📄 timeout.c
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//==========================================================================
//
// src/ecos/timeout.c
//
//==========================================================================
//####BSDCOPYRIGHTBEGIN####
//
// -------------------------------------------
//
// Portions of this software may have been derived from OpenBSD,
// FreeBSD or other sources, and are covered by the appropriate
// copyright disclaimers included herein.
//
// Portions created by Red Hat are
// Copyright (C) 2002 Red Hat, Inc. All Rights Reserved.
//
// -------------------------------------------
//
//####BSDCOPYRIGHTEND####
//==========================================================================
//==========================================================================
//
// lib/timeout.c
//
// timeout support
//
//==========================================================================
//####BSDCOPYRIGHTBEGIN####
//
// -------------------------------------------
//
// Portions of this software may have been derived from OpenBSD or other sources,
// and are covered by the appropriate copyright disclaimers included herein.
//
// -------------------------------------------
//
//####BSDCOPYRIGHTEND####
//==========================================================================
//#####DESCRIPTIONBEGIN####
//
// Author(s): gthomas, hmt
// Contributors: gthomas, hmt
// Date: 1999-02-05
// Description: Simple timeout functions
//####DESCRIPTIONEND####
#include <sys/param.h>
#include <pkgconf/net.h>
#include <cyg/kernel/kapi.h>
#include <cyg/infra/cyg_ass.h>
// Timeout support
void alarm_timeout_init(void);
#ifndef NTIMEOUTS
#define NTIMEOUTS 8
#endif
static timeout_entry _timeouts[NTIMEOUTS];
static timeout_entry *timeouts = (timeout_entry *)NULL;
static cyg_handle_t timeout_alarm_handle;
static cyg_alarm timeout_alarm;
static cyg_int32 last_delta;
static cyg_tick_count_t last_set_time;
#define STACK_SIZE CYGNUM_HAL_STACK_SIZE_TYPICAL
static char alarm_stack[STACK_SIZE];
static cyg_thread alarm_thread_data;
static cyg_handle_t alarm_thread_handle;
static cyg_flag_t alarm_flag;
// ------------------------------------------------------------------------
// This routine exists so that this module can synchronize:
extern cyg_uint32 cyg_splinternal(void);
#ifdef TIMEOUT_DEBUG
static void
_show_timeouts(void)
{
timeout_entry *f;
for (f = timeouts; f; f = f->next) {
diag_printf("%p: delta: %d, fun: %p, param: %p\n", f, f->delta, f->fun, f->arg);
}
}
#endif // TIMEOUT_DEBUG
// ------------------------------------------------------------------------
// CALLBACK FUNCTION
// Called from the thread, this runs the alarm callbacks.
// Locking is already in place when this is called.
static void
do_timeout(void)
{
cyg_int32 min_delta;
timeout_entry *e, *e_next;
CYG_ASSERT( 0 < last_delta, "last_delta underflow" );
min_delta = last_delta; // local copy
last_delta = -1; // flag recursive call underway
e = timeouts;
while (e) {
e_next = e->next; // Because this can change during processing
if (e->delta) {
#ifdef TIMEOUT_DEBUG
if ( !(e->delta >= min_delta)) {
diag_printf("Bad delta in timeout: %p, delta: %d, min: %d, last: %ld\n", e, e->delta, min_delta, last_set_time);
_show_timeouts();
}
#endif
// Note: this _can_ happen if timeouts are scheduled before the clock starts!
// CYG_ASSERT( e->delta >= min_delta, "e->delta underflow" );
e->delta -= min_delta;
if (e->delta <= 0) { // Defensive
// Time for this item to 'fire'
timeout_fun *fun = e->fun;
void *arg = e->arg;
// Call it *after* cleansing the record
// diag_printf("%s(%p, %p, %p)\n", __FUNCTION__, e, e->fun, e->arg);
e->flags &= ~CALLOUT_PENDING;
e->delta = 0;
if (e->next) {
e->next->prev = e->prev;
}
if (e->prev) {
e->prev->next = e->next;
} else {
timeouts = e->next;
}
(*fun)(arg);
}
}
e = e_next;
}
// Now scan for a new timeout *after* running all the callbacks
// (because they can add timeouts themselves)
min_delta = 0x7FFFFFFF; // Maxint
for (e = timeouts; e; e = e->next )
if (e->delta)
if (e->delta < min_delta)
min_delta = e->delta;
CYG_ASSERT( 0 < min_delta, "min_delta underflow" );
if (min_delta != 0x7FFFFFFF) {
// Still something to do, schedule it
last_set_time = cyg_current_time();
cyg_alarm_initialize(timeout_alarm_handle, last_set_time+min_delta, 0);
last_delta = min_delta;
} else {
last_delta = 0; // flag no activity
}
#ifdef TIMEOUT_DEBUG
diag_printf("Timeout list after %s\n", __FUNCTION__);
_show_timeouts();
#endif
}
// ------------------------------------------------------------------------
// ALARM EVENT FUNCTION
// This is the DSR for the alarm firing:
static void
do_alarm(cyg_handle_t alarm, cyg_addrword_t data)
{
cyg_flag_setbits( &alarm_flag, 1 );
}
void ecos_synch_eth_drv_dsr(void)
{
cyg_flag_setbits( &alarm_flag, 2 );
}
// ------------------------------------------------------------------------
// HANDLER THREAD ENTRY ROUTINE
// This waits on the DSR to tell it to run:
static void
alarm_thread(cyg_addrword_t param)
{
// This is from the logical ethernet dev; it calls those delivery
// functions who need attention.
