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AQuery/server/libaquery.cpp

644 lines
16 KiB

2 years ago
#include "pch_msc.hpp"
#include "io.h"
#include <limits>
#include <chrono>
#include <ctime>
#include "utils.h"
#include "libaquery.h"
#include <random>
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#include "gc.h"
char* gbuf = nullptr;
void setgbuf(char* buf) {
static char* b = nullptr;
if (buf == nullptr)
gbuf = b;
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else {
gbuf = buf;
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b = buf;
}
}
#ifdef __AQ__HAS__INT128__
template <>
void print<__int128_t>(const __int128_t& v, const char* delimiter){
char s[41];
s[40] = 0;
std::cout<< get_int128str(v, s+40)<< delimiter;
}
template <>
void print<__uint128_t>(const __uint128_t&v, const char* delimiter){
char s[41];
s[40] = 0;
std::cout<< get_uint128str(v, s+40) << delimiter;
}
std::ostream& operator<<(std::ostream& os, __int128 & v)
{
print(v);
return os;
}
std::ostream& operator<<(std::ostream& os, __uint128_t & v)
{
print(v);
return os;
}
#endif
template <>
void print<bool>(const bool&v, const char* delimiter){
std::cout<< (v?"true":"false") << delimiter;
}
template<class T>
T getInt(const char*& buf){
T ret = 0;
while(*buf >= '0' and *buf <= '9'){
ret = ret*10 + *buf - '0';
buf++;
}
return ret;
}
template<class T>
char* intToString(T val, char* buf){
while (val > 0){
*--buf = val%10 + '0';
val /= 10;
}
return buf;
}
void skip(const char*& buf){
while(*buf && (*buf >'9' || *buf < '0')) buf++;
}
namespace types {
date_t::date_t(const char* str) { fromString(str); }
date_t& date_t::fromString(const char* str) {
if(str) {
skip(str);
year = getInt<short>(str);
skip(str);
month = getInt<unsigned char>(str);
skip(str);
day = getInt<unsigned char>(str);
}
else{
day = month = year = 0;
}
return *this;
}
bool date_t::validate() const{
return year <= 9999 && month <= 12 && day <= 31;
}
char* date_t::toString(char* buf) const {
// if (!validate()) return "(invalid date)";
*--buf = 0;
buf = intToString(day, buf);
*--buf = '-';
buf = intToString(month, buf);
*--buf = '-';
buf = intToString(year, buf);
return buf;
}
bool date_t::operator > (const date_t& other) const {
return year > other.year || (year == other.year && (month > other.month || (month == other.month && day > other.day)));
}
bool date_t::operator < (const date_t& other) const {
return year < other.year || (year == other.year && (month < other.month || (month == other.month && day < other.day)));
}
bool date_t::operator >= (const date_t& other) const {
return year >= other.year || (year == other.year && (month >= other.month || (month == other.month && day >= other.day)));
}
bool date_t::operator <= (const date_t& other) const {
return year <= other.year || (year == other.year && (month <= other.month || (month == other.month && day <= other.day)));
}
bool date_t::operator == (const date_t& other) const {
return year == other.year && month == other.month && day == other.day;
}
bool date_t::operator != (const date_t& other) const {
return !operator==(other);
}
time_t::time_t(const char* str) { fromString(str); }
time_t& time_t::fromString(const char* str) {
if(str) {
skip(str);
hours = getInt<unsigned char>(str);
skip(str);
minutes = getInt<unsigned char>(str);
skip(str);
seconds = getInt<unsigned char>(str);
skip(str);
ms = getInt<unsigned int> (str);
}
else {
hours = minutes = seconds = ms = 0;
}
return *this;
}
char* time_t::toString(char* buf) const {
// if (!validate()) return "(invalid date)";
*--buf = 0;
buf = intToString(ms, buf);
*--buf = ':';
buf = intToString(seconds, buf);
*--buf = ':';
buf = intToString(minutes, buf);
*--buf = ':';
buf = intToString(hours, buf);
return buf;
}
bool time_t::operator > (const time_t& other) const {
return hours > other.hours || (hours == other.hours && (minutes > other.minutes || (minutes == other.minutes && (seconds > other.seconds || (seconds == other.seconds && ms > other.ms)))));
}
bool time_t::operator< (const time_t& other) const {
return hours < other.hours || (hours == other.hours && (minutes < other.minutes || (minutes == other.minutes && (seconds < other.seconds || (seconds == other.seconds && ms < other.ms)))));
}
bool time_t::operator>= (const time_t& other) const {
