blob: 04cc5bb30ade1cb7cbfa8e0e29ce4cd0b918576e [file] [log] [blame]
/*
* Copyright (C) 2016 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 ATRACE_TAG ATRACE_TAG_RESOURCES
#include "androidfw/AssetManager2.h"
#include <algorithm>
#include <iterator>
#include <set>
#include "android-base/logging.h"
#include "android-base/stringprintf.h"
#include "utils/ByteOrder.h"
#include "utils/Trace.h"
#ifdef _WIN32
#ifdef ERROR
#undef ERROR
#endif
#endif
#include "androidfw/ResourceUtils.h"
namespace android {
struct FindEntryResult {
// A pointer to the resource table entry for this resource.
// If the size of the entry is > sizeof(ResTable_entry), it can be cast to
// a ResTable_map_entry and processed as a bag/map.
const ResTable_entry* entry;
// The configuration for which the resulting entry was defined. This is already swapped to host
// endianness.
ResTable_config config;
// The bitmask of configuration axis with which the resource value varies.
uint32_t type_flags;
// The dynamic package ID map for the package from which this resource came from.
const DynamicRefTable* dynamic_ref_table;
// The string pool reference to the type's name. This uses a different string pool than
// the global string pool, but this is hidden from the caller.
StringPoolRef type_string_ref;
// The string pool reference to the entry's name. This uses a different string pool than
// the global string pool, but this is hidden from the caller.
StringPoolRef entry_string_ref;
};
AssetManager2::AssetManager2() {
memset(&configuration_, 0, sizeof(configuration_));
}
bool AssetManager2::SetApkAssets(const std::vector<const ApkAssets*>& apk_assets,
bool invalidate_caches, bool filter_incompatible_configs) {
apk_assets_ = apk_assets;
BuildDynamicRefTable();
RebuildFilterList(filter_incompatible_configs);
if (invalidate_caches) {
InvalidateCaches(static_cast<uint32_t>(-1));
}
return true;
}
void AssetManager2::BuildDynamicRefTable() {
package_groups_.clear();
package_ids_.fill(0xff);
// 0x01 is reserved for the android package.
int next_package_id = 0x02;
const size_t apk_assets_count = apk_assets_.size();
for (size_t i = 0; i < apk_assets_count; i++) {
const LoadedArsc* loaded_arsc = apk_assets_[i]->GetLoadedArsc();
for (const std::unique_ptr<const LoadedPackage>& package : loaded_arsc->GetPackages()) {
// Get the package ID or assign one if a shared library.
int package_id;
if (package->IsDynamic()) {
package_id = next_package_id++;
} else {
package_id = package->GetPackageId();
}
// Add the mapping for package ID to index if not present.
uint8_t idx = package_ids_[package_id];
if (idx == 0xff) {
package_ids_[package_id] = idx = static_cast<uint8_t>(package_groups_.size());
package_groups_.push_back({});
DynamicRefTable& ref_table = package_groups_.back().dynamic_ref_table;
ref_table.mAssignedPackageId = package_id;
ref_table.mAppAsLib = package->IsDynamic() && package->GetPackageId() == 0x7f;
}
PackageGroup* package_group = &package_groups_[idx];
// Add the package and to the set of packages with the same ID.
package_group->packages_.push_back(ConfiguredPackage{package.get(), {}});
package_group->cookies_.push_back(static_cast<ApkAssetsCookie>(i));
// Add the package name -> build time ID mappings.
for (const DynamicPackageEntry& entry : package->GetDynamicPackageMap()) {
String16 package_name(entry.package_name.c_str(), entry.package_name.size());
package_group->dynamic_ref_table.mEntries.replaceValueFor(
package_name, static_cast<uint8_t>(entry.package_id));
}
}
}
// Now assign the runtime IDs so that we have a build-time to runtime ID map.
