jni/node-inl.h - platform/packages/providers/MediaProvider - Git at Google

 /*
  * Copyright (C) 2020 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 specic language governing permissions and
  * limitations under the License.
  */

 #ifndef MEDIA_PROVIDER_JNI_NODE_INL_H_
 #define MEDIA_PROVIDER_JNI_NODE_INL_H_

 #include <android-base/logging.h>

 #include <sys/types.h>
 #include <atomic>
 #include <cstdint>
 #include <limits>
 #include <list>
 #include <memory>
 #include <mutex>
 #include <set>
 #include <sstream>
 #include <string>
 #include <unordered_set>
 #include <utility>
 #include <vector>

 #include "libfuse_jni/ReaddirHelper.h"
 #include "libfuse_jni/RedactionInfo.h"

 class NodeTest;

 namespace mediaprovider {
 namespace fuse {

 struct handle {
     explicit handle(int fd, const RedactionInfo* ri, bool cached, bool passthrough, uid_t uid,
                     uid_t transforms_uid)
         : fd(fd),
           ri(ri),
           cached(cached),
           passthrough(passthrough),
           uid(uid),
           transforms_uid(transforms_uid) {
         CHECK(ri != nullptr);
     }

     const int fd;
     const std::unique_ptr<const RedactionInfo> ri;
     const bool cached;
     const bool passthrough;
     const uid_t uid;
     const uid_t transforms_uid;

     ~handle() { close(fd); }
 };

 struct dirhandle {
     explicit dirhandle(DIR* dir) : d(dir), next_off(0) { CHECK(dir != nullptr); }

     DIR* const d;
     off_t next_off;
     // Fuse readdir() is called multiple times based on the size of the buffer and
     // number of directory entries in the given directory. 'de' holds the list
     // of directory entries for the directory handle and this list is available
     // across subsequent readdir() calls for the same directory handle.
     std::vector<std::shared_ptr<DirectoryEntry>> de;

     ~dirhandle() { closedir(d); }
 };

 /** Represents file open result from MediaProvider */
 struct FdAccessResult {
     FdAccessResult(const std::string& file_path, const bool should_redact)
         : file_path(file_path), should_redact(should_redact) {}

     const std::string file_path;
     const bool should_redact;
 };

 // Whether inode tracking is enabled or not. When enabled, we maintain a
 // separate mapping from inode numbers to "live" nodes so we can detect when
 // we receive a request to a node that has been deleted.
 static constexpr bool kEnableInodeTracking = true;

 class node;

 // Tracks the set of active nodes associated with a FUSE instance so that we
 // can assert that we only ever return an active node in response to a lookup.
 class NodeTracker {
   public:
     explicit NodeTracker(std::recursive_mutex* lock) : lock_(lock) {}

     bool Exists(__u64 ino) const {
         if (kEnableInodeTracking) {
             const node* node = reinterpret_cast<const class node*>(ino);
             std::lock_guard<std::recursive_mutex> guard(*lock_);
             return active_nodes_.find(node) != active_nodes_.end();
         }
     }

     void CheckTracked(__u64 ino) const {
         if (kEnableInodeTracking) {
             const node* node = reinterpret_cast<const class node*>(ino);
             std::lock_guard<std::recursive_mutex> guard(*lock_);
             CHECK(active_nodes_.find(node) != active_nodes_.end());
         }
     }

     void NodeDeleted(const node* node) {
         if (kEnableInodeTracking) {
             std::lock_guard<std::recursive_mutex> guard(*lock_);
             LOG(DEBUG) << "Node: " << reinterpret_cast<uintptr_t>(node) << " deleted.";

             CHECK(active_nodes_.find(node) != active_nodes_.end());
             active_nodes_.erase(node);
         }
     }

     void NodeCreated(const node* node) {
         if (kEnableInodeTracking) {
             std::lock_guard<std::recursive_mutex> guard(*lock_);
             LOG(DEBUG) << "Node: " << reinterpret_cast<uintptr_t>(node) << " created.";

             CHECK(active_nodes_.find(node) == active_nodes_.end());
             active_nodes_.insert(node);
         }
     }

   private:
     std::recursive_mutex* lock_;
     std::unordered_set<const node*> active_nodes_;
 };

 class node {
   public:
     // Creates a new node with the specified parent, name and lock.
     static node* Create(node* parent, const std::string& name, const std::string& io_path,
                         const bool transforms_complete, const int transforms,
                         const int transforms_reason, std::recursive_mutex* lock, ino_t ino,
                         NodeTracker* tracker) {
         // Place the entire constructor under a critical section to make sure
         // node creation, tracking (if enabled) and the addition to a parent are
         // atomic.
         std::lock_guard<std::recursive_mutex> guard(*lock);
         return new node(parent, name, io_path, transforms_complete, transforms, transforms_reason,
                         lock, ino, tracker);
     }

