[u/mdw/putty] / timing.c

/*
 * timing.c
 * 
 * This module tracks any timers set up by schedule_timer(). It
 * keeps all the currently active timers in a list; it informs the
 * front end of when the next timer is due to go off if that
 * changes; and, very importantly, it tracks the context pointers
 * passed to schedule_timer(), so that if a context is freed all
 * the timers associated with it can be immediately annulled.
 *
 *
 * The problem is that computer clocks aren't perfectly accurate.
 * The GETTICKCOUNT function returns a 32bit number that normally
 * increases by about 1000 every second. On windows this uses the PC's
 * interrupt timer and so is only accurate to around 20ppm.  On unix it's
 * a value that's calculated from the current UTC time and so is in theory
 * accurate in the long term but may jitter and jump in the short term.
 *
 * What PuTTY needs from these timers is simply a way of delaying the
 * calling of a function for a little while, if it's occasionally called a
 * little early or late that's not a problem. So to protect against clock
 * jumps schedule_timer records the time that it was called in the timer
 * structure. With this information the run_timers function can see when
 * the current GETTICKCOUNT value is after the time the event should be
 * fired OR before the time it was set. In the latter case the clock must
 * have jumped, the former is (probably) just the normal passage of time.
 *
 */

#include <assert.h>
#include <stdio.h>

#include "putty.h"
#include "tree234.h"

struct timer {
    timer_fn_t fn;
    void *ctx;
    long now;
    long when_set;
};

static tree234 *timers = NULL;
static tree234 *timer_contexts = NULL;
static long now = 0L;

static int compare_timers(void *av, void *bv)
{
    struct timer *a = (struct timer *)av;
    struct timer *b = (struct timer *)bv;
    long at = a->now - now;
    long bt = b->now - now;

    if (at < bt)
	return -1;
    else if (at > bt)
	return +1;

    /*
     * Failing that, compare on the other two fields, just so that
     * we don't get unwanted equality.
     */
#ifdef __LCC__
    /* lcc won't let us compare function pointers. Legal, but annoying. */
    {
	int c = memcmp(&a->fn, &b->fn, sizeof(a->fn));
	if (c < 0)
	    return -1;
	else if (c > 0)
	    return +1;
    }
#else    
    if (a->fn < b->fn)
	return -1;
    else if (a->fn > b->fn)
	return +1;
#endif

    if (a->ctx < b->ctx)
	return -1;
    else if (a->ctx > b->ctx)
	return +1;

    /*
     * Failing _that_, the two entries genuinely are equal, and we
     * never have a need to store them separately in the tree.
     */
    return 0;
}

static int compare_timer_contexts(void *av, void *bv)
{
    char *a = (char *)av;
    char *b = (char *)bv;
    if (a < b)
	return -1;
    else if (a > b)
	return +1;
    return 0;
}

static void init_timers(void)
{
    if (!timers) {
	timers = newtree234(compare_timers);
	timer_contexts = newtree234(compare_timer_contexts);
	now = GETTICKCOUNT();
    }
}

long schedule_timer(int ticks, timer_fn_t fn, void *ctx)
{
    long when;
    struct timer *t, *first;

    init_timers();

    now = GETTICKCOUNT();
    when = ticks + now;

    /*
     * Just in case our various defences against timing skew fail
     * us: if we try to schedule a timer that's already in the
     * past, we instead schedule it for the immediate future.
     */
    if (when - now <= 0)
	when = now + 1;

    t = snew(struct timer);
    t->fn = fn;
    t->ctx = ctx;
    t->now = when;
    t->when_set = now;

    if (t != add234(timers, t)) {
	sfree(t);		       /* identical timer already exists */
    } else {
	add234(timer_contexts, t->ctx);/* don't care if this fails */
    }

    first = (struct timer *)index234(timers, 0);
    if (first == t) {
	/*
	 * This timer is the very first on the list, so we must
	 * notify the front end.
	 */
	timer_change_notify(first->now);
    }

    return when;
}

/*
 * Call to run any timers whose time has reached the present.
 * Returns the time (in ticks) expected until the next timer after
 * that triggers.
 */
int run_timers(long anow, long *next)
{
    struct timer *first;