const auto package_groups_end = package_groups_.end();
for (auto iter = package_groups_.begin(); iter != package_groups_end; ++iter) {
const std::string& package_name = iter->packages_[0].loaded_package_->GetPackageName();
for (auto iter2 = package_groups_.begin(); iter2 != package_groups_end; ++iter2) {
iter2->dynamic_ref_table.addMapping(String16(package_name.c_str(), package_name.size()),
iter->dynamic_ref_table.mAssignedPackageId);
}
}
}
void AssetManager2::DumpToLog() const {
base::ScopedLogSeverity _log(base::INFO);
LOG(INFO) << base::StringPrintf("AssetManager2(this=%p)", this);
std::string list;
for (const auto& apk_assets : apk_assets_) {
base::StringAppendF(&list, "%s,", apk_assets->GetPath().c_str());
}
LOG(INFO) << "ApkAssets: " << list;
list = "";
for (size_t i = 0; i < package_ids_.size(); i++) {
if (package_ids_[i] != 0xff) {
base::StringAppendF(&list, "%02x -> %d, ", (int)i, package_ids_[i]);
}
}
LOG(INFO) << "Package ID map: " << list;
for (const auto& package_group: package_groups_) {
list = "";
for (const auto& package : package_group.packages_) {
const LoadedPackage* loaded_package = package.loaded_package_;
base::StringAppendF(&list, "%s(%02x%s), ", loaded_package->GetPackageName().c_str(),
loaded_package->GetPackageId(),
(loaded_package->IsDynamic() ? " dynamic" : ""));
}
LOG(INFO) << base::StringPrintf("PG (%02x): ",
package_group.dynamic_ref_table.mAssignedPackageId)
<< list;
}
}
const ResStringPool* AssetManager2::GetStringPoolForCookie(ApkAssetsCookie cookie) const {
if (cookie < 0 || static_cast<size_t>(cookie) >= apk_assets_.size()) {
return nullptr;
}
return apk_assets_[cookie]->GetLoadedArsc()->GetStringPool();
}
const DynamicRefTable* AssetManager2::GetDynamicRefTableForPackage(uint32_t package_id) const {
if (package_id >= package_ids_.size()) {
return nullptr;
}
const size_t idx = package_ids_[package_id];
if (idx == 0xff) {
return nullptr;
}
return &package_groups_[idx].dynamic_ref_table;
}
const DynamicRefTable* AssetManager2::GetDynamicRefTableForCookie(ApkAssetsCookie cookie) const {
for (const PackageGroup& package_group : package_groups_) {
for (const ApkAssetsCookie& package_cookie : package_group.cookies_) {
if (package_cookie == cookie) {
return &package_group.dynamic_ref_table;
}
}
}
return nullptr;
}
void AssetManager2::SetConfiguration(const ResTable_config& configuration) {
const int diff = configuration_.diff(configuration);
configuration_ = configuration;
if (diff) {
RebuildFilterList();
InvalidateCaches(static_cast<uint32_t>(diff));
}
}
std::set<ResTable_config> AssetManager2::GetResourceConfigurations(bool exclude_system,
bool exclude_mipmap) const {
ATRACE_NAME("AssetManager::GetResourceConfigurations");
std::set<ResTable_config> configurations;
for (const PackageGroup& package_group : package_groups_) {
for (const ConfiguredPackage& package : package_group.packages_) {
if (exclude_system && package.loaded_package_->IsSystem()) {
continue;
}
package.loaded_package_->CollectConfigurations(exclude_mipmap, &configurations);
}
}
return configurations;
}
std::set<std::string> AssetManager2::GetResourceLocales(bool exclude_system,
bool merge_equivalent_languages) const {
ATRACE_NAME("AssetManager::GetResourceLocales");
std::set<std::string> locales;
for (const PackageGroup& package_group : package_groups_) {
for (const ConfiguredPackage& package : package_group.packages_) {
if (exclude_system && package.loaded_package_->IsSystem()) {
continue;
}
package.loaded_package_->CollectLocales(merge_equivalent_languages, &locales);
}
}
return locales;
}
std::unique_ptr<Asset> AssetManager2::Open(const std::string& filename,
Asset::AccessMode mode) const {
const std::string new_path = "assets/" + filename;
return OpenNonAsset(new_path, mode);
}
std::unique_ptr<Asset> AssetManager2::Open(const std::string& filename, ApkAssetsCookie cookie,
Asset::AccessMode mode) const {
const std::string new_path = "assets/" + filename;
return OpenNonAsset(new_path, cookie, mode);
}
std::unique_ptr<AssetDir> AssetManager2::OpenDir(const std::string& dirname) const {
ATRACE_NAME("AssetManager::OpenDir");
std::string full_path = "assets/" + dirname;
std::unique_ptr<SortedVector<AssetDir::FileInfo>> files =
util::make_unique<SortedVector<AssetDir::FileInfo>>();
// Start from the back.
for (auto iter = apk_assets_.rbegin(); iter != apk_assets_.rend(); ++iter) {
const ApkAssets* apk_assets = *iter;
auto func = [&](const StringPiece& name, FileType type) {
AssetDir::FileInfo info;
info.setFileName(String8(name.data(), name.size()));
info.setFileType(type);
info.setSourceName(String8(apk_assets->GetPath().c_str()));
files->add(info);
};
if (!apk_assets->ForEachFile(full_path, func)) {
return {};
}
}
std::unique_ptr<AssetDir> asset_dir = util::make_unique<AssetDir>();
asset_dir->setFileList(files.release());
return asset_dir;
}
// Search in reverse because that's how we used to do it and we need to preserve behaviour.
