tools/aapt2/split/TableSplitter.cpp - LeafOS-Project/android_frameworks_base - Gitiles

 /*
  * 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.
  */

 #include "split/TableSplitter.h"

 #include <algorithm>
 #include <map>
 #include <set>
 #include <unordered_set>
 #include <unordered_map>
 #include <vector>

 #include "android-base/logging.h"
 #include "androidfw/ConfigDescription.h"

 #include "ResourceTable.h"
 #include "trace/TraceBuffer.h"
 #include "util/Util.h"

 using ::android::ConfigDescription;

 namespace aapt {

 using ConfigClaimedMap = std::unordered_map<ResourceConfigValue*, bool>;
 using ConfigDensityGroups = std::map<ConfigDescription, std::vector<ResourceConfigValue*>>;

 static ConfigDescription CopyWithoutDensity(const ConfigDescription& config) {
   ConfigDescription without_density = config;
   without_density.density = 0;
   return without_density;
 }

 /**
  * Selects values that match exactly the constraints given.
  */
 class SplitValueSelector {
  public:
   explicit SplitValueSelector(const SplitConstraints& constraints) {
     for (const ConfigDescription& config : constraints.configs) {
       if (config.density == 0) {
         density_independent_configs_.insert(config);
       } else {
         density_dependent_config_to_density_map_[CopyWithoutDensity(config)] = config.density;
       }
     }
   }

   std::vector<ResourceConfigValue*> SelectValues(
       const ConfigDensityGroups& density_groups,
       ConfigClaimedMap* claimed_values) {
     std::vector<ResourceConfigValue*> selected;

     // Select the regular values.
     for (auto& entry : *claimed_values) {
       // Check if the entry has a density.
       ResourceConfigValue* config_value = entry.first;
       if (config_value->config.density == 0 && !entry.second) {
         // This is still available.
         if (density_independent_configs_.find(config_value->config) !=
             density_independent_configs_.end()) {
           selected.push_back(config_value);

           // Mark the entry as taken.
           entry.second = true;
         }
       }
     }

     // Now examine the densities
     for (auto& entry : density_groups) {
       // We do not care if the value is claimed, since density values can be
       // in multiple splits.
       const ConfigDescription& config = entry.first;
       const std::vector<ResourceConfigValue*>& related_values = entry.second;
       auto density_value_iter =
           density_dependent_config_to_density_map_.find(config);
       if (density_value_iter !=
           density_dependent_config_to_density_map_.end()) {
         // Select the best one!
         ConfigDescription target_density = config;
         target_density.density = density_value_iter->second;

         ResourceConfigValue* best_value = nullptr;
         for (ResourceConfigValue* this_value : related_values) {
           if (!best_value || this_value->config.isBetterThan(best_value->config, &target_density)) {
             best_value = this_value;
           }
         }
         CHECK(best_value != nullptr);

         // When we select one of these, they are all claimed such that the base
         // doesn't include any anymore.
         (*claimed_values)[best_value] = true;
         selected.push_back(best_value);
       }
     }
     return selected;
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(SplitValueSelector);

   std::set<ConfigDescription> density_independent_configs_;
   std::map<ConfigDescription, uint16_t>
       density_dependent_config_to_density_map_;
 };

 /**
  * Marking non-preferred densities as claimed will make sure the base doesn't include them, leaving
  * only the preferred density behind.
  */
 static void MarkNonPreferredDensitiesAsClaimed(
     const std::vector<uint16_t>& preferred_densities, const ConfigDensityGroups& density_groups,
     ConfigClaimedMap* config_claimed_map) {
   for (auto& entry : density_groups) {
     const ConfigDescription& config = entry.first;
     const std::vector<ResourceConfigValue*>& related_values = entry.second;

     // There can be multiple best values if there are multiple preferred densities.
     std::unordered_set<ResourceConfigValue*> best_values;

     // For each preferred density, find the value that is the best.
     for (uint16_t preferred_density : preferred_densities) {
       ConfigDescription target_density = config;
       target_density.density = preferred_density;
       ResourceConfigValue* best_value = nullptr;
       for (ResourceConfigValue* this_value : related_values) {
         if (!best_value || this_value->config.isBetterThan(best_value->config, &target_density)) {
           best_value = this_value;
         }
       }
       CHECK(best_value != nullptr);
       best_values.insert(best_value);
     }