    init_timers();

    now = GETTICKCOUNT();

    while (1) {
	first = (struct timer *)index234(timers, 0);

	if (!first)
	    return FALSE;	       /* no timers remaining */

	if (find234(timer_contexts, first->ctx, NULL) == NULL) {
	    /*
	     * This timer belongs to a context that has been
	     * expired. Delete it without running.
	     */
	    delpos234(timers, 0);
	    sfree(first);
	} else if (first->now - now <= 0 ||
	           now - (first->when_set - 10) < 0) {
	    /*
	     * This timer is active and has reached its running
	     * time. Run it.
	     */
	    delpos234(timers, 0);
	    first->fn(first->ctx, first->now);
	    sfree(first);
	} else {
	    /*
	     * This is the first still-active timer that is in the
	     * future. Return how long it has yet to go.
	     */
	    *next = first->now;
	    return TRUE;
	}
    }
}

/*
 * Call to expire all timers associated with a given context.
 */
void expire_timer_context(void *ctx)
{
    init_timers();

    /*
     * We don't bother to check the return value; if the context
     * already wasn't in the tree (presumably because no timers
     * ever actually got scheduled for it) then that's fine and we
     * simply don't need to do anything.
     */
    del234(timer_contexts, ctx);
}
Commit	Line	Data
39934deb	1	/*
	2	* timing.c
	3	*
	4	* This module tracks any timers set up by schedule_timer(). It
	5	* keeps all the currently active timers in a list; it informs the
	6	* front end of when the next timer is due to go off if that
	7	* changes; and, very importantly, it tracks the context pointers
	8	* passed to schedule_timer(), so that if a context is freed all
	9	* the timers associated with it can be immediately annulled.
c2eb6cb7	10	*
	11	*
	12	* The problem is that computer clocks aren't perfectly accurate.
	13	* The GETTICKCOUNT function returns a 32bit number that normally
	14	* increases by about 1000 every second. On windows this uses the PC's
	15	* interrupt timer and so is only accurate to around 20ppm. On unix it's
	16	* a value that's calculated from the current UTC time and so is in theory
	17	* accurate in the long term but may jitter and jump in the short term.
	18	*
	19	* What PuTTY needs from these timers is simply a way of delaying the
	20	* calling of a function for a little while, if it's occasionally called a
	21	* little early or late that's not a problem. So to protect against clock
	22	* jumps schedule_timer records the time that it was called in the timer
	23	* structure. With this information the run_timers function can see when
	24	* the current GETTICKCOUNT value is after the time the event should be
	25	* fired OR before the time it was set. In the latter case the clock must
	26	* have jumped, the former is (probably) just the normal passage of time.
	27	*
39934deb	28	*/
	29
	30	#include <assert.h>
	31	#include <stdio.h>
	32
	33	#include "putty.h"
	34	#include "tree234.h"
	35
	36	struct timer {
	37	timer_fn_t fn;
	38	void *ctx;
	39	long now;
c2eb6cb7	40	long when_set;
39934deb	41	};
	42
	43	static tree234 *timers = NULL;
1605c493	44	static tree234 *timer_contexts = NULL;
39934deb	45	static long now = 0L;
	46
	47	static int compare_timers(void av, void bv)
	48	{
	49	struct timer a = (struct timer )av;
	50	struct timer b = (struct timer )bv;
	51	long at = a->now - now;
	52	long bt = b->now - now;
	53
	54	if (at < bt)
	55	return -1;
	56	else if (at > bt)
	57	return +1;
	58
	59	/*
	60	* Failing that, compare on the other two fields, just so that
	61	* we don't get unwanted equality.
	62	*/
8136216b	63	#ifdef __LCC__
	64	/* lcc won't let us compare function pointers. Legal, but annoying. */
	65	{
	66	int c = memcmp(&a->fn, &b->fn, sizeof(a->fn));