// This is unfortunate, because ClassLoaders delegate to the parent first, so the order
// is inconsistent for split APKs.
std::unique_ptr<Asset> AssetManager2::OpenNonAsset(const std::string& filename,
Asset::AccessMode mode,
ApkAssetsCookie* out_cookie) const {
for (int32_t i = apk_assets_.size() - 1; i >= 0; i--) {
std::unique_ptr<Asset> asset = apk_assets_[i]->Open(filename, mode);
if (asset) {
if (out_cookie != nullptr) {
*out_cookie = i;
}
return asset;
}
}
if (out_cookie != nullptr) {
*out_cookie = kInvalidCookie;
}
return {};
}
std::unique_ptr<Asset> AssetManager2::OpenNonAsset(const std::string& filename,
ApkAssetsCookie cookie,
Asset::AccessMode mode) const {
if (cookie < 0 || static_cast<size_t>(cookie) >= apk_assets_.size()) {
return {};
}
return apk_assets_[cookie]->Open(filename, mode);
}
ApkAssetsCookie AssetManager2::FindEntry(uint32_t resid, uint16_t density_override,
bool /*stop_at_first_match*/,
FindEntryResult* out_entry) const {
// Might use this if density_override != 0.
ResTable_config density_override_config;
// Select our configuration or generate a density override configuration.
const ResTable_config* desired_config = &configuration_;
if (density_override != 0 && density_override != configuration_.density) {
density_override_config = configuration_;
density_override_config.density = density_override;
desired_config = &density_override_config;
}
if (!is_valid_resid(resid)) {
LOG(ERROR) << base::StringPrintf("Invalid ID 0x%08x.", resid);
return kInvalidCookie;
}
const uint32_t package_id = get_package_id(resid);
const uint8_t type_idx = get_type_id(resid) - 1;
const uint16_t entry_idx = get_entry_id(resid);
const uint8_t package_idx = package_ids_[package_id];
if (package_idx == 0xff) {
LOG(ERROR) << base::StringPrintf("No package ID %02x found for ID 0x%08x.", package_id, resid);
return kInvalidCookie;
}
const PackageGroup& package_group = package_groups_[package_idx];
const size_t package_count = package_group.packages_.size();
ApkAssetsCookie best_cookie = kInvalidCookie;
const LoadedPackage* best_package = nullptr;
const ResTable_type* best_type = nullptr;
const ResTable_config* best_config = nullptr;
ResTable_config best_config_copy;
uint32_t best_offset = 0u;
uint32_t type_flags = 0u;
// If desired_config is the same as the set configuration, then we can use our filtered list
// and we don't need to match the configurations, since they already matched.
const bool use_fast_path = desired_config == &configuration_;
for (size_t pi = 0; pi < package_count; pi++) {
const ConfiguredPackage& loaded_package_impl = package_group.packages_[pi];
const LoadedPackage* loaded_package = loaded_package_impl.loaded_package_;
ApkAssetsCookie cookie = package_group.cookies_[pi];
// If the type IDs are offset in this package, we need to take that into account when searching
// for a type.
const TypeSpec* type_spec = loaded_package->GetTypeSpecByTypeIndex(type_idx);
if (UNLIKELY(type_spec == nullptr)) {
continue;
}
uint16_t local_entry_idx = entry_idx;
// If there is an IDMAP supplied with this package, translate the entry ID.
if (type_spec->idmap_entries != nullptr) {
if (!LoadedIdmap::Lookup(type_spec->idmap_entries, local_entry_idx, &local_entry_idx)) {
// There is no mapping, so the resource is not meant to be in this overlay package.
continue;
}
}
type_flags |= type_spec->GetFlagsForEntryIndex(local_entry_idx);
// If the package is an overlay, then even configurations that are the same MUST be chosen.
const bool package_is_overlay = loaded_package->IsOverlay();
const FilteredConfigGroup& filtered_group = loaded_package_impl.filtered_configs_[type_idx];
if (use_fast_path) {
const std::vector<ResTable_config>& candidate_configs = filtered_group.configurations;
const size_t type_count = candidate_configs.size();
for (uint32_t i = 0; i < type_count; i++) {
const ResTable_config& this_config = candidate_configs[i];
// We can skip calling ResTable_config::match() because we know that all candidate
// configurations that do NOT match have been filtered-out.
if ((best_config == nullptr || this_config.isBetterThan(*best_config, desired_config)) ||
(package_is_overlay && this_config.compare(*best_config) == 0)) {
// The configuration matches and is better than the previous selection.
// Find the entry value if it exists for this configuration.
const ResTable_type* type_chunk = filtered_group.types[i];
const uint32_t offset = LoadedPackage::GetEntryOffset(type_chunk, local_entry_idx);
if (offset == ResTable_type::NO_ENTRY) {
continue;
}
best_cookie = cookie;
best_package = loaded_package;
best_type = type_chunk;
best_config = &this_config;
best_offset = offset;
}
}
} else {
// This is the slower path, which doesn't use the filtered list of configurations.
// Here we must read the ResTable_config from the mmapped APK, convert it to host endianness
// and fill in any new fields that did not exist when the APK was compiled.
