// Copyright (c) Hercules Dev Team, licensed under GNU GPL.
// See the LICENSE file
// Portions Copyright (c) Athena Dev Teams
#define HERCULES_CORE
#include "timer.h"
#include "common/cbasetypes.h"
#include "common/db.h"
#include "common/malloc.h"
#include "common/showmsg.h"
#include "common/utils.h"
#ifdef WIN32
# include "common/winapi.h" // GetTickCount()
#else
# include <sys/time.h> // struct timeval, gettimeofday()
# include <unistd.h>
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
struct timer_interface timer_s;
struct timer_interface *timer;
// If the server can't handle processing thousands of monsters
// or many connected clients, please increase TIMER_MIN_INTERVAL.
#define TIMER_MIN_INTERVAL 50
#define TIMER_MAX_INTERVAL 1000
// timers (array)
static struct TimerData* timer_data = NULL;
static int timer_data_max = 0;
static int timer_data_num = 0;
// free timers (array)
static int* free_timer_list = NULL;
static int free_timer_list_max = 0;
static int free_timer_list_pos = 0;
/// Comparator for the timer heap. (minimum tick at top)
/// Returns negative if tid1's tick is smaller, positive if tid2's tick is smaller, 0 if equal.
///
/// @param tid1 First timer
/// @param tid2 Second timer
/// @return negative if tid1 is top, positive if tid2 is top, 0 if equal
#define DIFFTICK_MINTOPCMP(tid1,tid2) DIFF_TICK(timer_data[tid1].tick,timer_data[tid2].tick)
// timer heap (binary heap of tid's)
static BHEAP_VAR(int, timer_heap);
// server startup time
time_t start_time;
/*----------------------------
* Timer debugging
*----------------------------*/
struct timer_func_list {
struct timer_func_list* next;
TimerFunc func;
char* name;
} *tfl_root = NULL;
/// Sets the name of a timer function.
int timer_add_func_list(TimerFunc func, char* name) {
struct timer_func_list* tfl;
if (name) {
for( tfl=tfl_root; tfl != NULL; tfl=tfl->next )
{// check suspicious cases
if( func == tfl->func )
ShowWarning("timer_add_func_list: duplicating function %p(%s) as %s.\n",tfl->func,tfl->name,name);
else if( strcmp(name,tfl->name) == 0 )
ShowWarning("timer_add_func_list: function %p has the same name as %p(%s)\n",func,tfl->func,tfl->name);
}
CREATE(tfl,struct timer_func_list,1);
tfl->next = tfl_root;
tfl->func = func;
tfl->name = aStrdup(name);
tfl_root = tfl;
}
return 0;
}
/// Returns the name of the timer function.
char* search_timer_func_list(TimerFunc func)
{
struct timer_func_list* tfl;
for( tfl=tfl_root; tfl != NULL; tfl=tfl->next )
if (func == tfl->func)
return tfl->name;
return "unknown timer function";
}
/*----------------------------
* Get tick time
*----------------------------*/
#if defined(ENABLE_RDTSC)
static uint64 RDTSC_BEGINTICK = 0, RDTSC_CLOCK = 0;
static __inline uint64 rdtsc_(void) {
register union {
uint64 qw;
uint32 dw[2];
} t;
asm volatile("rdtsc":"=a"(t.dw[0]), "=d"(t.dw[1]) );
return t.qw;
}
static void rdtsc_calibrate(void){
uint64 t1, t2;
int32 i;
ShowStatus("Calibrating Timer Source, please wait... ");
RDTSC_CLOCK = 0;
for(i = 0; i < 5; i++){
t1 = rdtsc_();
usleep(1000000); //1000 MS
t2 = rdtsc_();
RDTSC_CLOCK += (t2 - t1) / 1000;
}
RDTSC_CLOCK /= 5;
RDTSC_BEGINTICK = rdtsc_();
ShowMessage(" done. (Frequency: %u Mhz)\n", (uint32)(RDTSC_CLOCK/1000) );
}
#endif
/**
* platform-abstracted tick retrieval
* @return server's current tick
*/
static int64 sys_tick(void) {
#if defined(WIN32)
// Windows: GetTickCount/GetTickCount64: Return the number of
// milliseconds that have elapsed since the system was started.
