memgraph/tests/manual/query_planner.cpp
Teon Banek 50c75c56a4 Add EXPLAIN to openCypher
Summary:
  * Move PlanPrinter from test to memgraph
  * Add explainQuery to MemgraphCypher.g4
  * Add Explain operator
  * Update changelog

Reviewers: mtomic, buda, ipaljak

Reviewed By: mtomic

Subscribers: pullbot

Differential Revision: https://phabricator.memgraph.io/D1555
2018-08-23 14:05:32 +02:00

584 lines
20 KiB
C++

#include <chrono>
#include <cstdio>
#include <cstdlib>
#include <experimental/filesystem>
#include <experimental/optional>
#include <fstream>
#include <iostream>
#include <string>
#include "gflags/gflags.h"
#include "glog/logging.h"
#include "database/graph_db.hpp"
#include "database/graph_db_accessor.hpp"
#include "query/context.hpp"
#include "query/frontend/ast/ast.hpp"
#include "query/frontend/ast/cypher_main_visitor.hpp"
#include "query/frontend/opencypher/parser.hpp"
#include "query/frontend/semantic/symbol_generator.hpp"
#include "query/frontend/stripped.hpp"
#include "query/plan/cost_estimator.hpp"
#include "query/plan/distributed.hpp"
#include "query/plan/planner.hpp"
#include "query/plan/pretty_print.hpp"
#include "query/typed_value.hpp"
#include "utils/hashing/fnv.hpp"
#include "utils/string.hpp"
DEFINE_string(save_mock_db_file, "",
"File where the mock database should be saved (on exit)");
DEFINE_string(load_mock_db_file, "",
"File from which the mock database should be loaded");
DECLARE_int32(min_log_level);
#ifdef HAS_READLINE
// TODO: This is copied from src/query/repl.cpp
// It should probably be moved to some utils file.
#include "readline/history.h"
#include "readline/readline.h"
/**
* Helper function that reads a line from the
* standard input using the 'readline' lib.
* Adds support for history and reverse-search.
*
* @param prompt The prompt to display.
* @return A single command the user entered, or nullopt on EOF.
*/
std::experimental::optional<std::string> ReadLine(const std::string &prompt) {
char *line = readline(prompt.c_str());
if (!line) return std::experimental::nullopt;
if (*line) add_history(line);
std::string r_val(line);
free(line);
return r_val;
}
#else
std::experimental::optional<std::string> ReadLine(const std::string &prompt) {
std::cout << prompt;
std::string line;
std::getline(std::cin, line);
if (std::cin.eof()) return std::experimental::nullopt;
return line;
}
#endif // HAS_READLINE
// Repeats the prompt untile the user inputs an integer.
int64_t ReadInt(const std::string &prompt) {
int64_t val = 0;
std::stringstream ss;
do {
auto line = ReadLine(prompt);
if (!line) continue;
ss.str(*line);
ss.clear();
ss >> val;
} while (ss.fail() || !ss.eof());
return val;
}
bool AskYesNo(const std::string &prompt) {
while (auto line = ReadLine(prompt + " (y/n) ")) {
if (*line == "y" || *line == "Y") return true;
if (*line == "n" || *line == "N") return false;
}
return false;
}
class Timer {
public:
void Start() {
duration_ = duration_.zero();
start_time_ = std::chrono::steady_clock::now();
}
void Pause() {
if (pause_ == 0) {
duration_ += std::chrono::steady_clock::now() - start_time_;
}
++pause_;
}
void Resume() {
if (pause_ == 1) {
start_time_ = std::chrono::steady_clock::now();
}
pause_ = std::max(0, pause_ - 1);
}
template <class TFun>
auto WithPause(const TFun &fun) {
Pause();
auto ret = fun();
Resume();
return std::move(ret);
}
std::chrono::duration<double> Elapsed() {
if (pause_ == 0) {
return duration_ + (std::chrono::steady_clock::now() - start_time_);
}
return duration_;
}
private:
std::chrono::duration<double> duration_;
std::chrono::time_point<std::chrono::steady_clock> start_time_;
int pause_ = 0;
};
// Dummy DbAccessor which forwards user input for various vertex counts.