     // Claim all the values that aren't the best so that they will be removed from the base.
     for (ResourceConfigValue* this_value : related_values) {
       if (best_values.find(this_value) == best_values.end()) {
         (*config_claimed_map)[this_value] = true;
       }
     }
   }
 }
 bool TableSplitter::VerifySplitConstraints(IAaptContext* context) {
   TRACE_CALL();
   bool error = false;
   for (size_t i = 0; i < split_constraints_.size(); i++) {
     if (split_constraints_[i].configs.size() == 0) {
       // For now, treat this as a warning. We may consider aborting processing.
       context->GetDiagnostics()->Warn(android::DiagMessage() << "no configurations for constraint '"
                                                              << split_constraints_[i].name << "'");
     }
     for (size_t j = i + 1; j < split_constraints_.size(); j++) {
       for (const ConfigDescription& config : split_constraints_[i].configs) {
         if (split_constraints_[j].configs.find(config) != split_constraints_[j].configs.end()) {
           context->GetDiagnostics()->Error(
               android::DiagMessage() << "config '" << config << "' appears in multiple splits, "
                                      << "target split ambiguous");
           error = true;
         }
       }
     }
   }
   return !error;
 }

 void TableSplitter::SplitTable(ResourceTable* original_table) {
   const size_t split_count = split_constraints_.size();
   for (auto& pkg : original_table->packages) {
     // Initialize all packages for splits.
     for (size_t idx = 0; idx < split_count; idx++) {
       ResourceTable* split_table = splits_[idx].get();
       split_table->FindOrCreatePackage(pkg->name);
     }

     for (auto& type : pkg->types) {
       if (type->named_type.type == ResourceType::kMipmap) {
         // Always keep mipmaps.
         continue;
       }

       for (auto& entry : type->entries) {
         if (options_.config_filter) {
           // First eliminate any resource that we definitely don't want.
           for (std::unique_ptr<ResourceConfigValue>& config_value : entry->values) {
             if (!options_.config_filter->Match(config_value->config)) {
               // null out the entry. We will clean up and remove nulls at the end for performance
               // reasons.
               config_value.reset();
             }
           }
         }

         // Organize the values into two separate buckets. Those that are density-dependent and those
         // that are density-independent. One density technically matches all density, it's just that
         // some densities match better. So we need to be aware of the full set of densities to make
         // this decision.
         ConfigDensityGroups density_groups;
         ConfigClaimedMap config_claimed_map;
         for (const std::unique_ptr<ResourceConfigValue>& config_value : entry->values) {
           if (config_value) {
             config_claimed_map[config_value.get()] = false;

             if (config_value->config.density != 0) {
               // Create a bucket for this density-dependent config.
               density_groups[CopyWithoutDensity(config_value->config)]
                   .push_back(config_value.get());
             }
           }
         }

         // First we check all the splits. If it doesn't match one of the splits, we leave it in the
         // base.
         for (size_t idx = 0; idx < split_count; idx++) {
           const SplitConstraints& split_constraint = split_constraints_[idx];
           ResourceTable* split_table = splits_[idx].get();
           CloningValueTransformer cloner(&split_table->string_pool);

           // Select the values we want from this entry for this split.
           SplitValueSelector selector(split_constraint);
           std::vector<ResourceConfigValue*> selected_values =
               selector.SelectValues(density_groups, &config_claimed_map);

           // No need to do any work if we selected nothing.
           if (!selected_values.empty()) {
             // Create the same resource structure in the split. We do this lazily because we might
             // not have actual values for each type/entry.
             ResourceTablePackage* split_pkg = split_table->FindPackage(pkg->name);
             ResourceTableType* split_type = split_pkg->FindOrCreateType(type->named_type);
             split_type->visibility_level = type->visibility_level;

             ResourceEntry* split_entry = split_type->FindOrCreateEntry(entry->name);
             if (!split_entry->id) {
               split_entry->id = entry->id;
               split_entry->visibility = entry->visibility;
               split_entry->overlayable_item = entry->overlayable_item;
             }

             // Copy the selected values into the new Split Entry.
             for (ResourceConfigValue* config_value : selected_values) {
               ResourceConfigValue* new_config_value =
                   split_entry->FindOrCreateValue(config_value->config, config_value->product);
               new_config_value->value = config_value->value->Transform(cloner);
             }
           }
         }

         if (!options_.preferred_densities.empty()) {
           MarkNonPreferredDensitiesAsClaimed(options_.preferred_densities,
                                              density_groups,
                                              &config_claimed_map);
         }

         // All splits are handled, now check to see what wasn't claimed and remove whatever exists
         // in other splits.
         for (std::unique_ptr<ResourceConfigValue>& config_value : entry->values) {
           if (config_value && config_claimed_map[config_value.get()]) {
             // Claimed, remove from base.
             config_value.reset();
           }
         }

         // Now erase all nullptrs.
         entry->values.erase(
             std::remove(entry->values.begin(), entry->values.end(), nullptr),
             entry->values.end());
       }
     }
   }
 }

