#ifndef _AQUERY_H #define _AQUERY_H #ifdef __INTELLISENSE__ #define __AQUERY_ITC_USE_SEMPH__ #define THREADING #endif #ifdef THREADING #include "threading.h" #endif #include #include #include #include class aq_timer { private: std::chrono::high_resolution_clock::time_point now; public: aq_timer(){ now = std::chrono::high_resolution_clock::now(); } void reset(){ now = std::chrono::high_resolution_clock::now(); } long long elapsed(){ long long ret = (std::chrono::high_resolution_clock::now() - now).count(); reset(); return ret; } long long lap() const{ long long ret = (std::chrono::high_resolution_clock::now() - now).count(); return ret; } }; #include "table.h" template T getInt(const char*& buf){ T ret = 0; while(*buf >= '0' and *buf <= '9'){ ret = ret*10 + *buf - '0'; buf++; } return ret; } template char* intToString(T val, char* buf){ while (val > 0){ *--buf = val%10 + '0'; val /= 10; } return buf; } enum Log_level { LOG_INFO, LOG_ERROR, LOG_SILENT }; #ifndef __AQBACKEND_TYPE__ #define __AQBACKEND_TYPE__ 1 enum Backend_Type { BACKEND_AQuery, BACKEND_MonetDB, BACKEND_MariaDB, BACKEND_DuckDB, BACKEND_SQLite, BACKEND_TOTAL }; #endif struct QueryStats{ long long monet_time; long long postproc_time; }; struct Config{ int running, new_query, server_mode, backend_type, has_dll, n_buffers; QueryStats stats; int buffer_sizes[]; }; #ifndef __AQQueryResult__ #define __AQQueryResult__ 1 struct AQQueryResult { void* res; unsigned ref; }; #endif struct Session{ struct Statistic{ size_t total_active; size_t cnt_object; size_t total_alloc; } stats; void* memory_map; }; struct StoredProcedure { uint32_t cnt, postproc_modules; char **queries; const char* name; void **__rt_loaded_modules; }; struct Trigger; struct IntervalBasedTriggerHost; struct CallbackBasedTriggerHost; struct Context { typedef int (*printf_type) (const char *format, ...); void* module_function_maps = nullptr; Config* cfg; int n_buffers, *sz_bufs; void **buffers; void* curr_server; void* alt_server[BACKEND_TOTAL] = {nullptr}; Log_level log_level = LOG_INFO; Session current; const char* aquery_root_path; #ifdef THREADING void* thread_pool; #endif #ifndef __AQ_USE_THREADEDGC__ void* gc; #endif printf_type print = &printf; Context(); virtual ~Context(); template void log(Types... args) { if (log_level == LOG_INFO) print(args...); } template void err(Types... args) { if (log_level <= LOG_ERROR) print(args...); } void init_session(); void end_session(); void* get_module_function(const char*); std::unordered_map tables; std::unordered_map cols; std::unordered_map stored_proc; std::unordered_map triggers; IntervalBasedTriggerHost *it_host; CallbackBasedTriggerHost *ct_host; }; struct StoredProcedurePayload { StoredProcedure *p; Context* cxt; }; struct StoredProcedurePayloadCond { StoredProcedure *condition; StoredProcedure *action; Context* cxt; }; int execTriggerPayload(void*); int execTriggerPayloadCond(void*); #ifdef _WIN32 #define __DLLEXPORT__ __declspec(dllexport) __stdcall #else #define __DLLEXPORT__ #endif #define __AQEXPORT__(_Ty) extern "C" _Ty __DLLEXPORT__ typedef void (*deallocator_t) (void*); #include #include "jeaiii_to_text.h" template inline std::enable_if_t, char *> aq_to_chars(void* value, char* buffer) { return to_text(buffer, *static_cast(value)); } template inline std::enable_if_t, char *> aq_to_chars(void* value, char* buffer) { return buffer; } #ifdef __SIZEOF_INT128__ template<> inline char* aq_to_chars<__int128_t>(void* value, char* buffer) { return jeaiii_i128<__int128_t>(buffer, *static_cast<__int128_t*>(value)); } template<> inline char* aq_to_chars<__uint128_t>(void* value, char* buffer) { return jeaiii_i128<__uint128_t>(buffer, *static_cast<__uint128_t*>(value)); } #endif template<> char* aq_to_chars(void* , char*); template<> char* aq_to_chars(void* , char*); template<> char* aq_to_chars(void* , char*); template<> char* aq_to_chars(void* , char*); template<> char* aq_to_chars(void* , char*); template<> char* aq_to_chars(void* , char*); template<> char* aq_to_chars(void* , char*); typedef int (*code_snippet)(void*); template inline void AQ_ZeroMemory(_This_Struct& __val) { memset(&__val, 0, sizeof(_This_Struct)); } template inline _This_Type* AQ_DupObject(_This_Type* __val) { auto ret = (_This_Type*)(malloc(sizeof(_This_Type))); memcpy(ret, __val, sizeof(_This_Type)); return ret; } #ifdef __USE_STD_SEMAPHORE__ #include class A_Semaphore { private: std::binary_semaphore native_handle; public: A_Semaphore(bool v = false) { native_handle = std::binary_semaphore(v); } void acquire() { native_handle.acquire(); } void release() { native_handle.release(); } ~A_Semaphore() { } }; #else #ifndef _WIN32 #ifdef __APPLE__ #include class A_Semaphore { private: dispatch_semaphore_t native_handle; public: explicit A_Semaphore(bool v = false) { native_handle = dispatch_semaphore_create(v); } void acquire() { // puts("acquire"); dispatch_semaphore_wait(native_handle, DISPATCH_TIME_FOREVER); } void release() { // puts("release"); dispatch_semaphore_signal(native_handle); } ~A_Semaphore() { } }; #else #include class A_Semaphore { private: sem_t native_handle; public: A_Semaphore(bool v = false) { sem_init(&native_handle, v, 1); } void acquire() { sem_wait(&native_handle); } void release() { sem_post(&native_handle); } ~A_Semaphore() { sem_destroy(&native_handle); } }; #endif // __APPLE__ #endif // _WIN32 #endif //__USE_STD_SEMAPHORE__ void print_monetdb_results(void* _srv, const char* sep, const char* end, uint32_t limit); StoredProcedure get_procedure(Context* cxt, const char* name); #endif