extern void eth_drv_run_deliveries( void );
// This is from the logical ethernet dev; it tickles somehow
// all ethernet devices in case one is wedged.
extern void eth_drv_tickle_devices( void );
while ( 1 ) {
int spl;
int x;
#ifdef CYGPKG_NET_FAST_THREAD_TICKLE_DEVS
cyg_tick_count_t later = cyg_current_time();
later += CYGNUM_NET_FAST_THREAD_TICKLE_DEVS_DELAY;
x = cyg_flag_timed_wait(
&alarm_flag,
-1,
CYG_FLAG_WAITMODE_OR | CYG_FLAG_WAITMODE_CLR,
later );
#else
x = cyg_flag_wait(
&alarm_flag,
-1,
CYG_FLAG_WAITMODE_OR | CYG_FLAG_WAITMODE_CLR );
CYG_ASSERT( 3 & x, "Lost my bits" );
#endif // CYGPKG_NET_FAST_THREAD_TICKLE_DEVS
CYG_ASSERT( !((~3) & x), "Extra bits" );
spl = cyg_splinternal();
CYG_ASSERT( 0 == spl, "spl nonzero" );
if ( 2 & x )
eth_drv_run_deliveries();
#ifdef CYGPKG_NET_FAST_THREAD_TICKLE_DEVS
// This is in the else clause for "do we deliver" because the
// network stack might have continuous timing events anyway - so
// the timeout would not occur, x would be 1 every time.
else // Tickle the devices...
eth_drv_tickle_devices();
#endif // CYGPKG_NET_FAST_THREAD_TICKLE_DEVS
if ( 1 & x )
do_timeout();
cyg_splx(spl);
}
}
// ------------------------------------------------------------------------
// INITIALIZATION FUNCTION
void
cyg_alarm_timeout_init( void )
{
// Init the alarm object, attached to the real time clock
cyg_handle_t h;
cyg_clock_to_counter(cyg_real_time_clock(), &h);
cyg_alarm_create(h, do_alarm, 0, &timeout_alarm_handle, &timeout_alarm);
// Init the flag of waking up
cyg_flag_init( &alarm_flag );
// Create alarm background thread to run the callbacks
cyg_thread_create(
CYGPKG_NET_FAST_THREAD_PRIORITY, // Priority
alarm_thread, // entry
0, // entry parameter
"Network alarm support", // Name
&alarm_stack[0], // Stack
STACK_SIZE, // Size
&alarm_thread_handle, // Handle
&alarm_thread_data // Thread data structure
);
cyg_thread_resume(alarm_thread_handle); // Start it
}
// ------------------------------------------------------------------------
// EXPORTED API: SET A TIMEOUT
// This can be called from anywhere, including recursively from the timeout
// functions themselves.
cyg_uint32
timeout(timeout_fun *fun, void *arg, cyg_int32 delta)
{
int i;
timeout_entry *e;
cyg_uint32 stamp;
// this needs to be atomic - recursive calls from the alarm
// handler thread itself are allowed:
int spl = cyg_splinternal();
stamp = 0; // Assume no slots available
for (e = _timeouts, i = 0; i < NTIMEOUTS; i++, e++) {
if ((e->flags & CALLOUT_PENDING) == 0) {
// Free entry
callout_init(e);
e->flags = CALLOUT_LOCAL;
callout_reset(e, delta, fun, arg);
stamp = (cyg_uint32)e;
break;
}
}
cyg_splx(spl);
return stamp;
}
// ------------------------------------------------------------------------
// EXPORTED API: CANCEL A TIMEOUT
// This can be called from anywhere, including recursively from the timeout
// functions themselves.
