pw_kvs/entry_cache.cc - platform/external/pigweed - Gitiles

 // Copyright 2020 The Pigweed Authors
 //
 // 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
 //
 //     https://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 PW_LOG_MODULE_NAME "KVS"
 #define PW_LOG_LEVEL PW_KVS_LOG_LEVEL

 #include "pw_kvs/internal/entry_cache.h"

 #include <cinttypes>

 #include "pw_kvs/flash_memory.h"
 #include "pw_kvs/internal/entry.h"
 #include "pw_kvs/internal/hash.h"
 #include "pw_kvs_private/config.h"
 #include "pw_log/log.h"

 namespace pw::kvs::internal {
 namespace {

 constexpr FlashPartition::Address kNoAddress = FlashPartition::Address(-1);

 }  // namespace

 void EntryMetadata::RemoveAddress(Address address_to_remove) {
   // Find the index of the address to remove.
   for (Address& address : addresses_) {
     if (address == address_to_remove) {
       // Move the address at the back of the list to the slot of the address
       // being removed. Do this unconditionally, even if the address to remove
       // is the last slot since the logic still works.
       address = addresses_.back();

       // Remove the back entry of the address list.
       addresses_.back() = kNoAddress;
       addresses_ = std::span(addresses_.begin(), addresses_.size() - 1);
       break;
     }
   }
 }

 void EntryMetadata::Reset(const KeyDescriptor& descriptor, Address address) {
   *descriptor_ = descriptor;

   addresses_[0] = address;
   for (size_t i = 1; i < addresses_.size(); ++i) {
     addresses_[i] = kNoAddress;
   }
   addresses_ = addresses_.first(1);
 }

 StatusWithSize EntryCache::Find(FlashPartition& partition,
                                 const Sectors& sectors,
                                 const EntryFormats& formats,
                                 Key key,
                                 EntryMetadata* metadata) const {
   const uint32_t hash = internal::Hash(key);
   Entry::KeyBuffer key_buffer;
   bool error_detected = false;

   for (size_t i = 0; i < descriptors_.size(); ++i) {
     if (descriptors_[i].key_hash == hash) {
       bool key_found = false;
       Key read_key;

       for (Address address : addresses(i)) {
         Status read_result =
             Entry::ReadKey(partition, address, key.size(), key_buffer.data());

         read_key = Key(key_buffer.data(), key.size());

         if (read_result.ok() && hash == internal::Hash(read_key)) {
           key_found = true;
           break;
         } else {
           // A hash mismatch can be caused by reading invalid data or a key hash
           // collision of keys with differing size. To verify the data read from
           // flash is good, validate the entry.
           Entry entry;
           read_result = Entry::Read(partition, address, formats, &entry);
           if (read_result.ok() && entry.VerifyChecksumInFlash().ok()) {
             key_found = true;
             break;
           }

           PW_LOG_WARN(
               "   Found corrupt entry, invalidating this copy of the key");
           error_detected = true;
           sectors.FromAddress(address).mark_corrupt();
         }
       }
       size_t error_val = error_detected ? 1 : 0;

       if (!key_found) {
         PW_LOG_ERROR("No valid entries for key. Data has been lost!");
         return StatusWithSize::DataLoss(error_val);
       } else if (key == read_key) {
         PW_LOG_DEBUG("Found match for key hash 0x%08" PRIx32, hash);
         *metadata = EntryMetadata(descriptors_[i], addresses(i));
         return StatusWithSize(error_val);
       } else {
         PW_LOG_WARN("Found key hash collision for 0x%08" PRIx32, hash);
         return StatusWithSize::AlreadyExists(error_val);
       }
     }
   }
   return StatusWithSize::NotFound();
 }

 EntryMetadata EntryCache::AddNew(const KeyDescriptor& descriptor,
                                  Address entry_address) const {
   // TODO(hepler): DCHECK(!full());
   Address* first_address = ResetAddresses(descriptors_.size(), entry_address);
   descriptors_.push_back(descriptor);
   return EntryMetadata(descriptors_.back(), std::span(first_address, 1));
 }

 // TODO: This method is the trigger of the O(valid_entries * all_entries) time
 // complexity for reading. At some cost to memory, this could be optimized by
 // using a hash table instead of scanning, but in practice this should be fine
 // for a small number of keys
 Status EntryCache::AddNewOrUpdateExisting(const KeyDescriptor& descriptor,
                                           Address address,
                                           size_t sector_size_bytes) const {
   // With the new key descriptor, either add it to the descriptor table or
   // overwrite an existing entry with an older version of the key.
   const int index = FindIndex(descriptor.key_hash);

   // Write a new entry if there is room.
   if (index == -1) {
     if (full()) {
       return Status::ResourceExhausted();
     }
     AddNew(descriptor, address);
     return OkStatus();
   }

   // Existing entry is old; replace the existing entry with the new one.
   if (descriptor.transaction_id > descriptors_[index].transaction_id) {
     descriptors_[index] = descriptor;
     ResetAddresses(index, address);
     return OkStatus();
   }