class InteractiveDbAccessor {
public:
InteractiveDbAccessor(database::GraphDbAccessor &dba, int64_t vertices_count,
Timer &timer)
: dba_(dba), vertices_count_(vertices_count), timer_(timer) {}
int64_t VerticesCount() const { return vertices_count_; }
int64_t VerticesCount(storage::Label label_id) const {
auto label = dba_.LabelName(label_id);
if (label_vertex_count_.find(label) == label_vertex_count_.end()) {
label_vertex_count_[label] = ReadVertexCount("label '" + label + "'");
}
return label_vertex_count_.at(label);
}
int64_t VerticesCount(storage::Label label_id,
storage::Property property_id) const {
auto label = dba_.LabelName(label_id);
auto property = dba_.PropertyName(property_id);
auto key = std::make_pair(label, property);
if (label_property_vertex_count_.find(key) ==
label_property_vertex_count_.end()) {
label_property_vertex_count_[key] = ReadVertexCount(
"label '" + label + "' and property '" + property + "'");
}
return label_property_vertex_count_.at(key);
}
int64_t VerticesCount(storage::Label label_id, storage::Property property_id,
const PropertyValue &value) const {
auto label = dba_.LabelName(label_id);
auto property = dba_.PropertyName(property_id);
auto label_prop = std::make_pair(label, property);
if (label_property_index_.find(label_prop) == label_property_index_.end()) {
return 0;
}
auto &value_vertex_count = property_value_vertex_count_[label_prop];
if (value_vertex_count.find(value) == value_vertex_count.end()) {
std::stringstream ss;
ss << value;
int64_t count = ReadVertexCount("label '" + label + "' and property '" +
property + "' value '" + ss.str() + "'");
value_vertex_count[value] = count;
}
return value_vertex_count.at(value);
}
int64_t VerticesCount(
storage::Label label_id, storage::Property property_id,
const std::experimental::optional<utils::Bound<PropertyValue>> lower,
const std::experimental::optional<utils::Bound<PropertyValue>> upper)
const {
auto label = dba_.LabelName(label_id);
auto property = dba_.PropertyName(property_id);
std::stringstream range_string;
if (lower) {
range_string << (lower->IsInclusive() ? "[" : "(") << lower->value()
<< (upper ? "," : ", inf)");
} else {
range_string << "(-inf, ";
}
if (upper) {
range_string << upper->value() << (upper->IsInclusive() ? "]" : ")");
}
return ReadVertexCount("label '" + label + "' and property '" + property +
"' in range " + range_string.str());
}
bool LabelPropertyIndexExists(storage::Label label_id,
storage::Property property_id) const {
auto label = dba_.LabelName(label_id);
auto property = dba_.PropertyName(property_id);
auto key = std::make_pair(label, property);
if (label_property_index_.find(key) == label_property_index_.end()) {
bool resp = timer_.WithPause([&label, &property]() {
return AskYesNo("Index for ':" + label + "(" + property + ")' exists:");
});
label_property_index_[key] = resp;
}
return label_property_index_.at(key);
}
// Save the cached vertex counts to a stream.
void Save(std::ostream &out) {
out << "vertex-count " << vertices_count_ << std::endl;
out << "label-index-count " << label_vertex_count_.size() << std::endl;
for (const auto &label_count : label_vertex_count_) {
out << " " << label_count.first << " " << label_count.second
<< std::endl;
}
auto save_label_prop_map = [&](const auto &name,
const auto &label_prop_map) {
out << name << " " << label_prop_map.size() << std::endl;
for (const auto &label_prop : label_prop_map) {
out << " " << label_prop.first.first << " " << label_prop.first.second
<< " " << label_prop.second << std::endl;
}
};
save_label_prop_map("label-property-index-exists", label_property_index_);
save_label_prop_map("label-property-index-count",
label_property_vertex_count_);
out << "label-property-value-index-count "
<< property_value_vertex_count_.size() << std::endl;
for (const auto &prop_value_count : property_value_vertex_count_) {
out << " " << prop_value_count.first.first << " "
<< prop_value_count.first.second << " "
<< prop_value_count.second.size() << std::endl;
for (const auto &value_count : prop_value_count.second) {
const auto &value = value_count.first;
out << " " << value.type() << " " << value << " "
<< value_count.second << std::endl;
}
}
}
// Load the cached vertex counts from a stream.