void
untimeout(timeout_fun *fun, void * arg)
{
int i;
timeout_entry *e;
int spl = cyg_splinternal();
for (e = _timeouts, i = 0; i < NTIMEOUTS; i++, e++) {
if (e->delta && (e->fun == fun) && (e->arg == arg)) {
callout_stop(e);
break;
}
}
cyg_splx(spl);
}
void
callout_init(struct callout *c)
{
bzero(c, sizeof(*c));
}
void
callout_reset(struct callout *c, int delta, timeout_fun *f, void *p)
{
int spl = cyg_splinternal();
CYG_ASSERT( 0 < delta, "delta is right now, or even sooner!" );
// Renormalize delta wrt the existing set alarm, if there is one
if (last_delta > 0) {
#ifdef TIMEOUT_DEBUG
int _delta = delta;
int _time = cyg_current_time();
#endif // TIMEOUT_DEBUG
// There is an active alarm
if (last_set_time != 0) {
// Adjust the delta to be absolute, relative to the alarm
delta += (cyg_int32)(cyg_current_time() - last_set_time);
} else {
// We don't know exactly when the alarm will fire, so just
// schedule this event for the first time, or sometime after
; // Leaving the value alone won't be "too wrong"
}
#ifdef TIMEOUT_DEBUG
diag_printf("delta changed from %d to %d, now: %d, then: %d, last_delta: %d\n",
_delta, delta, _time, (int)last_set_time, last_delta);
_show_timeouts();
#endif
}
// So recorded_delta is set to either:
// alarm is active: delta + NOW - THEN
// alarm is inactive: delta
// Add this callout/timeout to the list of things to do
if (c->flags & CALLOUT_PENDING) {
callout_stop(c);
}
c->prev = (timeout_entry *)NULL;
c->next = timeouts;
if (c->next != (timeout_entry *)NULL) {
c->next->prev = c;
}
timeouts = c;
c->flags |= CALLOUT_PENDING | CALLOUT_ACTIVE;
c->fun = f;
c->arg = p;
c->delta = delta;
#ifdef TIMEOUT_DEBUG
diag_printf("%s(%p, %d, %p, %p)\n", __FUNCTION__, c, delta, f, p);
_show_timeouts();
#endif
if ((0 == last_delta || // alarm was inactive OR
delta < last_delta) ) { // alarm was active but later than we need
// (if last_delta is -1, this call is recursive from the handler so
// also do nothing in that case)
// Here, we know the new item added is sooner than that which was
// most recently set, if any, so we can just go and set it up.
if ( 0 == last_delta )
last_set_time = cyg_current_time();
// So we use, to set the alarm either:
// alarm is active: (delta + NOW - THEN) + THEN
// alarm is inactive: delta + NOW
// and in either case it is true that
// (recorded_delta + last_set_time) == (delta + NOW)
cyg_alarm_initialize(timeout_alarm_handle, last_set_time+delta, 0);
#ifdef TIMEOUT_DEBUG
if ((int)last_set_time == 0) {
diag_printf("delta: %d, time: %ld, last_delta: %d\n", delta, last_set_time, last_delta);
}
#endif
last_delta = delta;
}
// Otherwise, the alarm is active, AND it is set to fire sooner than we
// require, so when it does, that will sort out calling the item we
// just added.
#ifdef CYGPKG_INFRA_DEBUG
// Do some more checking akin to that in the alarm handler:
if ( last_delta != -1 ) { // not a recursive call
cyg_tick_count_t now = cyg_current_time();
timeout_entry *e;
CYG_ASSERT( last_delta >= 0, "Bad last delta" );
delta = 0x7fffffff;
for (e = timeouts; e; e = e->next) {
if (e->delta) {
CYG_ASSERT( e->delta >= last_delta, "e->delta underflow" );
// the following triggers if the "next" timeout has not just
// passed, but passed by 1000 ticks - which with the normal
// 1 tick = 10ms means 10 seconds - a long time.
CYG_ASSERT( last_set_time + e->delta + 1000 > now,
"Recorded alarm not in the future! Starved network thread?" );
if ( e->delta < delta )
delta = e->delta;
} else {
CYG_ASSERT( 0 == e->fun, "Function recorded for 0 delta" );
}
}
if (delta < last_delta) {
diag_printf("Failed to pick smallest delta - picked: %d, last: %d\n", delta, last_delta);
for (e = timeouts; e; e = e->next) {
diag_printf(" timeout: %p at %d\n", e->fun, e->delta);
}
}
CYG_ASSERT( delta >= last_delta, "We didn't pick the smallest delta!" );
}
#endif
cyg_splx(spl);
}
void
callout_stop(struct callout *c)
{
int spl = cyg_splinternal();
#ifdef TIMEOUT_DEBUG
diag_printf("%s(%p) = %x\n", __FUNCTION__, c, c->flags);
#endif
if ((c->flags & CALLOUT_PENDING) == 0) {
c->flags &= ~CALLOUT_ACTIVE;
cyg_splx(spl);
return;
}
c->flags &= ~(CALLOUT_PENDING | CALLOUT_ACTIVE);
if (c->next) {
c->next->prev = c->prev;
}
if (c->prev) {
c->prev->next = c->next;
} else {
timeouts = c->next;
}
cyg_splx(spl);
}
int
callout_active(struct callout *c)
{
return ((c->flags & CALLOUT_ACTIVE) != 0);
}
void
callout_deactivate(struct callout *c)
{
c->flags &= ~CALLOUT_ACTIVE;
}
int
callout_pending(struct callout *c)
{
return ((c->flags & CALLOUT_PENDING) != 0);
}
// ------------------------------------------------------------------------
// EOF timeout.c
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