FreeCalypso > hg > fc-tourmaline
view src/gpf/osl/os_tim_ir.c @ 268:f2e52cab0a73
abb_inth.c: check all interrupt causes, not just one
The original code used if - else if - else if etc constructs, thus
the first detected interrupt was the only one handled. However,
Iota ITSTATREG is a clear-on-read register, thus if we only handle
the first detected interrupt and skip checking the others, then the
other interrupts will be lost, if more than one interrupt happened
to occur in one ABB interrupt handling cycle - a form of rare race
condition. Change the code to check all interrupts that were read
in this cycle.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Sun, 13 Jun 2021 18:17:53 +0000 |
parents | 4e78acac3d88 |
children |
line wrap: on
line source
/* * This C module is a reconstruction based on the disassembly of * os_tim.obj in frame_na7_db_ir.lib from the Leonardo package, * subsequently reworked by Space Falcon. * * The original decompilation has been contributed by Das Signal. */ /* set of included headers from COFF symtab: */ #include <stdio.h> #include "nucleus.h" #include "typedefs.h" #include "os.h" #include "gdi.h" #include "os_types.h" #include "os_glob.h" extern T_OS_TIMER_ENTRY TimerTable[]; extern T_OS_TIMER_TABLE_ENTRY *p_list[]; extern unsigned os_time_to_tick_multiplier; extern unsigned os_tick_to_time_multiplier; extern unsigned volatile t_start_ticks; extern T_OS_TIMER_TABLE_ENTRY *t_running; extern int used_timers; extern int next_t_handle; extern int volatile t_list_access; extern int max_used_timers; extern NU_SEMAPHORE TimSemCB; extern NU_TIMER os_timer_cb; #ifdef __GNUC__ #define BARRIER asm volatile ("": : :"memory") #else #define BARRIER /* prayer */ #endif void timer_error(int err) { } /* forward declaration */ void os_Timeout(UNSIGNED t_handle); static int os_remove_timer_from_list(T_OS_TIMER_TABLE_ENTRY *timer) { OS_TICK c_ticks; if (timer != t_running) { if (timer->next != t_running) timer->next->r_ticks += timer->r_ticks; } else { c_ticks = NU_Retrieve_Clock(); if (timer->next == timer) { t_running = 0; } else { timer->next->r_ticks = t_start_ticks + timer->r_ticks + timer->next->r_ticks - c_ticks; t_running = timer->next; } NU_Control_Timer(&os_timer_cb, NU_DISABLE_TIMER); if (t_running != NULL) { t_start_ticks = c_ticks; if (t_running->r_ticks != 0) NU_Reset_Timer(&os_timer_cb, os_Timeout, t_running->r_ticks, 0, NU_ENABLE_TIMER); } } if (timer->next != timer) { timer->prev->next = timer->next; timer->next->prev = timer->prev; } timer->next = NULL; timer->prev = NULL; timer->status = TMR_USED; return TMR_USED; } static unsigned os_add_timer_to_list(T_OS_TIMER_TABLE_ENTRY *timer, OS_TICK ticks) { T_OS_TIMER_TABLE_ENTRY *t_list; OS_TICK c_ticks, e_ticks, r1_ticks, return_ticks; if (ticks == 0) ticks = 1; c_ticks = NU_Retrieve_Clock(); t_list = t_running; if (t_list != NULL) { e_ticks = c_ticks - t_start_ticks; if (t_list->r_ticks >= e_ticks) { r1_ticks = t_list->r_ticks - e_ticks; t_list->r_ticks = r1_ticks; } else { r1_ticks = 0; t_list->r_ticks = 0; } t_start_ticks = c_ticks; return_ticks = 0; while (ticks >= r1_ticks) { ticks -= r1_ticks; t_list = t_list->next; if (t_list == t_running) goto out; r1_ticks = t_list->r_ticks; } t_list->r_ticks -= ticks; if (t_list == t_running) { t_running = timer; t_start_ticks = c_ticks; NU_Control_Timer(&os_timer_cb, NU_DISABLE_TIMER); return_ticks = ticks; } out: timer->next = t_list; timer->prev = t_list->prev; t_list->prev->next = timer; t_list->prev = timer; timer->r_ticks = ticks; } else { timer->next = timer; timer->prev = timer; timer->r_ticks = ticks; t_start_ticks = c_ticks; t_running = timer; return_ticks = ticks; } timer->status = TMR_ACTIVE; return return_ticks; } void os_Timeout(UNSIGNED t_handle) /* argument is unused */ { ULONG s_ticks; OS_HANDLE task_handle, e_handle; USHORT t_index; int i, done; T_OS_TIMER_TABLE_ENTRY **t_r4; T_OS_TIMER_TABLE_ENTRY *timer; void (*timeout_func) (OS_HANDLE, OS_HANDLE, USHORT); if (t_list_access) { t_start_ticks++; NU_Reset_Timer(&os_timer_cb, os_Timeout, 1, 0, NU_ENABLE_TIMER); return; } timer = t_running; if (timer) { s_ticks = 0; done = 0; i = 0; do { timeout_func = timer->TimeoutProc; if (timer->p_ticks) p_list[i++] = timer; task_handle = timer->task_handle; e_handle = timer->entity_handle; t_index = timer->t_index; timer->status = TMR_USED; if (timer->next == timer) { t_running = NULL; done = 1; } else { timer->prev->next = timer->next; timer->next->prev = timer->prev; if (timer->next->r_ticks) { t_running = timer->next; s_ticks = timer->next->r_ticks; done = 1; } else timer = timer->next; } timeout_func(task_handle, e_handle, t_index); } while (!done); if (s_ticks) { t_start_ticks = NU_Retrieve_Clock(); NU_Reset_Timer(&os_timer_cb, os_Timeout, s_ticks, 0, NU_ENABLE_TIMER); } } for (t_r4 = p_list; *t_r4; t_r4++) { timer = *t_r4; s_ticks = os_add_timer_to_list(timer, timer->p_ticks); if (s_ticks) NU_Reset_Timer(&os_timer_cb, os_Timeout, s_ticks, 0, NU_ENABLE_TIMER); *t_r4 = NULL; } } GLOBAL LONG os_StartTimer(OS_HANDLE TaskHandle, OS_HANDLE TimerHandle, USHORT Index, OS_TIME InitialTime, OS_TIME RescheduleTime) { T_OS_TIMER_TABLE_ENTRY *timer; OS_TICK ticks; STATUS sts; if (TimerHandle > MaxSimultaneousTimer) return(OS_ERROR); timer = &TimerTable[TimerHandle].entry; sts = NU_Obtain_Semaphore(&TimSemCB, NU_SUSPEND); if (timer->status == TMR_FREE) { if (sts == NU_SUCCESS) NU_Release_Semaphore(&TimSemCB); return(OS_ERROR); } t_list_access = 1; BARRIER; if (timer->status == TMR_ACTIVE) os_remove_timer_from_list(timer); timer->t_handle = TimerHandle; timer->task_handle = os_MyHandle(); timer->entity_handle = TaskHandle; timer->t_index = Index; timer->p_ticks = TIME_TO_SYSTEM_TICKS(RescheduleTime); ticks = os_add_timer_to_list(timer, TIME_TO_SYSTEM_TICKS(InitialTime)); if (ticks) NU_Reset_Timer(&os_timer_cb, os_Timeout, ticks, 0, NU_ENABLE_TIMER); BARRIER; t_list_access = 0; if (sts == NU_SUCCESS) NU_Release_Semaphore(&TimSemCB); return OS_OK; } GLOBAL LONG os_StopTimer(OS_HANDLE TaskHandle, OS_HANDLE TimerHandle) /* TaskHandle argument is unused */ { T_OS_TIMER_ENTRY *timer_e; STATUS sts; if (TimerHandle > MaxSimultaneousTimer) return(OS_ERROR); timer_e = &TimerTable[TimerHandle]; sts = NU_Obtain_Semaphore(&TimSemCB, NU_SUSPEND); if (timer_e->entry.status == TMR_FREE) { if (sts == NU_SUCCESS) NU_Release_Semaphore(&TimSemCB); return OS_ERROR; } t_list_access = 1; BARRIER; if (timer_e->entry.status == TMR_ACTIVE) os_remove_timer_from_list(&timer_e->entry); BARRIER; t_list_access = 0; if (sts == NU_SUCCESS) NU_Release_Semaphore(&TimSemCB); return OS_OK; } GLOBAL LONG os_IncrementTick(OS_TICK ticks) { return OS_OK; } GLOBAL LONG os_DestroyTimer(OS_HANDLE TaskHandle, OS_HANDLE TimerHandle) /* TaskHandle argument is unused */ { STATUS sts; T_OS_TIMER_ENTRY *timer_e; if (TimerHandle > MaxSimultaneousTimer) return(OS_ERROR); sts = NU_Obtain_Semaphore(&TimSemCB, NU_SUSPEND); timer_e = &TimerTable[TimerHandle]; if (timer_e->entry.status != TMR_USED) { if (sts == NU_SUCCESS) NU_Release_Semaphore(&TimSemCB); return OS_ERROR; } timer_e->next_t_handle = next_t_handle; next_t_handle = TimerHandle; timer_e->entry.status = TMR_FREE; used_timers--; if (sts == NU_SUCCESS) NU_Release_Semaphore(&TimSemCB); return OS_OK; } GLOBAL LONG os_CreateTimer(OS_HANDLE TaskHandle, void (*TimeoutProc) (OS_HANDLE, OS_HANDLE, USHORT), OS_HANDLE *TimerHandle, OS_HANDLE MemPoolHandle) /* TaskHandle and MemPoolHandle arguments are unused */ { STATUS sts; T_OS_TIMER_ENTRY *timer_e; sts = NU_Obtain_Semaphore(&TimSemCB, NU_SUSPEND); if (next_t_handle == 0) { /* no free timers left */ if (sts == NU_SUCCESS) NU_Release_Semaphore(&TimSemCB); return OS_ERROR; } timer_e = &TimerTable[next_t_handle]; timer_e->entry.status = TMR_USED; timer_e->entry.TimeoutProc = TimeoutProc; *TimerHandle = next_t_handle; next_t_handle = timer_e->next_t_handle; used_timers++; if (max_used_timers < used_timers) max_used_timers = used_timers; if (sts == NU_SUCCESS) NU_Release_Semaphore(&TimSemCB); return OS_OK; }