rocksdb/db_stress_tool/db_stress_shared_state.h
Yanqin Jin 670a916d01 Add more verification to db_stress (#6173)
Summary:
Currently, db_stress performs verification by calling `VerifyDb()` at the end of test and optionally before tests start. In case of corruption or incorrect result, it will be too late. This PR adds more verification in two ways.
1. For cf consistency test, each test thread takes a snapshot and verifies every N ops. N is configurable via `-verify_db_one_in`. This option is not supported in other stress tests.
2. For cf consistency test, we use another background thread in which a secondary instance periodically tails the primary (interval is configurable). We verify the secondary. Once an error is detected, we terminate the test and report. This does not affect other stress tests.

Test plan (devserver)
```
$./db_stress -test_cf_consistency -verify_db_one_in=0 -ops_per_thread=100000 -continuous_verification_interval=100
$./db_stress -test_cf_consistency -verify_db_one_in=1000 -ops_per_thread=10000 -continuous_verification_interval=0
$make crash_test
```
Pull Request resolved: https://github.com/facebook/rocksdb/pull/6173

Differential Revision: D19047367

Pulled By: riversand963

fbshipit-source-id: aeed584ad71f9310c111445f34975e5ab47a0615
2019-12-20 08:49:29 -08:00

391 lines
13 KiB
C++

// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
// This source code is licensed under both the GPLv2 (found in the
// COPYING file in the root directory) and Apache 2.0 License
// (found in the LICENSE.Apache file in the root directory).
//
// Copyright (c) 2011 The LevelDB Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file. See the AUTHORS file for names of contributors
#ifdef GFLAGS
#pragma once
#include "db_stress_tool/db_stress_stat.h"
#include "util/gflags_compat.h"
DECLARE_uint64(seed);
DECLARE_int64(max_key);
DECLARE_uint64(log2_keys_per_lock);
DECLARE_int32(threads);
DECLARE_int32(column_families);
DECLARE_int32(nooverwritepercent);
DECLARE_string(expected_values_path);
DECLARE_int32(clear_column_family_one_in);
DECLARE_bool(test_batches_snapshots);
DECLARE_int32(compaction_thread_pool_adjust_interval);
DECLARE_int32(continuous_verification_interval);
namespace rocksdb {
class StressTest;
// State shared by all concurrent executions of the same benchmark.
class SharedState {
public:
// indicates a key may have any value (or not be present) as an operation on
// it is incomplete.
static const uint32_t UNKNOWN_SENTINEL;
// indicates a key should definitely be deleted
static const uint32_t DELETION_SENTINEL;
SharedState(Env* env, StressTest* stress_test)
: cv_(&mu_),
seed_(static_cast<uint32_t>(FLAGS_seed)),
max_key_(FLAGS_max_key),
log2_keys_per_lock_(static_cast<uint32_t>(FLAGS_log2_keys_per_lock)),
num_threads_(FLAGS_threads),
num_initialized_(0),
num_populated_(0),
vote_reopen_(0),
num_done_(0),
start_(false),
start_verify_(false),
num_bg_threads_(0),
should_stop_bg_thread_(false),
bg_thread_finished_(0),
stress_test_(stress_test),
verification_failure_(false),
should_stop_test_(false),
no_overwrite_ids_(FLAGS_column_families),
values_(nullptr),
printing_verification_results_(false) {
// Pick random keys in each column family that will not experience
// overwrite
fprintf(stdout, "Choosing random keys with no overwrite\n");
Random64 rnd(seed_);
// Start with the identity permutation. Subsequent iterations of
// for loop below will start with perm of previous for loop
int64_t* permutation = new int64_t[max_key_];
for (int64_t i = 0; i < max_key_; i++) {
permutation[i] = i;
}
// Now do the Knuth shuffle
int64_t num_no_overwrite_keys = (max_key_ * FLAGS_nooverwritepercent) / 100;
// Only need to figure out first num_no_overwrite_keys of permutation
no_overwrite_ids_.reserve(num_no_overwrite_keys);
for (int64_t i = 0; i < num_no_overwrite_keys; i++) {
int64_t rand_index = i + rnd.Next() % (max_key_ - i);
// Swap i and rand_index;
int64_t temp = permutation[i];
permutation[i] = permutation[rand_index];
permutation[rand_index] = temp;
// Fill no_overwrite_ids_ with the first num_no_overwrite_keys of
// permutation
no_overwrite_ids_.insert(permutation[i]);
}
delete[] permutation;
size_t expected_values_size =
sizeof(std::atomic<uint32_t>) * FLAGS_column_families * max_key_;
bool values_init_needed = false;