// Furthermore when selecting configurations we can't just record the pointer to the
// ResTable_config, we must copy it.
const auto iter_end = type_spec->types + type_spec->type_count;
for (auto iter = type_spec->types; iter != iter_end; ++iter) {
ResTable_config this_config;
this_config.copyFromDtoH((*iter)->config);
if (this_config.match(*desired_config)) {
if ((best_config == nullptr || this_config.isBetterThan(*best_config, desired_config)) ||
(package_is_overlay && this_config.compare(*best_config) == 0)) {
// The configuration matches and is better than the previous selection.
// Find the entry value if it exists for this configuration.
const uint32_t offset = LoadedPackage::GetEntryOffset(*iter, local_entry_idx);
if (offset == ResTable_type::NO_ENTRY) {
continue;
}
best_cookie = cookie;
best_package = loaded_package;
best_type = *iter;
best_config_copy = this_config;
best_config = &best_config_copy;
best_offset = offset;
}
}
}
}
}
if (UNLIKELY(best_cookie == kInvalidCookie)) {
return kInvalidCookie;
}
const ResTable_entry* best_entry = LoadedPackage::GetEntryFromOffset(best_type, best_offset);
if (UNLIKELY(best_entry == nullptr)) {
return kInvalidCookie;
}
out_entry->entry = best_entry;
out_entry->config = *best_config;
out_entry->type_flags = type_flags;
out_entry->type_string_ref = StringPoolRef(best_package->GetTypeStringPool(), best_type->id - 1);
out_entry->entry_string_ref =
StringPoolRef(best_package->GetKeyStringPool(), best_entry->key.index);
out_entry->dynamic_ref_table = &package_group.dynamic_ref_table;
return best_cookie;
}
bool AssetManager2::GetResourceName(uint32_t resid, ResourceName* out_name) const {
FindEntryResult entry;
ApkAssetsCookie cookie =
FindEntry(resid, 0u /* density_override */, true /* stop_at_first_match */, &entry);
if (cookie == kInvalidCookie) {
return false;
}
const LoadedPackage* package =
apk_assets_[cookie]->GetLoadedArsc()->GetPackageById(get_package_id(resid));
if (package == nullptr) {
return false;
}
out_name->package = package->GetPackageName().data();
out_name->package_len = package->GetPackageName().size();
out_name->type = entry.type_string_ref.string8(&out_name->type_len);
out_name->type16 = nullptr;
if (out_name->type == nullptr) {
out_name->type16 = entry.type_string_ref.string16(&out_name->type_len);
if (out_name->type16 == nullptr) {
return false;
}
}
out_name->entry = entry.entry_string_ref.string8(&out_name->entry_len);
out_name->entry16 = nullptr;
if (out_name->entry == nullptr) {
out_name->entry16 = entry.entry_string_ref.string16(&out_name->entry_len);
if (out_name->entry16 == nullptr) {
return false;
}
}
return true;
}
bool AssetManager2::GetResourceFlags(uint32_t resid, uint32_t* out_flags) const {
FindEntryResult entry;
ApkAssetsCookie cookie =
FindEntry(resid, 0u /* density_override */, false /* stop_at_first_match */, &entry);
if (cookie != kInvalidCookie) {
*out_flags = entry.type_flags;
return cookie;
}
return kInvalidCookie;
}
ApkAssetsCookie AssetManager2::GetResource(uint32_t resid, bool may_be_bag,
uint16_t density_override, Res_value* out_value,
ResTable_config* out_selected_config,
uint32_t* out_flags) const {
FindEntryResult entry;
ApkAssetsCookie cookie =
FindEntry(resid, density_override, false /* stop_at_first_match */, &entry);
if (cookie == kInvalidCookie) {
return kInvalidCookie;
}
if (dtohs(entry.entry->flags) & ResTable_entry::FLAG_COMPLEX) {
if (!may_be_bag) {
LOG(ERROR) << base::StringPrintf("Resource %08x is a complex map type.", resid);
return kInvalidCookie;
}
// Create a reference since we can't represent this complex type as a Res_value.
out_value->dataType = Res_value::TYPE_REFERENCE;
out_value->data = resid;
*out_selected_config = entry.config;
*out_flags = entry.type_flags;
return cookie;
}
const Res_value* device_value = reinterpret_cast<const Res_value*>(
reinterpret_cast<const uint8_t*>(entry.entry) + dtohs(entry.entry->size));
out_value->copyFrom_dtoh(*device_value);
// Convert the package ID to the runtime assigned package ID.
entry.dynamic_ref_table->lookupResourceValue(out_value);
*out_selected_config = entry.config;
*out_flags = entry.type_flags;
return cookie;
}
ApkAssetsCookie AssetManager2::ResolveReference(ApkAssetsCookie cookie, Res_value* in_out_value,
ResTable_config* in_out_selected_config,
uint32_t* in_out_flags,
uint32_t* out_last_reference) const {
constexpr const int kMaxIterations = 20;
for (size_t iteration = 0u; in_out_value->dataType == Res_value::TYPE_REFERENCE &&
in_out_value->data != 0u && iteration < kMaxIterations;
iteration++) {
*out_last_reference = in_out_value->data;
uint32_t new_flags = 0u;
cookie = GetResource(in_out_value->data, true /*may_be_bag*/, 0u /*density_override*/,
in_out_value, in_out_selected_config, &new_flags);
if (cookie == kInvalidCookie) {
return kInvalidCookie;
}
if (in_out_flags != nullptr) {
*in_out_flags |= new_flags;
}
if (*out_last_reference == in_out_value->data) {
// This reference can't be resolved, so exit now and let the caller deal with it.