 }  // namespace aapt
	/*
	* 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.
	*/

	#include "split/TableSplitter.h"

	#include <algorithm>
	#include <map>
	#include <set>
	#include <unordered_set>
	#include <unordered_map>
	#include <vector>

	#include "android-base/logging.h"
	#include "androidfw/ConfigDescription.h"

	#include "ResourceTable.h"
	#include "trace/TraceBuffer.h"
	#include "util/Util.h"

	using ::android::ConfigDescription;

	namespace aapt {

	using ConfigClaimedMap = std::unordered_map<ResourceConfigValue*, bool>;
	using ConfigDensityGroups = std::map<ConfigDescription, std::vector<ResourceConfigValue*>>;

	static ConfigDescription CopyWithoutDensity(const ConfigDescription& config) {
	ConfigDescription without_density = config;
	without_density.density = 0;
	return without_density;
	}

	/**
	* Selects values that match exactly the constraints given.
	*/
	class SplitValueSelector {
	public:
	explicit SplitValueSelector(const SplitConstraints& constraints) {
	for (const ConfigDescription& config : constraints.configs) {
	if (config.density == 0) {
	density_independent_configs_.insert(config);
	} else {
	density_dependent_config_to_density_map_[CopyWithoutDensity(config)] = config.density;
	}
	}
	}

	std::vector<ResourceConfigValue*> SelectValues(
	const ConfigDensityGroups& density_groups,
	ConfigClaimedMap* claimed_values) {
	std::vector<ResourceConfigValue*> selected;

	// Select the regular values.
	for (auto& entry : *claimed_values) {
	// Check if the entry has a density.
	ResourceConfigValue* config_value = entry.first;
	if (config_value->config.density == 0 && !entry.second) {
	// This is still available.
	if (density_independent_configs_.find(config_value->config) !=
	density_independent_configs_.end()) {
	selected.push_back(config_value);

	// Mark the entry as taken.
	entry.second = true;
	}
	}
	}

	// Now examine the densities
	for (auto& entry : density_groups) {
	// We do not care if the value is claimed, since density values can be
	// in multiple splits.
	const ConfigDescription& config = entry.first;
	const std::vector<ResourceConfigValue*>& related_values = entry.second;
	auto density_value_iter =
	density_dependent_config_to_density_map_.find(config);
	if (density_value_iter !=
	density_dependent_config_to_density_map_.end()) {
	// Select the best one!
	ConfigDescription target_density = config;
	target_density.density = density_value_iter->second;

	ResourceConfigValue* best_value = nullptr;
	for (ResourceConfigValue* this_value : related_values) {
	if (!best_value \|\| this_value->config.isBetterThan(best_value->config, &target_density)) {
	best_value = this_value;
	}
	}
	CHECK(best_value != nullptr);

	// When we select one of these, they are all claimed such that the base
	// doesn't include any anymore.
	(*claimed_values)[best_value] = true;
	selected.push_back(best_value);
	}
	}
	return selected;
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(SplitValueSelector);

	std::set<ConfigDescription> density_independent_configs_;
	std::map<ConfigDescription, uint16_t>
	density_dependent_config_to_density_map_;
	};

	/**
	* Marking non-preferred densities as claimed will make sure the base doesn't include them, leaving
	* only the preferred density behind.
	*/
	static void MarkNonPreferredDensitiesAsClaimed(
	const std::vector<uint16_t>& preferred_densities, const ConfigDensityGroups& density_groups,
	ConfigClaimedMap* config_claimed_map) {
	for (auto& entry : density_groups) {
	const ConfigDescription& config = entry.first;
	const std::vector<ResourceConfigValue*>& related_values = entry.second;

	// There can be multiple best values if there are multiple preferred densities.
	std::unordered_set<ResourceConfigValue*> best_values;

	// For each preferred density, find the value that is the best.
	for (uint16_t preferred_density : preferred_densities) {
	ConfigDescription target_density = config;
	target_density.density = preferred_density;
	ResourceConfigValue* best_value = nullptr;
	for (ResourceConfigValue* this_value : related_values) {
	if (!best_value \|\| this_value->config.isBetterThan(best_value->config, &target_density)) {
	best_value = this_value;
	}
	}
	CHECK(best_value != nullptr);
	best_values.insert(best_value);
	}