     // Creates a new root node. Root nodes have no parents by definition
     // and their "name" must signify an absolute path.
     static node* CreateRoot(const std::string& path, std::recursive_mutex* lock, ino_t ino,
                             NodeTracker* tracker) {
         std::lock_guard<std::recursive_mutex> guard(*lock);
         node* root = new node(nullptr, path, path, true /* transforms_complete */,
                               0 /* transforms */, 0 /* transforms_reason */, lock, ino, tracker);

         // The root always has one extra reference to avoid it being
         // accidentally collected.
         root->Acquire();
         return root;
     }

     // Maps an inode to its associated node.
     static inline node* FromInode(__u64 ino, const NodeTracker* tracker) {
         tracker->CheckTracked(ino);
         return reinterpret_cast<node*>(static_cast<uintptr_t>(ino));
     }

     // TODO(b/215235604)
     static inline node* FromInodeNoThrow(__u64 ino, const NodeTracker* tracker) {
         if (!tracker->Exists(ino)) return nullptr;
         return reinterpret_cast<node*>(static_cast<uintptr_t>(ino));
     }

     // Maps a node to its associated inode.
     static __u64 ToInode(node* node) {
         return static_cast<__u64>(reinterpret_cast<uintptr_t>(node));
     }

     // Releases a reference to a node. Returns true iff the refcount dropped to
     // zero as a result of this call to Release, meaning that it's no longer
     // safe to perform any operations on references to this node.
     bool Release(uint32_t count) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         if (refcount_ >= count) {
             refcount_ -= count;
             if (refcount_ == 0) {
                 delete this;
                 return true;
             }
         } else {
             LOG(ERROR) << "Mismatched reference count: refcount_ = " << this->refcount_
                        << " ,count = " << count;
         }

         return false;
     }

     // Builds the full path associated with this node, including all path segments
     // associated with its descendants.
     std::string BuildPath() const;

     // Builds the full PII safe path associated with this node, including all path segments
     // associated with its descendants.
     std::string BuildSafePath() const;

     // Looks up a direct descendant of this node by case-insensitive |name|. If |acquire| is true,
     // also Acquire the node before returning a reference to it.
     // |transforms| is an opaque flag that is used to distinguish multiple nodes sharing the same
     // |name| but requiring different IO transformations as determined by the MediaProvider.
     node* LookupChildByName(const std::string& name, bool acquire, const int transforms = 0) const {
         return ForChild(name, [acquire, transforms](node* child) {
             if (child->transforms_ == transforms) {
                 if (acquire) {
                     child->Acquire();
                 }
                 return true;
             }
             return false;
         });
     }

     // Marks this node children as deleted. They are still associated with their parent, and
     // all open handles etc. to the deleted nodes are preserved until their refcount goes
     // to zero.
     void SetDeletedForChild(const std::string& name) {
         ForChild(name, [](node* child) {
             child->SetDeleted();
             return false;
         });
     }

     void SetDeleted() {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         deleted_ = true;
     }

     void RenameChild(const std::string& old_name, const std::string& new_name, node* new_parent) {
         ForChild(old_name, [=](node* child) {
             child->Rename(new_name, new_parent);
             return false;
         });
     }

     void Rename(const std::string& name, node* new_parent) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);

         if (new_parent != parent_) {
             RemoveFromParent();
             name_ = name;
             AddToParent(new_parent);
             return;
         }

         // Changing name_ will change the expected position of this node in parent's set of
         // children. Consider following scenario:
         // 1. This node: "b"; parent's set: {"a", "b", "c"}
         // 2. Rename("b", "d")
         //
         // After rename, parent's set should become: {"a", "b", "d"}, but if we simply change the
         // name it will be {"a", "d", "b"}, which violates properties of the set.
         //
         // To make sure that parent's set is always valid, changing name is 3 steps procedure:
         // 1. Remove this node from parent's set.
         // 2  Change the name.
         // 3. Add it back to the set.
         // Rename of node without changing its parent. Still need to remove and re-add it to make
         // sure lookup index is correct.
         if (name_ != name) {
             // If this is a root node, simply rename it.
             if (parent_ == nullptr) {
                 name_ = name;
                 return;
             }

             auto it = parent_->children_.find(this);
             CHECK(it != parent_->children_.end());
             parent_->children_.erase(it);

             name_ = name;

             parent_->children_.insert(this);
         }
     }

     const std::string& GetName() const {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         return name_;
     }