	67	if (c < 0)
	68	return -1;
	69	else if (c > 0)
	70	return +1;
	71	}
	72	#else
39934deb	73	if (a->fn < b->fn)
	74	return -1;
	75	else if (a->fn > b->fn)
	76	return +1;
8136216b	77	#endif
39934deb	78
	79	if (a->ctx < b->ctx)
	80	return -1;
	81	else if (a->ctx > b->ctx)
	82	return +1;
	83
	84	/*
	85	* Failing _that_, the two entries genuinely are equal, and we
	86	* never have a need to store them separately in the tree.
	87	*/
	88	return 0;
	89	}
	90
	91	static int compare_timer_contexts(void av, void bv)
	92	{
1605c493	93	char a = (char )av;
1605c493	94	char b = (char )bv;
39934deb	95	if (a < b)
	96	return -1;
	97	else if (a > b)
	98	return +1;
	99	return 0;
	100	}
	101
	102	static void init_timers(void)
	103	{
	104	if (!timers) {
	105	timers = newtree234(compare_timers);
1605c493	106	timer_contexts = newtree234(compare_timer_contexts);
39934deb	107	now = GETTICKCOUNT();
	108	}
	109	}
	110
	111	long schedule_timer(int ticks, timer_fn_t fn, void *ctx)
	112	{
	113	long when;
	114	struct timer t, first;
	115
	116	init_timers();
	117
c2eb6cb7	118	now = GETTICKCOUNT();
c2eb6cb7	119	when = ticks + now;
2ac3322e	120
	121	/*
	122	* Just in case our various defences against timing skew fail
	123	* us: if we try to schedule a timer that's already in the
	124	* past, we instead schedule it for the immediate future.
	125	*/
	126	if (when - now <= 0)
	127	when = now + 1;
39934deb	128
	129	t = snew(struct timer);
	130	t->fn = fn;
	131	t->ctx = ctx;
	132	t->now = when;
c2eb6cb7	133	t->when_set = now;
39934deb	134
	135	if (t != add234(timers, t)) {
	136	sfree(t); /* identical timer already exists */
1605c493	137	} else {
1605c493	138	add234(timer_contexts, t->ctx);/* don't care if this fails */
39934deb	139	}
	140
	141	first = (struct timer *)index234(timers, 0);
	142	if (first == t) {
	143	/*
	144	* This timer is the very first on the list, so we must
	145	* notify the front end.
	146	*/
	147	timer_change_notify(first->now);
	148	}
	149
	150	return when;
	151	}
	152
	153	/*
	154	* Call to run any timers whose time has reached the present.
	155	* Returns the time (in ticks) expected until the next timer after
	156	* that triggers.
	157	*/
	158	int run_timers(long anow, long *next)
	159	{
	160	struct timer *first;
	161
	162	init_timers();
	163
c2eb6cb7	164	now = GETTICKCOUNT();
39934deb	165
	166	while (1) {
	167	first = (struct timer *)index234(timers, 0);
	168
	169	if (!first)
	170	return FALSE; /* no timers remaining */
	171
1605c493	172	if (find234(timer_contexts, first->ctx, NULL) == NULL) {
	173	/*
	174	* This timer belongs to a context that has been
	175	* expired. Delete it without running.
	176	*/
	177	delpos234(timers, 0);
	178	sfree(first);
c2eb6cb7	179	} else if (first->now - now <= 0 \|\|
c2eb6cb7	180	now - (first->when_set - 10) < 0) {
39934deb	181	/*
	182	* This timer is active and has reached its running
	183	* time. Run it.
	184	*/
	185	delpos234(timers, 0);
	186	first->fn(first->ctx, first->now);
	187	sfree(first);
	188	} else {
	189	/*
	190	* This is the first still-active timer that is in the
	191	* future. Return how long it has yet to go.
	192	*/
	193	*next = first->now;
	194	return TRUE;
	195	}
	196	}
	197	}
	198
	199	/*
	200	* Call to expire all timers associated with a given context.
	201	*/
	202	void expire_timer_context(void *ctx)
	203	{
1605c493	204	init_timers();
5e376138	205
1605c493	206	/*
	207	* We don't bother to check the return value; if the context
	208	* already wasn't in the tree (presumably because no timers
	209	* ever actually got scheduled for it) then that's fine and we
	210	* simply don't need to do anything.
	211	*/
	212	del234(timer_contexts, ctx);
39934deb	213	}