHeader->stylesStart); } if (mHeader->header.headerSize > mHeader->header.size || mHeader->header.size > size) { ALOGW("Bad string block: header size %d or total size %d is larger than data size %d\n", (int)mHeader->header.headerSize, (int)mHeader->header.size, (int)size); return (mError=BAD_TYPE); } mSize = mHeader->header.size; mEntries = (const uint32_t*) (((const uint8_t*)data)+mHeader->header.headerSize); if (mHeader->stringCount > 0) { if ((mHeader->stringCount*sizeof(uint32_t) < mHeader->stringCount) // uint32 overflow? || (mHeader->header.headerSize+(mHeader->stringCount*sizeof(uint32_t))) > size) { ALOGW("Bad string block: entry of %d items extends past data size %d\n", (int)(mHeader->header.headerSize+(mHeader->stringCount*sizeof(uint32_t))), (int)size); return (mError=BAD_TYPE); } size_t charSize; if (mHeader->flags&ResStringPool_header::UTF8_FLAG) { charSize = sizeof(uint8_t); } else { charSize = sizeof(uint16_t); } // There should be at least space for the smallest string // (2 bytes length, null terminator). if (mHeader->stringsStart >= (mSize - sizeof(uint16_t))) { ALOGW("Bad string block: string pool starts at %d, after total size %d\n", (int)mHeader->stringsStart, (int)mHeader->header.size); return (mError=BAD_TYPE); } mStrings = (const void*) (((const uint8_t*)data) + mHeader->stringsStart); if (mHeader->styleCount == 0) { mStringPoolSize = (mSize - mHeader->stringsStart) / charSize; } else { // check invariant: styles starts before end of data if (mHeader->stylesStart >= (mSize - sizeof(uint16_t))) { ALOGW("Bad style block: style block starts at %d past data size of %d\n", (int)mHeader->stylesStart, (int)mHeader->header.size); return (mError=BAD_TYPE); } // check invariant: styles follow the strings if (mHeader->stylesStart <= mHeader->stringsStart) { ALOGW("Bad style block: style block starts at %d, before strings at %d\n", (int)mHeader->stylesStart, (int)mHeader->stringsStart); return (mError=BAD_TYPE); } mStringPoolSize = (mHeader->stylesStart-mHeader->stringsStart)/charSize; } // check invariant: stringCount > 0 requires a string pool to exist if (mStringPoolSize == 0) { ALOGW("Bad string block: stringCount is %d but pool size is 0\n", (int)mHeader->stringCount); return (mError=BAD_TYPE); } if (notDeviceEndian) { size_t i; uint32_t* e = const_cast(mEntries); for (i=0; istringCount; i++) { e[i] = dtohl(mEntries[i]); } if (!(mHeader->flags&ResStringPool_header::UTF8_FLAG)) { const uint16_t* strings = (const uint16_t*)mStrings; uint16_t* s = const_cast(strings); for (i=0; iflags&ResStringPool_header::UTF8_FLAG && ((uint8_t*)mStrings)[mStringPoolSize-1] != 0) || (!mHeader->flags&ResStringPool_header::UTF8_FLAG && ((uint16_t*)mStrings)[mStringPoolSize-1] != 0)) { ALOGW("Bad string block: last string is not 0-terminated\n"); return (mError=BAD_TYPE); } } else { mStrings = NULL; mStringPoolSize = 0; } if (mHeader->styleCount > 0) { mEntryStyles = mEntries + mHeader->stringCount; // invariant: integer overflow in calculating mEntryStyles if (mEntryStyles < mEntries) { ALOGW("Bad string block: integer overflow finding styles\n"); return (mError=BAD_TYPE); } if (((const uint8_t*)mEntryStyles-(const uint8_t*)mHeader) > (int)size) { ALOGW("Bad string block: entry of %d styles extends past data size %d\n", (int)((const uint8_t*)mEntryStyles-(const uint8_t*)mHeader), (int)size); return (mError=BAD_TYPE); } mStyles = (const uint32_t*) (((const uint8_t*)data)+mHeader->stylesStart); if (mHeader->stylesStart >= mHeader->header.size) { ALOGW("Bad string block: style pool starts %d, after total size %d\n", (int)mHeader->stylesStart, (int)mHeader->header.size); return (mError=BAD_TYPE); } mStylePoolSize = (mHeader->header.size-mHeader->stylesStart)/sizeof(uint32_t); if (notDeviceEndian) { size_t i; uint32_t* e = const_cast(mEntryStyles); for (i=0; istyleCount; i++) { e[i] = dtohl(mEntryStyles[i]); } uint32_t* s = const_cast(mStyles); for (i=0; istringCount; x++) { if (mCache[x] != NULL) { free(mCache[x]); mCache[x] = NULL; } } free(mCache); mCache = NULL; } if (mOwnedData) { free(mOwnedData); mOwnedData = NULL; } } /** * Strings in UTF-16 format have length indicated by a length encoded in the * stored data. It is either 1 or 2 characters of length data. This allows a * maximum length of 0x7FFFFFF (2147483647 bytes), but if you're storing that * much data in a string, you're abusing them. * * If the high bit is set, then there are two characters or 4 bytes of length * data encoded. In that case, drop the high bit of the first character and * add it together with the next character. */ static inline size_t decodeLength(const uint16_t** str) { size_t len = **str; if ((len & 0x8000) != 0) { (*str)++; len = ((len & 0x7FFF) << 16) | **str; } (*str)++; return len; } /** * Strings in UTF-8 format have length indicated by a length encoded in the * stored data. It is either 1 or 2 characters of length data. This allows a * maximum length of 0x7FFF (32767 bytes), but you should consider storing * text in another way if you're using that much data in a single string. * * If the high bit is set, then there are two characters or 2 bytes of length * data encoded. In that case, drop the high bit of the first character and * add it together with the next character. */ static inline size_t decodeLength(const uint8_t** str) { size_t len = **str; if ((len & 0x80) != 0) { (*str)++; len = ((len & 0x7F) << 8) | **str; } (*str)++; return len; } const char16_t* ResStringPool::stringAt(size_t idx, size_t* u16len) const { if (mError == NO_ERROR && idx < mHeader->stringCount) { const bool isUTF8 = (mHeader->flags&ResStringPool_header::UTF8_FLAG) != 0; const uint32_t off = mEntries[idx]/(isUTF8?sizeof(uint8_t):sizeof(uint16_t)); if (off < (mStringPoolSize-1)) { if (!isUTF8) { const uint16_t* strings = (uint16_t*)mStrings; const uint16_t* str = strings+off; *u16len = decodeLength(&str); if ((uint32_t)(str+*u16len-strings) < mStringPoolSize) { // Reject malformed (non null-terminated) strings if (str[*u16len] != 0x0000) { ALOGW("Bad string block: string #%d is not null-terminated", (int)idx); return NULL; } return reinterpret_cast(str); } else { ALOGW("Bad string block: string #%d extends to %d, past end at %d\n", (int)idx, (int)(str+*u16len-strings), (int)mStringPoolSize); } } else { const uint8_t* strings = (uint8_t*)mStrings; const uint8_t* u8str = strings+off; *u16len = decodeLength(&u8str); size_t u8len = decodeLength(&u8str); // encLen must be less than 0x7FFF due to encoding. if ((uint32_t)(u8str+u8len-strings) < mStringPoolSize) { AutoMutex lock(mDecodeLock); if (mCache == NULL) { #ifndef HAVE_ANDROID_OS if (kDebugStringPoolNoisy) { ALOGI("CREATING STRING CACHE OF %zu bytes", mHeader->stringCount*sizeof(char16_t**)); } #else // We do not want to be in this case when actually running Android. ALOGV("CREATING STRING CACHE OF %zu bytes", static_cast(mHeader->stringCount*sizeof(char16_t**))); #endif mCache = (char16_t**)calloc(mHeader->stringCount, sizeof(char16_t**)); if (mCache == NULL) { ALOGW("No memory trying to allocate decode cache table of %d bytes\n", (int)(mHeader->stringCount*sizeof(char16_t**))); return NULL; } } if (mCache[idx] != NULL) { return mCache[idx]; } ssize_t actualLen = utf8_to_utf16_length(u8str, u8len); if (actualLen < 0 || (size_t)actualLen != *u16len) { ALOGW("Bad string block: string #%lld decoded length is not correct " "%lld vs %llu\n", (long long)idx, (long long)actualLen, (long long)*u16len); return NULL; } // Reject malformed (non null-terminated) strings if (u8str[u8len] != 0x00) { ALOGW("Bad string block: string #%d is not null-terminated", (int)idx); return NULL; } char16_t *u16str = (char16_t *)calloc(*u16len+1, sizeof(char16_t)); if (!u16str) { ALOGW("No memory when trying to allocate decode cache for string #%d\n", (int)idx); return NULL; } if (kDebugStringPoolNoisy) { ALOGI("Caching UTF8 string: %s", u8str); } utf8_to_utf16(u8str, u8len, u16str); mCache[idx] = u16str; return u16str; } else { ALOGW("Bad string block: string #%lld extends to %lld, past end at %lld\n", (long long)idx, (long long)(u8str+u8len-strings), (long long)mStringPoolSize); } } } else { ALOGW("Bad string block: string #%d entry is at %d, past end at %d\n", (int)idx, (int)(off*sizeof(uint16_t)), (int)(mStringPoolSize*sizeof(uint16_t))); } } return NULL; } const char* ResStringPool::string8At(size_t idx, size_t* outLen) const { if (mError == NO_ERROR && idx < mHeader->stringCount) { if ((mHeader->flags&ResStringPool_header::UTF8_FLAG) == 0) { return NULL; } const uint32_t off = mEntries[idx]/sizeof(char); if (off < (mStringPoolSize-1)) { const uint8_t* strings = (uint8_t*)mStrings; const uint8_t* str = strings+off; *outLen = decodeLength(&str); size_t encLen = decodeLength(&str); if ((uint32_t)(str+encLen-strings) < mStringPoolSize) { return (const char*)str; } else { ALOGW("Bad string block: string #%d extends to %d, past end at %d\n", (int)idx, (int)(str+encLen-strings), (int)mStringPoolSize); } } else { ALOGW("Bad string block: string #%d entry is at %d, past end at %d\n", (int)idx, (int)(off*sizeof(uint16_t)), (int)(mStringPoolSize*sizeof(uint16_t))); } } return NULL; } const String8 ResStringPool::string8ObjectAt(size_t idx) const { size_t len; const char *str = string8At(idx, &len); if (str != NULL) { return String8(str, len); } const char16_t *str16 = stringAt(idx, &len); if (str16 != NULL) { return String8(str16, len); } return String8(); } const ResStringPool_span* ResStringPool::styleAt(const ResStringPool_ref& ref) const { return styleAt(ref.index); } const ResStringPool_span* ResStringPool::styleAt(size_t idx) const { if (mError == NO_ERROR && idx < mHeader->styleCount) { const uint32_t off = (mEntryStyles[idx]/sizeof(uint32_t)); if (off < mStylePoolSize) { return (const ResStringPool_span*)(mStyles+off); } else { ALOGW("Bad string block: style #%d entry is at %d, past end at %d\n", (int)idx, (int)(off*sizeof(uint32_t)), (int)(mStylePoolSize*sizeof(uint32_t))); } } return NULL; } ssize_t ResStringPool::indexOfString(const char16_t* str, size_t strLen) const { if (mError != NO_ERROR) { return mError; } size_t len; if ((mHeader->flags&ResStringPool_header::UTF8_FLAG) != 0) { if (kDebugStringPoolNoisy) { ALOGI("indexOfString UTF-8: %s", String8(str, strLen).string()); } // The string pool contains UTF 8 strings; we don't want to cause // temporary UTF-16 strings to be created as we search. if (mHeader->flags&ResStringPool_header::SORTED_FLAG) { // Do a binary search for the string... this is a little tricky, // because the strings are sorted with strzcmp16(). So to match // the ordering, we need to convert strings in the pool to UTF-16. // But we don't want to hit the cache, so instead we will have a // local temporary allocation for the conversions. char16_t* convBuffer = (char16_t*)malloc(strLen+4); ssize_t l = 0; ssize_t h = mHeader->stringCount-1; ssize_t mid; while (l <= h) { mid = l + (h - l)/2; const uint8_t* s = (const uint8_t*)string8At(mid, &len); int c; if (s != NULL) { char16_t* end = utf8_to_utf16_n(s, len, convBuffer, strLen+3); *end = 0; c = strzcmp16(convBuffer, end-convBuffer, str, strLen); } else { c = -1; } if (kDebugStringPoolNoisy) { ALOGI("Looking at %s, cmp=%d, l/mid/h=%d/%d/%d\n", (const char*)s, c, (int)l, (int)mid, (int)h); } if (c == 0) { if (kDebugStringPoolNoisy) { ALOGI("MATCH!"); } free(convBuffer); return mid; } else if (c < 0) { l = mid + 1; } else { h = mid - 1; } } free(convBuffer); } else { // It is unusual to get the ID from an unsorted string block... // most often this happens because we want to get IDs for style // span tags; since those always appear at the end of the string // block, start searching at the back. String8 str8(str, strLen); const size_t str8Len = str8.size(); for (int i=mHeader->stringCount-1; i>=0; i--) { const char* s = string8At(i, &len); if (kDebugStringPoolNoisy) { ALOGI("Looking at %s, i=%d\n", String8(s).string(), i); } if (s && str8Len == len && memcmp(s, str8.string(), str8Len) == 0) { if (kDebugStringPoolNoisy) { ALOGI("MATCH!"); } return i; } } } } else { if (kDebugStringPoolNoisy) { ALOGI("indexOfString UTF-16: %s", String8(str, strLen).string()); } if (mHeader->flags&ResStringPool_header::SORTED_FLAG) { // Do a binary search for the string... ssize_t l = 0; ssize_t h = mHeader->stringCount-1; ssize_t mid; while (l <= h) { mid = l + (h - l)/2; const char16_t* s = stringAt(mid, &len); int c = s ? strzcmp16(s, len, str, strLen) : -1; if (kDebugStringPoolNoisy) { ALOGI("Looking at %s, cmp=%d, l/mid/h=%d/%d/%d\n", String8(s).string(), c, (int)l, (int)mid, (int)h); } if (c == 0) { if (kDebugStringPoolNoisy) { ALOGI("MATCH!"); } return mid; } else if (c < 0) { l = mid + 1; } else { h = mid - 1; } } } else { // It is unusual to get the ID from an unsorted string block... // most often this happens because we want to get IDs for style // span tags; since those always appear at the end of the string // block, start searching at the back. for (int i=mHeader->stringCount-1; i>=0; i--) { const char16_t* s = stringAt(i, &len); if (kDebugStringPoolNoisy) { ALOGI("Looking at %s, i=%d\n", String8(s).string(), i); } if (s && strLen == len && strzcmp16(s, len, str, strLen) == 0) { if (kDebugStringPoolNoisy) { ALOGI("MATCH!"); } return i; } } } } return NAME_NOT_FOUND; } size_t ResStringPool::size() const { return (mError == NO_ERROR) ? mHeader->stringCount : 0; } size_t ResStringPool::styleCount() const { return (mError == NO_ERROR) ? mHeader->styleCount : 0; } size_t ResStringPool::bytes() const { return (mError == NO_ERROR) ? mHeader->header.size : 0; } bool ResStringPool::isSorted() const { return (mHeader->flags&ResStringPool_header::SORTED_FLAG)!=0; } bool ResStringPool::isUTF8() const { return (mHeader->flags&ResStringPool_header::UTF8_FLAG)!=0; } // -------------------------------------------------------------------- // -------------------------------------------------------------------- // -------------------------------------------------------------------- ResXMLParser::ResXMLParser(const ResXMLTree& tree) : mTree(tree), mEventCode(BAD_DOCUMENT) { } void ResXMLParser::restart() { mCurNode = NULL; mEventCode = mTree.mError == NO_ERROR ? START_DOCUMENT : BAD_DOCUMENT; } const ResStringPool& ResXMLParser::getStrings() const { return mTree.mStrings; } ResXMLParser::event_code_t ResXMLParser::getEventType() const { return mEventCode; } ResXMLParser::event_code_t ResXMLParser::next() { if (mEventCode == START_DOCUMENT) { mCurNode = mTree.mRootNode; mCurExt = mTree.mRootExt; return (mEventCode=mTree.mRootCode); } else if (mEventCode >= FIRST_CHUNK_CODE) { return nextNode(); } return mEventCode; } int32_t ResXMLParser::getCommentID() const { return mCurNode != NULL ? dtohl(mCurNode->comment.index) : -1; } const char16_t* ResXMLParser::getComment(size_t* outLen) const { int32_t id = getCommentID(); return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } uint32_t ResXMLParser::getLineNumber() const { return mCurNode != NULL ? dtohl(mCurNode->lineNumber) : -1; } int32_t ResXMLParser::getTextID() const { if (mEventCode == TEXT) { return dtohl(((const ResXMLTree_cdataExt*)mCurExt)->data.index); } return -1; } const char16_t* ResXMLParser::getText(size_t* outLen) const { int32_t id = getTextID(); return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } ssize_t ResXMLParser::getTextValue(Res_value* outValue) const { if (mEventCode == TEXT) { outValue->copyFrom_dtoh(((const ResXMLTree_cdataExt*)mCurExt)->typedData); return sizeof(Res_value); } return BAD_TYPE; } int32_t ResXMLParser::getNamespacePrefixID() const { if (mEventCode == START_NAMESPACE || mEventCode == END_NAMESPACE) { return dtohl(((const ResXMLTree_namespaceExt*)mCurExt)->prefix.index); } return -1; } const char16_t* ResXMLParser::getNamespacePrefix(size_t* outLen) const { int32_t id = getNamespacePrefixID(); //printf("prefix=%d event=%p\n", id, mEventCode); return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } int32_t ResXMLParser::getNamespaceUriID() const { if (mEventCode == START_NAMESPACE || mEventCode == END_NAMESPACE) { return dtohl(((const ResXMLTree_namespaceExt*)mCurExt)->uri.index); } return -1; } const char16_t* ResXMLParser::getNamespaceUri(size_t* outLen) const { int32_t id = getNamespaceUriID(); //printf("uri=%d event=%p\n", id, mEventCode); return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } int32_t ResXMLParser::getElementNamespaceID() const { if (mEventCode == START_TAG) { return dtohl(((const ResXMLTree_attrExt*)mCurExt)->ns.index); } if (mEventCode == END_TAG) { return dtohl(((const ResXMLTree_endElementExt*)mCurExt)->ns.index); } return -1; } const char16_t* ResXMLParser::getElementNamespace(size_t* outLen) const { int32_t id = getElementNamespaceID(); return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } int32_t ResXMLParser::getElementNameID() const { if (mEventCode == START_TAG) { return dtohl(((const ResXMLTree_attrExt*)mCurExt)->name.index); } if (mEventCode == END_TAG) { return dtohl(((const ResXMLTree_endElementExt*)mCurExt)->name.index); } return -1; } const char16_t* ResXMLParser::getElementName(size_t* outLen) const { int32_t id = getElementNameID(); return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } size_t ResXMLParser::getAttributeCount() const { if (mEventCode == START_TAG) { return dtohs(((const ResXMLTree_attrExt*)mCurExt)->attributeCount); } return 0; } int32_t ResXMLParser::getAttributeNamespaceID(size_t idx) const { if (mEventCode == START_TAG) { const ResXMLTree_attrExt* tag = (const ResXMLTree_attrExt*)mCurExt; if (idx < dtohs(tag->attributeCount)) { const ResXMLTree_attribute* attr = (const ResXMLTree_attribute*) (((const uint8_t*)tag) + dtohs(tag->attributeStart) + (dtohs(tag->attributeSize)*idx)); return dtohl(attr->ns.index); } } return -2; } const char16_t* ResXMLParser::getAttributeNamespace(size_t idx, size_t* outLen) const { int32_t id = getAttributeNamespaceID(idx); //printf("attribute namespace=%d idx=%d event=%p\n", id, idx, mEventCode); if (kDebugXMLNoisy) { printf("getAttributeNamespace 0x%zx=0x%x\n", idx, id); } return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } const char* ResXMLParser::getAttributeNamespace8(size_t idx, size_t* outLen) const { int32_t id = getAttributeNamespaceID(idx); //printf("attribute namespace=%d idx=%d event=%p\n", id, idx, mEventCode); if (kDebugXMLNoisy) { printf("getAttributeNamespace 0x%zx=0x%x\n", idx, id); } return id >= 0 ? mTree.mStrings.string8At(id, outLen) : NULL; } int32_t ResXMLParser::getAttributeNameID(size_t idx) const { if (mEventCode == START_TAG) { const ResXMLTree_attrExt* tag = (const ResXMLTree_attrExt*)mCurExt; if (idx < dtohs(tag->attributeCount)) { const ResXMLTree_attribute* attr = (const ResXMLTree_attribute*) (((const uint8_t*)tag) + dtohs(tag->attributeStart) + (dtohs(tag->attributeSize)*idx)); return dtohl(attr->name.index); } } return -1; } const char16_t* ResXMLParser::getAttributeName(size_t idx, size_t* outLen) const { int32_t id = getAttributeNameID(idx); //printf("attribute name=%d idx=%d event=%p\n", id, idx, mEventCode); if (kDebugXMLNoisy) { printf("getAttributeName 0x%zx=0x%x\n", idx, id); } return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } const char* ResXMLParser::getAttributeName8(size_t idx, size_t* outLen) const { int32_t id = getAttributeNameID(idx); //printf("attribute name=%d idx=%d event=%p\n", id, idx, mEventCode); if (kDebugXMLNoisy) { printf("getAttributeName 0x%zx=0x%x\n", idx, id); } return id >= 0 ? mTree.mStrings.string8At(id, outLen) : NULL; } uint32_t ResXMLParser::getAttributeNameResID(size_t idx) const { int32_t id = getAttributeNameID(idx); if (id >= 0 && (size_t)id < mTree.mNumResIds) { uint32_t resId = dtohl(mTree.mResIds[id]); if (mTree.mDynamicRefTable != NULL) { mTree.mDynamicRefTable->lookupResourceId(&resId); } return resId; } return 0; } int32_t ResXMLParser::getAttributeValueStringID(size_t idx) const { if (mEventCode == START_TAG) { const ResXMLTree_attrExt* tag = (const ResXMLTree_attrExt*)mCurExt; if (idx < dtohs(tag->attributeCount)) { const ResXMLTree_attribute* attr = (const ResXMLTree_attribute*) (((const uint8_t*)tag) + dtohs(tag->attributeStart) + (dtohs(tag->attributeSize)*idx)); return dtohl(attr->rawValue.index); } } return -1; } const char16_t* ResXMLParser::getAttributeStringValue(size_t idx, size_t* outLen) const { int32_t id = getAttributeValueStringID(idx); if (kDebugXMLNoisy) { printf("getAttributeValue 0x%zx=0x%x\n", idx, id); } return id >= 0 ? mTree.mStrings.stringAt(id, outLen) : NULL; } int32_t ResXMLParser::getAttributeDataType(size_t idx) const { if (mEventCode == START_TAG) { const ResXMLTree_attrExt* tag = (const ResXMLTree_attrExt*)mCurExt; if (idx < dtohs(tag->attributeCount)) { const ResXMLTree_attribute* attr = (const ResXMLTree_attribute*) (((const uint8_t*)tag) + dtohs(tag->attributeStart) + (dtohs(tag->attributeSize)*idx)); uint8_t type = attr->typedValue.dataType; if (type != Res_value::TYPE_DYNAMIC_REFERENCE) { return type; } // This is a dynamic reference. We adjust those references // to regular references at this level, so lie to the caller. return Res_value::TYPE_REFERENCE; } } return Res_value::TYPE_NULL; } int32_t ResXMLParser::getAttributeData(size_t idx) const { if (mEventCode == START_TAG) { const ResXMLTree_attrExt* tag = (const ResXMLTree_attrExt*)mCurExt; if (idx < dtohs(tag->attributeCount)) { const ResXMLTree_attribute* attr = (const ResXMLTree_attribute*) (((const uint8_t*)tag) + dtohs(tag->attributeStart) + (dtohs(tag->attributeSize)*idx)); if (attr->typedValue.dataType != Res_value::TYPE_DYNAMIC_REFERENCE || mTree.mDynamicRefTable == NULL) { return dtohl(attr->typedValue.data); } uint32_t data = dtohl(attr->typedValue.data); if (mTree.mDynamicRefTable->lookupResourceId(&data) == NO_ERROR) { return data; } } } return 0; } ssize_t ResXMLParser::getAttributeValue(size_t idx, Res_value* outValue) const { if (mEventCode == START_TAG) { const ResXMLTree_attrExt* tag = (const ResXMLTree_attrExt*)mCurExt; if (idx < dtohs(tag->attributeCount)) { const ResXMLTree_attribute* attr = (const ResXMLTree_attribute*) (((const uint8_t*)tag) + dtohs(tag->attributeStart) + (dtohs(tag->attributeSize)*idx)); outValue->copyFrom_dtoh(attr->typedValue); if (mTree.mDynamicRefTable != NULL && mTree.mDynamicRefTable->lookupResourceValue(outValue) != NO_ERROR) { return BAD_TYPE; } return sizeof(Res_value); } } return BAD_TYPE; } ssize_t ResXMLParser::indexOfAttribute(const char* ns, const char* attr) const { String16 nsStr(ns != NULL ? ns : ""); String16 attrStr(attr); return indexOfAttribute(ns ? nsStr.string() : NULL, ns ? nsStr.size() : 0, attrStr.string(), attrStr.size()); } ssize_t ResXMLParser::indexOfAttribute(const char16_t* ns, size_t nsLen, const char16_t* attr, size_t attrLen) const { if (mEventCode == START_TAG) { if (attr == NULL) { return NAME_NOT_FOUND; } const size_t N = getAttributeCount(); if (mTree.mStrings.isUTF8()) { String8 ns8, attr8; if (ns != NULL) { ns8 = String8(ns, nsLen); } attr8 = String8(attr, attrLen); if (kDebugStringPoolNoisy) { ALOGI("indexOfAttribute UTF8 %s (%zu) / %s (%zu)", ns8.string(), nsLen, attr8.string(), attrLen); } for (size_t i=0; i ns=%s, curNs=%s\n", // String8(ns).string(), String8(curNs).string()); if (memcmp(ns8.string(), curNs, nsLen) == 0) { if (kDebugStringPoolNoisy) { ALOGI(" FOUND!"); } return i; } } } } } else { if (kDebugStringPoolNoisy) { ALOGI("indexOfAttribute UTF16 %s (%zu) / %s (%zu)", String8(ns, nsLen).string(), nsLen, String8(attr, attrLen).string(), attrLen); } for (size_t i=0; i ns=%s, curNs=%s\n", // String8(ns).string(), String8(curNs).string()); if (memcmp(ns, curNs, nsLen*sizeof(char16_t)) == 0) { if (kDebugStringPoolNoisy) { ALOGI(" FOUND!"); } return i; } } } } } } return NAME_NOT_FOUND; } ssize_t ResXMLParser::indexOfID() const { if (mEventCode == START_TAG) { const ssize_t idx = dtohs(((const ResXMLTree_attrExt*)mCurExt)->idIndex); if (idx > 0) return (idx-1); } return NAME_NOT_FOUND; } ssize_t ResXMLParser::indexOfClass() const { if (mEventCode == START_TAG) { const ssize_t idx = dtohs(((const ResXMLTree_attrExt*)mCurExt)->classIndex); if (idx > 0) return (idx-1); } return NAME_NOT_FOUND; } ssize_t ResXMLParser::indexOfStyle() const { if (mEventCode == START_TAG) { const ssize_t idx = dtohs(((const ResXMLTree_attrExt*)mCurExt)->styleIndex); if (idx > 0) return (idx-1); } return NAME_NOT_FOUND; } ResXMLParser::event_code_t ResXMLParser::nextNode() { if (mEventCode < 0) { return mEventCode; } do { const ResXMLTree_node* next = (const ResXMLTree_node*) (((const uint8_t*)mCurNode) + dtohl(mCurNode->header.size)); if (kDebugXMLNoisy) { ALOGI("Next node: prev=%p, next=%p\n", mCurNode, next); } if (((const uint8_t*)next) >= mTree.mDataEnd) { mCurNode = NULL; return (mEventCode=END_DOCUMENT); } if (mTree.validateNode(next) != NO_ERROR) { mCurNode = NULL; return (mEventCode=BAD_DOCUMENT); } mCurNode = next; const uint16_t headerSize = dtohs(next->header.headerSize); const uint32_t totalSize = dtohl(next->header.size); mCurExt = ((const uint8_t*)next) + headerSize; size_t minExtSize = 0; event_code_t eventCode = (event_code_t)dtohs(next->header.type); switch ((mEventCode=eventCode)) { case RES_XML_START_NAMESPACE_TYPE: case RES_XML_END_NAMESPACE_TYPE: minExtSize = sizeof(ResXMLTree_namespaceExt); break; case RES_XML_START_ELEMENT_TYPE: minExtSize = sizeof(ResXMLTree_attrExt); break; case RES_XML_END_ELEMENT_TYPE: minExtSize = sizeof(ResXMLTree_endElementExt); break; case RES_XML_CDATA_TYPE: minExtSize = sizeof(ResXMLTree_cdataExt); break; default: ALOGW("Unknown XML block: header type %d in node at %d\n", (int)dtohs(next->header.type), (int)(((const uint8_t*)next)-((const uint8_t*)mTree.mHeader))); continue; } if ((totalSize-headerSize) < minExtSize) { ALOGW("Bad XML block: header type 0x%x in node at 0x%x has size %d, need %d\n", (int)dtohs(next->header.type), (int)(((const uint8_t*)next)-((const uint8_t*)mTree.mHeader)), (int)(totalSize-headerSize), (int)minExtSize); return (mEventCode=BAD_DOCUMENT); } //printf("CurNode=%p, CurExt=%p, headerSize=%d, minExtSize=%d\n", // mCurNode, mCurExt, headerSize, minExtSize); return eventCode; } while (true); } void ResXMLParser::getPosition(ResXMLParser::ResXMLPosition* pos) const { pos->eventCode = mEventCode; pos->curNode = mCurNode; pos->curExt = mCurExt; } void ResXMLParser::setPosition(const ResXMLParser::ResXMLPosition& pos) { mEventCode = pos.eventCode; mCurNode = pos.curNode; mCurExt = pos.curExt; } // -------------------------------------------------------------------- static volatile int32_t gCount = 0; ResXMLTree::ResXMLTree(const DynamicRefTable* dynamicRefTable) : ResXMLParser(*this) , mDynamicRefTable(dynamicRefTable) , mError(NO_INIT), mOwnedData(NULL) { if (kDebugResXMLTree) { ALOGI("Creating ResXMLTree %p #%d\n", this, android_atomic_inc(&gCount)+1); } restart(); } ResXMLTree::ResXMLTree() : ResXMLParser(*this) , mDynamicRefTable(NULL) , mError(NO_INIT), mOwnedData(NULL) { if (kDebugResXMLTree) { ALOGI("Creating ResXMLTree %p #%d\n", this, android_atomic_inc(&gCount)+1); } restart(); } ResXMLTree::~ResXMLTree() { if (kDebugResXMLTree) { ALOGI("Destroying ResXMLTree in %p #%d\n", this, android_atomic_dec(&gCount)-1); } uninit(); } status_t ResXMLTree::setTo(const void* data, size_t size, bool copyData) { uninit(); mEventCode = START_DOCUMENT; if (!data || !size) { return (mError=BAD_TYPE); } if (copyData) { mOwnedData = malloc(size); if (mOwnedData == NULL) { return (mError=NO_MEMORY); } memcpy(mOwnedData, data, size); data = mOwnedData; } mHeader = (const ResXMLTree_header*)data; mSize = dtohl(mHeader->header.size); if (dtohs(mHeader->header.headerSize) > mSize || mSize > size) { ALOGW("Bad XML block: header size %d or total size %d is larger than data size %d\n", (int)dtohs(mHeader->header.headerSize), (int)dtohl(mHeader->header.size), (int)size); mError = BAD_TYPE; restart(); return mError; } mDataEnd = ((const uint8_t*)mHeader) + mSize; mStrings.uninit(); mRootNode = NULL; mResIds = NULL; mNumResIds = 0; // First look for a couple interesting chunks: the string block // and first XML node. const ResChunk_header* chunk = (const ResChunk_header*)(((const uint8_t*)mHeader) + dtohs(mHeader->header.headerSize)); const ResChunk_header* lastChunk = chunk; while (((const uint8_t*)chunk) < (mDataEnd-sizeof(ResChunk_header)) && ((const uint8_t*)chunk) < (mDataEnd-dtohl(chunk->size))) { status_t err = validate_chunk(chunk, sizeof(ResChunk_header), mDataEnd, "XML"); if (err != NO_ERROR) { mError = err; goto done; } const uint16_t type = dtohs(chunk->type); const size_t size = dtohl(chunk->size); if (kDebugXMLNoisy) { printf("Scanning @ %p: type=0x%x, size=0x%zx\n", (void*)(((uintptr_t)chunk)-((uintptr_t)mHeader)), type, size); } if (type == RES_STRING_POOL_TYPE) { mStrings.setTo(chunk, size); } else if (type == RES_XML_RESOURCE_MAP_TYPE) { mResIds = (const uint32_t*) (((const uint8_t*)chunk)+dtohs(chunk->headerSize)); mNumResIds = (dtohl(chunk->size)-dtohs(chunk->headerSize))/sizeof(uint32_t); } else if (type >= RES_XML_FIRST_CHUNK_TYPE && type <= RES_XML_LAST_CHUNK_TYPE) { if (validateNode((const ResXMLTree_node*)chunk) != NO_ERROR) { mError = BAD_TYPE; goto done; } mCurNode = (const ResXMLTree_node*)lastChunk; if (nextNode() == BAD_DOCUMENT) { mError = BAD_TYPE; goto done; } mRootNode = mCurNode; mRootExt = mCurExt; mRootCode = mEventCode; break; } else { if (kDebugXMLNoisy) { printf("Skipping unknown chunk!\n"); } } lastChunk = chunk; chunk = (const ResChunk_header*) (((const uint8_t*)chunk) + size); } if (mRootNode == NULL) { ALOGW("Bad XML block: no root element node found\n"); mError = BAD_TYPE; goto done; } mError = mStrings.getError(); done: restart(); return mError; } status_t ResXMLTree::getError() const { return mError; } void ResXMLTree::uninit() { mError = NO_INIT; mStrings.uninit(); if (mOwnedData) { free(mOwnedData); mOwnedData = NULL; } restart(); } status_t ResXMLTree::validateNode(const ResXMLTree_node* node) const { const uint16_t eventCode = dtohs(node->header.type); status_t err = validate_chunk( &node->header, sizeof(ResXMLTree_node), mDataEnd, "ResXMLTree_node"); if (err >= NO_ERROR) { // Only perform additional validation on START nodes if (eventCode != RES_XML_START_ELEMENT_TYPE) { return NO_ERROR; } const uint16_t headerSize = dtohs(node->header.headerSize); const uint32_t size = dtohl(node->header.size); const ResXMLTree_attrExt* attrExt = (const ResXMLTree_attrExt*) (((const uint8_t*)node) + headerSize); // check for sensical values pulled out of the stream so far... if ((size >= headerSize + sizeof(ResXMLTree_attrExt)) && ((void*)attrExt > (void*)node)) { const size_t attrSize = ((size_t)dtohs(attrExt->attributeSize)) * dtohs(attrExt->attributeCount); if ((dtohs(attrExt->attributeStart)+attrSize) <= (size-headerSize)) { return NO_ERROR; } ALOGW("Bad XML block: node attributes use 0x%x bytes, only have 0x%x bytes\n", (unsigned int)(dtohs(attrExt->attributeStart)+attrSize), (unsigned int)(size-headerSize)); } else { ALOGW("Bad XML start block: node header size 0x%x, size 0x%x\n", (unsigned int)headerSize, (unsigned int)size); } return BAD_TYPE; } return err; #if 0 const bool isStart = dtohs(node->header.type) == RES_XML_START_ELEMENT_TYPE; const uint16_t headerSize = dtohs(node->header.headerSize); const uint32_t size = dtohl(node->header.size); if (headerSize >= (isStart ? sizeof(ResXMLTree_attrNode) : sizeof(ResXMLTree_node))) { if (size >= headerSize) { if (((const uint8_t*)node) <= (mDataEnd-size)) { if (!isStart) { return NO_ERROR; } if ((((size_t)dtohs(node->attributeSize))*dtohs(node->attributeCount)) <= (size-headerSize)) { return NO_ERROR; } ALOGW("Bad XML block: node attributes use 0x%x bytes, only have 0x%x bytes\n", ((int)dtohs(node->attributeSize))*dtohs(node->attributeCount), (int)(size-headerSize)); return BAD_TYPE; } ALOGW("Bad XML block: node at 0x%x extends beyond data end 0x%x\n", (int)(((const uint8_t*)node)-((const uint8_t*)mHeader)), (int)mSize); return BAD_TYPE; } ALOGW("Bad XML block: node at 0x%x header size 0x%x smaller than total size 0x%x\n", (int)(((const uint8_t*)node)-((const uint8_t*)mHeader)), (int)headerSize, (int)size); return BAD_TYPE; } ALOGW("Bad XML block: node at 0x%x header size 0x%x too small\n", (int)(((const uint8_t*)node)-((const uint8_t*)mHeader)), (int)headerSize); return BAD_TYPE; #endif } // -------------------------------------------------------------------- // -------------------------------------------------------------------- // -------------------------------------------------------------------- void ResTable_config::copyFromDeviceNoSwap(const ResTable_config& o) { const size_t size = dtohl(o.size); if (size >= sizeof(ResTable_config)) { *this = o; } else { memcpy(this, &o, size); memset(((uint8_t*)this)+size, 0, sizeof(ResTable_config)-size); } } /* static */ size_t unpackLanguageOrRegion(const char in[2], const char base, char out[4]) { if (in[0] & 0x80) { // The high bit is "1", which means this is a packed three letter // language code. // The smallest 5 bits of the second char are the first alphabet. const uint8_t first = in[1] & 0x1f; // The last three bits of the second char and the first two bits // of the first char are the second alphabet. const uint8_t second = ((in[1] & 0xe0) >> 5) + ((in[0] & 0x03) << 3); // Bits 3 to 7 (inclusive) of the first char are the third alphabet. const uint8_t third = (in[0] & 0x7c) >> 2; out[0] = first + base; out[1] = second + base; out[2] = third + base; out[3] = 0; return 3; } if (in[0]) { memcpy(out, in, 2); memset(out + 2, 0, 2); return 2; } memset(out, 0, 4); return 0; } /* static */ void packLanguageOrRegion(const char* in, const char base, char out[2]) { if (in[2] == 0 || in[2] == '-') { out[0] = in[0]; out[1] = in[1]; } else { uint8_t first = (in[0] - base) & 0x007f; uint8_t second = (in[1] - base) & 0x007f; uint8_t third = (in[2] - base) & 0x007f; out[0] = (0x80 | (third << 2) | (second >> 3)); out[1] = ((second << 5) | first); } } void ResTable_config::packLanguage(const char* language) { packLanguageOrRegion(language, 'a', this->language); } void ResTable_config::packRegion(const char* region) { packLanguageOrRegion(region, '0', this->country); } size_t ResTable_config::unpackLanguage(char language[4]) const { return unpackLanguageOrRegion(this->language, 'a', language); } size_t ResTable_config::unpackRegion(char region[4]) const { return unpackLanguageOrRegion(this->country, '0', region); } void ResTable_config::copyFromDtoH(const ResTable_config& o) { copyFromDeviceNoSwap(o); size = sizeof(ResTable_config); mcc = dtohs(mcc); mnc = dtohs(mnc); density = dtohs(density); screenWidth = dtohs(screenWidth); screenHeight = dtohs(screenHeight); sdkVersion = dtohs(sdkVersion); minorVersion = dtohs(minorVersion); smallestScreenWidthDp = dtohs(smallestScreenWidthDp); screenWidthDp = dtohs(screenWidthDp); screenHeightDp = dtohs(screenHeightDp); } void ResTable_config::swapHtoD() { size = htodl(size); mcc = htods(mcc); mnc = htods(mnc); density = htods(density); screenWidth = htods(screenWidth); screenHeight = htods(screenHeight); sdkVersion = htods(sdkVersion); minorVersion = htods(minorVersion); smallestScreenWidthDp = htods(smallestScreenWidthDp); screenWidthDp = htods(screenWidthDp); screenHeightDp = htods(screenHeightDp); } /* static */ inline int compareLocales(const ResTable_config &l, const ResTable_config &r) { if (l.locale != r.locale) { // NOTE: This is the old behaviour with respect to comparison orders. // The diff value here doesn't make much sense (given our bit packing scheme) // but it's stable, and that's all we need. return l.locale - r.locale; } // The language & region are equal, so compare the scripts and variants. int script = memcmp(l.localeScript, r.localeScript, sizeof(l.localeScript)); if (script) { return script; } // The language, region and script are equal, so compare variants. // // This should happen very infrequently (if at all.) return memcmp(l.localeVariant, r.localeVariant, sizeof(l.localeVariant)); } int ResTable_config::compare(const ResTable_config& o) const { int32_t diff = (int32_t)(imsi - o.imsi); if (diff != 0) return diff; diff = compareLocales(*this, o); if (diff != 0) return diff; diff = (int32_t)(screenType - o.screenType); if (diff != 0) return diff; diff = (int32_t)(input - o.input); if (diff != 0) return diff; diff = (int32_t)(screenSize - o.screenSize); if (diff != 0) return diff; diff = (int32_t)(version - o.version); if (diff != 0) return diff; diff = (int32_t)(screenLayout - o.screenLayout); if (diff != 0) return diff; diff = (int32_t)(screenLayout2 - o.screenLayout2); if (diff != 0) return diff; diff = (int32_t)(uiMode - o.uiMode); if (diff != 0) return diff; diff = (int32_t)(smallestScreenWidthDp - o.smallestScreenWidthDp); if (diff != 0) return diff; diff = (int32_t)(screenSizeDp - o.screenSizeDp); return (int)diff; } int ResTable_config::compareLogical(const ResTable_config& o) const { if (mcc != o.mcc) { return mcc < o.mcc ? -1 : 1; } if (mnc != o.mnc) { return mnc < o.mnc ? -1 : 1; } int diff = compareLocales(*this, o); if (diff < 0) { return -1; } if (diff > 0) { return 1; } if ((screenLayout & MASK_LAYOUTDIR) != (o.screenLayout & MASK_LAYOUTDIR)) { return (screenLayout & MASK_LAYOUTDIR) < (o.screenLayout & MASK_LAYOUTDIR) ? -1 : 1; } if (smallestScreenWidthDp != o.smallestScreenWidthDp) { return smallestScreenWidthDp < o.smallestScreenWidthDp ? -1 : 1; } if (screenWidthDp != o.screenWidthDp) { return screenWidthDp < o.screenWidthDp ? -1 : 1; } if (screenHeightDp != o.screenHeightDp) { return screenHeightDp < o.screenHeightDp ? -1 : 1; } if (screenWidth != o.screenWidth) { return screenWidth < o.screenWidth ? -1 : 1; } if (screenHeight != o.screenHeight) { return screenHeight < o.screenHeight ? -1 : 1; } if (density != o.density) { return density < o.density ? -1 : 1; } if (orientation != o.orientation) { return orientation < o.orientation ? -1 : 1; } if (touchscreen != o.touchscreen) { return touchscreen < o.touchscreen ? -1 : 1; } if (input != o.input) { return input < o.input ? -1 : 1; } if (screenLayout != o.screenLayout) { return screenLayout < o.screenLayout ? -1 : 1; } if (screenLayout2 != o.screenLayout2) { return screenLayout2 < o.screenLayout2 ? -1 : 1; } if (uiMode != o.uiMode) { return uiMode < o.uiMode ? -1 : 1; } if (version != o.version) { return version < o.version ? -1 : 1; } return 0; } int ResTable_config::diff(const ResTable_config& o) const { int diffs = 0; if (mcc != o.mcc) diffs |= CONFIG_MCC; if (mnc != o.mnc) diffs |= CONFIG_MNC; if (orientation != o.orientation) diffs |= CONFIG_ORIENTATION; if (density != o.density) diffs |= CONFIG_DENSITY; if (touchscreen != o.touchscreen) diffs |= CONFIG_TOUCHSCREEN; if (((inputFlags^o.inputFlags)&(MASK_KEYSHIDDEN|MASK_NAVHIDDEN)) != 0) diffs |= CONFIG_KEYBOARD_HIDDEN; if (keyboard != o.keyboard) diffs |= CONFIG_KEYBOARD; if (navigation != o.navigation) diffs |= CONFIG_NAVIGATION; if (screenSize != o.screenSize) diffs |= CONFIG_SCREEN_SIZE; if (version != o.version) diffs |= CONFIG_VERSION; if ((screenLayout & MASK_LAYOUTDIR) != (o.screenLayout & MASK_LAYOUTDIR)) diffs |= CONFIG_LAYOUTDIR; if ((screenLayout & ~MASK_LAYOUTDIR) != (o.screenLayout & ~MASK_LAYOUTDIR)) diffs |= CONFIG_SCREEN_LAYOUT; if ((screenLayout2 & MASK_SCREENROUND) != (o.screenLayout2 & MASK_SCREENROUND)) diffs |= CONFIG_SCREEN_ROUND; if (uiMode != o.uiMode) diffs |= CONFIG_UI_MODE; if (smallestScreenWidthDp != o.smallestScreenWidthDp) diffs |= CONFIG_SMALLEST_SCREEN_SIZE; if (screenSizeDp != o.screenSizeDp) diffs |= CONFIG_SCREEN_SIZE; const int diff = compareLocales(*this, o); if (diff) diffs |= CONFIG_LOCALE; return diffs; } int ResTable_config::isLocaleMoreSpecificThan(const ResTable_config& o) const { if (locale || o.locale) { if (language[0] != o.language[0]) { if (!language[0]) return -1; if (!o.language[0]) return 1; } if (country[0] != o.country[0]) { if (!country[0]) return -1; if (!o.country[0]) return 1; } } // There isn't a well specified "importance" order between variants and // scripts. We can't easily tell whether, say "en-Latn-US" is more or less // specific than "en-US-POSIX". // // We therefore arbitrarily decide to give priority to variants over // scripts since it seems more useful to do so. We will consider // "en-US-POSIX" to be more specific than "en-Latn-US". const int score = ((localeScript[0] != 0) ? 1 : 0) + ((localeVariant[0] != 0) ? 2 : 0); const int oScore = ((o.localeScript[0] != 0) ? 1 : 0) + ((o.localeVariant[0] != 0) ? 2 : 0); return score - oScore; } bool ResTable_config::isMoreSpecificThan(const ResTable_config& o) const { // The order of the following tests defines the importance of one // configuration parameter over another. Those tests first are more // important, trumping any values in those following them. if (imsi || o.imsi) { if (mcc != o.mcc) { if (!mcc) return false; if (!o.mcc) return true; } if (mnc != o.mnc) { if (!mnc) return false; if (!o.mnc) return true; } } if (locale || o.locale) { const int diff = isLocaleMoreSpecificThan(o); if (diff < 0) { return false; } if (diff > 0) { return true; } } if (screenLayout || o.screenLayout) { if (((screenLayout^o.screenLayout) & MASK_LAYOUTDIR) != 0) { if (!(screenLayout & MASK_LAYOUTDIR)) return false; if (!(o.screenLayout & MASK_LAYOUTDIR)) return true; } } if (smallestScreenWidthDp || o.smallestScreenWidthDp) { if (smallestScreenWidthDp != o.smallestScreenWidthDp) { if (!smallestScreenWidthDp) return false; if (!o.smallestScreenWidthDp) return true; } } if (screenSizeDp || o.screenSizeDp) { if (screenWidthDp != o.screenWidthDp) { if (!screenWidthDp) return false; if (!o.screenWidthDp) return true; } if (screenHeightDp != o.screenHeightDp) { if (!screenHeightDp) return false; if (!o.screenHeightDp) return true; } } if (screenLayout || o.screenLayout) { if (((screenLayout^o.screenLayout) & MASK_SCREENSIZE) != 0) { if (!(screenLayout & MASK_SCREENSIZE)) return false; if (!(o.screenLayout & MASK_SCREENSIZE)) return true; } if (((screenLayout^o.screenLayout) & MASK_SCREENLONG) != 0) { if (!(screenLayout & MASK_SCREENLONG)) return false; if (!(o.screenLayout & MASK_SCREENLONG)) return true; } } if (screenLayout2 || o.screenLayout2) { if (((screenLayout2^o.screenLayout2) & MASK_SCREENROUND) != 0) { if (!(screenLayout2 & MASK_SCREENROUND)) return false; if (!(o.screenLayout2 & MASK_SCREENROUND)) return true; } } if (orientation != o.orientation) { if (!orientation) return false; if (!o.orientation) return true; } if (uiMode || o.uiMode) { if (((uiMode^o.uiMode) & MASK_UI_MODE_TYPE) != 0) { if (!(uiMode & MASK_UI_MODE_TYPE)) return false; if (!(o.uiMode & MASK_UI_MODE_TYPE)) return true; } if (((uiMode^o.uiMode) & MASK_UI_MODE_NIGHT) != 0) { if (!