     const std::string& GetIoPath() const { return io_path_; }

     int GetTransforms() const { return transforms_; }

     int GetTransformsReason() const { return transforms_reason_; }

     bool IsTransformsComplete() const {
         return transforms_complete_.load(std::memory_order_acquire);
     }

     void SetTransformsComplete(bool complete) {
         transforms_complete_.store(complete, std::memory_order_release);
     }

     node* GetParent() const {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         return parent_;
     }

     inline void AddHandle(handle* h) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         handles_.emplace_back(std::unique_ptr<handle>(h));
     }

     void DestroyHandle(handle* h) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);

         auto comp = [h](const std::unique_ptr<handle>& ptr) { return ptr.get() == h; };
         auto it = std::find_if(handles_.begin(), handles_.end(), comp);
         CHECK(it != handles_.end());
         handles_.erase(it);
     }

     bool HasCachedHandle() const {
         std::lock_guard<std::recursive_mutex> guard(*lock_);

         for (const auto& handle : handles_) {
             if (handle->cached) {
                 return true;
             }
         }
         return false;
     }

     std::unique_ptr<FdAccessResult> CheckHandleForUid(const uid_t uid) const {
         std::lock_guard<std::recursive_mutex> guard(*lock_);

         bool found_handle = false;
         bool redaction_not_needed = false;
         for (const auto& handle : handles_) {
             if (handle->uid == uid) {
                 found_handle = true;
                 redaction_not_needed |= !handle->ri->isRedactionNeeded();
             }
         }

         if (found_handle) {
             return std::make_unique<FdAccessResult>(BuildPath(), !redaction_not_needed);
         }

         return std::make_unique<FdAccessResult>(std::string(), false);
     }

     void SetName(std::string name) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         name_ = std::move(name);
     }

     bool HasRedactedCache() const {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         return has_redacted_cache_;
     }

     void SetRedactedCache(bool state) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         has_redacted_cache_ = state;
     }

     inline void AddDirHandle(dirhandle* d) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);

         dirhandles_.emplace_back(std::unique_ptr<dirhandle>(d));
     }

     void DestroyDirHandle(dirhandle* d) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);

         auto comp = [d](const std::unique_ptr<dirhandle>& ptr) { return ptr.get() == d; };
         auto it = std::find_if(dirhandles_.begin(), dirhandles_.end(), comp);
         CHECK(it != dirhandles_.end());
         dirhandles_.erase(it);
     }

     // Deletes the tree of nodes rooted at |tree|.
     static void DeleteTree(node* tree);

     // Looks up an absolute path rooted at |root|, or nullptr if no such path
     // through the hierarchy exists.
     static const node* LookupAbsolutePath(const node* root, const std::string& absolute_path);

     // Looks up for the node with the given ino rooted at |root|, or nullptr if no such node exists.
     static const node* LookupInode(const node* root, ino_t ino);

   private:
     node(node* parent, const std::string& name, const std::string& io_path,
          const bool transforms_complete, const int transforms, const int transforms_reason,
          std::recursive_mutex* lock, ino_t ino, NodeTracker* tracker)
         : name_(name),
           io_path_(io_path),
           transforms_complete_(transforms_complete),
           transforms_(transforms),
           transforms_reason_(transforms_reason),
           refcount_(0),
           parent_(nullptr),
           has_redacted_cache_(false),
           deleted_(false),
           lock_(lock),
           ino_(ino),
           tracker_(tracker) {
         tracker_->NodeCreated(this);
         Acquire();
         // This is a special case for the root node. All other nodes will have a
         // non-null parent.
         if (parent != nullptr) {
             AddToParent(parent);
         }
     }

     // Acquires a reference to a node. This maps to the "lookup count" specified
     // by the FUSE documentation and must only happen under the circumstances
     // documented in libfuse/include/fuse_lowlevel.h.
     inline void Acquire() {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         refcount_++;
     }

     // Adds this node to a specified parent.
     void AddToParent(node* parent) {
         std::lock_guard<std::recursive_mutex> guard(*lock_);
         // This method assumes this node is currently unparented.
         CHECK(parent_ == nullptr);
         // Check that the new parent isn't nullptr either.
         CHECK(parent != nullptr);

         parent_ = parent;
         parent_->children_.insert(this);

         // TODO(narayan, zezeozue): It's unclear why we need to call Acquire on the
         // parent node when we're adding a child to it.
         parent_->Acquire();
     }