	// Claim all the values that aren't the best so that they will be removed from the base.
	for (ResourceConfigValue* this_value : related_values) {
	if (best_values.find(this_value) == best_values.end()) {
	(*config_claimed_map)[this_value] = true;
	}
	}
	}
	}
	bool TableSplitter::VerifySplitConstraints(IAaptContext* context) {
	TRACE_CALL();
	bool error = false;
	for (size_t i = 0; i < split_constraints_.size(); i++) {
	if (split_constraints_[i].configs.size() == 0) {
	// For now, treat this as a warning. We may consider aborting processing.
	context->GetDiagnostics()->Warn(android::DiagMessage() << "no configurations for constraint '"
	<< split_constraints_[i].name << "'");
	}
	for (size_t j = i + 1; j < split_constraints_.size(); j++) {
	for (const ConfigDescription& config : split_constraints_[i].configs) {
	if (split_constraints_[j].configs.find(config) != split_constraints_[j].configs.end()) {
	context->GetDiagnostics()->Error(
	android::DiagMessage() << "config '" << config << "' appears in multiple splits, "
	<< "target split ambiguous");
	error = true;
	}
	}
	}
	}
	return !error;
	}

	void TableSplitter::SplitTable(ResourceTable* original_table) {
	const size_t split_count = split_constraints_.size();
	for (auto& pkg : original_table->packages) {
	// Initialize all packages for splits.
	for (size_t idx = 0; idx < split_count; idx++) {
	ResourceTable* split_table = splits_[idx].get();
	split_table->FindOrCreatePackage(pkg->name);
	}

	for (auto& type : pkg->types) {
	if (type->named_type.type == ResourceType::kMipmap) {
	// Always keep mipmaps.
	continue;
	}

	for (auto& entry : type->entries) {
	if (options_.config_filter) {
	// First eliminate any resource that we definitely don't want.
	for (std::unique_ptr<ResourceConfigValue>& config_value : entry->values) {
	if (!options_.config_filter->Match(config_value->config)) {
	// null out the entry. We will clean up and remove nulls at the end for performance
	// reasons.
	config_value.reset();
	}
	}
	}

	// Organize the values into two separate buckets. Those that are density-dependent and those
	// that are density-independent. One density technically matches all density, it's just that
	// some densities match better. So we need to be aware of the full set of densities to make
	// this decision.
	ConfigDensityGroups density_groups;
	ConfigClaimedMap config_claimed_map;
	for (const std::unique_ptr<ResourceConfigValue>& config_value : entry->values) {
	if (config_value) {
	config_claimed_map[config_value.get()] = false;

	if (config_value->config.density != 0) {
	// Create a bucket for this density-dependent config.
	density_groups[CopyWithoutDensity(config_value->config)]
	.push_back(config_value.get());
	}
	}
	}

	// First we check all the splits. If it doesn't match one of the splits, we leave it in the
	// base.
	for (size_t idx = 0; idx < split_count; idx++) {
	const SplitConstraints& split_constraint = split_constraints_[idx];
	ResourceTable* split_table = splits_[idx].get();
	CloningValueTransformer cloner(&split_table->string_pool);

	// Select the values we want from this entry for this split.
	SplitValueSelector selector(split_constraint);
	std::vector<ResourceConfigValue*> selected_values =
	selector.SelectValues(density_groups, &config_claimed_map);

	// No need to do any work if we selected nothing.
	if (!selected_values.empty()) {
	// Create the same resource structure in the split. We do this lazily because we might
	// not have actual values for each type/entry.
	ResourceTablePackage* split_pkg = split_table->FindPackage(pkg->name);
	ResourceTableType* split_type = split_pkg->FindOrCreateType(type->named_type);
	split_type->visibility_level = type->visibility_level;

	ResourceEntry* split_entry = split_type->FindOrCreateEntry(entry->name);
	if (!split_entry->id) {
	split_entry->id = entry->id;
	split_entry->visibility = entry->visibility;
	split_entry->overlayable_item = entry->overlayable_item;
	}

	// Copy the selected values into the new Split Entry.
	for (ResourceConfigValue* config_value : selected_values) {
	ResourceConfigValue* new_config_value =
	split_entry->FindOrCreateValue(config_value->config, config_value->product);
	new_config_value->value = config_value->value->Transform(cloner);
	}
	}
	}

	if (!options_.preferred_densities.empty()) {
	MarkNonPreferredDensitiesAsClaimed(options_.preferred_densities,
	density_groups,
	&config_claimed_map);
	}

	// All splits are handled, now check to see what wasn't claimed and remove whatever exists
	// in other splits.
	for (std::unique_ptr<ResourceConfigValue>& config_value : entry->values) {
	if (config_value && config_claimed_map[config_value.get()]) {
	// Claimed, remove from base.
	config_value.reset();
	}
	}

	// Now erase all nullptrs.
	entry->values.erase(
	std::remove(entry->values.begin(), entry->values.end(), nullptr),
	entry->values.end());
	}
	}
	}
	}

	} // namespace aapt