Status status;
if (!FLAGS_expected_values_path.empty()) {
if (!std::atomic<uint32_t>{}.is_lock_free()) {
status = Status::InvalidArgument(
"Cannot use --expected_values_path on platforms without lock-free "
"std::atomic<uint32_t>");
}
if (status.ok() && FLAGS_clear_column_family_one_in > 0) {
status = Status::InvalidArgument(
"Cannot use --expected_values_path on when "
"--clear_column_family_one_in is greater than zero.");
}
uint64_t size = 0;
if (status.ok()) {
status = env->GetFileSize(FLAGS_expected_values_path, &size);
}
std::unique_ptr<WritableFile> wfile;
if (status.ok() && size == 0) {
const EnvOptions soptions;
status =
env->NewWritableFile(FLAGS_expected_values_path, &wfile, soptions);
}
if (status.ok() && size == 0) {
std::string buf(expected_values_size, '\0');
status = wfile->Append(buf);
values_init_needed = true;
}
if (status.ok()) {
status = env->NewMemoryMappedFileBuffer(FLAGS_expected_values_path,
&expected_mmap_buffer_);
}
if (status.ok()) {
assert(expected_mmap_buffer_->GetLen() == expected_values_size);
values_ = static_cast<std::atomic<uint32_t>*>(
expected_mmap_buffer_->GetBase());
assert(values_ != nullptr);
} else {
fprintf(stderr, "Failed opening shared file '%s' with error: %s\n",
FLAGS_expected_values_path.c_str(), status.ToString().c_str());
assert(values_ == nullptr);
}
}
if (values_ == nullptr) {
values_allocation_.reset(
new std::atomic<uint32_t>[FLAGS_column_families * max_key_]);
values_ = &values_allocation_[0];
values_init_needed = true;
}
assert(values_ != nullptr);
if (values_init_needed) {
for (int i = 0; i < FLAGS_column_families; ++i) {
for (int j = 0; j < max_key_; ++j) {
Delete(i, j, false /* pending */);
}
}
}
if (FLAGS_test_batches_snapshots) {
fprintf(stdout, "No lock creation because test_batches_snapshots set\n");
return;
}
long num_locks = static_cast<long>(max_key_ >> log2_keys_per_lock_);
if (max_key_ & ((1 << log2_keys_per_lock_) - 1)) {
num_locks++;
}
fprintf(stdout, "Creating %ld locks\n", num_locks * FLAGS_column_families);
key_locks_.resize(FLAGS_column_families);
for (int i = 0; i < FLAGS_column_families; ++i) {
key_locks_[i].resize(num_locks);
for (auto& ptr : key_locks_[i]) {
ptr.reset(new port::Mutex);
}
}
if (FLAGS_compaction_thread_pool_adjust_interval > 0) {
++num_bg_threads_;
fprintf(stdout, "Starting compaction_thread_pool_adjust_thread\n");
}
if (FLAGS_continuous_verification_interval > 0) {
++num_bg_threads_;
fprintf(stdout, "Starting continuous_verification_thread\n");
}
}
~SharedState() {}
port::Mutex* GetMutex() { return &mu_; }
port::CondVar* GetCondVar() { return &cv_; }
StressTest* GetStressTest() const { return stress_test_; }
int64_t GetMaxKey() const { return max_key_; }
uint32_t GetNumThreads() const { return num_threads_; }
void IncInitialized() { num_initialized_++; }
void IncOperated() { num_populated_++; }
void IncDone() { num_done_++; }
void IncVotedReopen() { vote_reopen_ = (vote_reopen_ + 1) % num_threads_; }
bool AllInitialized() const { return num_initialized_ >= num_threads_; }
bool AllOperated() const { return num_populated_ >= num_threads_; }
bool AllDone() const { return num_done_ >= num_threads_; }
bool AllVotedReopen() { return (vote_reopen_ == 0); }
void SetStart() { start_ = true; }
void SetStartVerify() { start_verify_ = true; }
bool Started() const { return start_; }
bool VerifyStarted() const { return start_verify_; }
void SetVerificationFailure() { verification_failure_.store(true); }
bool HasVerificationFailedYet() const { return verification_failure_.load(); }
void SetShouldStopTest() { should_stop_test_.store(true); }
bool ShouldStopTest() const { return should_stop_test_.load(); }
port::Mutex* GetMutexForKey(int cf, int64_t key) {
return key_locks_[cf][key >> log2_keys_per_lock_].get();
}
void LockColumnFamily(int cf) {
for (auto& mutex : key_locks_[cf]) {
mutex->Lock();
}
}
void UnlockColumnFamily(int cf) {
for (auto& mutex : key_locks_[cf]) {
mutex->Unlock();
}
}
std::atomic<uint32_t>& Value(int cf, int64_t key) const {
return values_[cf * max_key_ + key];
}
void ClearColumnFamily(int cf) {
std::fill(&Value(cf, 0 /* key */), &Value(cf + 1, 0 /* key */),
DELETION_SENTINEL);
}
// @param pending True if the update may have started but is not yet
// guaranteed finished. This is useful for crash-recovery testing when the