return hours >= other.hours || (hours == other.hours && (minutes >= other.minutes || (minutes == other.minutes && (seconds >= other.seconds || (seconds == other.seconds && ms >= other.ms)))));
}
bool time_t::operator<= (const time_t& other) const{
return hours <= other.hours || (hours == other.hours && (minutes <= other.minutes || (minutes == other.minutes && (seconds <= other.seconds || (seconds == other.seconds && ms <= other.ms)))));
}
bool time_t::operator==(const time_t& other) const {
return hours == other.hours && minutes == other.minutes && seconds == other.seconds && ms == other.ms;
}
bool time_t::operator!= (const time_t& other) const {
return !operator==(other);
}
bool time_t::validate() const{
return hours < 24 && minutes < 60 && seconds < 60 && ms < 1000000;
}
timestamp_t::timestamp_t(const char* str) { fromString(str); }
timestamp_t& timestamp_t::fromString(const char* str) {
date.fromString(str);
time.fromString(str);
return *this;
}
bool timestamp_t::validate() const {
return date.validate() && time.validate();
}
char* timestamp_t::toString(char* buf) const {
buf = time.toString(buf);
auto ret = date.toString(buf);
*(buf-1) = ' ';
return ret;
}
bool timestamp_t::operator > (const timestamp_t& other) const {
return date > other.date || (date == other.date && time > other.time);
}
bool timestamp_t::operator < (const timestamp_t& other) const {
return date < other.date || (date == other.date && time < other.time);
}
bool timestamp_t::operator >= (const timestamp_t& other) const {
return date >= other.date || (date == other.date && time >= other.time);
}
bool timestamp_t::operator <= (const timestamp_t& other) const {
return date <= other.date || (date == other.date && time <= other.time);
}
bool timestamp_t::operator == (const timestamp_t& other) const {
return date == other.date && time == other.time;
}
bool timestamp_t::operator!= (const timestamp_t & other) const {
return !operator==(other);
}
}
template<class T>
void print_datetime(const T&v){
char buf[T::string_length()];
std::cout<<v.toString(buf + T::string_length());
}
std::ostream& operator<<(std::ostream& os, types::date_t & v)
{
print_datetime(v);
return os;
}
std::ostream& operator<<(std::ostream& os, types::time_t & v)
{
print_datetime(v);
return os;
}
std::ostream& operator<<(std::ostream& os, types::timestamp_t & v)
{
print_datetime(v);
return os;
}
std::ostream& operator<<(std::ostream& os, int8_t & v)
{
os<<static_cast<int>(v);
return os;
}
std::ostream& operator<<(std::ostream& os, uint8_t & v)
{
os<<static_cast<unsigned>(v);
return os;
}
std::string base62uuid(int l) {
using namespace std;
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constexpr static const char* base62alp =
"0123456789abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ";
static mt19937_64 engine(
std::chrono::system_clock::now().time_since_epoch().count());
static uniform_int_distribution<uint64_t> u(0x10000, 0xfffff);
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uint64_t uuid = (u(engine) << 32ull) +
(std::chrono::system_clock::now().time_since_epoch().count() & 0xffffffff);
string ret;
while (uuid && l-- >= 0) {
ret = string("") + base62alp[uuid % 62] + ret;
uuid /= 62;
}
return ret;
}
template <>
inline const char* str(const bool& v) {
return v ? "true" : "false";
}
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class A {
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public:
std::chrono::high_resolution_clock::time_point tp;
A(){
tp = std::chrono::high_resolution_clock::now();
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printf("A %llu created.\n", tp.time_since_epoch().count());
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}
~A() {
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printf("A %llu died after %lldns.\n", tp.time_since_epoch().count(),
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(std::chrono::high_resolution_clock::now() - tp).count());
}
};
Context::Context() {
current.memory_map = new std::unordered_map<void*, deallocator_t>;
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#ifndef __AQ_USE_THREADEDGC__
this->gc = new GC();
#endif
GC::gc_handle->reg(new A(), 6553600, [](void* a){
puts("deleting");
delete ((A*)a);
});
init_session();
}
Context::~Context() {