     // Removes this node from its current parent, and set its parent to nullptr.
     void RemoveFromParent() {
         std::lock_guard<std::recursive_mutex> guard(*lock_);

         if (parent_ != nullptr) {
             auto it = parent_->children_.find(this);
             CHECK(it != parent_->children_.end());
             parent_->children_.erase(it);

             parent_->Release(1);
             parent_ = nullptr;
         }
     }

     // Finds *all* non-deleted nodes matching |name| and runs the function |callback| on each
     // node until |callback| returns true.
     // When |callback| returns true, the matched node is returned
     node* ForChild(const std::string& name, const std::function<bool(node*)>& callback) const {
         std::lock_guard<std::recursive_mutex> guard(*lock_);

         // lower_bound will give us the first child with strcasecmp(child->name, name) >=0.
         // For more context see comment on the NodeCompare struct.
         auto start = children_.lower_bound(std::make_pair(name, 0));
         // upper_bound will give us the first child with strcasecmp(child->name, name) > 0
         auto end =
                 children_.upper_bound(std::make_pair(name, std::numeric_limits<uintptr_t>::max()));

         // Make a copy of the matches because calling callback might modify the list which will
         // cause issues while iterating over them.
         std::vector<node*> children(start, end);

         for (node* child : children) {
             if (!child->deleted_ && callback(child)) {
                 return child;
             }
         }

         return nullptr;
     }

     // A custom heterogeneous comparator used for set of this node's children_ to speed up child
     // node by name lookups.
     //
     // This comparator treats node* as pair (node->name_, node): two nodes* are first
     // compared by their name using case-insenstive comparison function. If their names are equal,
     // then pointers are compared as integers.
     //
     // See LookupChildByName function to see how this comparator is used.
     //
     // Note that it's important to first compare by name_, since it will make all nodes with same
     // name (compared using strcasecmp) together, which allows LookupChildByName function to find
     // range of the candidate nodes by issuing two binary searches.
     struct NodeCompare {
         using is_transparent = void;

         bool operator()(const node* lhs, const node* rhs) const {
             int cmp = strcasecmp(lhs->name_.c_str(), rhs->name_.c_str());
             if (cmp != 0) {
                 return cmp < 0;
             }
             return reinterpret_cast<uintptr_t>(lhs) < reinterpret_cast<uintptr_t>(rhs);
         }

         bool operator()(const node* lhs, const std::pair<std::string, uintptr_t>& rhs) const {
             int cmp = strcasecmp(lhs->name_.c_str(), rhs.first.c_str());
             if (cmp != 0) {
                 return cmp < 0;
             }
             return reinterpret_cast<uintptr_t>(lhs) < rhs.second;
         }

         bool operator()(const std::pair<std::string, uintptr_t>& lhs, const node* rhs) const {
             int cmp = strcasecmp(lhs.first.c_str(), rhs->name_.c_str());
             if (cmp != 0) {
                 return cmp < 0;
             }
             return lhs.second < reinterpret_cast<uintptr_t>(rhs);
         }
     };

     // A helper function to recursively construct the absolute path of a given node.
     // If |safe| is true, builds a PII safe path instead
     void BuildPathForNodeRecursive(bool safe, const node* node, std::stringstream* path) const;

     // The name of this node. Non-const because it can change during renames.
     std::string name_;
     // Filesystem path that will be used for IO (if it is non-empty) instead of node->BuildPath
     const std::string io_path_;
     // Whether any transforms required on |io_path_| are complete.
     // If false, might need to call a node transform function with |transforms| below
     std::atomic_bool transforms_complete_;
     // Opaque flags that determines the 'required' transforms to perform on node
     // before IO. These flags should not be interpreted in native but should be passed to the
     // MediaProvider as part of a transform function and if successful, |transforms_complete_|
     // should be set to true
     const int transforms_;
     // Opaque value indicating the reason why transforms are required.
     // This value should not be interpreted in native but should be passed to the MediaProvider
     // as part of a transform function
     const int transforms_reason_;
     // The reference count for this node. Guarded by |lock_|.
     uint32_t refcount_;
     // Set of children of this node. All of them contain a back reference
     // to their parent. Guarded by |lock_|.
     std::set<node*, NodeCompare> children_;
     // Containing directory for this node. Guarded by |lock_|.
     node* parent_;
     // List of file handles associated with this node. Guarded by |lock_|.
     std::vector<std::unique_ptr<handle>> handles_;
     // List of directory handles associated with this node. Guarded by |lock_|.
     std::vector<std::unique_ptr<dirhandle>> dirhandles_;
     bool has_redacted_cache_;
     bool deleted_;
     std::recursive_mutex* lock_;
     // Inode number of the file represented by this node.
     const ino_t ino_;

     NodeTracker* const tracker_;

     ~node() {
         RemoveFromParent();

         handles_.clear();
         dirhandles_.clear();

         tracker_->NodeDeleted(this);
     }

     friend class ::NodeTest;
 };