(uiMode & MASK_UI_MODE_NIGHT)) return false; if (!(o.uiMode & MASK_UI_MODE_NIGHT)) return true; } } // density is never 'more specific' // as the default just equals 160 if (touchscreen != o.touchscreen) { if (!touchscreen) return false; if (!o.touchscreen) return true; } if (input || o.input) { if (((inputFlags^o.inputFlags) & MASK_KEYSHIDDEN) != 0) { if (!(inputFlags & MASK_KEYSHIDDEN)) return false; if (!(o.inputFlags & MASK_KEYSHIDDEN)) return true; } if (((inputFlags^o.inputFlags) & MASK_NAVHIDDEN) != 0) { if (!(inputFlags & MASK_NAVHIDDEN)) return false; if (!(o.inputFlags & MASK_NAVHIDDEN)) return true; } if (keyboard != o.keyboard) { if (!keyboard) return false; if (!o.keyboard) return true; } if (navigation != o.navigation) { if (!navigation) return false; if (!o.navigation) return true; } } if (screenSize || o.screenSize) { if (screenWidth != o.screenWidth) { if (!screenWidth) return false; if (!o.screenWidth) return true; } if (screenHeight != o.screenHeight) { if (!screenHeight) return false; if (!o.screenHeight) return true; } } if (version || o.version) { if (sdkVersion != o.sdkVersion) { if (!sdkVersion) return false; if (!o.sdkVersion) return true; } if (minorVersion != o.minorVersion) { if (!minorVersion) return false; if (!o.minorVersion) return true; } } return false; } bool ResTable_config::isBetterThan(const ResTable_config& o, const ResTable_config* requested) const { if (requested) { if (imsi || o.imsi) { if ((mcc != o.mcc) && requested->mcc) { return (mcc); } if ((mnc != o.mnc) && requested->mnc) { return (mnc); } } if (locale || o.locale) { if ((language[0] != o.language[0]) && requested->language[0]) { return (language[0]); } if ((country[0] != o.country[0]) && requested->country[0]) { return (country[0]); } } if (localeScript[0] || o.localeScript[0]) { if (localeScript[0] != o.localeScript[0] && requested->localeScript[0]) { return localeScript[0]; } } if (localeVariant[0] || o.localeVariant[0]) { if (localeVariant[0] != o.localeVariant[0] && requested->localeVariant[0]) { return localeVariant[0]; } } if (screenLayout || o.screenLayout) { if (((screenLayout^o.screenLayout) & MASK_LAYOUTDIR) != 0 && (requested->screenLayout & MASK_LAYOUTDIR)) { int myLayoutDir = screenLayout & MASK_LAYOUTDIR; int oLayoutDir = o.screenLayout & MASK_LAYOUTDIR; return (myLayoutDir > oLayoutDir); } } if (smallestScreenWidthDp || o.smallestScreenWidthDp) { // The configuration closest to the actual size is best. // We assume that larger configs have already been filtered // out at this point. That means we just want the largest one. if (smallestScreenWidthDp != o.smallestScreenWidthDp) { return smallestScreenWidthDp > o.smallestScreenWidthDp; } } if (screenSizeDp || o.screenSizeDp) { // "Better" is based on the sum of the difference between both // width and height from the requested dimensions. We are // assuming the invalid configs (with smaller dimens) have // already been filtered. Note that if a particular dimension // is unspecified, we will end up with a large value (the // difference between 0 and the requested dimension), which is // good since we will prefer a config that has specified a // dimension value. int myDelta = 0, otherDelta = 0; if (requested->screenWidthDp) { myDelta += requested->screenWidthDp - screenWidthDp; otherDelta += requested->screenWidthDp - o.screenWidthDp; } if (requested->screenHeightDp) { myDelta += requested->screenHeightDp - screenHeightDp; otherDelta += requested->screenHeightDp - o.screenHeightDp; } if (kDebugTableSuperNoisy) { ALOGI("Comparing this %dx%d to other %dx%d in %dx%d: myDelta=%d otherDelta=%d", screenWidthDp, screenHeightDp, o.screenWidthDp, o.screenHeightDp, requested->screenWidthDp, requested->screenHeightDp, myDelta, otherDelta); } if (myDelta != otherDelta) { return myDelta < otherDelta; } } if (screenLayout || o.screenLayout) { if (((screenLayout^o.screenLayout) & MASK_SCREENSIZE) != 0 && (requested->screenLayout & MASK_SCREENSIZE)) { // A little backwards compatibility here: undefined is // considered equivalent to normal. But only if the // requested size is at least normal; otherwise, small // is better than the default. int mySL = (screenLayout & MASK_SCREENSIZE); int oSL = (o.screenLayout & MASK_SCREENSIZE); int fixedMySL = mySL; int fixedOSL = oSL; if ((requested->screenLayout & MASK_SCREENSIZE) >= SCREENSIZE_NORMAL) { if (fixedMySL == 0) fixedMySL = SCREENSIZE_NORMAL; if (fixedOSL == 0) fixedOSL = SCREENSIZE_NORMAL; } // For screen size, the best match is the one that is // closest to the requested screen size, but not over // (the not over part is dealt with in match() below). if (fixedMySL == fixedOSL) { // If the two are the same, but 'this' is actually // undefined, then the other is really a better match. if (mySL == 0) return false; return true; } if (fixedMySL != fixedOSL) { return fixedMySL > fixedOSL; } } if (((screenLayout^o.screenLayout) & MASK_SCREENLONG) != 0 && (requested->screenLayout & MASK_SCREENLONG)) { return (screenLayout & MASK_SCREENLONG); } } if (screenLayout2 || o.screenLayout2) { if (((screenLayout2^o.screenLayout2) & MASK_SCREENROUND) != 0 && (requested->screenLayout2 & MASK_SCREENROUND)) { return screenLayout2 & MASK_SCREENROUND; } } if ((orientation != o.orientation) && requested->orientation) { return (orientation); } if (uiMode || o.uiMode) { if (((uiMode^o.uiMode) & MASK_UI_MODE_TYPE) != 0 && (requested->uiMode & MASK_UI_MODE_TYPE)) { return (uiMode & MASK_UI_MODE_TYPE); } if (((uiMode^o.uiMode) & MASK_UI_MODE_NIGHT) != 0 && (requested->uiMode & MASK_UI_MODE_NIGHT)) { return (uiMode & MASK_UI_MODE_NIGHT); } } if (screenType || o.screenType) { if (density != o.density) { // Use the system default density (DENSITY_MEDIUM, 160dpi) if none specified. const int thisDensity = density ? density : int(ResTable_config::DENSITY_MEDIUM); const int otherDensity = o.density ? o.density : int(ResTable_config::DENSITY_MEDIUM); // We always prefer DENSITY_ANY over scaling a density bucket. if (thisDensity == ResTable_config::DENSITY_ANY) { return true; } else if (otherDensity == ResTable_config::DENSITY_ANY) { return false; } int requestedDensity = requested->density; if (requested->density == 0 || requested->density == ResTable_config::DENSITY_ANY) { requestedDensity = ResTable_config::DENSITY_MEDIUM; } // DENSITY_ANY is now dealt with. We should look to // pick a density bucket and potentially scale it. // Any density is potentially useful // because the system will scale it. Scaling down // is generally better than scaling up. int h = thisDensity; int l = otherDensity; bool bImBigger = true; if (l > h) { int t = h; h = l; l = t; bImBigger = false; } if (requestedDensity >= h) { // requested value higher than both l and h, give h return bImBigger; } if (l >= requestedDensity) { // requested value lower than both l and h, give l return !bImBigger; } // saying that scaling down is 2x better than up if (((2 * l) - requestedDensity) * h > requestedDensity * requestedDensity) { return !bImBigger; } else { return bImBigger; } } if ((touchscreen != o.touchscreen) && requested->touchscreen) { return (touchscreen); } } if (input || o.input) { const int keysHidden = inputFlags & MASK_KEYSHIDDEN; const int oKeysHidden = o.inputFlags & MASK_KEYSHIDDEN; if (keysHidden != oKeysHidden) { const int reqKeysHidden = requested->inputFlags & MASK_KEYSHIDDEN; if (reqKeysHidden) { if (!keysHidden) return false; if (!oKeysHidden) return true; // For compatibility, we count KEYSHIDDEN_NO as being // the same as KEYSHIDDEN_SOFT. Here we disambiguate // these by making an exact match more specific. if (reqKeysHidden == keysHidden) return true; if (reqKeysHidden == oKeysHidden) return false; } } const int navHidden = inputFlags & MASK_NAVHIDDEN; const int oNavHidden = o.inputFlags & MASK_NAVHIDDEN; if (navHidden != oNavHidden) { const int reqNavHidden = requested->inputFlags & MASK_NAVHIDDEN; if (reqNavHidden) { if (!navHidden) return false; if (!oNavHidden) return true; } } if ((keyboard != o.keyboard) && requested->keyboard) { return (keyboard); } if ((navigation != o.navigation) && requested->navigation) { return (navigation); } } if (screenSize || o.screenSize) { // "Better" is based on the sum of the difference between both // width and height from the requested dimensions. We are // assuming the invalid configs (with smaller sizes) have // already been filtered. Note that if a particular dimension // is unspecified, we will end up with a large value (the // difference between 0 and the requested dimension), which is // good since we will prefer a config that has specified a // size value. int myDelta = 0, otherDelta = 0; if (requested->screenWidth) { myDelta += requested->screenWidth - screenWidth; otherDelta += requested->screenWidth - o.screenWidth; } if (requested->screenHeight) { myDelta += requested->screenHeight - screenHeight; otherDelta += requested->screenHeight - o.screenHeight; } if (myDelta != otherDelta) { return myDelta < otherDelta; } } if (version || o.version) { if ((sdkVersion != o.sdkVersion) && requested->sdkVersion) { return (sdkVersion > o.sdkVersion); } if ((minorVersion != o.minorVersion) && requested->minorVersion) { return (minorVersion); } } return false; } return isMoreSpecificThan(o); } bool ResTable_config::match(const ResTable_config& settings) const { if (imsi != 0) { if (mcc != 0 && mcc != settings.mcc) { return false; } if (mnc != 0 && mnc != settings.mnc) { return false; } } if (locale != 0) { // Don't consider the script & variants when deciding matches. // // If we two configs differ only in their script or language, they // can be weeded out in the isMoreSpecificThan test. if (language[0] != 0 && (language[0] != settings.language[0] || language[1] != settings.language[1])) { return false; } if (country[0] != 0 && (country[0] != settings.country[0] || country[1] != settings.country[1])) { return false; } } if (screenConfig != 0) { const int layoutDir = screenLayout&MASK_LAYOUTDIR; const int setLayoutDir = settings.screenLayout&MASK_LAYOUTDIR; if (layoutDir != 0 && layoutDir != setLayoutDir) { return false; } const int screenSize = screenLayout&MASK_SCREENSIZE; const int setScreenSize = settings.screenLayout&MASK_SCREENSIZE; // Any screen sizes for larger screens than the setting do not // match. if (screenSize != 0 && screenSize > setScreenSize) { return false; } const int screenLong = screenLayout&MASK_SCREENLONG; const int setScreenLong = settings.screenLayout&MASK_SCREENLONG; if (screenLong != 0 && screenLong != setScreenLong) { return false; } const int uiModeType = uiMode&MASK_UI_MODE_TYPE; const int setUiModeType = settings.uiMode&MASK_UI_MODE_TYPE; if (uiModeType != 0 && uiModeType != setUiModeType) { return false; } const int uiModeNight = uiMode&MASK_UI_MODE_NIGHT; const int setUiModeNight = settings.uiMode&MASK_UI_MODE_NIGHT; if (uiModeNight != 0 && uiModeNight != setUiModeNight) { return false; } if (smallestScreenWidthDp != 0 && smallestScreenWidthDp > settings.smallestScreenWidthDp) { return false; } } if (screenConfig2 != 0) { const int screenRound = screenLayout2 & MASK_SCREENROUND; const int setScreenRound = settings.screenLayout2 & MASK_SCREENROUND; if (screenRound != 0 && screenRound != setScreenRound) { return false; } } if (screenSizeDp != 0) { if (screenWidthDp != 0 && screenWidthDp > settings.screenWidthDp) { if (kDebugTableSuperNoisy) { ALOGI("Filtering out width %d in requested %d", screenWidthDp, settings.screenWidthDp); } return false; } if (screenHeightDp != 0 && screenHeightDp > settings.screenHeightDp) { if (kDebugTableSuperNoisy) { ALOGI("Filtering out height %d in requested %d", screenHeightDp, settings.screenHeightDp); } return false; } } if (screenType != 0) { if (orientation != 0 && orientation != settings.orientation) { return false; } // density always matches - we can scale it. See isBetterThan if (touchscreen != 0 && touchscreen != settings.touchscreen) { return false; } } if (input != 0) { const int keysHidden = inputFlags&MASK_KEYSHIDDEN; const int setKeysHidden = settings.inputFlags&MASK_KEYSHIDDEN; if (keysHidden != 0 && keysHidden != setKeysHidden) { // For compatibility, we count a request for KEYSHIDDEN_NO as also // matching the more recent KEYSHIDDEN_SOFT. Basically // KEYSHIDDEN_NO means there is some kind of keyboard available. if (kDebugTableSuperNoisy) { ALOGI("Matching keysHidden: have=%d, config=%d\n", keysHidden, setKeysHidden); } if (keysHidden != KEYSHIDDEN_NO || setKeysHidden != KEYSHIDDEN_SOFT) { if (kDebugTableSuperNoisy) { ALOGI("No match!"); } return false; } } const int navHidden = inputFlags&MASK_NAVHIDDEN; const int setNavHidden = settings.inputFlags&MASK_NAVHIDDEN; if (navHidden != 0 && navHidden != setNavHidden) { return false; } if (keyboard != 0 && keyboard != settings.keyboard) { return false; } if (navigation != 0 && navigation != settings.navigation) { return false; } } if (screenSize != 0) { if (screenWidth != 0 && screenWidth > settings.screenWidth) { return false; } if (screenHeight != 0 && screenHeight > settings.screenHeight) { return false; } } if (version != 0) { if (sdkVersion != 0 && sdkVersion > settings.sdkVersion) { return false; } if (minorVersion != 0 && minorVersion != settings.minorVersion) { return false; } } return true; } void ResTable_config::appendDirLocale(String8& out) const { if (!language[0]) { return; } if (!localeScript[0] && !localeVariant[0]) { // Legacy format. if (out.size() > 0) { out.append("-"); } char buf[4]; size_t len = unpackLanguage(buf); out.append(buf, len); if (country[0]) { out.append("-r"); len = unpackRegion(buf); out.append(buf, len); } return; } // We are writing the modified bcp47 tag. // It starts with 'b+' and uses '+' as a separator. if (out.size() > 0) { out.append("-"); } out.append("b+"); char buf[4]; size_t len = unpackLanguage(buf); out.append(buf, len); if (localeScript[0]) { out.append("+"); out.append(localeScript, sizeof(localeScript)); } if (country[0]) { out.append("+"); len = unpackRegion(buf); out.append(buf, len); } if (localeVariant[0]) { out.append("+"); out.append(localeVariant, sizeof(localeVariant)); } } void ResTable_config::getBcp47Locale(char str[RESTABLE_MAX_LOCALE_LEN]) const { memset(str, 0, RESTABLE_MAX_LOCALE_LEN); // This represents the "any" locale value, which has traditionally been // represented by the empty string. if (!language[0] && !country[0]) { return; } size_t charsWritten = 0; if (language[0]) { charsWritten += unpackLanguage(str); } if (localeScript[0]) { if (charsWritten) { str[charsWritten++] = '-'; } memcpy(str + charsWritten, localeScript, sizeof(localeScript)); charsWritten += sizeof(localeScript); } if (country[0]) { if (charsWritten) { str[charsWritten++] = '-'; } charsWritten += unpackRegion(str + charsWritten); } if (localeVariant[0]) { if (charsWritten) { str[charsWritten++] = '-'; } memcpy(str + charsWritten, localeVariant, sizeof(localeVariant)); } } /* static */ inline bool assignLocaleComponent(ResTable_config* config, const char* start, size_t size) { switch (size) { case 0: return false; case 2: case 3: config->language[0] ? config->packRegion(start) : config->packLanguage(start); break; case 4: config->localeScript[0] = toupper(start[0]); for (size_t i = 1; i < 4; ++i) { config->localeScript[i] = tolower(start[i]); } break; case 5: case 6: case 7: case 8: for (size_t i = 0; i < size; ++i) { config->localeVariant[i] = tolower(start[i]); } break; default: return false; } return true; } void ResTable_config::setBcp47Locale(const char* in) { locale = 0; memset(localeScript, 0, sizeof(localeScript)); memset(localeVariant, 0, sizeof(localeVariant)); const char* separator = in; const char* start = in; while ((separator = strchr(start, '-')) != NULL) { const size_t size = separator - start; if (!assignLocaleComponent(this, start, size)) { fprintf(stderr, "Invalid BCP-47 locale string: %s", in); } start = (separator + 1); } const size_t size = in + strlen(in) - start; assignLocaleComponent(this, start, size); } String8 ResTable_config::toString() const { String8 res; if (mcc != 0) { if (res.size() > 0) res.append("-"); res.appendFormat("mcc%d", dtohs(mcc)); } if (mnc != 0) { if (res.size() > 0) res.append("-"); res.appendFormat("mnc%d", dtohs(mnc)); } appendDirLocale(res); if ((screenLayout&MASK_LAYOUTDIR) != 0) { if (res.size() > 0) res.append("-"); switch (screenLayout&ResTable_config::MASK_LAYOUTDIR) { case ResTable_config::LAYOUTDIR_LTR: res.append("ldltr"); break; case ResTable_config::LAYOUTDIR_RTL: res.append("ldrtl"); break; default: res.appendFormat("layoutDir=%d", dtohs(screenLayout&ResTable_config::MASK_LAYOUTDIR)); break; } } if (smallestScreenWidthDp != 0) { if (res.size() > 0) res.append("-"); res.appendFormat("sw%ddp", dtohs(smallestScreenWidthDp)); } if (screenWidthDp != 0) { if (res.size() > 0) res.append("-"); res.appendFormat("w%ddp", dtohs(screenWidthDp)); } if (screenHeightDp != 0) { if (res.size() > 0) res.append("-"); res.appendFormat("h%ddp", dtohs(screenHeightDp)); } if ((screenLayout&MASK_SCREENSIZE) != SCREENSIZE_ANY) { if (res.size() > 0) res.append("-"); switch (screenLayout&ResTable_config::MASK_SCREENSIZE) { case ResTable_config::SCREENSIZE_SMALL: res.append("small"); break; case ResTable_config::SCREENSIZE_NORMAL: res.append("normal"); break; case ResTable_config::SCREENSIZE_LARGE: res.append("large"); break; case ResTable_config::SCREENSIZE_XLARGE: res.append("xlarge"); break; default: res.appendFormat("screenLayoutSize=%d", dtohs(screenLayout&ResTable_config::MASK_SCREENSIZE)); break; } } if ((screenLayout&MASK_SCREENLONG) != 0) { if (res.size() > 0) res.append("-"); switch (screenLayout&ResTable_config::MASK_SCREENLONG) { case ResTable_config::SCREENLONG_NO: res.append("notlong"); break; case ResTable_config::SCREENLONG_YES: res.append("long"); break; default: res.appendFormat("screenLayoutLong=%d", dtohs(screenLayout&ResTable_config::MASK_SCREENLONG)); break; } } if ((screenLayout2&MASK_SCREENROUND) != 0) { if (res.size() > 0) res.append("-"); switch (screenLayout2&MASK_SCREENROUND) { case SCREENROUND_NO: res.append("notround"); break; case SCREENROUND_YES: res.append("round"); break; default: res.appendFormat("screenRound=%d", dtohs(screenLayout2&MASK_SCREENROUND)); break; } } if (orientation != ORIENTATION_ANY) { if (res.size() > 0) res.append("-"); switch (orientation) { case ResTable_config::ORIENTATION_PORT: res.append("port"); break; case ResTable_config::ORIENTATION_LAND: res.append("land"); break; case ResTable_config::ORIENTATION_SQUARE: res.append("square"); break; default: res.appendFormat("orientation=%d", dtohs(orientation)); break; } } if ((uiMode&MASK_UI_MODE_TYPE) != UI_MODE_TYPE_ANY) { if (res.size() > 0) res.append("-"); switch (uiMode&ResTable_config::MASK_UI_MODE_TYPE) { case ResTable_config::UI_MODE_TYPE_DESK: res.append("desk"); break; case ResTable_config::UI_MODE_TYPE_CAR: res.append("car"); break; case ResTable_config::UI_MODE_TYPE_TELEVISION: res.append("television"); break; case ResTable_config::UI_MODE_TYPE_APPLIANCE: res.append("appliance"); break; case ResTable_config::UI_MODE_TYPE_WATCH: res.append("watch"); break; default: res.appendFormat("uiModeType=%d", dtohs(screenLayout&ResTable_config::MASK_UI_MODE_TYPE)); break; } } if ((uiMode&MASK_UI_MODE_NIGHT) != 0) { if (res.size() > 0) res.append("-"); switch (uiMode&ResTable_config::MASK_UI_MODE_NIGHT) { case ResTable_config::UI_MODE_NIGHT_NO: res.append("notnight"); break; case ResTable_config::UI_MODE_NIGHT_YES: res.append("night"); break; default: res.appendFormat("uiModeNight=%d", dtohs(uiMode&MASK_UI_MODE_NIGHT)); break; } } if (density != DENSITY_DEFAULT) { if (res.size() > 0) res.append("-"); switch (density) { case ResTable_config::DENSITY_LOW: res.append("ldpi"); break; case ResTable_config::DENSITY_MEDIUM: res.append("mdpi"); break; case ResTable_config::DENSITY_TV: res.append("tvdpi"); break; case ResTable_config::DENSITY_HIGH: res.append("hdpi"); break; case ResTable_config::DENSITY_XHIGH: res.append("xhdpi"); break; case ResTable_config::DENSITY_XXHIGH: res.append("xxhdpi"); break; case ResTable_config::DENSITY_XXXHIGH: res.append("xxxhdpi"); break; case ResTable_config::DENSITY_NONE: res.append("nodpi"); break; case ResTable_config::DENSITY_ANY: res.append("anydpi"); break; default: res.appendFormat("%ddpi", dtohs(density)); break; } } if (touchscreen != TOUCHSCREEN_ANY) { if (res.size() > 0) res.append("-"); switch (touchscreen) { case ResTable_config::TOUCHSCREEN_NOTOUCH: res.append("notouch"); break; case ResTable_config::TOUCHSCREEN_FINGER: res.append("finger"); break; case ResTable_config::TOUCHSCREEN_STYLUS: res.append("stylus"); break; default: res.appendFormat("touchscreen=%d", dtohs(touchscreen)); break; } } if ((inputFlags&MASK_KEYSHIDDEN) != 0) { if (res.size() > 0) res.append("-"); switch (inputFlags&MASK_KEYSHIDDEN) { case ResTable_config::KEYSHIDDEN_NO: res.append("keysexposed"); break; case ResTable_config::KEYSHIDDEN_YES: res.append("keyshidden"); break; case ResTable_config::KEYSHIDDEN_SOFT: res.append("keyssoft"); break; } } if (keyboard != KEYBOARD_ANY) { if (res.size() > 0) res.append("-"); switch (keyboard) { case ResTable_config::KEYBOARD_NOKEYS: res.append("nokeys"); break; case ResTable_config::KEYBOARD_QWERTY: res.append("qwerty"); break; case ResTable_config::KEYBOARD_12KEY: res.append("12key"); break; default: res.appendFormat("keyboard=%d", dtohs(keyboard)); break; } } if ((inputFlags&MASK_NAVHIDDEN) != 0) { if (res.size() > 0) res.append("-"); switch (inputFlags&MASK_NAVHIDDEN) { case ResTable_config::NAVHIDDEN_NO: res.append("navexposed"); break; case ResTable_config::NAVHIDDEN_YES: res.append("navhidden"); break; default: res.appendFormat("inputFlagsNavHidden=%d", dtohs(inputFlags&MASK_NAVHIDDEN)); break; } } if (navigation != NAVIGATION_ANY) { if (res.size() > 0) res.append("-"); switch (navigation) { case ResTable_config::NAVIGATION_NONAV: res.append("nonav"); break; case ResTable_config::NAVIGATION_DPAD: res.append("dpad"); break; case ResTable_config::NAVIGATION_TRACKBALL: res.append("trackball"); break; case ResTable_config::NAVIGATION_WHEEL: res.append("wheel"); break; default: res.appendFormat("navigation=%d", dtohs(navigation)); break; } } if (screenSize != 0) { if (res.size() > 0) res.append("-"); res.appendFormat("%dx%d", dtohs(screenWidth), dtohs(screenHeight)); } if (version != 0) { if (res.size() > 0) res.append("-"); res.appendFormat("v%d", dtohs(sdkVersion)); if (minorVersion != 0) { res.appendFormat(".