auto memmap = (std::unordered_map<void*, deallocator_t>*) this->current.memory_map;
delete memmap;
}
void Context::init_session(){
if (log_level == LOG_INFO){
memset(&(this->current.stats), 0, sizeof(Session::Statistic));
}
auto memmap = (std::unordered_map<void*, deallocator_t>*) this->current.memory_map;
memmap->clear();
}
void Context::end_session(){
auto memmap = (std::unordered_map<void*, deallocator_t>*) this->current.memory_map;
for (auto& mem : *memmap) {
mem.second(mem.first);
}
memmap->clear();
}
void* Context::get_module_function(const char* fname){
auto fmap = static_cast<std::unordered_map<std::string, void*>*>
(this->module_function_maps);
// printf("%p\n", fmap->find("mydiv")->second);
// for (const auto& [key, value] : *fmap){
// printf("%s %p\n", key.c_str(), value);
// }
auto ret = fmap->find(fname);
return ret == fmap->end() ? nullptr : ret->second;
}
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// template<typename _Ty>
// inline void vector_type<_Ty>::out(uint32_t n, const char* sep) const
// {
// n = n > size ? size : n;
// std::cout << '(';
// {
// uint32_t i = 0;
// for (; i < n - 1; ++i)
// std::cout << this->operator[](i) << sep;
// std::cout << this->operator[](i);
// }
// std::cout << ')';
// }
#include <utility>
#include <thread>
#ifndef __AQ_USE_THREADEDGC__
struct gcmemory_t{
void* memory;
void (*deallocator)(void*);
};
using memoryqueue_t = gcmemory_t*;
void GC::acquire_lock() {
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// auto this_tid = std::this_thread::get_id();
// while(lock != this_tid)
// {
// while(lock != this_tid && lock != std::thread::id()) {
// std::this_thread::sleep_for(std::chrono::milliseconds(0));
// }
// lock = this_tid;
// }
}
void GC::release_lock(){
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// lock = std::thread::id();
}
void GC::gc()
{
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auto _q = static_cast<memoryqueue_t>(q);
auto _q_back = static_cast<memoryqueue_t>(q_back);
if (slot_pos == 0)
return;
auto t = _q;
lock = true;
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while(alive_cnt != 0);
q = _q_back;
uint32_t _slot = slot_pos;
slot_pos = 0;
current_size = 0;
lock = false;
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q_back = t;
for(uint32_t i = 0; i < _slot; ++i){
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if (_q[i].memory != nullptr && _q[i].deallocator != nullptr)
_q[i].deallocator(_q[i].memory);
}
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memset(_q, 0, sizeof(gcmemory_t) * _slot);
running = false;
}
void GC::daemon() {
using namespace std::chrono;
while (alive) {
if (running) {
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if (uint64_t(current_size) > max_size ||
forceclean_timer > forced_clean)
{
gc();
forceclean_timer = 0;
}
std::this_thread::sleep_for(microseconds(interval));
forceclean_timer += interval;
}
else {
std::this_thread::sleep_for(10ms);
forceclean_timer += 10000;
}
}
}
void GC::start_deamon() {
q = new gcmemory_t[max_slots << 1];
q_back = new memoryqueue_t[max_slots << 1];
lock = false;
slot_pos = 0;
current_size = 0;
alive_cnt = 0;
alive = true;
handle = new std::thread(&GC::daemon, this);
}
void GC::terminate_daemon() {
running = false;
alive = false;
decltype(auto) _handle = static_cast<std::thread*>(handle);
delete[] static_cast<memoryqueue_t>(q);
delete[] static_cast<memoryqueue_t>(q_back);
using namespace std::chrono;
std::this_thread::sleep_for(microseconds(1000 + std::max(static_cast<size_t>(10000), interval)));
if (_handle->joinable()) {
_handle->join();
}
delete _handle;
}
void GC::reg(void* v, uint32_t sz, void(*f)(void*)) { //~ 40ns expected v. free ~ 75ns
if (v == nullptr || f == nullptr)
return;
if (sz < threshould){
f(v);
return;
}
else if (sz == 0xffffffff)
sz = this->threshould;
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auto _q = static_cast<memoryqueue_t>(q);
while(lock);
++alive_cnt;
current_size += sz;
auto _slot = (slot_pos += 1);
_q[_slot-1] = {v, f};
--alive_cnt;
running = true;
}
#endif
inline GC* GC::gc_handle = nullptr;
inline ScratchSpace* GC::scratch_space = nullptr;
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void ScratchSpace::init(size_t initial_capacity) {
ret = nullptr;
scratchspace = static_cast<char*>(malloc(initial_capacity));