// process may crash before updating the expected values array.
void Put(int cf, int64_t key, uint32_t value_base, bool pending) {
if (!pending) {
// prevent expected-value update from reordering before Write
std::atomic_thread_fence(std::memory_order_release);
}
Value(cf, key).store(pending ? UNKNOWN_SENTINEL : value_base,
std::memory_order_relaxed);
if (pending) {
// prevent Write from reordering before expected-value update
std::atomic_thread_fence(std::memory_order_release);
}
}
uint32_t Get(int cf, int64_t key) const { return Value(cf, key); }
// @param pending See comment above Put()
// Returns true if the key was not yet deleted.
bool Delete(int cf, int64_t key, bool pending) {
if (Value(cf, key) == DELETION_SENTINEL) {
return false;
}
Put(cf, key, DELETION_SENTINEL, pending);
return true;
}
// @param pending See comment above Put()
// Returns true if the key was not yet deleted.
bool SingleDelete(int cf, int64_t key, bool pending) {
return Delete(cf, key, pending);
}
// @param pending See comment above Put()
// Returns number of keys deleted by the call.
int DeleteRange(int cf, int64_t begin_key, int64_t end_key, bool pending) {
int covered = 0;
for (int64_t key = begin_key; key < end_key; ++key) {
if (Delete(cf, key, pending)) {
++covered;
}
}
return covered;
}
bool AllowsOverwrite(int64_t key) {
return no_overwrite_ids_.find(key) == no_overwrite_ids_.end();
}
bool Exists(int cf, int64_t key) {
// UNKNOWN_SENTINEL counts as exists. That assures a key for which overwrite
// is disallowed can't be accidentally added a second time, in which case
// SingleDelete wouldn't be able to properly delete the key. It does allow
// the case where a SingleDelete might be added which covers nothing, but
// that's not a correctness issue.
uint32_t expected_value = Value(cf, key).load();
return expected_value != DELETION_SENTINEL;
}
uint32_t GetSeed() const { return seed_; }
void SetShouldStopBgThread() { should_stop_bg_thread_ = true; }
bool ShouldStopBgThread() { return should_stop_bg_thread_; }
void IncBgThreadsFinished() { ++bg_thread_finished_; }
bool BgThreadsFinished() const {
return bg_thread_finished_ == num_bg_threads_;
}
bool ShouldVerifyAtBeginning() const {
return expected_mmap_buffer_.get() != nullptr;
}
bool PrintingVerificationResults() {
bool tmp = false;
return !printing_verification_results_.compare_exchange_strong(
tmp, true, std::memory_order_relaxed);
}
void FinishPrintingVerificationResults() {
printing_verification_results_.store(false, std::memory_order_relaxed);
}
private:
port::Mutex mu_;
port::CondVar cv_;
const uint32_t seed_;
const int64_t max_key_;
const uint32_t log2_keys_per_lock_;
const int num_threads_;
long num_initialized_;
long num_populated_;
long vote_reopen_;
long num_done_;
bool start_;
bool start_verify_;
int num_bg_threads_;
bool should_stop_bg_thread_;
int bg_thread_finished_;
StressTest* stress_test_;
std::atomic<bool> verification_failure_;
std::atomic<bool> should_stop_test_;
// Keys that should not be overwritten
std::unordered_set<size_t> no_overwrite_ids_;
std::atomic<uint32_t>* values_;
std::unique_ptr<std::atomic<uint32_t>[]> values_allocation_;
// Has to make it owned by a smart ptr as port::Mutex is not copyable
// and storing it in the container may require copying depending on the impl.
std::vector<std::vector<std::unique_ptr<port::Mutex>>> key_locks_;
std::unique_ptr<MemoryMappedFileBuffer> expected_mmap_buffer_;
std::atomic<bool> printing_verification_results_;
};
// Per-thread state for concurrent executions of the same benchmark.
struct ThreadState {
uint32_t tid; // 0..n-1
Random rand; // Has different seeds for different threads
SharedState* shared;
Stats stats;
struct SnapshotState {
const Snapshot* snapshot;
// The cf from which we did a Get at this snapshot
int cf_at;
// The name of the cf at the time that we did a read
std::string cf_at_name;
// The key with which we did a Get at this snapshot
std::string key;
// The status of the Get
Status status;
// The value of the Get
std::string value;
// optional state of all keys in the db
std::vector<bool>* key_vec;
};
std::queue<std::pair<uint64_t, SnapshotState>> snapshot_queue;
ThreadState(uint32_t index, SharedState* _shared)
: tid(index), rand(1000 + index + _shared->GetSeed()), shared(_shared) {}
};
} // namespace rocksdb
#endif // GFLAGS