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OpenCellular/common/timer.c
Bill Richardson 8c4421759d Cr50: Mark several console commands as safe 
Even when CONFIG_RESTRICTED_CONSOLE_COMMANDS is enabled, there
are many commands that can't do anything dangerous. This marks
some of those commands as safe to use, even when restrictions are
enforced.

I'm only marking commands that are used by the Cr50, since that's
the only board that has restrictions.

BUG=chrome-os-partner:55322
BRANCH=none
TEST=make buildall, test on Cr50 hardware

Change-Id: I6289d332830175b6adcb6b20cb4c21d01d27a25e
Signed-off-by: Bill Richardson <wfrichar@chromium.org>
Reviewed-on: https://chromium-review.googlesource.com/376188
Reviewed-by: Randall Spangler <rspangler@chromium.org>
2016-08-31 17:20:26 +00:00

324 lines
7.2 KiB
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/* Copyright (c) 2012 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
/* Timer module for Chrome EC operating system */
#include "atomic.h"
#include "console.h"
#include "hooks.h"
#include "hwtimer.h"
#include "system.h"
#include "util.h"
#include "task.h"
#include "timer.h"
#define TIMER_SYSJUMP_TAG 0x4d54 /* "TM" */
/* High word of the 64-bit timestamp counter */
static volatile uint32_t clksrc_high;
/* Bitmap of currently running timers */
static uint32_t timer_running;
/* Deadlines of all timers */
static timestamp_t timer_deadline[TASK_ID_COUNT];
static uint32_t next_deadline = 0xffffffff;
/* Hardware timer routine IRQ number */
static int timer_irq;
static void expire_timer(task_id_t tskid)
{
/* we are done with this timer */
atomic_clear(&timer_running, 1 << tskid);
/* wake up the taks waiting for this timer */
task_set_event(tskid, TASK_EVENT_TIMER, 0);
}
int timestamp_expired(timestamp_t deadline, const timestamp_t *now)
{
timestamp_t now_val;
if (!now) {
now_val = get_time();
now = &now_val;
}
return ((int64_t)(now->val - deadline.val) >= 0);
}
void process_timers(int overflow)
{
uint32_t check_timer, running_t0;
timestamp_t next;
timestamp_t now;
if (overflow)
clksrc_high++;
do {
next.val = -1ull;
now = get_time();
do {
/* read atomically the current state of timer running */
check_timer = running_t0 = timer_running;
while (check_timer) {
int tskid = __fls(check_timer);
/* timer has expired ? */
if (timer_deadline[tskid].val <= now.val)
expire_timer(tskid);
else if ((timer_deadline[tskid].le.hi ==
now.le.hi) &&
(timer_deadline[tskid].le.lo <
next.le.lo))
next.val = timer_deadline[tskid].val;
check_timer &= ~(1 << tskid);
}
/* if there is a new timer, let's retry */
} while (timer_running & ~running_t0);
if (next.le.hi == 0xffffffff) {
/* no deadline to set */
__hw_clock_event_clear();
next_deadline = 0xffffffff;
return;
}
__hw_clock_event_set(next.le.lo);
next_deadline = next.le.lo;
} while (next.val <= get_time().val);
}
#ifndef CONFIG_HW_SPECIFIC_UDELAY
void udelay(unsigned us)
{
unsigned t0 = __hw_clock_source_read();
/*
* udelay() may be called with interrupts disabled, so we can't rely on
* process_timers() updating the top 32 bits. So handle wraparound
* ourselves rather than calling get_time() and comparing with a
* deadline.
*
* This may fail for delays close to 2^32 us (~4000 sec), because the
* subtraction below can overflow. That's acceptable, because the
* watchdog timer would have tripped long before that anyway.
*/
while (__hw_clock_source_read() - t0 <= us)
;
}
#endif
int timer_arm(timestamp_t tstamp, task_id_t tskid)
{
ASSERT(tskid < TASK_ID_COUNT);
if (timer_running & (1<<tskid))
return EC_ERROR_BUSY;
timer_deadline[tskid] = tstamp;
atomic_or(&timer_running, 1<<tskid);
/* Modify the next event if needed */
if ((tstamp.le.hi < clksrc_high) ||
((tstamp.le.hi == clksrc_high) && (tstamp.le.lo <= next_deadline)))
task_trigger_irq(timer_irq);
return EC_SUCCESS;
}
void timer_cancel(task_id_t tskid)
{
ASSERT(tskid < TASK_ID_COUNT);