return cookie;
}
}
return cookie;
}
const ResolvedBag* AssetManager2::GetBag(uint32_t resid) {
auto found_resids = std::vector<uint32_t>();
return GetBag(resid, found_resids);
}
const ResolvedBag* AssetManager2::GetBag(uint32_t resid, std::vector<uint32_t>& child_resids) {
ATRACE_NAME("AssetManager::GetBag");
auto cached_iter = cached_bags_.find(resid);
if (cached_iter != cached_bags_.end()) {
return cached_iter->second.get();
}
FindEntryResult entry;
ApkAssetsCookie cookie =
FindEntry(resid, 0u /* density_override */, false /* stop_at_first_match */, &entry);
if (cookie == kInvalidCookie) {
return nullptr;
}
// Check that the size of the entry header is at least as big as
// the desired ResTable_map_entry. Also verify that the entry
// was intended to be a map.
if (dtohs(entry.entry->size) < sizeof(ResTable_map_entry) ||
(dtohs(entry.entry->flags) & ResTable_entry::FLAG_COMPLEX) == 0) {
// Not a bag, nothing to do.
return nullptr;
}
const ResTable_map_entry* map = reinterpret_cast<const ResTable_map_entry*>(entry.entry);
const ResTable_map* map_entry =
reinterpret_cast<const ResTable_map*>(reinterpret_cast<const uint8_t*>(map) + map->size);
const ResTable_map* const map_entry_end = map_entry + dtohl(map->count);
// Keep track of ids that have already been seen to prevent infinite loops caused by circular
// dependencies between bags
child_resids.push_back(resid);
uint32_t parent_resid = dtohl(map->parent.ident);
if (parent_resid == 0 || std::find(child_resids.begin(), child_resids.end(), parent_resid)
!= child_resids.end()) {
// There is no parent or that a circular dependency exist, meaning there is nothing to
// inherit and we can do a simple copy of the entries in the map.
const size_t entry_count = map_entry_end - map_entry;
util::unique_cptr<ResolvedBag> new_bag{reinterpret_cast<ResolvedBag*>(
malloc(sizeof(ResolvedBag) + (entry_count * sizeof(ResolvedBag::Entry))))};
ResolvedBag::Entry* new_entry = new_bag->entries;
for (; map_entry != map_entry_end; ++map_entry) {
uint32_t new_key = dtohl(map_entry->name.ident);
if (!is_internal_resid(new_key)) {
// Attributes, arrays, etc don't have a resource id as the name. They specify
// other data, which would be wrong to change via a lookup.
if (entry.dynamic_ref_table->lookupResourceId(&new_key) != NO_ERROR) {
LOG(ERROR) << base::StringPrintf("Failed to resolve key 0x%08x in bag 0x%08x.", new_key,
resid);
return nullptr;
}
}
new_entry->cookie = cookie;
new_entry->key = new_key;
new_entry->key_pool = nullptr;
new_entry->type_pool = nullptr;
new_entry->value.copyFrom_dtoh(map_entry->value);
status_t err = entry.dynamic_ref_table->lookupResourceValue(&new_entry->value);
if (err != NO_ERROR) {
LOG(ERROR) << base::StringPrintf(
"Failed to resolve value t=0x%02x d=0x%08x for key 0x%08x.", new_entry->value.dataType,
new_entry->value.data, new_key);
return nullptr;
}
++new_entry;
}
new_bag->type_spec_flags = entry.type_flags;
new_bag->entry_count = static_cast<uint32_t>(entry_count);
ResolvedBag* result = new_bag.get();
cached_bags_[resid] = std::move(new_bag);
return result;
}
// In case the parent is a dynamic reference, resolve it.
entry.dynamic_ref_table->lookupResourceId(&parent_resid);
// Get the parent and do a merge of the keys.
const ResolvedBag* parent_bag = GetBag(parent_resid, child_resids);
if (parent_bag == nullptr) {
// Failed to get the parent that should exist.