// If loading fails, raises utils::BasicException.
void Load(std::istream &in) {
auto load_named_size = [&](const auto &name) {
int size;
in.ignore(std::numeric_limits<std::streamsize>::max(), ' ') >> size;
if (in.fail()) {
throw utils::BasicException("Unable to load {}", name);
}
DLOG(INFO) << "Load " << name << " " << size;
return size;
};
vertices_count_ = load_named_size("vertex-count");
int label_vertex_size = load_named_size("label-index-count");
for (int i = 0; i < label_vertex_size; ++i) {
std::string label;
int64_t count;
in >> label >> count;
if (in.fail()) {
throw utils::BasicException("Unable to load label count");
}
label_vertex_count_[label] = count;
DLOG(INFO) << "Load " << label << " " << count;
}
auto load_label_prop_map = [&](const auto &name, auto &label_prop_map) {
int size = load_named_size(name);
for (int i = 0; i < size; ++i) {
std::string label;
std::string property;
in >> label >> property;
auto &mapped = label_prop_map[std::make_pair(label, property)];
in >> mapped;
if (in.fail()) {
throw utils::BasicException("Unable to load label property");
}
DLOG(INFO) << "Load " << label << " " << property << " " << mapped;
}
};
load_label_prop_map("label-property-index-exists", label_property_index_);
load_label_prop_map("label-property-index-count",
label_property_vertex_count_);
int label_property_value_index_size =
load_named_size("label-property-value-index-count");
for (int i = 0; i < label_property_value_index_size; ++i) {
std::string label;
std::string property;
int64_t value_count;
in >> label >> property >> value_count;
if (in.fail()) {
throw utils::BasicException("Unable to load label property value");
}
DLOG(INFO) << "Load " << label << " " << property << " " << value_count;
for (int v = 0; v < value_count; ++v) {
auto value = LoadTypedValue(in);
int64_t count;
in >> count;
if (in.fail()) {
throw utils::BasicException("Unable to load label property value");
}
DLOG(INFO) << "Load " << value.type() << " " << value << " " << count;
property_value_vertex_count_[std::make_pair(label, property)][value] =
count;
}
}
}
private:
typedef std::pair<std::string, std::string> LabelPropertyKey;
database::GraphDbAccessor &dba_;
int64_t vertices_count_;
Timer &timer_;
mutable std::map<std::string, int64_t> label_vertex_count_;
mutable std::map<std::pair<std::string, std::string>, int64_t>
label_property_vertex_count_;
mutable std::map<std::pair<std::string, std::string>, bool>
label_property_index_;
mutable std::map<
std::pair<std::string, std::string>,
std::unordered_map<query::TypedValue, int64_t, query::TypedValue::Hash,
query::TypedValue::BoolEqual>>
property_value_vertex_count_;
// TODO: Cache faked index counts by range.
int64_t ReadVertexCount(const std::string &message) const {
return timer_.WithPause(
[&message]() { return ReadInt("Vertices with " + message + ": "); });
}
query::TypedValue LoadTypedValue(std::istream &in) {
std::string type;
in >> type;
if (type == "bool") {
return LoadTypedValue<bool>(in);
} else if (type == "int") {
return LoadTypedValue<int64_t>(in);
} else if (type == "double") {
return LoadTypedValue<double>(in);
} else if (type == "string") {
return LoadTypedValue<std::string>(in);
} else {
throw utils::BasicException("Unable to read type '{}'", type);
}
}
template <typename T>
query::TypedValue LoadTypedValue(std::istream &in) {
T val;
in >> val;
return query::TypedValue(val);
}
};
// Shorthand for a vector of pairs (logical_plan, cost).