 }  // namespace fuse
 }  // namespace mediaprovider

 #endif  // MEDIA_PROVIDER_JNI_MODE_INL_H_
	/*
	* Copyright (C) 2020 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 specic language governing permissions and
	* limitations under the License.
	*/

	#ifndef MEDIA_PROVIDER_JNI_NODE_INL_H_
	#define MEDIA_PROVIDER_JNI_NODE_INL_H_

	#include <android-base/logging.h>

	#include <sys/types.h>
	#include <atomic>
	#include <cstdint>
	#include <limits>
	#include <list>
	#include <memory>
	#include <mutex>
	#include <set>
	#include <sstream>
	#include <string>
	#include <unordered_set>
	#include <utility>
	#include <vector>

	#include "libfuse_jni/ReaddirHelper.h"
	#include "libfuse_jni/RedactionInfo.h"

	class NodeTest;

	namespace mediaprovider {
	namespace fuse {

	struct handle {
	explicit handle(int fd, const RedactionInfo* ri, bool cached, bool passthrough, uid_t uid,
	uid_t transforms_uid)
	: fd(fd),
	ri(ri),
	cached(cached),
	passthrough(passthrough),
	uid(uid),
	transforms_uid(transforms_uid) {
	CHECK(ri != nullptr);
	}

	const int fd;
	const std::unique_ptr<const RedactionInfo> ri;
	const bool cached;
	const bool passthrough;
	const uid_t uid;
	const uid_t transforms_uid;

	~handle() { close(fd); }
	};

	struct dirhandle {
	explicit dirhandle(DIR* dir) : d(dir), next_off(0) { CHECK(dir != nullptr); }

	DIR* const d;
	off_t next_off;
	// Fuse readdir() is called multiple times based on the size of the buffer and
	// number of directory entries in the given directory. 'de' holds the list
	// of directory entries for the directory handle and this list is available
	// across subsequent readdir() calls for the same directory handle.
	std::vector<std::shared_ptr<DirectoryEntry>> de;

	~dirhandle() { closedir(d); }
	};

	/** Represents file open result from MediaProvider */
	struct FdAccessResult {
	FdAccessResult(const std::string& file_path, const bool should_redact)
	: file_path(file_path), should_redact(should_redact) {}

	const std::string file_path;
	const bool should_redact;
	};

	// Whether inode tracking is enabled or not. When enabled, we maintain a
	// separate mapping from inode numbers to "live" nodes so we can detect when
	// we receive a request to a node that has been deleted.
	static constexpr bool kEnableInodeTracking = true;

	class node;

	// Tracks the set of active nodes associated with a FUSE instance so that we
	// can assert that we only ever return an active node in response to a lookup.
	class NodeTracker {
	public:
	explicit NodeTracker(std::recursive_mutex* lock) : lock_(lock) {}

	bool Exists(__u64 ino) const {
	if (kEnableInodeTracking) {
	const node* node = reinterpret_cast<const class node*>(ino);
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	return active_nodes_.find(node) != active_nodes_.end();
	}
	}

	void CheckTracked(__u64 ino) const {
	if (kEnableInodeTracking) {
	const node* node = reinterpret_cast<const class node*>(ino);
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	CHECK(active_nodes_.find(node) != active_nodes_.end());
	}
	}

	void NodeDeleted(const node* node) {
	if (kEnableInodeTracking) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	LOG(DEBUG) << "Node: " << reinterpret_cast<uintptr_t>(node) << " deleted.";

	CHECK(active_nodes_.find(node) != active_nodes_.end());
	active_nodes_.erase(node);
	}
	}

	void NodeCreated(const node* node) {
	if (kEnableInodeTracking) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	LOG(DEBUG) << "Node: " << reinterpret_cast<uintptr_t>(node) << " created.";

	CHECK(active_nodes_.find(node) == active_nodes_.end());
	active_nodes_.insert(node);
	}
	}

	private:
	std::recursive_mutex* lock_;
	std::unordered_set<const node*> active_nodes_;
	};

	class node {
	public:
	// Creates a new node with the specified parent, name and lock.
	static node* Create(node* parent, const std::string& name, const std::string& io_path,
	const bool transforms_complete, const int transforms,
	const int transforms_reason, std::recursive_mutex* lock, ino_t ino,
	NodeTracker* tracker) {
	// Place the entire constructor under a critical section to make sure
	// node creation, tracking (if enabled) and the addition to a parent are
	// atomic.
	std::lock_guard<std::recursive_mutex> guard(*lock);
	return new node(parent, name, io_path, transforms_complete, transforms, transforms_reason,
	lock, ino, tracker);
	}