LOG(ERROR) << base::StringPrintf("Failed to find parent 0x%08x of bag 0x%08x.", parent_resid,
resid);
return nullptr;
}
// Create the max possible entries we can make. Once we construct the bag,
// we will realloc to fit to size.
const size_t max_count = parent_bag->entry_count + dtohl(map->count);
util::unique_cptr<ResolvedBag> new_bag{reinterpret_cast<ResolvedBag*>(
malloc(sizeof(ResolvedBag) + (max_count * sizeof(ResolvedBag::Entry))))};
ResolvedBag::Entry* new_entry = new_bag->entries;
const ResolvedBag::Entry* parent_entry = parent_bag->entries;
const ResolvedBag::Entry* const parent_entry_end = parent_entry + parent_bag->entry_count;
// The keys are expected to be in sorted order. Merge the two bags.
while (map_entry != map_entry_end && parent_entry != parent_entry_end) {
uint32_t child_key = dtohl(map_entry->name.ident);
if (!is_internal_resid(child_key)) {
if (entry.dynamic_ref_table->lookupResourceId(&child_key) != NO_ERROR) {
LOG(ERROR) << base::StringPrintf("Failed to resolve key 0x%08x in bag 0x%08x.", child_key,
resid);
return nullptr;
}
}
if (child_key <= parent_entry->key) {
// Use the child key if it comes before the parent
// or is equal to the parent (overrides).
new_entry->cookie = cookie;
new_entry->key = child_key;
new_entry->key_pool = nullptr;
new_entry->type_pool = nullptr;
new_entry->value.copyFrom_dtoh(map_entry->value);
status_t err = entry.dynamic_ref_table->lookupResourceValue(&new_entry->value);
if (err != NO_ERROR) {
LOG(ERROR) << base::StringPrintf(
"Failed to resolve value t=0x%02x d=0x%08x for key 0x%08x.", new_entry->value.dataType,
new_entry->value.data, child_key);
return nullptr;
}
++map_entry;
} else {
// Take the parent entry as-is.
memcpy(new_entry, parent_entry, sizeof(*new_entry));
}
if (child_key >= parent_entry->key) {
// Move to the next parent entry if we used it or it was overridden.
++parent_entry;
}
// Increment to the next entry to fill.
++new_entry;
}
// Finish the child entries if they exist.
while (map_entry != map_entry_end) {
uint32_t new_key = dtohl(map_entry->name.ident);
if (!is_internal_resid(new_key)) {
if (entry.dynamic_ref_table->lookupResourceId(&new_key) != NO_ERROR) {
LOG(ERROR) << base::StringPrintf("Failed to resolve key 0x%08x in bag 0x%08x.", new_key,
resid);
return nullptr;
}
}
new_entry->cookie = cookie;
new_entry->key = new_key;
new_entry->key_pool = nullptr;
new_entry->type_pool = nullptr;
new_entry->value.copyFrom_dtoh(map_entry->value);
status_t err = entry.dynamic_ref_table->lookupResourceValue(&new_entry->value);
if (err != NO_ERROR) {
LOG(ERROR) << base::StringPrintf("Failed to resolve value t=0x%02x d=0x%08x for key 0x%08x.",
new_entry->value.dataType, new_entry->value.data, new_key);
return nullptr;
}
++map_entry;
++new_entry;
}
// Finish the parent entries if they exist.
if (parent_entry != parent_entry_end) {
// Take the rest of the parent entries as-is.
const size_t num_entries_to_copy = parent_entry_end - parent_entry;
memcpy(new_entry, parent_entry, num_entries_to_copy * sizeof(*new_entry));
new_entry += num_entries_to_copy;
}
// Resize the resulting array to fit.
const size_t actual_count = new_entry - new_bag->entries;
if (actual_count != max_count) {
new_bag.reset(reinterpret_cast<ResolvedBag*>(realloc(
new_bag.release(), sizeof(ResolvedBag) + (actual_count * sizeof(ResolvedBag::Entry)))));
}
// Combine flags from the parent and our own bag.
new_bag->type_spec_flags = entry.type_flags | parent_bag->type_spec_flags;
new_bag->entry_count = static_cast<uint32_t>(actual_count);
ResolvedBag* result = new_bag.get();
cached_bags_[resid] = std::move(new_bag);
return result;
}
static bool Utf8ToUtf16(const StringPiece& str, std::u16string* out) {
ssize_t len =
utf8_to_utf16_length(reinterpret_cast<const uint8_t*>(str.data()), str.size(), false);
if (len < 0) {
return false;
}
out->resize(static_cast<size_t>(len));
utf8_to_utf16(reinterpret_cast<const uint8_t*>(str.data()), str.size(), &*out->begin(),
static_cast<size_t>(len + 1));
return true;
}
uint32_t AssetManager2::GetResourceId(const std::string& resource_name,
const std::string& fallback_type,
const std::string& fallback_package) const {
StringPiece package_name, type, entry;
if (!ExtractResourceName(resource_name, &package_name, &type, &entry)) {
return 0u;
}
if (entry.empty()) {
return 0u;
}
if (package_name.empty()) {
package_name = fallback_package;
}
if (type.empty()) {
type = fallback_type;
}
std::u16string type16;
if (!Utf8ToUtf16(type, &type16)) {
return 0u;
}
std::u16string entry16;
if (!Utf8ToUtf16(entry, &entry16)) {
return 0u;
}
const StringPiece16 kAttr16 = u"attr";
const static std::u16string kAttrPrivate16 = u"^attr-private";
for (const PackageGroup& package_group : package_groups_) {
for (const ConfiguredPackage& package_impl : package_group.packages_) {
const LoadedPackage* package = package_impl.loaded_package_;
if (package_name != package->GetPackageName()) {
// All packages in the same group are expected to have the same package name.