// TODO: GetTickCount/GetTickCount64 has a resolution of only 10~15ms.
// Ai4rei recommends that we replace it with either performance
// counters or multimedia timers if we want it to be more accurate.
// I'm leaving this for a future follow-up patch.
// GetTickCount64 is only available in Windows Vista / Windows Server
// 2008 or newer. Since we still support older versions, this runtime
// check is required in order not to crash.
// http://msdn.microsoft.com/en-us/library/windows/desktop/ms724411%28v=vs.85%29.aspx
static bool first = true;
static ULONGLONG (WINAPI *pGetTickCount64)(void) = NULL;
if( first ) {
HMODULE hlib = GetModuleHandle(TEXT("KERNEL32.DLL"));
if( hlib != NULL )
pGetTickCount64 = (ULONGLONG (WINAPI *)(void))GetProcAddress(hlib, "GetTickCount64");
first = false;
}
if (pGetTickCount64)
return (int64)pGetTickCount64();
// 32-bit fall back. Note: This will wrap around every ~49 days since system startup!!!
return (int64)GetTickCount();
#elif defined(ENABLE_RDTSC)
// RDTSC: Returns the number of CPU cycles since reset. Unreliable if
// the CPU frequency is variable.
return (int64)((rdtsc_() - RDTSC_BEGINTICK) / RDTSC_CLOCK);
#elif defined(HAVE_MONOTONIC_CLOCK)
// Monotonic clock: Implementation-defined.
// Clock that cannot be set and represents monotonic time since some
// unspecified starting point. This clock is not affected by
// discontinuous jumps in the system time (e.g., if the system
// administrator manually changes the clock), but is affected by
// the incremental adjustments performed by adjtime(3) and NTP.
struct timespec tval;
clock_gettime(CLOCK_MONOTONIC, &tval);
// int64 cast to avoid overflows on platforms where time_t is 32 bit
return (int64)tval.tv_sec * 1000 + tval.tv_nsec / 1000000;
#else
// Fall back, regular clock: Number of milliseconds since epoch.
// The time returned by gettimeofday() is affected by discontinuous
// jumps in the system time (e.g., if the system administrator
// manually changes the system time). If you need a monotonically
// increasing clock, see clock_gettime(2).
struct timeval tval;
gettimeofday(&tval, NULL);
// int64 cast to avoid overflows on platforms where time_t is 32 bit
return (int64)tval.tv_sec * 1000 + tval.tv_usec / 1000;
#endif
}
//////////////////////////////////////////////////////////////////////////
#if defined(TICK_CACHE) && TICK_CACHE > 1
//////////////////////////////////////////////////////////////////////////
// tick is cached for TICK_CACHE calls
static int64 gettick_cache;
static int gettick_count = 1;
int64 timer_gettick_nocache(void) {
gettick_count = TICK_CACHE;
gettick_cache = sys_tick();
return gettick_cache;
}
int64 timer_gettick(void) {
return ( --gettick_count == 0 ) ? gettick_nocache() : gettick_cache;
}
//////////////////////////////
#else
//////////////////////////////
// tick doesn't get cached
int64 timer_gettick_nocache(void)
{
return sys_tick();
}
int64 timer_gettick(void) {
return sys_tick();
}
//////////////////////////////////////////////////////////////////////////
#endif
//////////////////////////////////////////////////////////////////////////
/*======================================
* CORE : Timer Heap
*--------------------------------------*/
/// Adds a timer to the timer_heap
static void push_timer_heap(int tid) {
BHEAP_ENSURE(timer_heap, 1, 256);
#ifdef __clang_analyzer__ // Clang's static analyzer warns that BHEAP_ENSURE might set BHEAP_DATA(timer_heap) to NULL.