	// Creates a new root node. Root nodes have no parents by definition
	// and their "name" must signify an absolute path.
	static node* CreateRoot(const std::string& path, std::recursive_mutex* lock, ino_t ino,
	NodeTracker* tracker) {
	std::lock_guard<std::recursive_mutex> guard(*lock);
	node* root = new node(nullptr, path, path, true /* transforms_complete */,
	0 /* transforms /, 0 / transforms_reason */, lock, ino, tracker);

	// The root always has one extra reference to avoid it being
	// accidentally collected.
	root->Acquire();
	return root;
	}

	// Maps an inode to its associated node.
	static inline node* FromInode(__u64 ino, const NodeTracker* tracker) {
	tracker->CheckTracked(ino);
	return reinterpret_cast<node*>(static_cast<uintptr_t>(ino));
	}

	// TODO(b/215235604)
	static inline node* FromInodeNoThrow(__u64 ino, const NodeTracker* tracker) {
	if (!tracker->Exists(ino)) return nullptr;
	return reinterpret_cast<node*>(static_cast<uintptr_t>(ino));
	}

	// Maps a node to its associated inode.
	static __u64 ToInode(node* node) {
	return static_cast<__u64>(reinterpret_cast<uintptr_t>(node));
	}

	// Releases a reference to a node. Returns true iff the refcount dropped to
	// zero as a result of this call to Release, meaning that it's no longer
	// safe to perform any operations on references to this node.
	bool Release(uint32_t count) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	if (refcount_ >= count) {
	refcount_ -= count;
	if (refcount_ == 0) {
	delete this;
	return true;
	}
	} else {
	LOG(ERROR) << "Mismatched reference count: refcount_ = " << this->refcount_
	<< " ,count = " << count;
	}

	return false;
	}

	// Builds the full path associated with this node, including all path segments
	// associated with its descendants.
	std::string BuildPath() const;

	// Builds the full PII safe path associated with this node, including all path segments
	// associated with its descendants.
	std::string BuildSafePath() const;

	// Looks up a direct descendant of this node by case-insensitive \|name\|. If \|acquire\| is true,
	// also Acquire the node before returning a reference to it.
	// \|transforms\| is an opaque flag that is used to distinguish multiple nodes sharing the same
	// \|name\| but requiring different IO transformations as determined by the MediaProvider.
	node* LookupChildByName(const std::string& name, bool acquire, const int transforms = 0) const {
	return ForChild(name, [acquire, transforms](node* child) {
	if (child->transforms_ == transforms) {
	if (acquire) {
	child->Acquire();
	}
	return true;
	}
	return false;
	});
	}

	// Marks this node children as deleted. They are still associated with their parent, and
	// all open handles etc. to the deleted nodes are preserved until their refcount goes
	// to zero.
	void SetDeletedForChild(const std::string& name) {
	ForChild(name, [](node* child) {
	child->SetDeleted();
	return false;
	});
	}

	void SetDeleted() {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	deleted_ = true;
	}

	void RenameChild(const std::string& old_name, const std::string& new_name, node* new_parent) {
	ForChild(old_name, [=](node* child) {
	child->Rename(new_name, new_parent);
	return false;
	});
	}

	void Rename(const std::string& name, node* new_parent) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);

	if (new_parent != parent_) {
	RemoveFromParent();
	name_ = name;
	AddToParent(new_parent);
	return;
	}

	// Changing name_ will change the expected position of this node in parent's set of
	// children. Consider following scenario:
	// 1. This node: "b"; parent's set: {"a", "b", "c"}
	// 2. Rename("b", "d")
	//
	// After rename, parent's set should become: {"a", "b", "d"}, but if we simply change the
	// name it will be {"a", "d", "b"}, which violates properties of the set.
	//
	// To make sure that parent's set is always valid, changing name is 3 steps procedure:
	// 1. Remove this node from parent's set.
	// 2 Change the name.
	// 3. Add it back to the set.
	// Rename of node without changing its parent. Still need to remove and re-add it to make
	// sure lookup index is correct.
	if (name_ != name) {
	// If this is a root node, simply rename it.
	if (parent_ == nullptr) {
	name_ = name;
	return;
	}

	auto it = parent_->children_.find(this);
	CHECK(it != parent_->children_.end());
	parent_->children_.erase(it);

	name_ = name;

	parent_->children_.insert(this);
	}
	}

	const std::string& GetName() const {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	return name_;
	}

	const std::string& GetIoPath() const { return io_path_; }

	int GetTransforms() const { return transforms_; }

	int GetTransformsReason() const { return transforms_reason_; }

	bool IsTransformsComplete() const {
	return transforms_complete_.load(std::memory_order_acquire);
	}