%d", dtohs(minorVersion)); } } return res; } // -------------------------------------------------------------------- // -------------------------------------------------------------------- // -------------------------------------------------------------------- struct ResTable::Header { Header(ResTable* _owner) : owner(_owner), ownedData(NULL), header(NULL), resourceIDMap(NULL), resourceIDMapSize(0) { } ~Header() { free(resourceIDMap); } const ResTable* const owner; void* ownedData; const ResTable_header* header; size_t size; const uint8_t* dataEnd; size_t index; int32_t cookie; ResStringPool values; uint32_t* resourceIDMap; size_t resourceIDMapSize; }; struct ResTable::Entry { ResTable_config config; const ResTable_entry* entry; const ResTable_type* type; uint32_t specFlags; const Package* package; StringPoolRef typeStr; StringPoolRef keyStr; bool isFromOverlay; }; struct ResTable::Type { Type(const Header* _header, const Package* _package, size_t count) : header(_header), package(_package), entryCount(count), typeSpec(NULL), typeSpecFlags(NULL) { } const Header* const header; const Package* const package; const size_t entryCount; const ResTable_typeSpec* typeSpec; const uint32_t* typeSpecFlags; IdmapEntries idmapEntries; Vector configs; }; struct ResTable::Package { Package(ResTable* _owner, const Header* _header, const ResTable_package* _package) : owner(_owner), header(_header), package(_package), typeIdOffset(0), pkgIdOverride(0) { if (dtohs(package->header.headerSize) == sizeof(package)) { // The package structure is the same size as the definition. // This means it contains the typeIdOffset field. typeIdOffset = package->typeIdOffset; } } const ResTable* const owner; const Header* const header; const ResTable_package* const package; ResStringPool typeStrings; ResStringPool keyStrings; size_t typeIdOffset; uint32_t pkgIdOverride; }; // A group of objects describing a particular resource package. // The first in 'package' is always the root object (from the resource // table that defined the package); the ones after are skins on top of it. struct ResTable::PackageGroup { PackageGroup(ResTable* _owner, const String16& _name, uint32_t _id) : owner(_owner) , name(_name) , id(_id) , largestTypeId(0) , bags(NULL) , dynamicRefTable(static_cast(_id)) , overlayPackage(NULL) { } ~PackageGroup() { clearBagCache(); const size_t numTypes = types.size(); for (size_t i = 0; i < numTypes; i++) { const TypeList& typeList = types[i]; const size_t numInnerTypes = typeList.size(); for (size_t j = 0; j < numInnerTypes; j++) { if (typeList[j]->package->owner == owner) { delete typeList[j]; } } } const size_t N = packages.size(); for (size_t i=0; iowner == owner) { delete pkg; } } } void clearBagCache() { if (bags) { if (kDebugTableNoisy) { printf("bags=%p\n", bags); } for (size_t i = 0; i < bags->size(); i++) { if (kDebugTableNoisy) { printf("type=%zu\n", i); } const TypeList& typeList = types[i]; if (!typeList.isEmpty()) { bag_set** typeBags = bags->get(i); if (kDebugTableNoisy) { printf("typeBags=%p\n", typeBags); } if (typeBags) { const size_t N = typeList[0]->entryCount; if (kDebugTableNoisy) { printf("type->entryCount=%zu\n", N); } for (size_t j = 0; j < N; j++) { if (typeBags[j] && typeBags[j] != (bag_set*)0xFFFFFFFF) free(typeBags[j]); } free(typeBags); } } } delete bags; bags = NULL; } } ssize_t findType16(const char16_t* type, size_t len) const { const size_t N = packages.size(); for (size_t i = 0; i < N; i++) { ssize_t index = packages[i]->typeStrings.indexOfString(type, len); if (index >= 0) { return index + packages[i]->typeIdOffset; } } return -1; } const ResTable* const owner; String16 const name; uint32_t const id; // This is mainly used to keep track of the loaded packages // and to clean them up properly. Accessing resources happens from // the 'types' array. Vector packages; ByteBucketArray types; uint8_t largestTypeId; // Computed attribute bags, first indexed by the type and second // by the entry in that type. ByteBucketArray* bags; // The table mapping dynamic references to resolved references for // this package group. // TODO: We may be able to support dynamic references in overlays // by having these tables in a per-package scope rather than // per-package-group. DynamicRefTable dynamicRefTable; Package* overlayPackage; }; struct ResTable::bag_set { size_t numAttrs; // number in array size_t availAttrs; // total space in array uint32_t typeSpecFlags; // Followed by 'numAttr' bag_entry structures. }; ResTable::Theme::Theme(const ResTable& table) : mTable(table) , mTypeSpecFlags(0) { memset(mPackages, 0, sizeof(mPackages)); } ResTable::Theme::~Theme() { for (size_t i=0; itypes[j].entries; if (te != NULL) { free(te); } } free(pi); } ResTable::Theme::package_info* ResTable::Theme::copy_package(package_info* pi) { package_info* newpi = (package_info*)malloc(sizeof(package_info)); for (size_t j = 0; j <= Res_MAXTYPE; j++) { size_t cnt = pi->types[j].numEntries; newpi->types[j].numEntries = cnt; theme_entry* te = pi->types[j].entries; size_t cnt_max = SIZE_MAX / sizeof(theme_entry); if (te != NULL && (cnt < 0xFFFFFFFF-1) && (cnt < cnt_max)) { theme_entry* newte = (theme_entry*)malloc(cnt*sizeof(theme_entry)); newpi->types[j].entries = newte; memcpy(newte, te, cnt*sizeof(theme_entry)); } else { newpi->types[j].entries = NULL; } } return newpi; } status_t ResTable::Theme::applyStyle(uint32_t resID, bool force) { const bag_entry* bag; uint32_t bagTypeSpecFlags = 0; mTable.lock(); const ssize_t N = mTable.getBagLocked(resID, &bag, &bagTypeSpecFlags); if (kDebugTableNoisy) { ALOGV("Applying style 0x%08x to theme %p, count=%zu", resID, this, N); } if (N < 0) { mTable.unlock(); return N; } mTypeSpecFlags |= bagTypeSpecFlags; uint32_t curPackage = 0xffffffff; ssize_t curPackageIndex = 0; package_info* curPI = NULL; uint32_t curType = 0xffffffff; size_t numEntries = 0; theme_entry* curEntries = NULL; const bag_entry* end = bag + N; while (bag < end) { const uint32_t attrRes = bag->map.name.ident; const uint32_t p = Res_GETPACKAGE(attrRes); const uint32_t t = Res_GETTYPE(attrRes); const uint32_t e = Res_GETENTRY(attrRes); if (curPackage != p) { const ssize_t pidx = mTable.getResourcePackageIndex(attrRes); if (pidx < 0) { ALOGE("Style contains key with bad package: 0x%08x\n", attrRes); bag++; continue; } curPackage = p; curPackageIndex = pidx; curPI = mPackages[pidx]; if (curPI == NULL) { curPI = (package_info*)malloc(sizeof(package_info)); memset(curPI, 0, sizeof(*curPI)); mPackages[pidx] = curPI; } curType = 0xffffffff; } if (curType != t) { if (t > Res_MAXTYPE) { ALOGE("Style contains key with bad type: 0x%08x\n", attrRes); bag++; continue; } curType = t; curEntries = curPI->types[t].entries; if (curEntries == NULL) { PackageGroup* const grp = mTable.mPackageGroups[curPackageIndex]; const TypeList& typeList = grp->types[t]; size_t cnt = typeList.isEmpty() ? 0 : typeList[0]->entryCount; size_t cnt_max = SIZE_MAX / sizeof(theme_entry); size_t buff_size = (cnt < cnt_max && cnt < 0xFFFFFFFF-1) ? cnt*sizeof(theme_entry) : 0; curEntries = (theme_entry*)malloc(buff_size); memset(curEntries, Res_value::TYPE_NULL, buff_size); curPI->types[t].numEntries = cnt; curPI->types[t].entries = curEntries; } numEntries = curPI->types[t].numEntries; } if (e >= numEntries) { ALOGE("Style contains key with bad entry: 0x%08x\n", attrRes); bag++; continue; } theme_entry* curEntry = curEntries + e; if (kDebugTableNoisy) { ALOGV("Attr 0x%08x: type=0x%x, data=0x%08x; curType=0x%x", attrRes, bag->map.value.dataType, bag->map.value.data, curEntry->value.dataType); } if (force || curEntry->value.dataType == Res_value::TYPE_NULL) { curEntry->stringBlock = bag->stringBlock; curEntry->typeSpecFlags |= bagTypeSpecFlags; curEntry->value = bag->map.value; } bag++; } mTable.unlock(); if (kDebugTableTheme) { ALOGI("Applying style 0x%08x (force=%d) theme %p...\n", resID, force, this); dumpToLog(); } return NO_ERROR; } status_t ResTable::Theme::setTo(const Theme& other) { if (kDebugTableTheme) { ALOGI("Setting theme %p from theme %p...\n", this, &other); dumpToLog(); other.dumpToLog(); } if (&mTable == &other.mTable) { for (size_t i=0; i= 0) { const package_info* const pi = mPackages[p]; if (kDebugTableTheme) { ALOGI("Found package: %p", pi); } if (pi != NULL) { if (kDebugTableTheme) { ALOGI("Desired type index is %zd in avail %zu", t, Res_MAXTYPE + 1); } if (t <= Res_MAXTYPE) { const type_info& ti = pi->types[t]; if (kDebugTableTheme) { ALOGI("Desired entry index is %u in avail %zu", e, ti.numEntries); } if (e < ti.numEntries) { const theme_entry& te = ti.entries[e]; if (outTypeSpecFlags != NULL) { *outTypeSpecFlags |= te.typeSpecFlags; } if (kDebugTableTheme) { ALOGI("Theme value: type=0x%x, data=0x%08x", te.value.dataType, te.value.data); } const uint8_t type = te.value.dataType; if (type == Res_value::TYPE_ATTRIBUTE) { if (cnt > 0) { cnt--; resID = te.value.data; continue; } ALOGW("Too many attribute references, stopped at: 0x%08x\n", resID); return BAD_INDEX; } else if (type != Res_value::TYPE_NULL) { *outValue = te.value; return te.stringBlock; } return BAD_INDEX; } } } } break; } while (true); return BAD_INDEX; } ssize_t ResTable::Theme::resolveAttributeReference(Res_value* inOutValue, ssize_t blockIndex, uint32_t* outLastRef, uint32_t* inoutTypeSpecFlags, ResTable_config* inoutConfig) const { //printf("Resolving type=0x%x\n", inOutValue->dataType); if (inOutValue->dataType == Res_value::TYPE_ATTRIBUTE) { uint32_t newTypeSpecFlags; blockIndex = getAttribute(inOutValue->data, inOutValue, &newTypeSpecFlags); if (kDebugTableTheme) { ALOGI("Resolving attr reference: blockIndex=%d, type=0x%x, data=0x%x\n", (int)blockIndex, (int)inOutValue->dataType, inOutValue->data); } if (inoutTypeSpecFlags != NULL) *inoutTypeSpecFlags |= newTypeSpecFlags; //printf("Retrieved attribute new type=0x%x\n", inOutValue->dataType); if (blockIndex < 0) { return blockIndex; } } return mTable.resolveReference(inOutValue, blockIndex, outLastRef, inoutTypeSpecFlags, inoutConfig); } uint32_t ResTable::Theme::getChangingConfigurations() const { return mTypeSpecFlags; } void ResTable::Theme::dumpToLog() const { ALOGI("Theme %p:\n", this); for (size_t i=0; itypes[j]; if (ti.numEntries == 0) continue; ALOGI(" Type #0x%02x:\n", (int)(j + 1)); for (size_t k = 0; k < ti.numEntries; k++) { const theme_entry& te = ti.entries[k]; if (te.value.dataType == Res_value::TYPE_NULL) continue; ALOGI(" 0x%08x: t=0x%x, d=0x%08x (block=%d)\n", (int)Res_MAKEID(i, j, k), te.value.dataType, (int)te.value.data, (int)te.stringBlock); } } } } ResTable::ResTable() : mError(NO_INIT), mNextPackageId(2) { memset(&mParams, 0, sizeof(mParams)); memset(mPackageMap, 0, sizeof(mPackageMap)); if (kDebugTableSuperNoisy) { ALOGI("Creating ResTable %p\n", this); } } ResTable::ResTable(const void* data, size_t size, const int32_t cookie, bool copyData) : mError(NO_INIT), mNextPackageId(2) { memset(&mParams, 0, sizeof(mParams)); memset(mPackageMap, 0, sizeof(mPackageMap)); addInternal(data, size, NULL, 0, cookie, copyData, 0); LOG_FATAL_IF(mError != NO_ERROR, "Error parsing resource table"); if (kDebugTableSuperNoisy) { ALOGI("Creating ResTable %p\n", this); } } ResTable::~ResTable() { if (kDebugTableSuperNoisy) { ALOGI("Destroying ResTable in %p\n", this); } uninit(); } inline ssize_t ResTable::getResourcePackageIndex(uint32_t resID) const { return ((ssize_t)mPackageMap[Res_GETPACKAGE(resID)+1])-1; } status_t ResTable::add(const void* data, size_t size, const int32_t cookie, bool copyData) { return addInternal(data, size, NULL, 0, cookie, copyData, 0); } status_t ResTable::add(const void* data, size_t size, const void* idmapData, size_t idmapDataSize, const int32_t cookie, bool copyData, const uint32_t pkgIdOverride) { return addInternal(data, size, idmapData, idmapDataSize, cookie, copyData, pkgIdOverride); } status_t ResTable::add(Asset* asset, const int32_t cookie, bool copyData) { const void* data = asset->getBuffer(true); if (data == NULL) { ALOGW("Unable to get buffer of resource asset file"); return UNKNOWN_ERROR; } return addInternal(data, static_cast(asset->getLength()), NULL, 0, cookie, copyData, 0); } status_t ResTable::add(Asset* asset, Asset* idmapAsset, const int32_t cookie, bool copyData, const uint32_t pkgIdOverride) { const void* data = asset->getBuffer(true); if (data == NULL) { ALOGW("Unable to get buffer of resource asset file"); return UNKNOWN_ERROR; } size_t idmapSize = 0; const void* idmapData = NULL; if (idmapAsset != NULL) { idmapData = idmapAsset->getBuffer(true); if (idmapData == NULL) { ALOGW("Unable to get buffer of idmap asset file"); return UNKNOWN_ERROR; } idmapSize = static_cast(idmapAsset->getLength()); } return addInternal(data, static_cast(asset->getLength()), idmapData, idmapSize, cookie, copyData, pkgIdOverride); } status_t ResTable::add(ResTable* src) { mError = src->mError; for (size_t i=0; imHeaders.size(); i++) { mHeaders.add(src->mHeaders[i]); } for (size_t i=0; imPackageGroups.size(); i++) { PackageGroup* srcPg = src->mPackageGroups[i]; PackageGroup* pg = new PackageGroup(this, srcPg->name, srcPg->id); for (size_t j=0; jpackages.size(); j++) { pg->packages.add(srcPg->packages[j]); } for (size_t j = 0; j < srcPg->types.size(); j++) { if (srcPg->types[j].isEmpty()) { continue; } TypeList& typeList = pg->types.editItemAt(j); typeList.appendVector(srcPg->types[j]); } pg->dynamicRefTable.addMappings(srcPg->dynamicRefTable); pg->largestTypeId = max(pg->largestTypeId, srcPg->largestTypeId); mPackageGroups.add(pg); } memcpy(mPackageMap, src->mPackageMap, sizeof(mPackageMap)); return mError; } status_t ResTable::addEmpty(const int32_t cookie) { Header* header = new Header(this); header->index = mHeaders.size(); header->cookie = cookie; header->values.setToEmpty(); header->ownedData = calloc(1, sizeof(ResTable_header)); ResTable_header* resHeader = (ResTable_header*) header->ownedData; resHeader->header.type = RES_TABLE_TYPE; resHeader->header.headerSize = sizeof(ResTable_header); resHeader->header.size = sizeof(ResTable_header); header->header = (const ResTable_header*) resHeader; mHeaders.add(header); return (mError=NO_ERROR); } status_t ResTable::addInternal(const void* data, size_t dataSize, const void* idmapData, size_t idmapDataSize, const int32_t cookie, bool copyData, const uint32_t pkgIdOverride) { if (!data) { return NO_ERROR; } if (dataSize < sizeof(ResTable_header)) { ALOGE("Invalid data. Size(%d) is smaller than a ResTable_header(%d).", (int) dataSize, (int) sizeof(ResTable_header)); return UNKNOWN_ERROR; } Header* header = new Header(this); header->index = mHeaders.size(); header->cookie = cookie; if (idmapData != NULL) { header->resourceIDMap = (uint32_t*) malloc(idmapDataSize); if (header->resourceIDMap == NULL) { delete header; return (mError = NO_MEMORY); } memcpy(header->resourceIDMap, idmapData, idmapDataSize); header->resourceIDMapSize = idmapDataSize; } mHeaders.add(header); const bool notDeviceEndian = htods(0xf0) != 0xf0; if (kDebugLoadTableNoisy) { ALOGV("Adding resources to ResTable: data=%p, size=%zu, cookie=%d, copy=%d " "idmap=%p\n", data, dataSize, cookie, copyData, idmapData); } if (copyData || notDeviceEndian) { header->ownedData = malloc(dataSize); if (header->ownedData == NULL) { return (mError=NO_MEMORY); } memcpy(header->ownedData, data, dataSize); data = header->ownedData; } header->header = (const ResTable_header*)data; header->size = dtohl(header->header->header.size); if (kDebugLoadTableSuperNoisy) { ALOGI("Got size %zu, again size 0x%x, raw size 0x%x\n", header->size, dtohl(header->header->header.size), header->header->header.size); } if (kDebugLoadTableNoisy) { ALOGV("Loading ResTable @%p:\n", header->header); } if (dtohs(header->header->header.headerSize) > header->size || header->size > dataSize) { ALOGW("Bad resource table: header size 0x%x or total size 0x%x is larger than data size 0x%x\n", (int)dtohs(header->header->header.headerSize), (int)header->size, (int)dataSize); return (mError=BAD_TYPE); } if (((dtohs(header->header->header.headerSize)|header->size)&0x3) != 0) { ALOGW("Bad resource table: header size 0x%x or total size 0x%x is not on an integer boundary\n", (int)dtohs(header->header->header.headerSize), (int)header->size); return (mError=BAD_TYPE); } header->dataEnd = ((const uint8_t*)header->header) + header->size; // Iterate through all chunks. size_t curPackage = 0; const ResChunk_header* chunk = (const ResChunk_header*)(((const uint8_t*)header->header) + dtohs(header->header->header.headerSize)); while (((const uint8_t*)chunk) <= (header->dataEnd-sizeof(ResChunk_header)) && ((const uint8_t*)chunk) <= (header->dataEnd-dtohl(chunk->size))) { status_t err = validate_chunk(chunk, sizeof(ResChunk_header), header->dataEnd, "ResTable"); if (err != NO_ERROR) { return (mError=err); } if (kDebugTableNoisy) { ALOGV("Chunk: type=0x%x, headerSize=0x%x, size=0x%x, pos=%p\n", dtohs(chunk->type), dtohs(chunk->headerSize), dtohl(chunk->size), (void*)(((const uint8_t*)chunk) - ((const uint8_t*)header->header))); } const size_t csize = dtohl(chunk->size); const uint16_t ctype = dtohs(chunk->type); if (ctype == RES_STRING_POOL_TYPE) { if (header->values.getError() != NO_ERROR) { // Only use the first string chunk; ignore any others that // may appear. status_t err = header->values.setTo(chunk, csize); if (err != NO_ERROR) { return (mError=err); } } else { ALOGW("Multiple string chunks found in resource table."); } } else if (ctype == RES_TABLE_PACKAGE_TYPE) { if (curPackage >= dtohl(header->header->packageCount)) { ALOGW("More package chunks were found than the %d declared in the header.", dtohl(header->header->packageCount)); return (mError=BAD_TYPE); } // Warning: If the pkg id will be overriden and there is more than one package in the // resource table then the caller should make sure there are enough unique ids above // pkgIdOverride. uint32_t idOverride = (pkgIdOverride == 0) ? 0 : pkgIdOverride + curPackage; if (parsePackage((ResTable_package*)chunk, header, idOverride) != NO_ERROR) { return mError; } curPackage++; } else { ALOGW("Unknown chunk type 0x%x in table at %p.