   // If the entries have a duplicate transaction ID, add the new (redundant)
   // entry to the existing descriptor.
   if (descriptors_[index].transaction_id == descriptor.transaction_id) {
     if (descriptors_[index].key_hash != descriptor.key_hash) {
       PW_LOG_ERROR("Duplicate entry for key 0x%08" PRIx32
                    " with transaction ID %" PRIu32 " has non-matching hash",
                    descriptor.key_hash,
                    descriptor.transaction_id);
       return Status::DataLoss();
     }

     // Verify that this entry is not in the same sector as an existing copy of
     // this same key.
     for (Address existing_address : addresses(index)) {
       if (existing_address / sector_size_bytes == address / sector_size_bytes) {
         PW_LOG_DEBUG("Multiple Redundant entries in same sector %u",
                      unsigned(address / sector_size_bytes));
         return Status::DataLoss();
       }
     }

     AddAddressIfRoom(index, address);
   } else {
     PW_LOG_DEBUG("Found stale entry when appending; ignoring");
   }
   return OkStatus();
 }

 size_t EntryCache::present_entries() const {
   size_t present_entries = 0;

   for (const KeyDescriptor& descriptor : descriptors_) {
     if (descriptor.state != EntryState::kDeleted) {
       present_entries += 1;
     }
   }

   return present_entries;
 }

 int EntryCache::FindIndex(uint32_t key_hash) const {
   for (size_t i = 0; i < descriptors_.size(); ++i) {
     if (descriptors_[i].key_hash == key_hash) {
       return i;
     }
   }
   return -1;
 }

 void EntryCache::AddAddressIfRoom(size_t descriptor_index,
                                   Address address) const {
   Address* const existing = first_address(descriptor_index);

   for (size_t i = 0; i < redundancy(); ++i) {
     if (existing[i] == kNoAddress) {
       existing[i] = address;
       return;
     }
   }
 }

 std::span<EntryCache::Address> EntryCache::addresses(
     size_t descriptor_index) const {
   Address* const addresses = first_address(descriptor_index);

   size_t size = 0;
   while (size < redundancy() && addresses[size] != kNoAddress) {
     size += 1;
   }

   return std::span(addresses, size);
 }

 EntryCache::Address* EntryCache::ResetAddresses(size_t descriptor_index,
                                                 Address address) const {
   Address* first = first_address(descriptor_index);
   *first = address;

   // Clear the additional addresses, if any.
   for (size_t i = 1; i < redundancy_; ++i) {
     first[i] = kNoAddress;
   }

   return first;
 }

 }  // namespace pw::kvs::internal
	// Copyright 2020 The Pigweed Authors
	//
	// 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
	//
	// https://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 PW_LOG_MODULE_NAME "KVS"
	#define PW_LOG_LEVEL PW_KVS_LOG_LEVEL

	#include "pw_kvs/internal/entry_cache.h"

	#include <cinttypes>

	#include "pw_kvs/flash_memory.h"
	#include "pw_kvs/internal/entry.h"
	#include "pw_kvs/internal/hash.h"
	#include "pw_kvs_private/config.h"
	#include "pw_log/log.h"

	namespace pw::kvs::internal {
	namespace {

	constexpr FlashPartition::Address kNoAddress = FlashPartition::Address(-1);

	} // namespace

	void EntryMetadata::RemoveAddress(Address address_to_remove) {
	// Find the index of the address to remove.
	for (Address& address : addresses_) {
	if (address == address_to_remove) {
	// Move the address at the back of the list to the slot of the address
	// being removed. Do this unconditionally, even if the address to remove
	// is the last slot since the logic still works.
	address = addresses_.back();

	// Remove the back entry of the address list.
	addresses_.back() = kNoAddress;
	addresses_ = std::span(addresses_.begin(), addresses_.size() - 1);
	break;
	}
	}
	}

	void EntryMetadata::Reset(const KeyDescriptor& descriptor, Address address) {
	*descriptor_ = descriptor;

	addresses_[0] = address;
	for (size_t i = 1; i < addresses_.size(); ++i) {
	addresses_[i] = kNoAddress;
	}
	addresses_ = addresses_.first(1);
	}

	StatusWithSize EntryCache::Find(FlashPartition& partition,
	const Sectors& sectors,
	const EntryFormats& formats,
	Key key,
	EntryMetadata* metadata) const {
	const uint32_t hash = internal::Hash(key);
	Entry::KeyBuffer key_buffer;
	bool error_detected = false;

	for (size_t i = 0; i < descriptors_.size(); ++i) {
	if (descriptors_[i].key_hash == hash) {
	bool key_found = false;
	Key read_key;

	for (Address address : addresses(i)) {
	Status read_result =
	Entry::ReadKey(partition, address, key.size(), key_buffer.data());

	read_key = Key(key_buffer.data(), key.size());

	if (read_result.ok() && hash == internal::Hash(read_key)) {
	key_found = true;
	break;
	} else {
	// A hash mismatch can be caused by reading invalid data or a key hash
	// collision of keys with differing size. To verify the data read from
	// flash is good, validate the entry.
	Entry entry;
	read_result = Entry::Read(partition, address, formats, &entry);
	if (read_result.ok() && entry.VerifyChecksumInFlash().ok()) {
	key_found = true;
	break;
	}