ptr = cnt = 0;
capacity = initial_capacity;
this->initial_capacity = initial_capacity;
temp_memory_fractions = new vector_type<void*>();
}
inline void* ScratchSpace::alloc(uint32_t sz){
ptr = this->cnt;
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this->cnt += sz; // major cost
if (this->cnt > capacity) {
[[unlikely]]
capacity = this->cnt + (capacity >> 1);
auto vec_tmpmem_fractions = static_cast<vector_type<char *>*>(temp_memory_fractions);
vec_tmpmem_fractions->emplace_back(scratchspace);
scratchspace = static_cast<char*>(malloc(capacity));
ptr = 0;
}
return scratchspace + ptr;
}
inline void ScratchSpace::register_ret(void* ret){
this->ret = ret;
}
inline void ScratchSpace::release(){
ptr = cnt = 0;
auto vec_tmpmem_fractions =
static_cast<vector_type<void*>*>(temp_memory_fractions);
if (vec_tmpmem_fractions->size) {
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[[unlikely]]
for(auto& mem : *vec_tmpmem_fractions){
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//free(mem);
GC::gc_handle->reg(mem);
}
vec_tmpmem_fractions->clear();
}
}
inline void ScratchSpace::reset() {
this->release();
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ret = nullptr;
if (capacity != initial_capacity){
capacity = initial_capacity;
scratchspace = static_cast<char*>(realloc(scratchspace, capacity));
}
}
void ScratchSpace::cleanup(){
auto vec_tmpmem_fractions =
static_cast<vector_type<void*>*>(temp_memory_fractions);
if (vec_tmpmem_fractions->size) {
for(auto& mem : *vec_tmpmem_fractions){
//free(mem);
GC::gc_handle->reg(mem);
}
vec_tmpmem_fractions->clear();
}
delete vec_tmpmem_fractions;
free(this->scratchspace);
}
#include "dragonbox/dragonbox_to_chars.hpp"
template<>
char*
aq_to_chars<float>(void* value, char* buffer) {
return jkj::dragonbox::to_chars_n(*static_cast<float*>(value), buffer);
}
template<>
char*
aq_to_chars<double>(void* value, char* buffer) {
return jkj::dragonbox::to_chars_n(*static_cast<double*>(value), buffer);
}
template<>
inline char*
aq_to_chars<bool>(void* value, char* buffer) {
if (*static_cast<bool*>(value)){
memcpy(buffer, "true", 4);
return buffer + 4;
}
else{
memcpy(buffer, "false", 5);
return buffer + 5;
}
}
template<>
char*
aq_to_chars<char*>(void* value, char* buffer) {
const auto src = *static_cast<char**>(value);
const auto len = strlen(src);
memcpy(buffer, src, len);
return buffer + len;
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}
template<>
char*
aq_to_chars<types::date_t>(void* value, char* buffer) {
const auto& src = *static_cast<types::date_t*>(value);
buffer = to_text(buffer, src.year);
*buffer++ = '-';
buffer = to_text(buffer, src.month);
*buffer++ = '-';
buffer = to_text(buffer, src.day);
return buffer;
}
template<>
char*
aq_to_chars<types::time_t>(void* value, char* buffer) {
const auto& src = *static_cast<types::time_t*>(value);
buffer = to_text(buffer, src.hours);
*buffer++ = ':';
buffer = to_text(buffer, src.minutes);
*buffer++ = ':';
buffer = to_text(buffer, src.seconds);
*buffer++ = ':';
buffer = to_text(buffer, src.ms);
return buffer;
}
template<>
char*
aq_to_chars<types::timestamp_t>(void* value, char* buffer) {
auto& src = *static_cast<types::timestamp_t*>(value);
buffer = aq_to_chars<types::date_t>(static_cast<void*>(&src.date), buffer);
*buffer++ = ' ';
buffer = aq_to_chars<types::time_t>(static_cast<void*>(&src.time), buffer);
return buffer;
}
template<>
char*
aq_to_chars<std::string_view>(void* value, char* buffer){
const auto& src = *static_cast<std::string_view*>(value);
memcpy(buffer, src.data(), src.size());
return buffer + src.size();
}
// Defined in vector_type.h
template <>
vector_type<std::string_view>::vector_type(const char** container, uint32_t len,
typename std::enable_if_t<true>*) noexcept
{
size = capacity = len;
this->container = static_cast<std::string_view*>(
malloc(sizeof(std::string_view) * len));
for(uint32_t i = 0; i < len; ++i){
this->container[i] = container[i];
}
}
template<>
vector_type<std::string_view>::vector_type(const uint32_t size, void* data) :
size(size), capacity(0) {
this->container = static_cast<std::string_view*>(
malloc(sizeof(std::string_view) * size));
for(uint32_t i = 0; i < size; ++i){
this->container[i] = ((const char**)data)[i];
}
//std::cout<<size << container[1];
}