\n", ctype, (void*)(((const uint8_t*)chunk) - ((const uint8_t*)header->header))); } chunk = (const ResChunk_header*) (((const uint8_t*)chunk) + csize); } if (curPackage < dtohl(header->header->packageCount)) { ALOGW("Fewer package chunks (%d) were found than the %d declared in the header.", (int)curPackage, dtohl(header->header->packageCount)); return (mError=BAD_TYPE); } mError = header->values.getError(); if (mError != NO_ERROR) { ALOGW("No string values found in resource table!"); } if (kDebugTableNoisy) { ALOGV("Returning from add with mError=%d\n", mError); } return mError; } status_t ResTable::getError() const { return mError; } void ResTable::uninit() { mError = NO_INIT; size_t N = mPackageGroups.size(); for (size_t i=0; iowner == this) { if (header->ownedData) { free(header->ownedData); } delete header; } } mPackageGroups.clear(); mHeaders.clear(); } bool ResTable::getResourceName(uint32_t resID, bool allowUtf8, resource_name* outName) const { if (mError != NO_ERROR) { return false; } const ssize_t p = getResourcePackageIndex(resID); const int t = Res_GETTYPE(resID); const int e = Res_GETENTRY(resID); if (p < 0) { if (Res_GETPACKAGE(resID)+1 == 0) { ALOGW("No package identifier when getting name for resource number 0x%08x", resID); } else { ALOGW("No known package when getting name for resource number 0x%08x", resID); } return false; } if (t < 0) { ALOGW("No type identifier when getting name for resource number 0x%08x", resID); return false; } const PackageGroup* const grp = mPackageGroups[p]; if (grp == NULL) { ALOGW("Bad identifier when getting name for resource number 0x%08x", resID); return false; } Entry entry; status_t err = getEntry(grp, t, e, NULL, &entry); if (err != NO_ERROR) { return false; } outName->package = grp->name.string(); outName->packageLen = grp->name.size(); if (allowUtf8) { outName->type8 = entry.typeStr.string8(&outName->typeLen); outName->name8 = entry.keyStr.string8(&outName->nameLen); } else { outName->type8 = NULL; outName->name8 = NULL; } if (outName->type8 == NULL) { outName->type = entry.typeStr.string16(&outName->typeLen); // If we have a bad index for some reason, we should abort. if (outName->type == NULL) { return false; } } if (outName->name8 == NULL) { outName->name = entry.keyStr.string16(&outName->nameLen); // If we have a bad index for some reason, we should abort. if (outName->name == NULL) { return false; } } return true; } ssize_t ResTable::getResource(uint32_t resID, Res_value* outValue, bool mayBeBag, uint16_t density, uint32_t* outSpecFlags, ResTable_config* outConfig) const { if (mError != NO_ERROR) { return mError; } const ssize_t p = getResourcePackageIndex(resID); const int t = Res_GETTYPE(resID); const int e = Res_GETENTRY(resID); if (p < 0) { if (Res_GETPACKAGE(resID)+1 == 0) { ALOGW("No package identifier when getting value for resource number 0x%08x", resID); } else { ALOGW("No known package when getting value for resource number 0x%08x", resID); } return BAD_INDEX; } if (t < 0) { ALOGW("No type identifier when getting value for resource number 0x%08x", resID); return BAD_INDEX; } const PackageGroup* const grp = mPackageGroups[p]; if (grp == NULL) { ALOGW("Bad identifier when getting value for resource number 0x%08x", resID); return BAD_INDEX; } // Allow overriding density ResTable_config desiredConfig = mParams; if (density > 0) { desiredConfig.density = density; } Entry entry; status_t err = getEntry(grp, t, e, &desiredConfig, &entry); if (err != NO_ERROR) { // Only log the failure when we're not running on the host as // part of a tool. The caller will do its own logging. #ifndef STATIC_ANDROIDFW_FOR_TOOLS ALOGW("Failure getting entry for 0x%08x (t=%d e=%d) (error %d)\n", resID, t, e, err); #endif return err; } if ((dtohs(entry.entry->flags) & ResTable_entry::FLAG_COMPLEX) != 0) { if (!mayBeBag) { ALOGW("Requesting resource 0x%08x failed because it is complex\n", resID); } return BAD_VALUE; } const Res_value* value = reinterpret_cast( reinterpret_cast(entry.entry) + entry.entry->size); outValue->size = dtohs(value->size); outValue->res0 = value->res0; outValue->dataType = value->dataType; outValue->data = dtohl(value->data); // The reference may be pointing to a resource in a shared library. These // references have build-time generated package IDs. These ids may not match // the actual package IDs of the corresponding packages in this ResTable. // We need to fix the package ID based on a mapping. if (grp->dynamicRefTable.lookupResourceValue(outValue) != NO_ERROR) { ALOGW("Failed to resolve referenced package: 0x%08x", outValue->data); return BAD_VALUE; } if (kDebugTableNoisy) { size_t len; printf("Found value: pkg=%zu, type=%d, str=%s, int=%d\n", entry.package->header->index, outValue->dataType, outValue->dataType == Res_value::TYPE_STRING ? String8(entry.package->header->values.stringAt(outValue->data, &len)).string() : "", outValue->data); } if (outSpecFlags != NULL) { *outSpecFlags = entry.specFlags; } if (outConfig != NULL) { *outConfig = entry.config; } return entry.package->header->index; } ssize_t ResTable::resolveReference(Res_value* value, ssize_t blockIndex, uint32_t* outLastRef, uint32_t* inoutTypeSpecFlags, ResTable_config* outConfig) const { int count=0; while (blockIndex >= 0 && value->dataType == Res_value::TYPE_REFERENCE && value->data != 0 && count < 20) { if (outLastRef) *outLastRef = value->data; uint32_t newFlags = 0; const ssize_t newIndex = getResource(value->data, value, true, 0, &newFlags, outConfig); if (newIndex == BAD_INDEX) { return BAD_INDEX; } if (kDebugTableTheme) { ALOGI("Resolving reference 0x%x: newIndex=%d, type=0x%x, data=0x%x\n", value->data, (int)newIndex, (int)value->dataType, value->data); } //printf("Getting reference 0x%08x: newIndex=%d\n", value->data, newIndex); if (inoutTypeSpecFlags != NULL) *inoutTypeSpecFlags |= newFlags; if (newIndex < 0) { // This can fail if the resource being referenced is a style... // in this case, just return the reference, and expect the // caller to deal with. return blockIndex; } blockIndex = newIndex; count++; } return blockIndex; } const char16_t* ResTable::valueToString( const Res_value* value, size_t stringBlock, char16_t /*tmpBuffer*/ [TMP_BUFFER_SIZE], size_t* outLen) const { if (!value) { return NULL; } if (value->dataType == value->TYPE_STRING) { return getTableStringBlock(stringBlock)->stringAt(value->data, outLen); } // XXX do int to string conversions. return NULL; } ssize_t ResTable::lockBag(uint32_t resID, const bag_entry** outBag) const { mLock.lock(); ssize_t err = getBagLocked(resID, outBag); if (err < NO_ERROR) { //printf("*** get failed! unlocking\n"); mLock.unlock(); } return err; } void ResTable::unlockBag(const bag_entry* /*bag*/) const { //printf("<<< unlockBag %p\n", this); mLock.unlock(); } void ResTable::lock() const { mLock.lock(); } void ResTable::unlock() const { mLock.unlock(); } // Protected attributes are not permitted to be themed. If a theme // does try to change a protected attribute it will be overriden // by the app's original value. const static uint32_t PROTECTED_ATTRS[] = { ATTR_WINDOW_NO_TITLE, ATTR_WINDOW_ACTION_BAR }; bool ResTable::isProtectedAttr(uint32_t resID) const { int length = sizeof(PROTECTED_ATTRS) / sizeof(PROTECTED_ATTRS[0]); for(int i=0; i < length; i++) { if (PROTECTED_ATTRS[i] == resID) { return true; } } return false; } ssize_t ResTable::getBagLocked(uint32_t resID, const bag_entry** outBag, uint32_t* outTypeSpecFlags, bool performMapping) const { if (mError != NO_ERROR) { return mError; } const ssize_t p = getResourcePackageIndex(resID); const int t = Res_GETTYPE(resID); const int e = Res_GETENTRY(resID); if (p < 0) { ALOGW("Invalid package identifier when getting bag for resource number 0x%08x", resID); return BAD_INDEX; } if (t < 0) { ALOGW("No type identifier when getting bag for resource number 0x%08x", resID); return BAD_INDEX; } //printf("Get bag: id=0x%08x, p=%d, t=%d\n", resID, p, t); PackageGroup* const grp = mPackageGroups[p]; if (grp == NULL) { ALOGW("Bad identifier when getting bag for resource number 0x%08x", resID); return BAD_INDEX; } const TypeList& typeConfigs = grp->types[t]; if (typeConfigs.isEmpty()) { ALOGW("Type identifier 0x%x does not exist.", t+1); return BAD_INDEX; } const size_t NENTRY = typeConfigs[0]->entryCount; if (e >= (int)NENTRY) { ALOGW("Entry identifier 0x%x is larger than entry count 0x%x", e, (int)typeConfigs[0]->entryCount); return BAD_INDEX; } // First see if we've already computed this bag... if (grp->bags && performMapping) { bag_set** typeSet = grp->bags->get(t); if (typeSet) { bag_set* set = typeSet[e]; if (set) { if (set != (bag_set*)0xFFFFFFFF) { if (outTypeSpecFlags != NULL) { *outTypeSpecFlags = set->typeSpecFlags; } *outBag = (bag_entry*)(set+1); if (kDebugTableSuperNoisy) { ALOGI("Found existing bag for: 0x%x\n", resID); } return set->numAttrs; } ALOGW("Attempt to retrieve bag 0x%08x which is invalid or in a cycle.", resID); return BAD_INDEX; } } } // Bag not found, we need to compute it! if (!grp->bags) { grp->bags = new ByteBucketArray(); if (!grp->bags) return NO_MEMORY; } bag_set** typeSet = grp->bags->get(t); if (!typeSet) { typeSet = (bag_set**)calloc(NENTRY, sizeof(bag_set*)); if (!typeSet) return NO_MEMORY; grp->bags->set(t, typeSet); } // Mark that we are currently working on this one. typeSet[e] = (bag_set*)0xFFFFFFFF; if (kDebugTableNoisy) { ALOGI("Building bag: %x\n", resID); } // Now collect all bag attributes Entry entry; status_t err = getEntry(grp, t, e, &mParams, &entry, performMapping); if (err != NO_ERROR) { return err; } const uint16_t entrySize = dtohs(entry.entry->size); const uint32_t parent = entrySize >= sizeof(ResTable_map_entry) ? dtohl(((const ResTable_map_entry*)entry.entry)->parent.ident) : 0; const uint32_t count = entrySize >= sizeof(ResTable_map_entry) ? dtohl(((const ResTable_map_entry*)entry.entry)->count) : 0; size_t N = count; if (kDebugTableNoisy) { ALOGI("Found map: size=%x parent=%x count=%d\n", entrySize, parent, count); // If this map inherits from another, we need to start // with its parent's values. Otherwise start out empty. ALOGI("Creating new bag, entrySize=0x%08x, parent=0x%08x\n", entrySize, parent); } // This is what we are building. bag_set* set = NULL; if (parent) { uint32_t resolvedParent = parent; // Bags encode a parent reference without using the standard // Res_value structure. That means we must always try to // resolve a parent reference in case it is actually a // TYPE_DYNAMIC_REFERENCE. status_t err = grp->dynamicRefTable.lookupResourceId(&resolvedParent); if (err != NO_ERROR) { ALOGE("Failed resolving bag parent id 0x%08x", parent); return UNKNOWN_ERROR; } const bag_entry* parentBag; uint32_t parentTypeSpecFlags = 0; const ssize_t NP = getBagLocked(resolvedParent, &parentBag, &parentTypeSpecFlags, (resolvedParent != resID || !entry.isFromOverlay)); const size_t NT = ((NP >= 0) ? NP : 0) + N; set = (bag_set*)malloc(sizeof(bag_set)+sizeof(bag_entry)*NT); if (set == NULL) { return NO_MEMORY; } if (NP > 0) { memcpy(set+1, parentBag, NP*sizeof(bag_entry)); set->numAttrs = NP; if (kDebugTableNoisy) { ALOGI("Initialized new bag with %zd inherited attributes.\n", NP); } } else { if (kDebugTableNoisy) { ALOGI("Initialized new bag with no inherited attributes.\n"); } set->numAttrs = 0; } set->availAttrs = NT; set->typeSpecFlags = parentTypeSpecFlags; } else { set = (bag_set*)malloc(sizeof(bag_set)+sizeof(bag_entry)*N); if (set == NULL) { return NO_MEMORY; } set->numAttrs = 0; set->availAttrs = N; set->typeSpecFlags = 0; } set->typeSpecFlags |= entry.specFlags; // Now merge in the new attributes... size_t curOff = (reinterpret_cast(entry.entry) - reinterpret_cast(entry.type)) + dtohs(entry.entry->size); const ResTable_map* map; bag_entry* entries = (bag_entry*)(set+1); size_t curEntry = 0; uint32_t pos = 0; if (kDebugTableNoisy) { ALOGI("Starting with set %p, entries=%p, avail=%zu\n", set, entries, set->availAttrs); } while (pos < count) { if (kDebugTableNoisy) { ALOGI("Now at %p\n", (void*)curOff); } if (curOff > (dtohl(entry.type->header.size)-sizeof(ResTable_map))) { ALOGW("ResTable_map at %d is beyond type chunk data %d", (int)curOff, dtohl(entry.type->header.size)); return BAD_TYPE; } map = (const ResTable_map*)(((const uint8_t*)entry.type) + curOff); N++; uint32_t newName = htodl(map->name.ident); if (!Res_INTERNALID(newName)) { // Attributes don't have a resource id as the name. They specify // other data, which would be wrong to change via a lookup. if (grp->dynamicRefTable.lookupResourceId(&newName) != NO_ERROR) { ALOGE("Failed resolving ResTable_map name at %d with ident 0x%08x", (int) curOff, (int) newName); return UNKNOWN_ERROR; } } bool isInside; uint32_t oldName = 0; while ((isInside=(curEntry < set->numAttrs)) && (oldName=entries[curEntry].map.name.ident) < newName) { if (kDebugTableNoisy) { ALOGI("#%zu: Keeping existing attribute: 0x%08x\n", curEntry, entries[curEntry].map.name.ident); } curEntry++; } if ((!isInside) || oldName != newName) { // This is a new attribute... figure out what to do with it. if (set->numAttrs >= set->availAttrs) { // Need to alloc more memory... const size_t newAvail = set->availAttrs+N; set = (bag_set*)realloc(set, sizeof(bag_set) + sizeof(bag_entry)*newAvail); if (set == NULL) { return NO_MEMORY; } set->availAttrs = newAvail; entries = (bag_entry*)(set+1); if (kDebugTableNoisy) { ALOGI("Reallocated set %p, entries=%p, avail=%zu\n", set, entries, set->availAttrs); } } if (isInside) { // Going in the middle, need to make space. memmove(entries+curEntry+1, entries+curEntry, sizeof(bag_entry)*(set->numAttrs-curEntry)); set->numAttrs++; } if (kDebugTableNoisy) { ALOGI("#%zu: Inserting new attribute: 0x%08x\n", curEntry, newName); } } else { if (kDebugTableNoisy) { ALOGI("#%zu: Replacing existing attribute: 0x%08x\n", curEntry, oldName); } } bag_entry* cur = entries+curEntry; cur->stringBlock = entry.package->header->index; cur->map.name.ident = newName; cur->map.value.copyFrom_dtoh(map->value); status_t err = grp->dynamicRefTable.lookupResourceValue(&cur->map.value); if (err != NO_ERROR) { ALOGE("Reference item(0x%08x) in bag could not be resolved.", cur->map.value.data); return UNKNOWN_ERROR; } if (kDebugTableNoisy) { ALOGI("Setting entry #%zu %p: block=%zd, name=0x%08d, type=%d, data=0x%08x\n", curEntry, cur, cur->stringBlock, cur->map.name.ident, cur->map.value.dataType, cur->map.value.data); } // On to the next! curEntry++; pos++; const size_t size = dtohs(map->value.size); curOff += size + sizeof(*map)-sizeof(map->value); }; if (curEntry > set->numAttrs) { set->numAttrs = curEntry; } if (entry.isFromOverlay) { const bag_entry* originalBag; uint32_t originalTypeSpecFlags = 0; const ssize_t NO = getBagLocked(resID, &originalBag, &originalTypeSpecFlags, false); if (NO <= 0) { ALOGW("Failed to retrieve original bag for 0x%08x", resID); } // Now merge in the original attributes... bag_entry* entries = (bag_entry*)(set+1); size_t curEntry = 0; for (int i = 0; i < NO; i++) { const uint32_t newName = originalBag[i].map.name.ident; bool isInside; uint32_t oldName = 0; curEntry = 0; while ((isInside=(curEntry < set->numAttrs)) && (oldName=entries[curEntry].map.name.ident) < newName) { curEntry++; } if ((!isInside) || oldName != newName) { // This is a new attribute... figure out what to do with it. // Need to alloc more memory... size_t prevEntry = curEntry; curEntry = set->availAttrs; set->availAttrs++; const size_t newAvail = set->availAttrs; set = (bag_set*)realloc(set, sizeof(bag_set) + sizeof(bag_entry)*newAvail); if (set == NULL) { return NO_MEMORY; } entries = (bag_entry*)(set+1); if (isInside) { // Going in the middle, need to make space. memmove(entries+prevEntry+1, entries+prevEntry, sizeof(bag_entry)*(set->numAttrs-prevEntry)); } bag_entry* cur = entries+curEntry; cur->stringBlock = originalBag[i].stringBlock; cur->map.name.ident = originalBag[i].map.name.ident; cur->map.value = originalBag[i].map.value; set->typeSpecFlags |= originalTypeSpecFlags; set->numAttrs = set->availAttrs; } else if (isProtectedAttr(newName)) { // The attribute exists in both the original and the new theme bags, // furthermore it is an attribute we don't wish themers to theme, so // give our current themed bag the same value as the original bag_entry* cur = entries+curEntry; cur->stringBlock = originalBag[i].stringBlock; cur->map.name.ident = originalBag[i].map.name.ident; cur->map.value = originalBag[i].map.value; } } } // And this is it... typeSet[e] = set; if (set) { if (outTypeSpecFlags != NULL) { *outTypeSpecFlags = set->typeSpecFlags; } *outBag = (bag_entry*)(set+1); if (kDebugTableNoisy) { ALOGI("Returning %zu attrs\n", set->numAttrs); } return set->numAttrs; } return BAD_INDEX; } void ResTable::setParameters(const ResTable_config* params) { mLock.lock(); if (kDebugTableGetEntry) { ALOGI("Setting parameters: %s\n", params->toString().string()); } mParams = *params; for (size_t i=0; iclearBagCache(); } mLock.unlock(); } void ResTable::getParameters(ResTable_config* params) const { mLock.lock(); *params = mParams; mLock.unlock(); } struct id_name_map { uint32_t id; size_t len; char16_t name[6]; }; const static id_name_map ID_NAMES[] = { { ResTable_map::ATTR_TYPE, 5, { '^', 't', 'y', 'p', 'e' } }, { ResTable_map::ATTR_L10N, 5, { '^', 'l', '1', '0', 'n' } }, { ResTable_map::ATTR_MIN, 4, { '^', 'm', 'i', 'n' } }, { ResTable_map::ATTR_MAX, 4, { '^', 'm', 'a', 'x' } }, { ResTable_map::ATTR_OTHER, 6, { '^', 'o', 't', 'h', 'e', 'r' } }, { ResTable_map::ATTR_ZERO, 5, { '^', 'z', 'e', 'r', 'o' } }, { ResTable_map::ATTR_ONE, 4, { '^', 'o', 'n', 'e' } }, { ResTable_map::ATTR_TWO, 4, { '^', 't', 'w', 'o' } }, { ResTable_map::ATTR_FEW, 4, { '^', 'f', 'e', 'w' } }, { ResTable_map::ATTR_MANY, 5, { '^', 'm', 'a', 'n', 'y' } }, }; uint32_t ResTable::identifierForName(const char16_t* name, size_t nameLen, const char16_t* type, size_t typeLen, const char16_t* package, size_t packageLen, uint32_t* outTypeSpecFlags) const { if (kDebugTableSuperNoisy) { printf("Identifier for name: error=%d\n", mError); } // Check for internal resource identifier as the very first thing, so // that we will always find them even when there are no resources. if (name[0] == '^') { const int N = (sizeof(ID_NAMES)/sizeof(ID_NAMES[0])); size_t len; for (int i=0; ilen; if (len != nameLen) { continue; } for (size_t j=1; jname[j] != name[j]) { goto nope; } } if (outTypeSpecFlags) { *outTypeSpecFlags = ResTable_typeSpec::SPEC_PUBLIC; } return m->id; nope: ; } if (nameLen > 7) { if (name[1] == 'i' && name[2] == 'n' && name[3] == 'd' && name[4] == 'e' && name[5] == 'x' && name[6] == '_') { int index = atoi(String8(name + 7, nameLen - 7).string()); if (Res_CHECKID(index)) { ALOGW("Array resource index: %d is too large.", index); return 0; } if (outTypeSpecFlags) { *outTypeSpecFlags = ResTable_typeSpec::SPEC_PUBLIC; } return Res_MAKEARRAY(index); } } return 0; } if (mError != NO_ERROR) { return 0; } bool fakePublic = false; // Figure out the package and type we are looking in... const char16_t* packageEnd = NULL; const char16_t* typeEnd = NULL; const char16_t* const nameEnd = name+nameLen; const char16_t* p = name; while (p < nameEnd) { if (*p == ':') packageEnd = p; else if (*p == '/') typeEnd = p; p++; } if (*name == '@') { name++; if (*name == '*') { fakePublic = true; name++; } } if (name >= nameEnd) { return 0; } if (packageEnd) { package = name; packageLen = packageEnd-name; name = packageEnd+1; } else if (!package) { return 0; } if (typeEnd) { type = name; typeLen = typeEnd-name; name = typeEnd+1; } else if (!type) { return 0; } if (name >= nameEnd) { return 0; } nameLen = nameEnd-name; if (kDebugTableNoisy) { printf("Looking for identifier: type=%s, name=%s, package=%s\n", String8(type, typeLen).string(), String8(name, nameLen).string(), String8(package, packageLen).string()); } const String16 attr("attr"); const String16 attrPrivate("^attr-private"); const size_t NG = mPackageGroups.size(); for (size_t ig=0; igname.string(), group->name.size())) { if (kDebugTableNoisy) { printf("Skipping package group: %s\n", String8(group->name).string()); } continue; } const size_t packageCount = group->packages.size(); for (size_t pi = 0; pi < packageCount; pi++) { const char16_t* targetType = type; size_t targetTypeLen = typeLen; do { ssize_t ti = group->packages[pi]->typeStrings.indexOfString( targetType, targetTypeLen); if (ti < 0) { continue; } ti += group->packages[pi]->typeIdOffset; const uint32_t identifier = findEntry(group, ti, name, nameLen, outTypeSpecFlags); if (identifier != 0) { if (fakePublic && outTypeSpecFlags) { *outTypeSpecFlags |= ResTable_typeSpec::SPEC_PUBLIC; } return identifier; } } while (strzcmp16(attr.string(), attr.size(), targetType, targetTypeLen) == 0 && (targetType = attrPrivate.string()) && (targetTypeLen = attrPrivate.size()) ); } break; } return 0; } uint32_t ResTable::findEntry(const PackageGroup* group, ssize_t typeIndex, const char16_t* name, size_t nameLen, uint32_t* outTypeSpecFlags) const { const TypeList& typeList = group->types[typeIndex]; const size_t typeCount = typeList.size(); for (size_t i = 0; i < typeCount; i++) { const Type* t = typeList[i]; const ssize_t ei = t->package->keyStrings.indexOfString(name, nameLen); if (ei < 0) { continue; } const size_t configCount = t->configs.size(); for (size_t j = 0; j < configCount; j++) { const TypeVariant tv(t->configs[j]); for (TypeVariant::iterator iter = tv.beginEntries(); iter != tv.endEntries(); iter++) { const ResTable_entry* entry = *iter; if (entry == NULL) { continue; } if (dtohl(entry->key.index) == (size_t) ei) { uint32_t resId = Res_MAKEID(group->id - 1, typeIndex, iter.index()); if (outTypeSpecFlags) { Entry result; if (getEntry(group, typeIndex, iter.index(), NULL, &result) != NO_ERROR) { ALOGW("Failed to find spec flags for 0x%08x", resId); return 0; } *outTypeSpecFlags = result.specFlags; } return resId; } } } } return 0; } bool ResTable::expandResourceRef(const char16_t* refStr, size_t refLen, String16* outPackage, String16* outType, String16* outName, const String16* defType, const String16* defPackage, const char** outErrorMsg, bool* outPublicOnly) { const char16_t* packageEnd = NULL; const char16_t* typeEnd = NULL; const char16_t* p = refStr; const char16_t* const end = p + refLen; while (p < end) { if (*p == ':') packageEnd = p; else if (*p == '/') { typeEnd = p; break; } p++; } p = refStr; if (*p == '@') p++; if (outPublicOnly != NULL) { *outPublicOnly = true; } if (*p == '*') { p++; if (outPublicOnly != NULL) { *outPublicOnly = false; } } if (packageEnd) { *outPackage = String16(p, packageEnd-p); p = packageEnd+1; } else { if (!defPackage) { if (outErrorMsg) { *outErrorMsg = "No resource package specified"; } return false; } *outPackage = *defPackage; } if (typeEnd) { *outType = String16(p, typeEnd-p); p = typeEnd+1; } else { if (!defType) { if (outErrorMsg) { *outErrorMsg = "No resource type specified"; } return false; } *outType = *defType; } *outName = String16(p, end-p); if(**outPackage == 0) { if(outErrorMsg) { *outErrorMsg = "Resource package cannot be an empty string"; } return false; } if(**outType == 0) { if(outErrorMsg) { *outErrorMsg = "Resource type cannot be an empty string"; } return false; } if(**outName == 0) { if(outErrorMsg) { *outErrorMsg = "Resource id cannot be an empty string"; } return false; } return true; } static uint32_t get_hex(char c, bool* outError) { if (c >= '0' && c <= '9') { return c - '0'; } else if (c >= 'a' && c <= 'f') { return c - 'a' + 0xa; } else if (c >= 'A' && c <= 'F') { return c - 'A' + 0xa; } *outError = true; return 0; } struct unit_entry { const char* name; size_t len; uint8_t type; uint32_t unit; float scale; }; static const unit_entry unitNames[] = { { "px", strlen("px"), Res_value::TYPE_DIMENSION, Res_value::COMPLEX_UNIT_PX, 1.0f }, { "dip", strlen("dip"), Res_value::TYPE_DIMENSION, Res_value::COMPLEX_UNIT_DIP, 1.0f }, { "dp", strlen("dp"), Res_value::TYPE_DIMENSION, Res_value::COMPLEX_UNIT_DIP, 1.0f }, { "sp", strlen("sp"), Res_value::TYPE_DIMENSION, Res_value::COMPLEX_UNIT_SP, 1.0f }, { "pt", strlen("pt"), Res_value::TYPE_DIMENSION, Res_value::COMPLEX_UNIT_PT, 1.0f }, { "in", strlen("in"), Res_value::TYPE_DIMENSION, Res_value::COMPLEX_UNIT_IN, 1.0f }, { "mm", strlen("mm"), Res_value::TYPE_DIMENSION, Res_value::COMPLEX_UNIT_MM, 1.0f }, { "%", strlen("%"), Res_value::TYPE_FRACTION, Res_value::COMPLEX_UNIT_FRACTION, 1.0f/100 }, { "%p", strlen("%p"), Res_value::TYPE_FRACTION, Res_value::COMPLEX_UNIT_FRACTION_PARENT, 1.0f/100 }, { NULL, 0, 0, 0, 0 } }; static bool parse_unit(const char* str, Res_value* outValue, float* outScale, const char** outEnd) { const char* end = str; while (*end != 0 && !isspace((unsigned char)*end)) { end++; } const size_t len = end-str; const char* realEnd = end; while (*realEnd != 0 && isspace((unsigned char)*realEnd)) { realEnd++; } if (*realEnd != 0) { return false; } const unit_entry* cur = unitNames; while (cur->name) { if (len == cur->len && strncmp(cur->name, str, len) == 0) { outValue->dataType = cur->type; outValue->data = cur->unit << Res_value::COMPLEX_UNIT_SHIFT; *outScale = cur->scale; *outEnd = end; //printf("Found unit %s for %s\n", cur->name, str); return true; } cur++; } return false; } bool U16StringToInt(const char16_t* s, size_t len, Res_value* outValue) { while (len > 0 && isspace16(*s)) { s++; len--; } if (len <= 0) { return false; } size_t i = 0; int64_t val = 0; bool neg = false; if (*s == '-') { neg = true; i++; } if (s[i] < '0' || s[i] > '9') { return false; } static_assert(std::is_same::value, "Res_value::data_type has changed. The range checks in this " "function are no longer correct."); // Decimal or hex? bool isHex; if (len > 1 && s[i] == '0' && s[i+1] == 'x') { isHex = true; i += 2; if (neg) { return false; } if (i == len) { // Just u"0x" return false; } bool error = false; while (i < len && !error) { val = (val*16) + get_hex(s[i], &error); i++; if (val > std::numeric_limits::max()) { return false; } } if (error) { return false; } } else { isHex = false; while (i < len) { if (s[i] < '0' || s[i] > '9') { return false; } val = (val*10) + s[i]-'0'; i++; if ((neg && -val < std::numeric_limits::min()) || (!neg && val > std::numeric_limits::max())) { return false; } } } if (neg) val = -val; while (i < len && isspace16(s[i])) { i++; } if (i != len) { return false; } if (outValue) { outValue->dataType = isHex ? outValue->TYPE_INT_HEX : outValue->TYPE_INT_DEC; outValue->data = static_cast(val); } return true; } bool ResTable::stringToInt(const char16_t* s, size_t len, Res_value* outValue) { return U16StringToInt(s, len, outValue); } bool ResTable::stringToFloat(const char16_t* s, size_t len, Res_value* outValue) { while (len > 0 && isspace16(*s)) { s++; len--; } if (len <= 0) { return false; } char buf[128]; int i=0; while (len > 0 && *s != 0 && i < 126) { if (*s > 255) { return false; } buf[i++] = *s++; len--; } if (len > 0) { return false; } if ((buf[0] < '0' || buf[0] > '9') && buf[0] != '.' && buf[0] != '-' && buf[0] != '+') { return false; } buf[i] = 0; const char* end; float f = strtof(buf, (char**)&end); if (*end != 0 && !isspace((unsigned char)*end)) { // Might be a unit... float scale; if (parse_unit(end, outValue, &scale, &end)) { f *= scale; const bool neg = f < 0; if (neg) f = -f; uint64_t bits = (uint64_t)(f*(1<<23)+.5f); uint32_t radix; uint32_t shift; if ((bits&0x7fffff) == 0) { // Always use 23p0 if there is no fraction, just to make // things easier to read. radix = Res_value::COMPLEX_RADIX_23p0; shift = 23; } else if ((bits&0xffffffffff800000LL) == 0) { // Magnitude is zero -- can fit in 0 bits of precision. radix = Res_value::COMPLEX_RADIX_0p23; shift = 0; } else if ((bits&0xffffffff80000000LL) == 0) { // Magnitude can fit in 8 bits of precision. radix = Res_value::COMPLEX_RADIX_8p15; shift = 8; } else if ((bits&0xffffff8000000000LL) == 0) { // Magnitude can fit in 16 bits of precision. radix = Res_value::COMPLEX_RADIX_16p7; shift = 16; } else { // Magnitude needs entire range, so no fractional part. radix = Res_value::COMPLEX_RADIX_23p0; shift = 23; } int32_t mantissa = (int32_t)( (bits>>shift) & Res_value::COMPLEX_MANTISSA_MASK); if (neg) { mantissa = (-mantissa) & Res_value::COMPLEX_MANTISSA_MASK; } outValue->data |= (radix<data); return true; } return false; } while (*end != 0 && isspace((unsigned char)*end)) { end++; } if (*end == 0) { if (outValue) { outValue->dataType = outValue->TYPE_FLOAT; *(float*)(&outValue->data) = f; return true; } } return false; } bool ResTable::stringToValue(Res_value* outValue, String16* outString, const char16_t* s, size_t len, bool preserveSpaces, bool coerceType, uint32_t attrID, const String16* defType, const String16* defPackage, Accessor* accessor, void* accessorCookie, uint32_t attrType, bool enforcePrivate) const { bool localizationSetting = accessor != NULL && accessor->getLocalizationSetting(); const char* errorMsg = NULL; outValue->size = sizeof(Res_value); outValue->res0 = 0; // First strip leading/trailing whitespace. Do this before handling // escapes, so they can be used to force whitespace into the string. if (!preserveSpaces) { while (len > 0 && isspace16(*s)) { s++; len--; } while (len > 0 && isspace16(s[len-1])) { len--; } // If the string ends with '\', then we keep the space after it. if (len > 0 && s[len-1] == '\\' && s[len] != 0) { len++; } } //printf("Value for: %s\n", String8(s, len).string()); uint32_t l10nReq = ResTable_map::L10N_NOT_REQUIRED; uint32_t attrMin = 0x80000000, attrMax = 0x7fffffff; bool fromAccessor = false; if (attrID != 0 && !Res_INTERNALID(attrID)) { const ssize_t p = getResourcePackageIndex(attrID); const bag_entry* bag; ssize_t cnt = p >= 0 ? lockBag(attrID, &bag) : -1; //printf("For attr 0x%08x got bag of %d\n", attrID, cnt); if (cnt >= 0) { while (cnt > 0) { //printf("Entry 0x%08x = 0x%08x\n", bag->map.name.ident, bag->map.value.data); switch (bag->map.name.ident) { case ResTable_map::ATTR_TYPE: attrType = bag->map.value.data; break; case ResTable_map::ATTR_MIN: attrMin = bag->map.value.data; break; case ResTable_map::ATTR_MAX: attrMax = bag->map.value.data; break; case ResTable_map::ATTR_L10N: l10nReq = bag->map.value.data; break; } bag++; cnt--; } unlockBag(bag); } else if (accessor && accessor->getAttributeType(attrID, &attrType)) { fromAccessor = true; if (attrType == ResTable_map::TYPE_ENUM || attrType == ResTable_map::TYPE_FLAGS || attrType == ResTable_map::TYPE_INTEGER) { accessor->getAttributeMin(attrID, &attrMin); accessor->getAttributeMax(attrID, &attrMax); } if (localizationSetting) { l10nReq = accessor->getAttributeL10N(attrID); } } } const bool canStringCoerce = coerceType && (attrType&ResTable_map::TYPE_STRING) != 0; if (*s == '@') { outValue->dataType = outValue->TYPE_REFERENCE; // Note: we don't check attrType here because the reference can // be to any other type; we just need to count on the client making // sure the referenced type is correct. //printf("Looking up ref: %s\n", String8(s, len).string()); // It's a reference! if (len == 5 && s[1]=='n' && s[2]=='u' && s[3]=='l' && s[4]=='l') { // Special case @null as undefined. This will be converted by // AssetManager to TYPE_NULL with data DATA_NULL_UNDEFINED. outValue->data = 0; return true; } else if (len == 6 && s[1]=='e' && s[2]=='m' && s[3]=='p' && s[4]=='t' && s[5]=='y') { // Special case @empty as explicitly defined empty value. outValue->dataType = Res_value::TYPE_NULL; outValue->data = Res_value::DATA_NULL_EMPTY; return true; } else { bool createIfNotFound = false; const char16_t* resourceRefName; int resourceNameLen; if (len > 2 && s[1] == '+') { createIfNotFound = true; resourceRefName = s + 2; resourceNameLen = len - 2; } else if (len > 2 && s[1] == '*') { enforcePrivate = false; resourceRefName = s + 2; resourceNameLen = len - 2; } else { createIfNotFound = false; resourceRefName = s + 1; resourceNameLen = len - 1; } String16 package, type, name; if (!expandResourceRef(resourceRefName,resourceNameLen, &package, &type, &name, defType, defPackage, &errorMsg)) { if (accessor != NULL) { accessor->reportError(accessorCookie, errorMsg); } return false; } uint32_t specFlags = 0; uint32_t rid = identifierForName(name.string(), name.size(), type.string(), type.size(), package.string(), package.size(), &specFlags); if (rid != 0) { if (enforcePrivate) { if (accessor == NULL || accessor->getAssetsPackage() != package) { if ((specFlags&ResTable_typeSpec::SPEC_PUBLIC) == 0) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Resource is not public."); } return false; } } } if (accessor) { rid = Res_MAKEID( accessor->getRemappedPackage(Res_GETPACKAGE(rid)), Res_GETTYPE(rid), Res_GETENTRY(rid)); if (kDebugTableNoisy) { ALOGI("Incl %s:%s/%s: 0x%08x\n", String8(package).string(), String8(type).string(), String8(name).string(), rid); } } uint32_t packageId = Res_GETPACKAGE(rid) + 1; if (isDynamicPackageId(packageId)) { outValue->dataType = Res_value::TYPE_DYNAMIC_REFERENCE; } outValue->data = rid; return true; } if (accessor) { uint32_t rid = accessor->getCustomResourceWithCreation(package, type, name, createIfNotFound); if (rid != 0) { if (kDebugTableNoisy) { ALOGI("Pckg %s:%s/%s: 0x%08x\n", String8(package).string(), String8(type).string(), String8(name).string(), rid); } uint32_t packageId = Res_GETPACKAGE(rid) + 1; if (packageId == 0x00) { outValue->data = rid; outValue->dataType = Res_value::TYPE_DYNAMIC_REFERENCE; return true; } else if (!isDynamicPackageId(packageId)) { // We accept packageId's generated as 0x01 in order to support // building the android system resources outValue->data = rid; return true; } } } } if (accessor != NULL) { accessor->reportError(accessorCookie, "No resource found that matches the given name"); } return false; } // if we got to here, and localization is required and it's not a reference, // complain and bail. if (l10nReq == ResTable_map::L10N_SUGGESTED) { if (localizationSetting) { if (accessor != NULL) { accessor->reportError(accessorCookie, "This attribute must be localized."); } } } if (*s == '#') { // It's a color! Convert to an integer of the form 0xaarrggbb. uint32_t color = 0; bool error = false; if (len == 4) { outValue->dataType = outValue->TYPE_INT_COLOR_RGB4; color |= 0xFF000000; color |= get_hex(s[1], &error) << 20; color |= get_hex(s[1], &error) << 16; color |= get_hex(s[2], &error) << 12; color |= get_hex(s[2], &error) << 8; color |= get_hex(s[3], &error) << 4; color |= get_hex(s[3], &error); } else if (len == 5) { outValue->dataType = outValue->TYPE_INT_COLOR_ARGB4; color |= get_hex(s[1], &error) << 28; color |= get_hex(s[1], &error) << 24; color |= get_hex(s[2], &error) << 20; color |= get_hex(s[2], &error) << 16; color |= get_hex(s[3], &error) << 12; color |= get_hex(s[3], &error) << 8; color |= get_hex(s[4], &error) << 4; color |= get_hex(s[4], &error); } else if (len == 7) { outValue->dataType = outValue->TYPE_INT_COLOR_RGB8; color |= 0xFF000000; color |= get_hex(s[1], &error) << 20; color |= get_hex(s[2], &error) << 16; color |= get_hex(s[3], &error) << 12; color |= get_hex(s[4], &error) << 8; color |= get_hex(s[5], &error) << 4; color |= get_hex(s[6], &error); } else if (len == 9) { outValue->dataType = outValue->TYPE_INT_COLOR_ARGB8; color |= get_hex(s[1], &error) << 28; color |= get_hex(s[2], &error) << 24; color |= get_hex(s[3], &error) << 20; color |= get_hex(s[4], &error) << 16; color |= get_hex(s[5], &error) << 12; color |= get_hex(s[6], &error) << 8; color |= get_hex(s[7], &error) << 4; color |= get_hex(s[8], &error); } else { error = true; } if (!error) { if ((attrType&ResTable_map::TYPE_COLOR) == 0) { if (!canStringCoerce) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Color types not allowed"); } return false; } } else { outValue->data = color; //printf("Color input=%s, output=0x%x\n", String8(s, len).string(), color); return true; } } else { if ((attrType&ResTable_map::TYPE_COLOR) != 0) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Color value not valid --" " must be #rgb, #argb, #rrggbb, or #aarrggbb"); } #if 0 fprintf(stderr, "%s: Color ID %s value %s is not valid\n", "Resource File", //(const char*)in->getPrintableSource(), String8(*curTag).string(), String8(s, len).string()); #endif return false; } } } if (*s == '?') { outValue->dataType = outValue->TYPE_ATTRIBUTE; // Note: we don't check attrType here because the reference can // be to any other type; we just need to count on the client making // sure the referenced type is correct. //printf("Looking up attr: %s\n", String8(s, len).string()); static const String16 attr16("attr"); String16 package, type, name; if (!expandResourceRef(s+1, len-1, &package, &type, &name, &attr16, defPackage, &errorMsg)) { if (accessor != NULL) { accessor->reportError(accessorCookie, errorMsg); } return false; } //printf("Pkg: %s, Type: %s, Name: %s\n", // String8(package).string(), String8(type).string(), // String8(name).string()); uint32_t specFlags = 0; uint32_t rid = identifierForName(name.string(), name.size(), type.string(), type.size(), package.string(), package.size(), &specFlags); // HACK // This allows themes to reference attributes that are app specific and // normally private. Only applies to aapt running on device not host // build systems. #ifdef HAVE_ANDROID_OS enforcePrivate = false; #endif if (rid != 0) { if (enforcePrivate) { if ((specFlags&ResTable_typeSpec::SPEC_PUBLIC) == 0) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Attribute is not public."); } return false; } } if (!accessor) { outValue->data = rid; return true; } rid = Res_MAKEID( accessor->getRemappedPackage(Res_GETPACKAGE(rid)), Res_GETTYPE(rid), Res_GETENTRY(rid)); //printf("Incl %s:%s/%s: 0x%08x\n", // String8(package).string(), String8(type).string(), // String8(name).string(), rid); outValue->data = rid; return true; } if (accessor) { uint32_t rid = accessor->getCustomResource(package, type, name); if (rid != 0) { //printf("Mine %s:%s/%s: 0x%08x\n", // String8(package).string(), String8(type).string(), // String8(name).string(), rid); outValue->data = rid; return true; } } if (accessor != NULL) { accessor->reportError(accessorCookie, "No resource found that matches the given name"); } return false; } if (stringToInt(s, len, outValue)) { if ((attrType&ResTable_map::TYPE_INTEGER) == 0) { // If this type does not allow integers, but does allow floats, // fall through on this error case because the float type should // be able to accept any integer value. if (!canStringCoerce && (attrType&ResTable_map::TYPE_FLOAT) == 0) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Integer types not allowed"); } return false; } } else { if (((int32_t)outValue->data) < ((int32_t)attrMin) || ((int32_t)outValue->data) > ((int32_t)attrMax)) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Integer value out of range"); } return false; } return true; } } if (stringToFloat(s, len, outValue)) { if (outValue->dataType == Res_value::TYPE_DIMENSION) { if ((attrType&ResTable_map::TYPE_DIMENSION) != 0) { return true; } if (!canStringCoerce) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Dimension types not allowed"); } return false; } } else if (outValue->dataType == Res_value::TYPE_FRACTION) { if ((attrType&ResTable_map::TYPE_FRACTION) != 0) { return true; } if (!canStringCoerce) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Fraction types not allowed"); } return false; } } else if ((attrType&ResTable_map::TYPE_FLOAT) == 0) { if (!canStringCoerce) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Float types not allowed"); } return false; } } else { return true; } } if (len == 4) { if ((s[0] == 't' || s[0] == 'T') && (s[1] == 'r' || s[1] == 'R') && (s[2] == 'u' || s[2] == 'U') && (s[3] == 'e' || s[3] == 'E')) { if ((attrType&ResTable_map::TYPE_BOOLEAN) == 0) { if (!canStringCoerce) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Boolean types not allowed"); } return false; } } else { outValue->dataType = outValue->TYPE_INT_BOOLEAN; outValue->data = (uint32_t)-1; return true; } } } if (len == 5) { if ((s[0] == 'f' || s[0] == 'F') && (s[1] == 'a' || s[1] == 'A') && (s[2] == 'l' || s[2] == 'L') && (s[3] == 's' || s[3] == 'S') && (s[4] == 'e' || s[4] == 'E')) { if ((attrType&ResTable_map::TYPE_BOOLEAN) == 0) { if (!canStringCoerce) { if (accessor != NULL) { accessor->reportError(accessorCookie, "Boolean types not allowed"); } return false; } } else { outValue->dataType = outValue->TYPE_INT_BOOLEAN; outValue->data = 0; return true; } } } if ((attrType&ResTable_map::TYPE_ENUM) != 0) { const ssize_t p = getResourcePackageIndex(attrID); const bag_entry* bag; ssize_t cnt = p >= 0 ? lockBag(attrID, &bag) : -1; //printf("Got %d for enum\n", cnt); if (cnt >= 0) { resource_name rname; while (cnt > 0) { if (!Res_INTERNALID(bag->map.name.ident)) { //printf("Trying attr #%08x\n", bag->map.name.ident); if (getResourceName(bag->map.name.ident, false, &rname)) { #if 0 printf("Matching %s against %s (0x%08x)\n", String8(s, len).string(), String8(rname.name, rname.nameLen).string(), bag->map.name.ident); #endif if (strzcmp16(s, len, rname.name, rname.nameLen) == 0) { outValue->dataType = bag->map.value.dataType; outValue->data = bag->map.value.data; unlockBag(bag); return true; } } } bag++; cnt--; } unlockBag(bag); } if (fromAccessor) { if (accessor->getAttributeEnum(attrID, s, len, outValue)) { return true; } } } if ((attrType&ResTable_map::TYPE_FLAGS) != 0) { const ssize_t p = getResourcePackageIndex(attrID); const bag_entry* bag; ssize_t cnt = p >= 0 ? lockBag(attrID, &bag) : -1; //printf("Got %d for flags\n", cnt); if (cnt >= 0) { bool failed = false; resource_name rname; outValue->dataType = Res_value::TYPE_INT_HEX; outValue->data = 0; const char16_t* end = s + len; const char16_t* pos = s; while (pos < end && !failed) { const char16_t* start = pos; pos++; while (pos < end && *pos != '|') { pos++; } //printf("Looking for: %s\n", String8(start, pos-start).string()); const bag_entry* bagi = bag; ssize_t i; for (i=0; imap.name.ident)) { //printf("Trying attr #%08x\n", bagi->map.name.ident); if (getResourceName(bagi->map.name.ident, false, &rname)) { #if 0 printf("Matching %s against %s (0x%08x)\n", String8(start,pos-start).string(), String8(rname.name, rname.nameLen).string(), bagi->map.name.ident); #endif if (strzcmp16(start, pos-start, rname.name, rname.nameLen) == 0) { outValue->data |= bagi->map.value.data; break; } } } } if (i >= cnt) { // Didn't find this flag identifier. failed = true; } if (pos < end) { pos++; } } unlockBag(bag); if (!failed) { //printf("Final flag value: 0x%lx\n", outValue->data); return true; } } if (fromAccessor) { if (accessor->getAttributeFlags(attrID, s, len, outValue)) { //printf("Final flag value: 0x%lx\n", outValue->data); return true; } } } if ((attrType&ResTable_map::TYPE_STRING) == 0) { if (accessor != NULL) { accessor->reportError(accessorCookie, "String types not allowed"); } return false; } // Generic string handling... outValue->dataType = outValue->TYPE_STRING; if (outString) { bool failed = collectString(outString, s, len, preserveSpaces, &errorMsg); if (accessor != NULL) { accessor->reportError(accessorCookie, errorMsg); } return failed; } return true; } bool ResTable::collectString(String16* outString, const char16_t* s, size_t len, bool preserveSpaces, const char** outErrorMsg, bool append) { String16 tmp; char quoted = 0; const char16_t* p = s; while (p < (s+len)) { while (p < (s+len)) { const char16_t c = *p; if (c == '\\') { break; } if (!preserveSpaces) { if (quoted == 0 && isspace16(c) && (c != ' ' || isspace16(*(p+1)))) { break; } if (c == '"' && (quoted == 0 || quoted == '"')) { break; } if (c == '\'' && (quoted == 0 || quoted == '\'')) { /* * In practice, when people write ' instead of \' * in a string, they are doing it by accident * instead of really meaning to use ' as a quoting * character. Warn them so they don't lose it. */ if (outErrorMsg) { *outErrorMsg = "Apostrophe not preceded by \\"; } return false; } } p++; } if (p < (s+len)) { if (p > s) { tmp.append(String16(s, p-s)); } if (!preserveSpaces && (*p == '"' || *p == '\'')) { if (quoted == 0) { quoted = *p; } else { quoted = 0; } p++; } else if (!preserveSpaces && isspace16(*p)) { // Space outside of a quote -- consume all spaces and // leave a single plain space char. tmp.append(String16(" ")); p++; while (p < (s+len) && isspace16(*p)) { p++; } } else if (*p == '\\') { p++; if (p < (s+len)) { switch (*p) { case 't': tmp.append(String16("\t")); break; case 'n': tmp.append(String16("\n")); break; case '#': tmp.append(String16("#")); break; case '@': tmp.append(String16("@")); break; case '?': tmp.append(String16("?")); break; case '"': tmp.append(String16("\"")); break; case '\'': tmp.append(String16("'")); break; case '\\': tmp.append(String16("\\")); break; case 'u': { char16_t chr = 