break;
}
uint32_t resid = package->FindEntryByName(type16, entry16);
if (resid == 0u && kAttr16 == type16) {
// Private attributes in libraries (such as the framework) are sometimes encoded
// under the type '^attr-private' in order to leave the ID space of public 'attr'
// free for future additions. Check '^attr-private' for the same name.
resid = package->FindEntryByName(kAttrPrivate16, entry16);
}
if (resid != 0u) {
return fix_package_id(resid, package_group.dynamic_ref_table.mAssignedPackageId);
}
}
}
return 0u;
}
void AssetManager2::RebuildFilterList(bool filter_incompatible_configs) {
for (PackageGroup& group : package_groups_) {
for (ConfiguredPackage& impl : group.packages_) {
// Destroy it.
impl.filtered_configs_.~ByteBucketArray();
// Re-create it.
new (&impl.filtered_configs_) ByteBucketArray<FilteredConfigGroup>();
// Create the filters here.
impl.loaded_package_->ForEachTypeSpec([&](const TypeSpec* spec, uint8_t type_index) {
FilteredConfigGroup& group = impl.filtered_configs_.editItemAt(type_index);
const auto iter_end = spec->types + spec->type_count;
for (auto iter = spec->types; iter != iter_end; ++iter) {
ResTable_config this_config;
this_config.copyFromDtoH((*iter)->config);
if (!filter_incompatible_configs || this_config.match(configuration_)) {
group.configurations.push_back(this_config);
group.types.push_back(*iter);
}
}
});
}
}
}
void AssetManager2::InvalidateCaches(uint32_t diff) {
if (diff == 0xffffffffu) {
// Everything must go.
cached_bags_.clear();
return;
}
// Be more conservative with what gets purged. Only if the bag has other possible
// variations with respect to what changed (diff) should we remove it.
for (auto iter = cached_bags_.cbegin(); iter != cached_bags_.cend();) {
if (diff & iter->second->type_spec_flags) {
iter = cached_bags_.erase(iter);
} else {
++iter;
}
}
}
std::unique_ptr<Theme> AssetManager2::NewTheme() {
return std::unique_ptr<Theme>(new Theme(this));
}
Theme::Theme(AssetManager2* asset_manager) : asset_manager_(asset_manager) {
}
Theme::~Theme() = default;
namespace {
struct ThemeEntry {
ApkAssetsCookie cookie;
uint32_t type_spec_flags;
Res_value value;
};
struct ThemeType {
int entry_count;
ThemeEntry entries[0];
};
constexpr size_t kTypeCount = std::numeric_limits<uint8_t>::max() + 1;
} // namespace
struct Theme::Package {
// Each element of Type will be a dynamically sized object
// allocated to have the entries stored contiguously with the Type.
std::array<util::unique_cptr<ThemeType>, kTypeCount> types;
};
bool Theme::ApplyStyle(uint32_t resid, bool force) {
ATRACE_NAME("Theme::ApplyStyle");
const ResolvedBag* bag = asset_manager_->GetBag(resid);
if (bag == nullptr) {
return false;
}
// Merge the flags from this style.
type_spec_flags_ |= bag->type_spec_flags;
int last_type_idx = -1;
int last_package_idx = -1;
Package* last_package = nullptr;
ThemeType* last_type = nullptr;
// Iterate backwards, because each bag is sorted in ascending key ID order, meaning we will only
// need to perform one resize per type.
using reverse_bag_iterator = std::reverse_iterator<const ResolvedBag::Entry*>;
const auto bag_iter_end = reverse_bag_iterator(begin(bag));
for (auto bag_iter = reverse_bag_iterator(end(bag)); bag_iter != bag_iter_end; ++bag_iter) {
const uint32_t attr_resid = bag_iter->key;
// If the resource ID passed in is not a style, the key can be some other identifier that is not
// a resource ID. We should fail fast instead of operating with strange resource IDs.
if (!is_valid_resid(attr_resid)) {
return false;
}
// We don't use the 0-based index for the type so that we can avoid doing ID validation
// upon lookup. Instead, we keep space for the type ID 0 in our data structures. Since
// the construction of this type is guarded with a resource ID check, it will never be
// populated, and querying type ID 0 will always fail.
const int package_idx = get_package_id(attr_resid);
const int type_idx = get_type_id(attr_resid);
const int entry_idx = get_entry_id(attr_resid);
if (last_package_idx != package_idx) {
std::unique_ptr<Package>& package = packages_[package_idx];
if (package == nullptr) {
package.reset(new Package());
}
last_package_idx = package_idx;
last_package = package.get();
last_type_idx = -1;
}
if (last_type_idx != type_idx) {
util::unique_cptr<ThemeType>& type = last_package->types[type_idx];
if (type == nullptr) {
// Allocate enough memory to contain this entry_idx. Since we're iterating in reverse over
// a sorted list of attributes, this shouldn't be resized again during this method call.