typedef std::vector<
std::pair<std::unique_ptr<query::plan::LogicalOperator>, double>>
PlansWithCost;
// Encapsulates a consoles command function.
struct Command {
typedef std::vector<std::string> Args;
// Function of this command
std::function<void(database::GraphDbAccessor &, const query::SymbolTable &,
PlansWithCost &, const Args &)>
function;
// Number of arguments the function works with.
int arg_count;
// Explanation of the command.
std::string documentation;
};
#define DEFCOMMAND(Name) \
void Name##Command(database::GraphDbAccessor &dba, \
const query::SymbolTable &symbol_table, \
PlansWithCost &plans, const Command::Args &args)
DEFCOMMAND(Top) {
int64_t n_plans = 0;
std::stringstream ss(args[0]);
ss >> n_plans;
if (ss.fail() || !ss.eof()) return;
n_plans = std::min(static_cast<int64_t>(plans.size()), n_plans);
for (int64_t i = 0; i < n_plans; ++i) {
auto &plan_pair = plans[i];
std::cout << "---- Plan #" << i << " ---- " << std::endl;
std::cout << "cost: " << plan_pair.second << std::endl;
query::plan::PrettyPrint(dba, plan_pair.first.get());
std::cout << std::endl;
}
}
DEFCOMMAND(Show) {
int64_t plan_ix = 0;
std::stringstream ss(args[0]);
ss >> plan_ix;
if (ss.fail() || !ss.eof() || plan_ix >= plans.size()) return;
const auto &plan = plans[plan_ix].first;
auto cost = plans[plan_ix].second;
std::cout << "Plan cost: " << cost << std::endl;
query::plan::PrettyPrint(dba, plan.get());
}
DEFCOMMAND(ShowDistributed) {
int64_t plan_ix = 0;
std::stringstream ss(args[0]);
ss >> plan_ix;
if (ss.fail() || !ss.eof() || plan_ix >= plans.size()) return;
const auto &plan = plans[plan_ix].first;
std::atomic<int64_t> plan_id{0};
auto distributed_plan = MakeDistributedPlan(*plan, symbol_table, plan_id);
{
std::cout << "---- Master Plan ---- " << std::endl;
query::plan::PrettyPrint(dba, distributed_plan.master_plan.get());
std::cout << std::endl;
}
for (size_t i = 0; i < distributed_plan.worker_plans.size(); ++i) {
int64_t id;
std::shared_ptr<query::plan::LogicalOperator> worker_plan;
std::tie(id, worker_plan) = distributed_plan.worker_plans[i];
std::cout << "---- Worker Plan #" << id << " ---- " << std::endl;
query::plan::PrettyPrint(dba, worker_plan.get());
std::cout << std::endl;
}
}
DEFCOMMAND(Help);
std::map<std::string, Command> commands = {
{"top", {TopCommand, 1, "Show top N plans"}},
{"show", {ShowCommand, 1, "Show the Nth plan"}},
{"show-distributed",
{ShowDistributedCommand, 1,
"Show the Nth plan as for distributed execution"}},
{"help", {HelpCommand, 0, "Show available commands"}},
};
DEFCOMMAND(Help) {
std::cout << "Available commands:" << std::endl;
for (const auto &command : commands) {
std::cout << command.first;
for (int i = 1; i <= command.second.arg_count; ++i) {
std::cout << " arg" << i;
}
std::cout << " -- " << command.second.documentation << std::endl;
}
}
#undef DEFCOMMAND
void ExaminePlans(
database::GraphDbAccessor &dba, const query::SymbolTable &symbol_table,
std::vector<std::pair<std::unique_ptr<query::plan::LogicalOperator>,
double>> &plans) {
while (true) {
auto line = ReadLine("plan? ");
if (!line || *line == "quit") break;
auto words = utils::Split(utils::ToLowerCase(*line));
if (words.empty()) continue;
auto command_name = words[0];
std::vector<std::string> args(words.begin() + 1, words.end());
auto command_it = commands.find(command_name);
if (command_it == commands.end()) {
std::cout << "Undefined command: '" << command_name << "'. Try 'help'."