0; int i = 0; while (i < 4 && p[1] != 0) { p++; i++; int c; if (*p >= '0' && *p <= '9') { c = *p - '0'; } else if (*p >= 'a' && *p <= 'f') { c = *p - 'a' + 10; } else if (*p >= 'A' && *p <= 'F') { c = *p - 'A' + 10; } else { if (outErrorMsg) { *outErrorMsg = "Bad character in \\u unicode escape sequence"; } return false; } chr = (chr<<4) | c; } tmp.append(String16(&chr, 1)); } break; default: // ignore unknown escape chars. break; } p++; } } len -= (p-s); s = p; } } if (tmp.size() != 0) { if (len > 0) { tmp.append(String16(s, len)); } if (append) { outString->append(tmp); } else { outString->setTo(tmp); } } else { if (append) { outString->append(String16(s, len)); } else { outString->setTo(s, len); } } return true; } size_t ResTable::getBasePackageCount() const { if (mError != NO_ERROR) { return 0; } return mPackageGroups.size(); } const String16 ResTable::getBasePackageName(size_t idx) const { if (mError != NO_ERROR) { return String16(); } LOG_FATAL_IF(idx >= mPackageGroups.size(), "Requested package index %d past package count %d", (int)idx, (int)mPackageGroups.size()); return mPackageGroups[idx]->name; } uint32_t ResTable::getBasePackageId(size_t idx) const { if (mError != NO_ERROR) { return 0; } LOG_FATAL_IF(idx >= mPackageGroups.size(), "Requested package index %d past package count %d", (int)idx, (int)mPackageGroups.size()); return mPackageGroups[idx]->id; } uint32_t ResTable::getLastTypeIdForPackage(size_t idx) const { if (mError != NO_ERROR) { return 0; } LOG_FATAL_IF(idx >= mPackageGroups.size(), "Requested package index %d past package count %d", (int)idx, (int)mPackageGroups.size()); const PackageGroup* const group = mPackageGroups[idx]; return group->largestTypeId; } size_t ResTable::getTableCount() const { return mHeaders.size(); } const ResStringPool* ResTable::getTableStringBlock(size_t index) const { return &mHeaders[index]->values; } int32_t ResTable::getTableCookie(size_t index) const { return mHeaders[index]->cookie; } const DynamicRefTable* ResTable::getDynamicRefTableForCookie(int32_t cookie) const { const size_t N = mPackageGroups.size(); for (size_t i = 0; i < N; i++) { const PackageGroup* pg = mPackageGroups[i]; size_t M = pg->packages.size(); for (size_t j = 0; j < M; j++) { if (pg->packages[j]->header->cookie == cookie) { return &pg->dynamicRefTable; } } } return NULL; } void ResTable::getConfigurations(Vector* configs, bool ignoreMipmap) const { const size_t packageCount = mPackageGroups.size(); for (size_t i = 0; i < packageCount; i++) { const PackageGroup* packageGroup = mPackageGroups[i]; const size_t typeCount = packageGroup->types.size(); for (size_t j = 0; j < typeCount; j++) { const TypeList& typeList = packageGroup->types[j]; const size_t numTypes = typeList.size(); for (size_t k = 0; k < numTypes; k++) { const Type* type = typeList[k]; const ResStringPool& typeStrings = type->package->typeStrings; if (ignoreMipmap && typeStrings.string8ObjectAt( type->typeSpec->id - 1) == "mipmap") { continue; } const size_t numConfigs = type->configs.size(); for (size_t m = 0; m < numConfigs; m++) { const ResTable_type* config = type->configs[m]; ResTable_config cfg; memset(&cfg, 0, sizeof(ResTable_config)); cfg.copyFromDtoH(config->config); // only insert unique const size_t N = configs->size(); size_t n; for (n = 0; n < N; n++) { if (0 == (*configs)[n].compare(cfg)) { break; } } // if we didn't find it if (n == N) { configs->add(cfg); } } } } } } void ResTable::getLocales(Vector* locales) const { Vector configs; ALOGV("calling getConfigurations"); getConfigurations(&configs); ALOGV("called getConfigurations size=%d", (int)configs.size()); const size_t I = configs.size(); char locale[RESTABLE_MAX_LOCALE_LEN]; for (size_t i=0; isize(); size_t j; for (j=0; jadd(String8(locale)); } } } StringPoolRef::StringPoolRef(const ResStringPool* pool, uint32_t index) : mPool(pool), mIndex(index) {} StringPoolRef::StringPoolRef() : mPool(NULL), mIndex(0) {} const char* StringPoolRef::string8(size_t* outLen) const { if (mPool != NULL) { return mPool->string8At(mIndex, outLen); } if (outLen != NULL) { *outLen = 0; } return NULL; } const char16_t* StringPoolRef::string16(size_t* outLen) const { if (mPool != NULL) { return mPool->stringAt(mIndex, outLen); } if (outLen != NULL) { *outLen = 0; } return NULL; } bool ResTable::getResourceFlags(uint32_t resID, uint32_t* outFlags) const { if (mError != NO_ERROR) { return false; } const ssize_t p = getResourcePackageIndex(resID); const int t = Res_GETTYPE(resID); const int e = Res_GETENTRY(resID); if (p < 0) { if (Res_GETPACKAGE(resID)+1 == 0) { ALOGW("No package identifier when getting flags for resource number 0x%08x", resID); } else { ALOGW("No known package when getting flags for resource number 0x%08x", resID); } return false; } if (t < 0) { ALOGW("No type identifier when getting flags for resource number 0x%08x", resID); return false; } const PackageGroup* const grp = mPackageGroups[p]; if (grp == NULL) { ALOGW("Bad identifier when getting flags for resource number 0x%08x", resID); return false; } Entry entry; status_t err = getEntry(grp, t, e, NULL, &entry); if (err != NO_ERROR) { return false; } *outFlags = entry.specFlags; return true; } status_t ResTable::getEntry( const PackageGroup* packageGroup, int typeIndex, int entryIndex, const ResTable_config* config, Entry* outEntry, const bool performMapping) const { const TypeList& typeList = packageGroup->types[typeIndex]; if (typeList.isEmpty()) { ALOGV("Skipping entry type index 0x%02x because type is NULL!\n", typeIndex); return BAD_TYPE; } const ResTable_type* bestType = NULL; uint32_t bestOffset = ResTable_type::NO_ENTRY; const Package* bestPackage = NULL; uint32_t specFlags = 0; uint8_t actualTypeIndex = typeIndex; ResTable_config bestConfig; memset(&bestConfig, 0, sizeof(bestConfig)); bool currentTypeIsOverlay = false; // Iterate over the Types of each package. const size_t typeCount = typeList.size(); for (size_t i = 0; i < typeCount; i++) { const Type* const typeSpec = typeList[i]; int realEntryIndex = entryIndex; int realTypeIndex = typeIndex; currentTypeIsOverlay = false; // Runtime overlay packages provide a mapping of app resource // ID to package resource ID. if (performMapping && typeSpec->idmapEntries.hasEntries()) { uint16_t overlayEntryIndex; if (typeSpec->idmapEntries.lookup(entryIndex, &overlayEntryIndex) != NO_ERROR) { // No such mapping exists continue; } realEntryIndex = overlayEntryIndex; realTypeIndex = typeSpec->idmapEntries.overlayTypeId() - 1; currentTypeIsOverlay = true; } if (static_cast(realEntryIndex) >= typeSpec->entryCount) { ALOGV("For resource 0x%08x, entry index(%d) is beyond type entryCount(%d)", Res_MAKEID(packageGroup->id - 1, typeIndex, entryIndex), entryIndex, static_cast(typeSpec->entryCount)); // We should normally abort here, but some legacy apps declare // resources in the 'android' package (old bug in AAPT). continue; } // Aggregate all the flags for each package that defines this entry. if (typeSpec->typeSpecFlags != NULL) { specFlags |= dtohl(typeSpec->typeSpecFlags[realEntryIndex]); } else { specFlags = -1; } const size_t numConfigs = typeSpec->configs.size(); for (size_t c = 0; c < numConfigs; c++) { const ResTable_type* const thisType = typeSpec->configs[c]; if (thisType == NULL) { continue; } ResTable_config thisConfig; thisConfig.copyFromDtoH(thisType->config); // Check to make sure this one is valid for the current parameters. if (config != NULL && !thisConfig.match(*config)) { continue; } // Check if there is the desired entry in this type. const uint32_t* const eindex = reinterpret_cast( reinterpret_cast(thisType) + dtohs(thisType->header.headerSize)); uint32_t thisOffset = dtohl(eindex[realEntryIndex]); if (thisOffset == ResTable_type::NO_ENTRY) { // There is no entry for this index and configuration. continue; } if (bestType != NULL) { // Check if this one is less specific than the last found. If so, // we will skip it. We check starting with things we most care // about to those we least care about. if (!currentTypeIsOverlay && !thisConfig.isBetterThan(bestConfig, config)) { if (!currentTypeIsOverlay || thisConfig.compare(bestConfig) != 0) { continue; } } } bestType = thisType; bestOffset = thisOffset; bestConfig = thisConfig; bestPackage = typeSpec->package; actualTypeIndex = realTypeIndex; // If no config was specified, any type will do, so skip if (config == NULL) { break; } } } if (bestType == NULL) { return BAD_INDEX; } bestOffset += dtohl(bestType->entriesStart); if (bestOffset > (dtohl(bestType->header.size)-sizeof(ResTable_entry))) { ALOGW("ResTable_entry at 0x%x is beyond type chunk data 0x%x", bestOffset, dtohl(bestType->header.size)); return BAD_TYPE; } if ((bestOffset & 0x3) != 0) { ALOGW("ResTable_entry at 0x%x is not on an integer boundary", bestOffset); return BAD_TYPE; } const ResTable_entry* const entry = reinterpret_cast( reinterpret_cast(bestType) + bestOffset); if (dtohs(entry->size) < sizeof(*entry)) { ALOGW("ResTable_entry size 0x%x is too small", dtohs(entry->size)); return BAD_TYPE; } if (outEntry != NULL) { outEntry->entry = entry; outEntry->config = bestConfig; outEntry->type = bestType; outEntry->specFlags = specFlags; outEntry->package = bestPackage; outEntry->typeStr = StringPoolRef(&bestPackage->typeStrings, actualTypeIndex - bestPackage->typeIdOffset); outEntry->keyStr = StringPoolRef(&bestPackage->keyStrings, dtohl(entry->key.index)); outEntry->isFromOverlay = currentTypeIsOverlay; } return NO_ERROR; } status_t ResTable::parsePackage(const ResTable_package* const pkg, const Header* const header, const uint32_t pkgIdOverride) { const uint8_t* base = (const uint8_t*)pkg; status_t err = validate_chunk(&pkg->header, sizeof(*pkg) - sizeof(pkg->typeIdOffset), header->dataEnd, "ResTable_package"); if (err != NO_ERROR) { return (mError=err); } const uint32_t pkgSize = dtohl(pkg->header.size); if (dtohl(pkg->typeStrings) >= pkgSize) { ALOGW("ResTable_package type strings at 0x%x are past chunk size 0x%x.", dtohl(pkg->typeStrings), pkgSize); return (mError=BAD_TYPE); } if ((dtohl(pkg->typeStrings)&0x3) != 0) { ALOGW("ResTable_package type strings at 0x%x is not on an integer boundary.", dtohl(pkg->typeStrings)); return (mError=BAD_TYPE); } if (dtohl(pkg->keyStrings) >= pkgSize) { ALOGW("ResTable_package key strings at 0x%x are past chunk size 0x%x.", dtohl(pkg->keyStrings), pkgSize); return (mError=BAD_TYPE); } if ((dtohl(pkg->keyStrings)&0x3) != 0) { ALOGW("ResTable_package key strings at 0x%x is not on an integer boundary.", dtohl(pkg->keyStrings)); return (mError=BAD_TYPE); } uint32_t id = dtohl(pkg->id); KeyedVector idmapEntries; uint8_t targetPackageId = 0; if (header->resourceIDMap != NULL) { status_t err = parseIdmap(header->resourceIDMap, header->resourceIDMapSize, &targetPackageId, &idmapEntries); if (err != NO_ERROR) { ALOGW("Overlay is broken"); return (mError=err); } } if (id >= 256) { LOG_ALWAYS_FATAL("Package id out of range"); return NO_ERROR; } else if (id == 0) { // This is a library so assign an ID id = mNextPackageId++; } if (pkgIdOverride != 0) { ALOGV("Overriding pkg id %d with %d", id, pkgIdOverride); id = pkgIdOverride; } PackageGroup* group = NULL; Package* package = new Package(this, header, pkg); if (package == NULL) { return (mError=NO_MEMORY); } package->pkgIdOverride = pkgIdOverride; err = package->typeStrings.setTo(base+dtohl(pkg->typeStrings), header->dataEnd-(base+dtohl(pkg->typeStrings))); if (err != NO_ERROR) { delete group; delete package; return (mError=err); } err = package->keyStrings.setTo(base+dtohl(pkg->keyStrings), header->dataEnd-(base+dtohl(pkg->keyStrings))); if (err != NO_ERROR) { delete group; delete package; return (mError=err); } size_t idx = mPackageMap[id]; if (idx == 0) { idx = mPackageGroups.size() + 1; char16_t tmpName[sizeof(pkg->name)/sizeof(pkg->name[0])]; strcpy16_dtoh(tmpName, pkg->name, sizeof(pkg->name)/sizeof(pkg->name[0])); group = new PackageGroup(this, String16(tmpName), id); if (group == NULL) { delete package; return (mError=NO_MEMORY); } err = mPackageGroups.add(group); if (err < NO_ERROR) { return (mError=err); } mPackageMap[id] = static_cast(idx); // Find all packages that reference this package size_t N = mPackageGroups.size(); for (size_t i = 0; i < N; i++) { mPackageGroups[i]->dynamicRefTable.addMapping( group->name, static_cast(group->id)); } } else { group = mPackageGroups.itemAt(idx - 1); if (group == NULL) { return (mError=UNKNOWN_ERROR); } } err = group->packages.add(package); if (err < NO_ERROR) { return (mError=err); } // Get the target group if this is an overlay PackageGroup* targetGroup = NULL; if (header->resourceIDMap != NULL) { targetGroup = mPackageGroups.itemAt(mPackageMap[targetPackageId] - 1); if (targetGroup != NULL) { targetGroup->overlayPackage = package; } } // Iterate through all chunks. const ResChunk_header* chunk = (const ResChunk_header*)(((const uint8_t*)pkg) + dtohs(pkg->header.headerSize)); const uint8_t* endPos = ((const uint8_t*)pkg) + dtohs(pkg->header.size); while (((const uint8_t*)chunk) <= (endPos-sizeof(ResChunk_header)) && ((const uint8_t*)chunk) <= (endPos-dtohl(chunk->size))) { if (kDebugTableNoisy) { ALOGV("PackageChunk: type=0x%x, headerSize=0x%x, size=0x%x, pos=%p\n", dtohs(chunk->type), dtohs(chunk->headerSize), dtohl(chunk->size), (void*)(((const uint8_t*)chunk) - ((const uint8_t*)header->header))); } const size_t csize = dtohl(chunk->size); const uint16_t ctype = dtohs(chunk->type); if (ctype == RES_TABLE_TYPE_SPEC_TYPE) { const ResTable_typeSpec* typeSpec = (const ResTable_typeSpec*)(chunk); err = validate_chunk(&typeSpec->header, sizeof(*typeSpec), endPos, "ResTable_typeSpec"); if (err != NO_ERROR) { return (mError=err); } const size_t typeSpecSize = dtohl(typeSpec->header.size); const size_t newEntryCount = dtohl(typeSpec->entryCount); if (kDebugLoadTableNoisy) { ALOGI("TypeSpec off %p: type=0x%x, headerSize=0x%x, size=%p\n", (void*)(base-(const uint8_t*)chunk), dtohs(typeSpec->header.type), dtohs(typeSpec->header.headerSize), (void*)typeSpecSize); } // look for block overrun or int overflow when multiplying by 4 if ((dtohl(typeSpec->entryCount) > (INT32_MAX/sizeof(uint32_t)) || dtohs(typeSpec->header.headerSize)+(sizeof(uint32_t)*newEntryCount) > typeSpecSize)) { ALOGW("ResTable_typeSpec entry index to %p extends beyond chunk end %p.", (void*)(dtohs(typeSpec->header.headerSize) + (sizeof(uint32_t)*newEntryCount)), (void*)typeSpecSize); return (mError=BAD_TYPE); } if (typeSpec->id == 0) { ALOGW("ResTable_type has an id of 0."); return (mError=BAD_TYPE); } if (newEntryCount > 0) { uint8_t typeIndex = typeSpec->id - 1; TypeList& typeList = group->types.editItemAt(typeIndex); if (!typeList.isEmpty()) { const Type* existingType = typeList[0]; if (existingType->entryCount != newEntryCount) { ALOGV("ResTable_typeSpec entry count inconsistent: given %d, previously %d", (int) newEntryCount, (int) existingType->entryCount); // We should normally abort here, but some legacy apps declare // resources in the 'android' package (old bug in AAPT). } } Type* t = new Type(header, package, newEntryCount); t->typeSpec = typeSpec; t->typeSpecFlags = (const uint32_t*)( ((const uint8_t*)typeSpec) + dtohs(typeSpec->header.headerSize)); typeList.add(t); group->largestTypeId = max(group->largestTypeId, typeSpec->id); // Add this type spec to the targetGroup if (targetGroup != NULL) { ssize_t idmapIndex = idmapEntries.indexOfKey(typeSpec->id); if (idmapIndex >= 0) { typeIndex = idmapEntries[idmapIndex].targetTypeId() - 1; TypeList& typeList = targetGroup->types.editItemAt(typeIndex); Type* t = new Type(header, package, newEntryCount); t->idmapEntries = idmapEntries[idmapIndex]; t->typeSpec = typeSpec; t->typeSpecFlags = (const uint32_t*)( ((const uint8_t*)typeSpec) + dtohs(typeSpec->header.headerSize)); typeList.add(t); } } } else { ALOGV("Skipping empty ResTable_typeSpec for type %d", typeSpec->id); } } else if (ctype == RES_TABLE_TYPE_TYPE) { const ResTable_type* type = (const ResTable_type*)(chunk); err = validate_chunk(&type->header, sizeof(*type)-sizeof(ResTable_config)+4, endPos, "ResTable_type"); if (err != NO_ERROR) { return (mError=err); } const uint32_t typeSize = dtohl(type->header.size); const size_t newEntryCount = dtohl(type->entryCount); if (kDebugLoadTableNoisy) { printf("Type off %p: type=0x%x, headerSize=0x%x, size=%u\n", (void*)(base-(const uint8_t*)chunk), dtohs(type->header.type), dtohs(type->header.headerSize), typeSize); } if (dtohs(type->header.headerSize)+(sizeof(uint32_t)*newEntryCount) > typeSize) { ALOGW("ResTable_type entry index to %p extends beyond chunk end 0x%x.", (void*)(dtohs(type->header.headerSize) + (sizeof(uint32_t)*newEntryCount)), typeSize); return (mError=BAD_TYPE); } if (newEntryCount != 0 && dtohl(type->entriesStart) > (typeSize-sizeof(ResTable_entry))) { ALOGW("ResTable_type entriesStart at 0x%x extends beyond chunk end 0x%x.", dtohl(type->entriesStart), typeSize); return (mError=BAD_TYPE); } if (type->id == 0) { ALOGW("ResTable_type has an id of 0."); return (mError=BAD_TYPE); } if (newEntryCount > 0) { uint8_t typeIndex = type->id - 1; TypeList& typeList = group->types.editItemAt(typeIndex); if (typeList.isEmpty()) { ALOGE("No TypeSpec for type %d", type->id); return (mError=BAD_TYPE); } Type* t = typeList.editItemAt(typeList.size() - 1); if (newEntryCount != t->entryCount) { ALOGE("ResTable_type entry count inconsistent: given %d, previously %d", (int)newEntryCount, (int)t->entryCount); return (mError=BAD_TYPE); } if (t->package != package) { ALOGE("No TypeSpec for type %d", type->id); return (mError=BAD_TYPE); } t->configs.add(type); if (kDebugTableGetEntry) { ResTable_config thisConfig; thisConfig.copyFromDtoH(type->config); ALOGI("Adding config to type %d: %s\n", type->id, thisConfig.toString().string()); } // Add this type to the targetGroup if (targetGroup != NULL) { ssize_t idmapIndex = idmapEntries.indexOfKey(type->id); if (idmapIndex >= 0) { typeIndex = idmapEntries[idmapIndex].targetTypeId() - 1; TypeList& typeList = targetGroup->types.editItemAt(typeIndex); if (typeList.isEmpty()) { ALOGE("No TypeSpec for type %d", type->id); return (mError=BAD_TYPE); } Type* t = typeList.editItemAt(typeList.size() - 1); if (newEntryCount != t->entryCount) { ALOGE("ResTable_type entry count inconsistent: given %d, previously %d", (int)newEntryCount, (int)t->entryCount); return (mError=BAD_TYPE); } if (t->package != package) { ALOGE("No TypeSpec for type %d", type->id); return (mError=BAD_TYPE); } t->configs.add(type); } } } else { ALOGV("Skipping empty ResTable_type for type %d", type->id); } } else if (ctype == RES_TABLE_LIBRARY_TYPE) { if (group->dynamicRefTable.entries().size() == 0) { status_t err = group->dynamicRefTable.load((const ResTable_lib_header*) chunk); if (err != NO_ERROR) { return (mError=err); } // Fill in the reference table with the entries we already know about. size_t N = mPackageGroups.size(); for (size_t i = 0; i < N; i++) { group->dynamicRefTable.addMapping(mPackageGroups[i]->name, mPackageGroups[i]->id); } } else { ALOGW("Found multiple library tables, ignoring..."); } } else { status_t err = validate_chunk(chunk, sizeof(ResChunk_header), endPos, "ResTable_package:unknown"); if (err != NO_ERROR) { return (mError=err); } } chunk = (const ResChunk_header*) (((const uint8_t*)chunk) + csize); } return NO_ERROR; } DynamicRefTable::DynamicRefTable(uint8_t packageId) : mAssignedPackageId(packageId) { memset(mLookupTable, 0, sizeof(mLookupTable)); // Reserved package ids mLookupTable[APP_PACKAGE_ID] = APP_PACKAGE_ID; mLookupTable[SYS_PACKAGE_ID] = SYS_PACKAGE_ID; mLookupTable[CMSDK_PACKAGE_ID] = CMSDK_PACKAGE_ID; mLookupTable[OVERLAY_APP_PACKAGE_ID] = OVERLAY_APP_PACKAGE_ID; mLookupTable[OVERLAY_SYS_PACKAGE_ID] = OVERLAY_SYS_PACKAGE_ID; mLookupTable[OVERLAY_COMMON_PACKAGE_ID] = OVERLAY_COMMON_PACKAGE_ID; mLookupTable[OVERLAY_CMSDK_PACKAGE_ID] = OVERLAY_CMSDK_PACKAGE_ID; } status_t DynamicRefTable::load(const ResTable_lib_header* const header) { const uint32_t entryCount = dtohl(header->count); const uint32_t sizeOfEntries = sizeof(ResTable_lib_entry) * entryCount; const uint32_t expectedSize = dtohl(header->header.size) - dtohl(header->header.headerSize); if (sizeOfEntries > expectedSize) { ALOGE("ResTable_lib_header size %u is too small to fit %u entries (x %u).", expectedSize, entryCount, (uint32_t)sizeof(ResTable_lib_entry)); return UNKNOWN_ERROR; } const ResTable_lib_entry* entry = (const ResTable_lib_entry*)(((uint8_t*) header) + dtohl(header->header.headerSize)); for (uint32_t entryIndex = 0; entryIndex < entryCount; entryIndex++) { uint32_t packageId = dtohl(entry->packageId); char16_t tmpName[sizeof(entry->packageName) / sizeof(char16_t)]; strcpy16_dtoh(tmpName, entry->packageName, sizeof(entry->packageName) / sizeof(char16_t)); if (kDebugLibNoisy) { ALOGV("Found lib entry %s with id %d\n", String8(tmpName).string(), dtohl(entry->packageId)); } if (packageId >= 256) { ALOGE("Bad package id 0x%08x", packageId); return UNKNOWN_ERROR; } mEntries.replaceValueFor(String16(tmpName), (uint8_t) packageId); entry = entry + 1; } return NO_ERROR; } status_t DynamicRefTable::addMappings(const DynamicRefTable& other) { if (mAssignedPackageId != other.mAssignedPackageId) { return UNKNOWN_ERROR; } const size_t entryCount = other.mEntries.size(); for (size_t i = 0; i < entryCount; i++) { ssize_t index = mEntries.indexOfKey(other.mEntries.keyAt(i)); if (index < 0) { mEntries.add(other.mEntries.keyAt(i), other.mEntries[i]); } else { if (other.mEntries[i] != mEntries[index]) { return UNKNOWN_ERROR; } } } // Merge the lookup table. No entry can conflict // (value of 0 means not set). for (size_t i = 0; i < 256; i++) { if (mLookupTable[i] != other.mLookupTable[i]) { if (mLookupTable[i] == 0) { mLookupTable[i] = other.mLookupTable[i]; } else if (other.mLookupTable[i] != 0) { return UNKNOWN_ERROR; } } } return NO_ERROR; } status_t DynamicRefTable::addMapping(const String16& packageName, uint8_t packageId) { ssize_t index = mEntries.indexOfKey(packageName); if (index < 0) { return UNKNOWN_ERROR; } mLookupTable[mEntries.valueAt(index)] = packageId; return NO_ERROR; } status_t DynamicRefTable::lookupResourceId(uint32_t* resId) const { uint32_t res = *resId; size_t packageId = Res_GETPACKAGE(res) + 1; if (packageId == APP_PACKAGE_ID || packageId == OVERLAY_APP_PACKAGE_ID || packageId == OVERLAY_SYS_PACKAGE_ID || packageId == OVERLAY_COMMON_PACKAGE_ID || packageId == OVERLAY_CMSDK_PACKAGE_ID) { // No lookup needs to be done, app package IDs are absolute. return NO_ERROR; } if (packageId == 0) { // The package ID is 0x00. That means that a shared library is accessing // its own local resource, so we fix up the resource with the calling // package ID. *resId |= ((uint32_t) mAssignedPackageId) << 24; return NO_ERROR; } // Do a proper lookup. uint8_t translatedId = mLookupTable[packageId]; if (translatedId == 0) { ALOGV("DynamicRefTable(0x%02x): No mapping for build-time package ID 0x%02x.", (uint8_t)mAssignedPackageId, (uint8_t)packageId); for (size_t i = 0; i < 256; i++) { if (mLookupTable[i] != 0) { ALOGV("e[0x%02x] -> 0x%02x", (uint8_t)i, mLookupTable[i]); } } return UNKNOWN_ERROR; } *resId = (res & 0x00ffffff) | (((uint32_t) translatedId) << 24); return NO_ERROR; } status_t DynamicRefTable::lookupResourceValue(Res_value* value) const { if (value->dataType != Res_value::TYPE_DYNAMIC_REFERENCE) { return NO_ERROR; } status_t err = lookupResourceId(&value->data); if (err != NO_ERROR) { return err; } value->dataType = Res_value::TYPE_REFERENCE; return NO_ERROR; } struct IdmapTypeMap { ssize_t overlayTypeId; size_t entryOffset; Vector entryMap; }; status_t ResTable::createIdmap(const ResTable& overlay, uint32_t targetCrc, uint32_t overlayCrc, time_t targetMtime, time_t overlayMtime, const char* targetPath, const char* overlayPath, void** outData, size_t* outSize) const { // see README for details on the format of map if (mPackageGroups.size() == 0) { ALOGW("idmap: target package has no package groups, cannot create idmap\n"); return UNKNOWN_ERROR; } if (mPackageGroups[0]->packages.size() == 0) { ALOGW("idmap: target package has no packages in its first package group, " "cannot create idmap\n"); return UNKNOWN_ERROR; } KeyedVector map; // Overlaid packages are assumed to contain only one package group or two package group // as one is "system package(android)", and another is "application package". So we need // to use the last package group to create idmap. const PackageGroup* pg = mPackageGroups[mPackageGroups.size() - 1]; // starting size is header *outSize = ResTable::IDMAP_HEADER_SIZE_BYTES; // target package id and number of types in map *outSize += 2 * sizeof(uint16_t); // overlay packages are assumed to contain only one package group const ResTable_package* overlayPackageStruct = overlay.mPackageGroups[0]->packages[0]->package; char16_t tmpName[sizeof(overlayPackageStruct->name)/sizeof(overlayPackageStruct->name[0])]; strcpy16_dtoh(tmpName, overlayPackageStruct->name, sizeof(overlayPackageStruct->name)/sizeof(overlayPackageStruct->name[0])); const String16 overlayPackage(tmpName); Package* pkg; size_t typeCount; uint32_t pkg_id; const uint32_t groupCount = mPackageGroups.size(); for (int groupIdx = groupCount - 1; groupIdx >= 0; groupIdx--) { pg = mPackageGroups[groupIdx]; pkg = pg->packages[0]; typeCount = pg->types.size(); pkg_id = pkg->package->id << 24; for (size_t typeIndex = 0; typeIndex < typeCount; ++typeIndex) { const TypeList& typeList = pg->types[typeIndex]; if (typeList.isEmpty()) { continue; } const Type* typeConfigs = typeList[0]; IdmapTypeMap typeMap; typeMap.overlayTypeId = -1; typeMap.entryOffset = 0; for (size_t entryIndex = 0; entryIndex < typeConfigs->entryCount; ++entryIndex) { uint32_t resID = Res_MAKEID(pg->id - 1, typeIndex, entryIndex); resource_name resName; if (!this->getResourceName(resID, false, &resName)) { if (typeMap.entryMap.isEmpty()) { typeMap.entryOffset++; } continue; } // check if resource type is "allowed", if not continue String8 type8; if (resName.type8 != NULL) { type8 = String8(resName.type8, resName.typeLen); } else { type8 = String8(resName.type, resName.typeLen); } if (!isResTypeAllowed(type8.string())) { if (typeMap.entryMap.isEmpty()) { typeMap.entryOffset++; } continue; } const String16 overlayType(resName.type, resName.typeLen); const String16 overlayName(resName.name, resName.nameLen); uint32_t overlayResID = overlay.identifierForName(overlayName.string(), overlayName.size(), overlayType.string(), overlayType.size(), overlayPackage.string(), overlayPackage.size()); if (overlayResID == 0) { if (typeMap.entryMap.isEmpty()) { typeMap.entryOffset++; } continue; } else { overlayResID = pkg_id | (0x00ffffff & overlayResID); } if (typeMap.overlayTypeId == -1) { typeMap.overlayTypeId = Res_GETTYPE(overlayResID) + 1; } if (Res_GETTYPE(overlayResID) + 1 != static_cast(typeMap.overlayTypeId)) { ALOGE("idmap: can't mix type ids in entry map. Resource 0x%08x maps to 0x%08x" " but entries should map to resources of type %02zx", resID, overlayResID, typeMap.overlayTypeId); return BAD_TYPE; } if (typeMap.entryOffset + typeMap.entryMap.size() < entryIndex) { // pad with 0xffffffff's (indicating non-existing entries) before adding this entry size_t index = typeMap.entryMap.size(); size_t numItems = entryIndex - (typeMap.entryOffset + index); if (typeMap.entryMap.insertAt(0xffffffff, index, numItems) < 0) { return NO_MEMORY; } } typeMap.entryMap.add(Res_GETENTRY(overlayResID)); } if (!typeMap.entryMap.isEmpty()) { if (map.add(static_cast(typeIndex), typeMap) < 0) { return NO_MEMORY; } *outSize += (4 * sizeof(uint16_t)) + (typeMap.entryMap.size() * sizeof(uint32_t)); } } } if (map.isEmpty()) { ALOGW("idmap: no resources in overlay package present in base package"); } if ((*outData = malloc(*outSize)) == NULL) { return NO_MEMORY; } uint32_t* data = (uint32_t*)*outData; *data++ = htodl(IDMAP_MAGIC); *data++ = htodl(IDMAP_CURRENT_VERSION); *data++ = htodl(targetCrc); *data++ = htodl(overlayCrc); *data++ = htodl(targetMtime); *data++ = htodl(overlayMtime); const char* paths[] = { targetPath, overlayPath }; for (int j = 0; j < 2; ++j) { char* p = (char*)data; const char* path = paths[j]; const size_t I = strlen(path); if (I > 255) { ALOGV("path exceeds expected 255 characters: %s\n", path); return UNKNOWN_ERROR; } for (size_t i = 0; i < 256; ++i) { *p++ = i < I ? path[i] : '\0'; } data += 256 / sizeof(uint32_t); } const size_t mapSize = map.size(); uint16_t* typeData = reinterpret_cast(data); *typeData++ = htods(pg->id); *typeData++ = htods(mapSize); for (size_t i = 0; i < mapSize; ++i) { uint8_t targetTypeId = map.keyAt(i); const IdmapTypeMap& typeMap = map[i]; *typeData++ = htods(targetTypeId + 1); *typeData++ = htods(typeMap.overlayTypeId); *typeData++ = htods(typeMap.entryMap.size()); *typeData++ = htods(typeMap.entryOffset); const size_t entryCount = typeMap.entryMap.size(); uint32_t* entries = reinterpret_cast(typeData); for (size_t j = 0; j < entryCount; j++) { entries[j] = htodl(typeMap.entryMap[j]); } typeData += entryCount * 2; } return NO_ERROR; } bool ResTable::getIdmapInfo(const void* idmap, size_t sizeBytes, uint32_t* pVersion, uint32_t* pTargetCrc, uint32_t* pOverlayCrc, String8* pTargetPath, String8* pOverlayPath) { const uint32_t* map = (const uint32_t*)idmap; if (!assertIdmapHeader(map, sizeBytes)) { return false; } if (pVersion) { *pVersion = dtohl(map[1]); } if (pTargetCrc) { *pTargetCrc = dtohl(map[2]); } if (pOverlayCrc) { *pOverlayCrc = dtohl(map[3]); } if (pTargetPath) { pTargetPath->setTo(reinterpret_cast(map + 6)); } if (pOverlayPath) { pOverlayPath->setTo(reinterpret_cast(map + 6 + 256 / sizeof(uint32_t))); } return true; } void ResTable::removeAssetsByCookie(const String8& /* packageName */, int32_t cookie) { mError = NO_ERROR; size_t pgCount = mPackageGroups.size(); for (size_t pgIndex = 0; pgIndex < pgCount; pgIndex++) { PackageGroup* pg = mPackageGroups[pgIndex]; size_t pkgCount = pg->packages.size(); size_t index = pkgCount; for (size_t pkgIndex = 0; pkgIndex < pkgCount; pkgIndex++) { const Package* pkg = pg->packages[pkgIndex]; if (pkg->header->cookie == cookie) { index = pkgIndex; break; } } if (index < pkgCount) { const Package* pkg = pg->packages[index]; uint32_t id = dtohl(pkg->package->id); if (pkg->pkgIdOverride != 0) { id = pkg->pkgIdOverride; } if (id != 0 && id < 256 && pkgCount == 1) { mPackageMap[id] = 0; } // Check if this package is being reference in any other groups and remove it size_t N = mPackageGroups.size(); for (size_t i = 0; i < N; i++) { PackageGroup* grp = mPackageGroups.itemAt(i); if (grp->overlayPackage == pkg) { removeIdmappedTypesFromPackageGroup(grp); grp->clearBagCache(); grp->overlayPackage = NULL; } } if (pkgCount == 1) { mPackageGroups.removeAt(pgIndex); delete pg; } else { pg->packages.removeAt(index); delete pkg; } break; } } size_t N = mHeaders.size(); for (size_t i = 0; i < N; i++) { Header* header = mHeaders[i]; if (header->cookie == cookie) { if (header->ownedData != NULL) { free(header->ownedData); } mHeaders.removeAt(i); break; } } } bool ResTable::isResTypeAllowed(const char* type) const { if (type == NULL) return false; const char* allowedResources[] = { "color", "dimen", "drawable", "mipmap", "style", "anim" }; // ALLOWED_RESOURCE_COUNT should match the number of elements in allowedResources const uint32_t ALLOWED_RESOURCE_COUNT = 6; for (uint32_t i = 0; i < ALLOWED_RESOURCE_COUNT; i++) { if (strstr(type, allowedResources[i]) != NULL) return true; } return false; } bool ResTable::isDynamicPackageId(const uint32_t pkgId) const { return pkgId != APP_PACKAGE_ID && pkgId != SYS_PACKAGE_ID && pkgId != OVERLAY_APP_PACKAGE_ID && pkgId != OVERLAY_SYS_PACKAGE_ID && pkgId != OVERLAY_COMMON_PACKAGE_ID && pkgId != CMSDK_PACKAGE_ID && pkgId != OVERLAY_CMSDK_PACKAGE_ID; } status_t ResTable::removeIdmappedTypesFromPackageGroup(PackageGroup* packageGroup) const { for (size_t idx = 0; idx < Res_MAXTYPE; idx++) { const TypeList& typeList = packageGroup->types[idx]; if (!typeList.isEmpty()) { TypeList& editTypeList = packageGroup->types.editItemAt(idx); // Iterate over the Types of each package. for (Vector::iterator iter = editTypeList.begin(); iter != editTypeList.end();) { Type* type = *iter; if (type->idmapEntries.hasEntries()) { iter = editTypeList.erase(iter); } else { ++iter; } } } } return NO_ERROR; } #define CHAR16_TO_CSTR(c16, len) (String8(String16(c16,len)).string()) #define CHAR16_ARRAY_EQ(constant, var, len) \ ((len == (sizeof(constant)/sizeof(constant[0]))) && (0 == memcmp((var), (constant), (len)))) static void print_complex(uint32_t complex, bool isFraction) { const float MANTISSA_MULT = 1.0f / (1<>Res_value::COMPLEX_RADIX_SHIFT) & Res_value::COMPLEX_RADIX_MASK]; printf("%f", value); if (!isFraction) { switch ((complex>>Res_value::COMPLEX_UNIT_SHIFT)&Res_value::COMPLEX_UNIT_MASK) { case Res_value::COMPLEX_UNIT_PX: printf("px"); break; case Res_value::COMPLEX_UNIT_DIP: printf("dp"); break; case Res_value::COMPLEX_UNIT_SP: printf("sp"); break; case Res_value::COMPLEX_UNIT_PT: printf("pt"); break; case Res_value::COMPLEX_UNIT_IN: printf("in"); break; case Res_value::COMPLEX_UNIT_MM: printf("mm"); break; default: printf(" (unknown unit)"); break; } } else { switch ((complex>>Res_value::COMPLEX_UNIT_SHIFT)&Res_value::COMPLEX_UNIT_MASK) { case Res_value::COMPLEX_UNIT_FRACTION: printf("%%"); break; case Res_value::COMPLEX_UNIT_FRACTION_PARENT: printf("%%p"); break; default: printf(" (unknown unit)"); break; } } } // Normalize a string for output String8 ResTable::normalizeForOutput( const char *input ) { String8 ret; char buff[2]; buff[1] = '\0'; while (*input != '\0') { switch (*input) { // All interesting characters are in the ASCII zone, so we are making our own lives // easier by scanning the string one byte at a time. case '\\': ret += "\\\\"; break; case '\n': ret += "\\n"; break; case '"': ret += "\\\""; break; default: buff[0] = *input; ret += buff; break; } input++; } return ret; } void ResTable::print_value(const Package* pkg, const Res_value& value) const { if (value.dataType == Res_value::TYPE_NULL) { if (value.data == Res_value::DATA_NULL_UNDEFINED) { printf("(null)\n"); } else if (value.data == Res_value::DATA_NULL_EMPTY) { printf("(null empty)\n"); } else { // This should never happen. printf("(null) 0x%08x\n", value.data); } } else if (value.dataType == Res_value::TYPE_REFERENCE) { printf("(reference) 0x%08x\n", value.data); } else if (value.dataType == Res_value::TYPE_DYNAMIC_REFERENCE) { printf("(dynamic reference) 0x%08x\n", value.data); } else if (value.dataType == Res_value::TYPE_ATTRIBUTE) { printf("(attribute) 0x%08x\n", value.data); } else if (value.dataType == Res_value::TYPE_STRING) { size_t len; const char* str8 = pkg->header->values.string8At( value.data, &len); if (str8 != NULL) { printf("(string8) \"%s\"\n", normalizeForOutput(str8).string()); } else { const char16_t* str16 = pkg->header->values.stringAt( value.data, &len); if (str16 != NULL) { printf("(string16) \"%s\"\n", normalizeForOutput(String8(str16, len).string()).string()); } else { printf("(string) null\n"); } } } else if (value.dataType == Res_value::TYPE_FLOAT) { printf("(float) %g\n", *(const float*)&value.data); } else if (value.dataType == Res_value::TYPE_DIMENSION) { printf("(dimension) "); print_complex(value.data, false); printf("\n"); } else if (value.dataType == Res_value::TYPE_FRACTION) { printf("(fraction) "); print_complex(value.data, true); printf("\n"); } else if (value.dataType >= Res_value::TYPE_FIRST_COLOR_INT || value.dataType <= Res_value::TYPE_LAST_COLOR_INT) { printf("(color) #%08x\n", value.data); } else if (value.dataType == Res_value::TYPE_INT_BOOLEAN) { printf("(boolean) %s\n", value.data ? "true" : "false"); } else if (value.dataType >= Res_value::TYPE_FIRST_INT || value.dataType <= Res_value::TYPE_LAST_INT) { printf("(int) 0x%08x or %d\n", value.data, value.data); } else { printf("(unknown type) t=0x%02x d=0x%08x (s=0x%04x r=0x%02x)\n", (int)value.dataType, (int)value.data, (int)value.size, (int)value.res0); } } void ResTable::print(bool inclValues) const { if (mError != 0) { printf("mError=0x%x (%s)\n", mError, strerror(mError)); } size_t pgCount = mPackageGroups.size(); printf("Package Groups (%d)\n", (int)pgCount); for (size_t pgIndex=0; pgIndexid, (int)pg->packages.size(), String8(pg->name).string()); const KeyedVector& refEntries = pg->dynamicRefTable.entries(); const size_t refEntryCount = refEntries.size(); if (refEntryCount > 0) { printf(" DynamicRefTable entryCount=%d:\n", (int) refEntryCount); for (size_t refIndex = 0; refIndex < refEntryCount; refIndex++) { printf(" 0x%02x -> %s\n", refEntries.valueAt(refIndex), String8(refEntries.keyAt(refIndex)).string()); } printf("\n"); } int packageId = pg->id; size_t pkgCount = pg->packages.size(); for (size_t pkgIndex=0; pkgIndexpackages[pkgIndex]; // Use a package's real ID, since the ID may have been assigned // if this package is a shared library. packageId = pkg->package->id; char16_t tmpName[sizeof(pkg->package->name)/sizeof(pkg->package->name[0])]; strcpy16_dtoh(tmpName, pkg->package->name, sizeof(pkg->package->name)/sizeof(pkg->package->name[0])); printf(" Package %d id=0x%02x name=%s\n", (int)pkgIndex, pkg->package->id, String8(tmpName).string()); } for (size_t typeIndex=0; typeIndex < pg->types.size(); typeIndex++) { const TypeList& typeList = pg->types[typeIndex]; if (typeList.isEmpty()) { continue; } const Type* typeConfigs = typeList[0]; const size_t NTC = typeConfigs->configs.size(); printf(" type %d configCount=%d entryCount=%d\n", (int)typeIndex, (int)NTC, (int)typeConfigs->entryCount); if (typeConfigs->typeSpecFlags != NULL) { for (size_t entryIndex=0; entryIndexentryCount; entryIndex++) { uint32_t resID = (0xff000000 & ((packageId)<<24)) | (0x00ff0000 & ((typeIndex+1)<<16)) | (0x0000ffff & (entryIndex)); // Since we are creating resID without actually // iterating over them, we have no idea which is a // dynamic reference. We must check. if (packageId == 0) { pg->dynamicRefTable.lookupResourceId(&resID); } resource_name resName; if (this->getResourceName(resID, true, &resName)) { String8 type8; String8 name8; if (resName.type8 != NULL) { type8 = String8(resName.type8, resName.typeLen); } else { type8 = String8(resName.type, resName.typeLen); } if (resName.name8 != NULL) { name8 = String8(resName.name8, resName.nameLen); } else { name8 = String8(resName.name, resName.nameLen); } printf(" spec resource 0x%08x %s:%s/%s: flags=0x%08x\n", resID, CHAR16_TO_CSTR(resName.package, resName.packageLen), type8.string(), name8.string(), dtohl(typeConfigs->typeSpecFlags[entryIndex])); } else { printf(" INVALID TYPE CONFIG FOR RESOURCE 0x%08x\n", resID); } } } for (size_t configIndex=0; configIndexconfigs[configIndex]; if ((((uint64_t)type)&0x3) != 0) { printf(" NON-INTEGER ResTable_type ADDRESS: %p\n", type); continue; } // Always copy the config, as fields get added and we need to // set the defaults. ResTable_config thisConfig; thisConfig.copyFromDtoH(type->config); String8 configStr = thisConfig.toString(); printf(" config %s:\n", configStr.size() > 0 ? configStr.string() : "(default)"); size_t entryCount = dtohl(type->entryCount); uint32_t entriesStart = dtohl(type->entriesStart); if ((entriesStart&0x3) != 0) { printf(" NON-INTEGER ResTable_type entriesStart OFFSET: 0x%x\n", entriesStart); continue; } uint32_t typeSize = dtohl(type->header.size); if ((typeSize&0x3) != 0) { printf(" NON-INTEGER ResTable_type header.size: 0x%x\n", typeSize); continue; } for (size_t entryIndex=0; entryIndexheader.headerSize)); uint32_t thisOffset = dtohl(eindex[entryIndex]); if (thisOffset == ResTable_type::NO_ENTRY) { continue; } uint32_t resID = (0xff000000 & ((packageId)<<24)) | (0x00ff0000 & ((typeIndex+1)<<16)) | (0x0000ffff & (entryIndex)); if (packageId == 0) { pg->dynamicRefTable.lookupResourceId(&resID); } resource_name resName; if (this->getResourceName(resID, true, &resName)) { String8 type8; String8 name8; if (resName.type8 != NULL) { type8 = String8(resName.type8, resName.typeLen); } else { type8 = String8(resName.type, resName.typeLen); } if (resName.name8 != NULL) { name8 = String8(resName.name8, resName.nameLen); } else { name8 = String8(resName.name, resName.nameLen); } printf(" resource 0x%08x %s:%s/%s: ", resID, CHAR16_TO_CSTR(resName.package, resName.packageLen), type8.string(), name8.string()); } else { printf(" INVALID RESOURCE 0x%08x: ", resID); } if ((thisOffset&0x3) != 0) { printf("NON-INTEGER OFFSET: 0x%x\n", thisOffset); continue; } if ((thisOffset+sizeof(ResTable_entry)) > typeSize) { printf("OFFSET OUT OF BOUNDS: 0x%x+0x%x (size is 0x%x)\n", entriesStart, thisOffset, typeSize); continue; } const ResTable_entry* ent = (const ResTable_entry*) (((const uint8_t*)type) + entriesStart + thisOffset); if (((entriesStart + thisOffset)&0x3) != 0) { printf("NON-INTEGER ResTable_entry OFFSET: 0x%x\n", (entriesStart + thisOffset)); continue; } uintptr_t esize = dtohs(ent->size); if ((esize&0x3) != 0) { printf("NON-INTEGER ResTable_entry SIZE: %p\n", (void *)esize); continue; } if ((thisOffset+esize) > typeSize) { printf("ResTable_entry OUT OF BOUNDS: 0x%x+0x%x+%p (size is 0x%x)\n", entriesStart, thisOffset, (void *)esize, typeSize); continue; } const Res_value* valuePtr = NULL; const ResTable_map_entry* bagPtr = NULL; Res_value value; if ((dtohs(ent->flags)&ResTable_entry::FLAG_COMPLEX) != 0) { printf(""); bagPtr = (const ResTable_map_entry*)ent; } else { valuePtr = (const Res_value*) (((const uint8_t*)ent) + esize); value.copyFrom_dtoh(*valuePtr); printf("t=0x%02x d=0x%08x (s=0x%04x r=0x%02x)", (int)value.dataType, (int)value.data, (int)value.size, (int)value.res0); } if ((dtohs(ent->flags)&ResTable_entry::FLAG_PUBLIC) != 0) { printf(" (PUBLIC)"); } printf("\n"); if (inclValues) { if (valuePtr != NULL) { printf(" "); print_value(typeConfigs->package, value); } else if (bagPtr != NULL) { const int N = dtohl(bagPtr->count); const uint8_t* baseMapPtr = (const uint8_t*)ent; size_t mapOffset = esize; const ResTable_map* mapPtr = (ResTable_map*)(baseMapPtr+mapOffset); const uint32_t parent = dtohl(bagPtr->parent.ident); uint32_t resolvedParent = parent; if (Res_GETPACKAGE(resolvedParent) + 1 == 0) { status_t err = pg->dynamicRefTable.lookupResourceId(&resolvedParent); if (err != NO_ERROR) { resolvedParent = 0; } } printf(" Parent=0x%08x(Resolved=0x%08x), Count=%d\n", parent, resolvedParent, N); for (int i=0; iname.ident)); value.copyFrom_dtoh(mapPtr->value); print_value(typeConfigs->package, value); const size_t size = dtohs(mapPtr->value.size); mapOffset += size + sizeof(*mapPtr)-sizeof(mapPtr->value); mapPtr = (ResTable_map*)(baseMapPtr+mapOffset); } } } } } } } } } // namespace android