atomic_clear(&timer_running, 1 << tskid);
/*
* Don't need to cancel the interrupt: it would be slow, just do it on
* the next IT
*/
}
/*
* For us < (2^31 - task scheduling latency)(~ 2147 sec), this function will
* sleep for at least us, and no more than 2*us. As us approaches 2^32-1, the
* probability of delay longer than 2*us (and possibly infinite delay)
* increases.
*/
void usleep(unsigned us)
{
uint32_t evt = 0;
uint32_t t0 = __hw_clock_source_read();
/* If task scheduling has not started, just delay */
if (!task_start_called()) {
udelay(us);
return;
}
ASSERT(us);
do {
evt |= task_wait_event(us);
} while (!(evt & TASK_EVENT_TIMER) &&
((__hw_clock_source_read() - t0) < us));
/* Re-queue other events which happened in the meanwhile */
if (evt)
atomic_or(task_get_event_bitmap(task_get_current()),
evt & ~TASK_EVENT_TIMER);
}
timestamp_t get_time(void)
{
timestamp_t ts;
ts.le.hi = clksrc_high;
ts.le.lo = __hw_clock_source_read();
if (ts.le.hi != clksrc_high) {
ts.le.hi = clksrc_high;
ts.le.lo = __hw_clock_source_read();
}
return ts;
}
clock_t clock(void)
{
/* __hw_clock_source_read() returns a microsecond resolution timer.*/
return (clock_t) __hw_clock_source_read() / 1000;
}
void force_time(timestamp_t ts)
{
clksrc_high = ts.le.hi;
__hw_clock_source_set(ts.le.lo);
/* some timers might be already expired : process them */
task_trigger_irq(timer_irq);
}
#ifdef CONFIG_CMD_TIMERINFO
void timer_print_info(void)
{
uint64_t t = get_time().val;
uint64_t deadline = (uint64_t)clksrc_high << 32 |
__hw_clock_event_get();
int tskid;
ccprintf("Time: 0x%016lx us\n"
"Deadline: 0x%016lx -> %11.6ld s from now\n"
"Active timers:\n",
t, deadline, deadline - t);
cflush();
for (tskid = 0; tskid < TASK_ID_COUNT; tskid++) {
if (timer_running & (1<<tskid)) {
ccprintf(" Tsk %2d 0x%016lx -> %11.6ld\n", tskid,
timer_deadline[tskid].val,
timer_deadline[tskid].val - t);
cflush();
}
}
}
#else
void timer_print_info(void) { }
#endif
void timer_init(void)
{
const timestamp_t *ts;
int size, version;
BUILD_ASSERT(TASK_ID_COUNT < sizeof(timer_running) * 8);
/* Restore time from before sysjump */
ts = (const timestamp_t *)system_get_jump_tag(TIMER_SYSJUMP_TAG,
&version, &size);
if (ts && version == 1 && size == sizeof(timestamp_t)) {
clksrc_high = ts->le.hi;
timer_irq = __hw_clock_source_init(ts->le.lo);
} else {
clksrc_high = 0;
timer_irq = __hw_clock_source_init(0);
}
}
/* Preserve time across a sysjump */
static void timer_sysjump(void)
{
timestamp_t ts = get_time();
system_add_jump_tag(TIMER_SYSJUMP_TAG, 1, sizeof(ts), &ts);
}
DECLARE_HOOK(HOOK_SYSJUMP, timer_sysjump, HOOK_PRIO_DEFAULT);
static int command_wait(int argc, char **argv)
{
char *e;
int i;
if (argc < 2)
return EC_ERROR_PARAM_COUNT;
i = strtoi(argv[1], &e, 0);
if (*e)
return EC_ERROR_PARAM1;
udelay(i * 1000);
return EC_SUCCESS;
}
DECLARE_CONSOLE_COMMAND(waitms, command_wait,
"msec",
"Busy-wait for msec");
#ifdef CONFIG_CMD_FORCETIME
static int command_force_time(int argc, char **argv)
{
char *e;
timestamp_t new;
if (argc < 3)
return EC_ERROR_PARAM_COUNT;
new.le.hi = strtoi(argv[1], &e, 0);
if (*e)
return EC_ERROR_PARAM1;
new.le.lo = strtoi(argv[2], &e, 0);
if (*e)
return EC_ERROR_PARAM2;
ccprintf("Time: 0x%016lx = %.6ld s\n", new.val, new.val);
force_time(new);
return EC_SUCCESS;
}
DECLARE_CONSOLE_COMMAND(forcetime, command_force_time,
"hi lo",
"Force current time");
#endif
static int command_get_time(int argc, char **argv)
{
timestamp_t ts = get_time();
ccprintf("Time: 0x%016lx = %.6ld s\n", ts.val, ts.val);
return EC_SUCCESS;
}
DECLARE_SAFE_CONSOLE_COMMAND(gettime, command_get_time,
NULL,
"Print current time");
#ifdef CONFIG_CMD_TIMERINFO
int command_timer_info(int argc, char **argv)
{
timer_print_info();
return EC_SUCCESS;
}
DECLARE_SAFE_CONSOLE_COMMAND(timerinfo, command_timer_info,
NULL,
"Print timer info");
#endif
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