#include "assert.h"
assert(BHEAP_DATA(timer_heap) != NULL);
#endif // __clang_analyzer__
BHEAP_PUSH(timer_heap, tid, DIFFTICK_MINTOPCMP, swap);
}
/*==========================
* Timer Management
*--------------------------*/
/// Returns a free timer id.
static int acquire_timer(void) {
int tid;
// select a free timer
if (free_timer_list_pos) {
do {
tid = free_timer_list[--free_timer_list_pos];
} while(tid >= timer_data_num && free_timer_list_pos > 0);
} else
tid = timer_data_num;
// check available space
if( tid >= timer_data_num )
// possible timer_data null pointer
for (tid = timer_data_num; tid < timer_data_max && timer_data[tid].type; tid++);
if (tid >= timer_data_num && tid >= timer_data_max)
{// expand timer array
timer_data_max += 256;
if( timer_data )
RECREATE(timer_data, struct TimerData, timer_data_max);
else
CREATE(timer_data, struct TimerData, timer_data_max);
memset(timer_data + (timer_data_max - 256), 0, sizeof(struct TimerData)*256);
}
if( tid >= timer_data_num )
timer_data_num = tid + 1;
return tid;
}
/// Starts a new timer that is deleted once it expires (single-use).
/// Returns the timer's id.
int timer_add(int64 tick, TimerFunc func, int id, intptr_t data) {
int tid;
tid = acquire_timer();
timer_data[tid].tick = tick;
timer_data[tid].func = func;
timer_data[tid].id = id;
timer_data[tid].data = data;
timer_data[tid].type = TIMER_ONCE_AUTODEL;
timer_data[tid].interval = 1000;
push_timer_heap(tid);
return tid;
}
/// Starts a new timer that automatically restarts itself (infinite loop until manually removed).
/// Returns the timer's id, or INVALID_TIMER if it fails.
int timer_add_interval(int64 tick, TimerFunc func, int id, intptr_t data, int interval) {
int tid;
if (interval < 1) {
ShowError("timer_add_interval: invalid interval (tick=%"PRId64" %p[%s] id=%d data=%"PRIdPTR" diff_tick=%"PRId64")\n",
tick, func, search_timer_func_list(func), id, data, DIFF_TICK(tick, timer->gettick()));
return INVALID_TIMER;
}
tid = acquire_timer();
timer_data[tid].tick = tick;
timer_data[tid].func = func;
timer_data[tid].id = id;
timer_data[tid].data = data;
timer_data[tid].type = TIMER_INTERVAL;
timer_data[tid].interval = interval;
push_timer_heap(tid);
return tid;
}
/// Retrieves internal timer data
const struct TimerData* timer_get(int tid) {
return ( tid >= 0 && tid < timer_data_num ) ? &timer_data[tid] : NULL;
}
/// Marks a timer specified by 'id' for immediate deletion once it expires.
/// Param 'func' is used for debug/verification purposes.
/// Returns 0 on success, < 0 on failure.
int timer_do_delete(int tid, TimerFunc func) {
if( tid < 0 || tid >= timer_data_num ) {
ShowError("timer_do_delete error : no such timer %d (%p(%s))\n", tid, func, search_timer_func_list(func));
return -1;
}
if( timer_data[tid].func != func ) {
ShowError("timer_do_delete error : function mismatch %p(%s) != %p(%s)\n", timer_data[tid].func, search_timer_func_list(timer_data[tid].func), func, search_timer_func_list(func));
return -2;
}
timer_data[tid].func = NULL;
timer_data[tid].type = TIMER_ONCE_AUTODEL;
return 0;
}
/// Adjusts a timer's expiration time.
/// Returns the new tick value, or -1 if it fails.
int64 timer_addtick(int tid, int64 tick) {
return timer->settick(tid, timer_data[tid].tick+tick);
}
/**
* Modifies a timer's expiration time (an alternative to deleting a timer and starting a new one).
*
* @param tid The timer ID.
* @param tick New expiration time.
* @return The new tick value.
* @retval -1 in case of failure.