	PW_LOG_WARN(
	" Found corrupt entry, invalidating this copy of the key");
	error_detected = true;
	sectors.FromAddress(address).mark_corrupt();
	}
	}
	size_t error_val = error_detected ? 1 : 0;

	if (!key_found) {
	PW_LOG_ERROR("No valid entries for key. Data has been lost!");
	return StatusWithSize::DataLoss(error_val);
	} else if (key == read_key) {
	PW_LOG_DEBUG("Found match for key hash 0x%08" PRIx32, hash);
	*metadata = EntryMetadata(descriptors_[i], addresses(i));
	return StatusWithSize(error_val);
	} else {
	PW_LOG_WARN("Found key hash collision for 0x%08" PRIx32, hash);
	return StatusWithSize::AlreadyExists(error_val);
	}
	}
	}
	return StatusWithSize::NotFound();
	}

	EntryMetadata EntryCache::AddNew(const KeyDescriptor& descriptor,
	Address entry_address) const {
	// TODO(hepler): DCHECK(!full());
	Address* first_address = ResetAddresses(descriptors_.size(), entry_address);
	descriptors_.push_back(descriptor);
	return EntryMetadata(descriptors_.back(), std::span(first_address, 1));
	}

	// TODO: This method is the trigger of the O(valid_entries * all_entries) time
	// complexity for reading. At some cost to memory, this could be optimized by
	// using a hash table instead of scanning, but in practice this should be fine
	// for a small number of keys
	Status EntryCache::AddNewOrUpdateExisting(const KeyDescriptor& descriptor,
	Address address,
	size_t sector_size_bytes) const {
	// With the new key descriptor, either add it to the descriptor table or
	// overwrite an existing entry with an older version of the key.
	const int index = FindIndex(descriptor.key_hash);

	// Write a new entry if there is room.
	if (index == -1) {
	if (full()) {
	return Status::ResourceExhausted();
	}
	AddNew(descriptor, address);
	return OkStatus();
	}

	// Existing entry is old; replace the existing entry with the new one.
	if (descriptor.transaction_id > descriptors_[index].transaction_id) {
	descriptors_[index] = descriptor;
	ResetAddresses(index, address);
	return OkStatus();
	}

	// If the entries have a duplicate transaction ID, add the new (redundant)
	// entry to the existing descriptor.
	if (descriptors_[index].transaction_id == descriptor.transaction_id) {
	if (descriptors_[index].key_hash != descriptor.key_hash) {
	PW_LOG_ERROR("Duplicate entry for key 0x%08" PRIx32
	" with transaction ID %" PRIu32 " has non-matching hash",
	descriptor.key_hash,
	descriptor.transaction_id);
	return Status::DataLoss();
	}

	// Verify that this entry is not in the same sector as an existing copy of
	// this same key.
	for (Address existing_address : addresses(index)) {
	if (existing_address / sector_size_bytes == address / sector_size_bytes) {
	PW_LOG_DEBUG("Multiple Redundant entries in same sector %u",
	unsigned(address / sector_size_bytes));
	return Status::DataLoss();
	}
	}

	AddAddressIfRoom(index, address);
	} else {
	PW_LOG_DEBUG("Found stale entry when appending; ignoring");
	}
	return OkStatus();
	}

	size_t EntryCache::present_entries() const {
	size_t present_entries = 0;

	for (const KeyDescriptor& descriptor : descriptors_) {
	if (descriptor.state != EntryState::kDeleted) {
	present_entries += 1;
	}
	}

	return present_entries;
	}

	int EntryCache::FindIndex(uint32_t key_hash) const {
	for (size_t i = 0; i < descriptors_.size(); ++i) {
	if (descriptors_[i].key_hash == key_hash) {
	return i;
	}
	}
	return -1;
	}

	void EntryCache::AddAddressIfRoom(size_t descriptor_index,
	Address address) const {
	Address* const existing = first_address(descriptor_index);

	for (size_t i = 0; i < redundancy(); ++i) {
	if (existing[i] == kNoAddress) {
	existing[i] = address;
	return;
	}
	}
	}

	std::span<EntryCache::Address> EntryCache::addresses(
	size_t descriptor_index) const {
	Address* const addresses = first_address(descriptor_index);

	size_t size = 0;
	while (size < redundancy() && addresses[size] != kNoAddress) {
	size += 1;
	}

	return std::span(addresses, size);
	}

	EntryCache::Address* EntryCache::ResetAddresses(size_t descriptor_index,
	Address address) const {
	Address* first = first_address(descriptor_index);
	*first = address;

	// Clear the additional addresses, if any.
	for (size_t i = 1; i < redundancy_; ++i) {
	first[i] = kNoAddress;
	}

	return first;
	}

	} // namespace pw::kvs::internal