	void SetTransformsComplete(bool complete) {
	transforms_complete_.store(complete, std::memory_order_release);
	}

	node* GetParent() const {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	return parent_;
	}

	inline void AddHandle(handle* h) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	handles_.emplace_back(std::unique_ptr<handle>(h));
	}

	void DestroyHandle(handle* h) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);

	auto comp = [h](const std::unique_ptr<handle>& ptr) { return ptr.get() == h; };
	auto it = std::find_if(handles_.begin(), handles_.end(), comp);
	CHECK(it != handles_.end());
	handles_.erase(it);
	}

	bool HasCachedHandle() const {
	std::lock_guard<std::recursive_mutex> guard(*lock_);

	for (const auto& handle : handles_) {
	if (handle->cached) {
	return true;
	}
	}
	return false;
	}

	std::unique_ptr<FdAccessResult> CheckHandleForUid(const uid_t uid) const {
	std::lock_guard<std::recursive_mutex> guard(*lock_);

	bool found_handle = false;
	bool redaction_not_needed = false;
	for (const auto& handle : handles_) {
	if (handle->uid == uid) {
	found_handle = true;
	redaction_not_needed \|= !handle->ri->isRedactionNeeded();
	}
	}

	if (found_handle) {
	return std::make_unique<FdAccessResult>(BuildPath(), !redaction_not_needed);
	}

	return std::make_unique<FdAccessResult>(std::string(), false);
	}

	void SetName(std::string name) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	name_ = std::move(name);
	}

	bool HasRedactedCache() const {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	return has_redacted_cache_;
	}

	void SetRedactedCache(bool state) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	has_redacted_cache_ = state;
	}

	inline void AddDirHandle(dirhandle* d) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);

	dirhandles_.emplace_back(std::unique_ptr<dirhandle>(d));
	}

	void DestroyDirHandle(dirhandle* d) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);

	auto comp = [d](const std::unique_ptr<dirhandle>& ptr) { return ptr.get() == d; };
	auto it = std::find_if(dirhandles_.begin(), dirhandles_.end(), comp);
	CHECK(it != dirhandles_.end());
	dirhandles_.erase(it);
	}

	// Deletes the tree of nodes rooted at \|tree\|.
	static void DeleteTree(node* tree);

	// Looks up an absolute path rooted at \|root\|, or nullptr if no such path
	// through the hierarchy exists.
	static const node* LookupAbsolutePath(const node* root, const std::string& absolute_path);

	// Looks up for the node with the given ino rooted at \|root\|, or nullptr if no such node exists.
	static const node* LookupInode(const node* root, ino_t ino);

	private:
	node(node* parent, const std::string& name, const std::string& io_path,
	const bool transforms_complete, const int transforms, const int transforms_reason,
	std::recursive_mutex* lock, ino_t ino, NodeTracker* tracker)
	: name_(name),
	io_path_(io_path),
	transforms_complete_(transforms_complete),
	transforms_(transforms),
	transforms_reason_(transforms_reason),
	refcount_(0),
	parent_(nullptr),
	has_redacted_cache_(false),
	deleted_(false),
	lock_(lock),
	ino_(ino),
	tracker_(tracker) {
	tracker_->NodeCreated(this);
	Acquire();
	// This is a special case for the root node. All other nodes will have a
	// non-null parent.
	if (parent != nullptr) {
	AddToParent(parent);
	}
	}

	// Acquires a reference to a node. This maps to the "lookup count" specified
	// by the FUSE documentation and must only happen under the circumstances
	// documented in libfuse/include/fuse_lowlevel.h.
	inline void Acquire() {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	refcount_++;
	}

	// Adds this node to a specified parent.
	void AddToParent(node* parent) {
	std::lock_guard<std::recursive_mutex> guard(*lock_);
	// This method assumes this node is currently unparented.
	CHECK(parent_ == nullptr);
	// Check that the new parent isn't nullptr either.
	CHECK(parent != nullptr);

	parent_ = parent;
	parent_->children_.insert(this);

	// TODO(narayan, zezeozue): It's unclear why we need to call Acquire on the
	// parent node when we're adding a child to it.
	parent_->Acquire();
	}

	// Removes this node from its current parent, and set its parent to nullptr.
	void RemoveFromParent() {
	std::lock_guard<std::recursive_mutex> guard(*lock_);

	if (parent_ != nullptr) {
	auto it = parent_->children_.find(this);
	CHECK(it != parent_->children_.end());
	parent_->children_.erase(it);

	parent_->Release(1);
	parent_ = nullptr;
	}
	}

	// Finds all non-deleted nodes matching \|name\| and runs the function \|callback\| on each
	// node until \|callback\| returns true.
	// When \|callback\| returns true, the matched node is returned
	node* ForChild(const std::string& name, const std::function<bool(node*)>& callback) const {
	std::lock_guard<std::recursive_mutex> guard(*lock_);