*/
int64 timer_settick(int tid, int64 tick)
{
int i;
// search timer position
ARR_FIND(0, BHEAP_LENGTH(timer_heap), i, BHEAP_DATA(timer_heap)[i] == tid);
if (i == BHEAP_LENGTH(timer_heap)) {
ShowError("timer_settick: no such timer %d (%p(%s))\n", tid, timer_data[tid].func, search_timer_func_list(timer_data[tid].func));
return -1;
}
if( tick == -1 )
tick = 0; // add 1ms to avoid the error value -1
if( timer_data[tid].tick == tick )
return tick; // nothing to do, already in proper position
// pop and push adjusted timer
BHEAP_POPINDEX(timer_heap, i, DIFFTICK_MINTOPCMP, swap);
timer_data[tid].tick = tick;
BHEAP_PUSH(timer_heap, tid, DIFFTICK_MINTOPCMP, swap);
return tick;
}
/**
* Executes all expired timers.
*
* @param tick The current tick.
* @return The value of the smallest non-expired timer (or 1 second if there aren't any).
*/
int do_timer(int64 tick)
{
int64 diff = TIMER_MAX_INTERVAL; // return value
// process all timers one by one
while (BHEAP_LENGTH(timer_heap) > 0) {
int tid = BHEAP_PEEK(timer_heap);// top element in heap (smallest tick)
diff = DIFF_TICK(timer_data[tid].tick, tick);
if( diff > 0 )
break; // no more expired timers to process
// remove timer
BHEAP_POP(timer_heap, DIFFTICK_MINTOPCMP, swap);
timer_data[tid].type |= TIMER_REMOVE_HEAP;
if( timer_data[tid].func ) {
if( diff < -1000 )
// timer was delayed for more than 1 second, use current tick instead
timer_data[tid].func(tid, tick, timer_data[tid].id, timer_data[tid].data);
else
timer_data[tid].func(tid, timer_data[tid].tick, timer_data[tid].id, timer_data[tid].data);
}
// in the case the function didn't change anything...
if( timer_data[tid].type & TIMER_REMOVE_HEAP ) {
timer_data[tid].type &= ~TIMER_REMOVE_HEAP;
switch( timer_data[tid].type ) {
default:
case TIMER_ONCE_AUTODEL:
timer_data[tid].type = 0;
if (free_timer_list_pos >= free_timer_list_max) {
free_timer_list_max += 256;
RECREATE(free_timer_list,int,free_timer_list_max);
memset(free_timer_list + (free_timer_list_max - 256), 0, 256 * sizeof(int));
}
free_timer_list[free_timer_list_pos++] = tid;
break;
case TIMER_INTERVAL:
if( DIFF_TICK(timer_data[tid].tick, tick) < -1000 )
timer_data[tid].tick = tick + timer_data[tid].interval;
else
timer_data[tid].tick += timer_data[tid].interval;
push_timer_heap(tid);
break;
}
}
}
return (int)cap_value(diff, TIMER_MIN_INTERVAL, TIMER_MAX_INTERVAL);
}
unsigned long timer_get_uptime(void) {
return (unsigned long)difftime(time(NULL), start_time);
}
void timer_init(void)
{
#if defined(ENABLE_RDTSC)
rdtsc_calibrate();
#endif
time(&start_time);
}
void timer_final(void) {
struct timer_func_list *tfl;
struct timer_func_list *next;
for( tfl=tfl_root; tfl != NULL; tfl = next ) {
next = tfl->next; // copy next pointer
aFree(tfl->name); // free structures
aFree(tfl);
}
if (timer_data) aFree(timer_data);
BHEAP_CLEAR(timer_heap);
if (free_timer_list) aFree(free_timer_list);
}
/*=====================================
* Default Functions : timer.h
* Generated by HerculesInterfaceMaker
* created by Susu
*-------------------------------------*/
void timer_defaults(void) {
timer = &timer_s;
/* funcs */
timer->gettick = timer_gettick;
timer->gettick_nocache = timer_gettick_nocache;
timer->add = timer_add;
timer->add_interval = timer_add_interval;
timer->add_func_list = timer_add_func_list;
timer->get = timer_get;
timer->delete = timer_do_delete;
timer->addtick = timer_addtick;
timer->settick = timer_settick;
timer->get_uptime = timer_get_uptime;
timer->perform = do_timer;
timer->init = timer_init;
timer->final = timer_final;
}