<< std::endl;
continue;
}
const auto &command = command_it->second;
if (args.size() < command.arg_count) {
std::cout << command_name << " expects " << command.arg_count
<< " arguments" << std::endl;
continue;
}
command.function(dba, symbol_table, plans, args);
}
}
query::AstStorage MakeAst(const std::string &query,
database::GraphDbAccessor &dba) {
query::Context ctx(dba);
// query -> AST
auto parser = std::make_unique<query::frontend::opencypher::Parser>(query);
// AST -> high level tree
query::frontend::CypherMainVisitor visitor(ctx);
visitor.visit(parser->tree());
return std::move(visitor.storage());
}
query::SymbolTable MakeSymbolTable(const query::AstStorage &ast) {
query::SymbolTable symbol_table;
query::SymbolGenerator symbol_generator(symbol_table);
ast.query()->Accept(symbol_generator);
return symbol_table;
}
// Returns a list of pairs (plan, estimated cost), sorted in the ascending
// order by cost.
auto MakeLogicalPlans(query::AstStorage &ast, query::SymbolTable &symbol_table,
InteractiveDbAccessor &dba) {
auto query_parts = query::plan::CollectQueryParts(symbol_table, ast);
std::vector<std::pair<std::unique_ptr<query::plan::LogicalOperator>, double>>
plans_with_cost;
auto ctx = query::plan::MakePlanningContext(ast, symbol_table, dba);
if (query_parts.query_parts.size() <= 0) {
std::cerr << "Failed to extract query parts" << std::endl;
std::exit(EXIT_FAILURE);
}
auto plans = query::plan::MakeLogicalPlanForSingleQuery<
query::plan::VariableStartPlanner>(
query_parts.query_parts.at(0).single_query_parts, ctx);
Parameters parameters;
for (auto plan : plans) {
query::plan::CostEstimator<InteractiveDbAccessor> estimator(dba,
parameters);
plan->Accept(estimator);
plans_with_cost.emplace_back(std::move(plan), estimator.cost());
}
std::stable_sort(
plans_with_cost.begin(), plans_with_cost.end(),
[](const auto &a, const auto &b) { return a.second < b.second; });
return plans_with_cost;
}
int main(int argc, char *argv[]) {
gflags::ParseCommandLineFlags(&argc, &argv, true);
FLAGS_min_log_level = google::ERROR;
google::InitGoogleLogging(argv[0]);
auto in_db_filename = utils::Trim(FLAGS_load_mock_db_file);
if (!in_db_filename.empty() &&
!std::experimental::filesystem::exists(in_db_filename)) {
std::cerr << "File '" << in_db_filename << "' does not exist!" << std::endl;
std::exit(EXIT_FAILURE);
}
database::SingleNode db;
auto dba = db.Access();
Timer planning_timer;
InteractiveDbAccessor interactive_db(
*dba, in_db_filename.empty() ? ReadInt("Vertices in DB: ") : 0,
planning_timer);
if (!in_db_filename.empty()) {
std::ifstream db_file(in_db_filename);
interactive_db.Load(db_file);
}
while (true) {
auto line = ReadLine("query? ");
if (!line || *line == "quit") break;
if (line->empty()) continue;
try {
auto ast = MakeAst(*line, *dba);
auto symbol_table = MakeSymbolTable(ast);
planning_timer.Start();
auto plans = MakeLogicalPlans(ast, symbol_table, interactive_db);
auto planning_time = planning_timer.Elapsed();
std::cout
<< "Planning took "
<< std::chrono::duration<double, std::milli>(planning_time).count()
<< "ms" << std::endl;
std::cout << "Generated " << plans.size() << " plans" << std::endl;
ExaminePlans(*dba, symbol_table, plans);
} catch (const utils::BasicException &e) {
std::cout << "Error: " << e.what() << std::endl;
}
}
auto db_filename = utils::Trim(FLAGS_save_mock_db_file);
if (!db_filename.empty()) {
std::ofstream db_file(db_filename);
interactive_db.Save(db_file);
}
return 0;
}