	// lower_bound will give us the first child with strcasecmp(child->name, name) >=0.
	// For more context see comment on the NodeCompare struct.
	auto start = children_.lower_bound(std::make_pair(name, 0));
	// upper_bound will give us the first child with strcasecmp(child->name, name) > 0
	auto end =
	children_.upper_bound(std::make_pair(name, std::numeric_limits<uintptr_t>::max()));

	// Make a copy of the matches because calling callback might modify the list which will
	// cause issues while iterating over them.
	std::vector<node*> children(start, end);

	for (node* child : children) {
	if (!child->deleted_ && callback(child)) {
	return child;
	}
	}

	return nullptr;
	}

	// A custom heterogeneous comparator used for set of this node's children_ to speed up child
	// node by name lookups.
	//
	// This comparator treats node* as pair (node->name_, node): two nodes* are first
	// compared by their name using case-insenstive comparison function. If their names are equal,
	// then pointers are compared as integers.
	//
	// See LookupChildByName function to see how this comparator is used.
	//
	// Note that it's important to first compare by name_, since it will make all nodes with same
	// name (compared using strcasecmp) together, which allows LookupChildByName function to find
	// range of the candidate nodes by issuing two binary searches.
	struct NodeCompare {
	using is_transparent = void;

	bool operator()(const node* lhs, const node* rhs) const {
	int cmp = strcasecmp(lhs->name_.c_str(), rhs->name_.c_str());
	if (cmp != 0) {
	return cmp < 0;
	}
	return reinterpret_cast<uintptr_t>(lhs) < reinterpret_cast<uintptr_t>(rhs);
	}

	bool operator()(const node* lhs, const std::pair<std::string, uintptr_t>& rhs) const {
	int cmp = strcasecmp(lhs->name_.c_str(), rhs.first.c_str());
	if (cmp != 0) {
	return cmp < 0;
	}
	return reinterpret_cast<uintptr_t>(lhs) < rhs.second;
	}

	bool operator()(const std::pair<std::string, uintptr_t>& lhs, const node* rhs) const {
	int cmp = strcasecmp(lhs.first.c_str(), rhs->name_.c_str());
	if (cmp != 0) {
	return cmp < 0;
	}
	return lhs.second < reinterpret_cast<uintptr_t>(rhs);
	}
	};

	// A helper function to recursively construct the absolute path of a given node.
	// If \|safe\| is true, builds a PII safe path instead
	void BuildPathForNodeRecursive(bool safe, const node* node, std::stringstream* path) const;

	// The name of this node. Non-const because it can change during renames.
	std::string name_;
	// Filesystem path that will be used for IO (if it is non-empty) instead of node->BuildPath
	const std::string io_path_;
	// Whether any transforms required on \|io_path_\| are complete.
	// If false, might need to call a node transform function with \|transforms\| below
	std::atomic_bool transforms_complete_;
	// Opaque flags that determines the 'required' transforms to perform on node
	// before IO. These flags should not be interpreted in native but should be passed to the
	// MediaProvider as part of a transform function and if successful, \|transforms_complete_\|
	// should be set to true
	const int transforms_;
	// Opaque value indicating the reason why transforms are required.
	// This value should not be interpreted in native but should be passed to the MediaProvider
	// as part of a transform function
	const int transforms_reason_;
	// The reference count for this node. Guarded by \|lock_\|.
	uint32_t refcount_;
	// Set of children of this node. All of them contain a back reference
	// to their parent. Guarded by \|lock_\|.
	std::set<node*, NodeCompare> children_;
	// Containing directory for this node. Guarded by \|lock_\|.
	node* parent_;
	// List of file handles associated with this node. Guarded by \|lock_\|.
	std::vector<std::unique_ptr<handle>> handles_;
	// List of directory handles associated with this node. Guarded by \|lock_\|.
	std::vector<std::unique_ptr<dirhandle>> dirhandles_;
	bool has_redacted_cache_;
	bool deleted_;
	std::recursive_mutex* lock_;
	// Inode number of the file represented by this node.
	const ino_t ino_;

	NodeTracker* const tracker_;

	~node() {
	RemoveFromParent();

	handles_.clear();
	dirhandles_.clear();

	tracker_->NodeDeleted(this);
	}

	friend class ::NodeTest;
	};

	} // namespace fuse
	} // namespace mediaprovider

	#endif // MEDIA_PROVIDER_JNI_MODE_INL_H_