type.reset(reinterpret_cast<ThemeType*>(
calloc(sizeof(ThemeType) + (entry_idx + 1) * sizeof(ThemeEntry), 1)));
type->entry_count = entry_idx + 1;
} else if (entry_idx >= type->entry_count) {
// Reallocate the memory to contain this entry_idx. Since we're iterating in reverse over
// a sorted list of attributes, this shouldn't be resized again during this method call.
const int new_count = entry_idx + 1;
type.reset(reinterpret_cast<ThemeType*>(
realloc(type.release(), sizeof(ThemeType) + (new_count * sizeof(ThemeEntry)))));
// Clear out the newly allocated space (which isn't zeroed).
memset(type->entries + type->entry_count, 0,
(new_count - type->entry_count) * sizeof(ThemeEntry));
type->entry_count = new_count;
}
last_type_idx = type_idx;
last_type = type.get();
}
ThemeEntry& entry = last_type->entries[entry_idx];
if (force || (entry.value.dataType == Res_value::TYPE_NULL &&
entry.value.data != Res_value::DATA_NULL_EMPTY)) {
entry.cookie = bag_iter->cookie;
entry.type_spec_flags |= bag->type_spec_flags;
entry.value = bag_iter->value;
}
}
return true;
}
ApkAssetsCookie Theme::GetAttribute(uint32_t resid, Res_value* out_value,
uint32_t* out_flags) const {
int cnt = 20;
uint32_t type_spec_flags = 0u;
do {
const int package_idx = get_package_id(resid);
const Package* package = packages_[package_idx].get();
if (package != nullptr) {
// The themes are constructed with a 1-based type ID, so no need to decrement here.
const int type_idx = get_type_id(resid);
const ThemeType* type = package->types[type_idx].get();
if (type != nullptr) {
const int entry_idx = get_entry_id(resid);
if (entry_idx < type->entry_count) {
const ThemeEntry& entry = type->entries[entry_idx];
type_spec_flags |= entry.type_spec_flags;
if (entry.value.dataType == Res_value::TYPE_ATTRIBUTE) {
if (cnt > 0) {
cnt--;
resid = entry.value.data;
continue;
}
return kInvalidCookie;
}
// @null is different than @empty.
if (entry.value.dataType == Res_value::TYPE_NULL &&
entry.value.data != Res_value::DATA_NULL_EMPTY) {
return kInvalidCookie;
}
*out_value = entry.value;
*out_flags = type_spec_flags;
return entry.cookie;
}
}
}
break;
} while (true);
return kInvalidCookie;
}
ApkAssetsCookie Theme::ResolveAttributeReference(ApkAssetsCookie cookie, Res_value* in_out_value,
ResTable_config* in_out_selected_config,
uint32_t* in_out_type_spec_flags,
uint32_t* out_last_ref) const {
if (in_out_value->dataType == Res_value::TYPE_ATTRIBUTE) {
uint32_t new_flags;
cookie = GetAttribute(in_out_value->data, in_out_value, &new_flags);
if (cookie == kInvalidCookie) {
return kInvalidCookie;
}
if (in_out_type_spec_flags != nullptr) {
*in_out_type_spec_flags |= new_flags;
}
}
return asset_manager_->ResolveReference(cookie, in_out_value, in_out_selected_config,
in_out_type_spec_flags, out_last_ref);
}
void Theme::Clear() {
type_spec_flags_ = 0u;
for (std::unique_ptr<Package>& package : packages_) {
package.reset();
}
}
bool Theme::SetTo(const Theme& o) {
if (this == &o) {
return true;
}
type_spec_flags_ = o.type_spec_flags_;
const bool copy_only_system = asset_manager_ != o.asset_manager_;
for (size_t p = 0; p < packages_.size(); p++) {
const Package* package = o.packages_[p].get();
if (package == nullptr || (copy_only_system && p != 0x01)) {
// The other theme doesn't have this package, clear ours.
packages_[p].reset();
continue;
}
if (packages_[p] == nullptr) {
// The other theme has this package, but we don't. Make one.
packages_[p].reset(new Package());
}
for (size_t t = 0; t < package->types.size(); t++) {
const ThemeType* type = package->types[t].get();
if (type == nullptr) {
// The other theme doesn't have this type, clear ours.
packages_[p]->types[t].reset();
continue;
}
// Create a new type and update it to theirs.
const size_t type_alloc_size = sizeof(ThemeType) + (type->entry_count * sizeof(ThemeEntry));
void* copied_data = malloc(type_alloc_size);
memcpy(copied_data, type, type_alloc_size);
packages_[p]->types[t].reset(reinterpret_cast<ThemeType*>(copied_data));
}
}
return true;
}
} // namespace android