linux-stable/kernel/printk/nbcon.c
John Ogness 1529bbb6e2 printk: nbcon: Assign nice -20 for printing threads
It is important that console printing threads are scheduled
shortly after a printk call and with generous runtime budgets.

Signed-off-by: John Ogness <john.ogness@linutronix.de>
Reviewed-by: Petr Mladek <pmladek@suse.com>
Link: https://lore.kernel.org/r/20240904120536.115780-17-john.ogness@linutronix.de
Signed-off-by: Petr Mladek <pmladek@suse.com>
2024-09-04 15:56:33 +02:00

1817 lines
55 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
// Copyright (C) 2022 Linutronix GmbH, John Ogness
// Copyright (C) 2022 Intel, Thomas Gleixner
#include <linux/atomic.h>
#include <linux/bug.h>
#include <linux/console.h>
#include <linux/delay.h>
#include <linux/errno.h>
#include <linux/export.h>
#include <linux/init.h>
#include <linux/irqflags.h>
#include <linux/kthread.h>
#include <linux/minmax.h>
#include <linux/percpu.h>
#include <linux/preempt.h>
#include <linux/slab.h>
#include <linux/smp.h>
#include <linux/stddef.h>
#include <linux/string.h>
#include <linux/types.h>
#include "internal.h"
#include "printk_ringbuffer.h"
/*
* Printk console printing implementation for consoles which does not depend
* on the legacy style console_lock mechanism.
*
* The state of the console is maintained in the "nbcon_state" atomic
* variable.
*
* The console is locked when:
*
* - The 'prio' field contains the priority of the context that owns the
* console. Only higher priority contexts are allowed to take over the
* lock. A value of 0 (NBCON_PRIO_NONE) means the console is not locked.
*
* - The 'cpu' field denotes on which CPU the console is locked. It is used
* to prevent busy waiting on the same CPU. Also it informs the lock owner
* that it has lost the lock in a more complex scenario when the lock was
* taken over by a higher priority context, released, and taken on another
* CPU with the same priority as the interrupted owner.
*
* The acquire mechanism uses a few more fields:
*
* - The 'req_prio' field is used by the handover approach to make the
* current owner aware that there is a context with a higher priority
* waiting for the friendly handover.
*
* - The 'unsafe' field allows to take over the console in a safe way in the
* middle of emitting a message. The field is set only when accessing some
* shared resources or when the console device is manipulated. It can be
* cleared, for example, after emitting one character when the console
* device is in a consistent state.
*
* - The 'unsafe_takeover' field is set when a hostile takeover took the
* console in an unsafe state. The console will stay in the unsafe state
* until re-initialized.
*
* The acquire mechanism uses three approaches:
*
* 1) Direct acquire when the console is not owned or is owned by a lower
* priority context and is in a safe state.
*
* 2) Friendly handover mechanism uses a request/grant handshake. It is used
* when the current owner has lower priority and the console is in an
* unsafe state.
*
* The requesting context:
*
* a) Sets its priority into the 'req_prio' field.
*
* b) Waits (with a timeout) for the owning context to unlock the
* console.
*
* c) Takes the lock and clears the 'req_prio' field.
*
* The owning context:
*
* a) Observes the 'req_prio' field set on exit from the unsafe
* console state.
*
* b) Gives up console ownership by clearing the 'prio' field.
*
* 3) Unsafe hostile takeover allows to take over the lock even when the
* console is an unsafe state. It is used only in panic() by the final
* attempt to flush consoles in a try and hope mode.
*
* Note that separate record buffers are used in panic(). As a result,
* the messages can be read and formatted without any risk even after
* using the hostile takeover in unsafe state.
*
* The release function simply clears the 'prio' field.
*
* All operations on @console::nbcon_state are atomic cmpxchg based to
* handle concurrency.
*
* The acquire/release functions implement only minimal policies:
*
* - Preference for higher priority contexts.
* - Protection of the panic CPU.
*
* All other policy decisions must be made at the call sites:
*
* - What is marked as an unsafe section.
* - Whether to spin-wait if there is already an owner and the console is
* in an unsafe state.
* - Whether to attempt an unsafe hostile takeover.
*
* The design allows to implement the well known:
*
* acquire()
* output_one_printk_record()
* release()
*
* The output of one printk record might be interrupted with a higher priority
* context. The new owner is supposed to reprint the entire interrupted record
* from scratch.
*/
/**
* nbcon_state_set - Helper function to set the console state
* @con: Console to update
* @new: The new state to write
*
* Only to be used when the console is not yet or no longer visible in the
* system. Otherwise use nbcon_state_try_cmpxchg().
*/
static inline void nbcon_state_set(struct console *con, struct nbcon_state *new)
{
atomic_set(&ACCESS_PRIVATE(con, nbcon_state), new->atom);
}
/**
* nbcon_state_read - Helper function to read the console state
* @con: Console to read
* @state: The state to store the result
*/
static inline void nbcon_state_read(struct console *con, struct nbcon_state *state)
{
state->atom = atomic_read(&ACCESS_PRIVATE(con, nbcon_state));
}
/**
* nbcon_state_try_cmpxchg() - Helper function for atomic_try_cmpxchg() on console state
* @con: Console to update
* @cur: Old/expected state
* @new: New state
*
* Return: True on success. False on fail and @cur is updated.
*/
static inline bool nbcon_state_try_cmpxchg(struct console *con, struct nbcon_state *cur,
struct nbcon_state *new)
{
return atomic_try_cmpxchg(&ACCESS_PRIVATE(con, nbcon_state), &cur->atom, new->atom);
}
/**
* nbcon_seq_read - Read the current console sequence
* @con: Console to read the sequence of
*
* Return: Sequence number of the next record to print on @con.
*/
u64 nbcon_seq_read(struct console *con)
{
unsigned long nbcon_seq = atomic_long_read(&ACCESS_PRIVATE(con, nbcon_seq));
return __ulseq_to_u64seq(prb, nbcon_seq);
}
/**
* nbcon_seq_force - Force console sequence to a specific value
* @con: Console to work on
* @seq: Sequence number value to set
*
* Only to be used during init (before registration) or in extreme situations
* (such as panic with CONSOLE_REPLAY_ALL).
*/
void nbcon_seq_force(struct console *con, u64 seq)
{
/*
* If the specified record no longer exists, the oldest available record
* is chosen. This is especially important on 32bit systems because only
* the lower 32 bits of the sequence number are stored. The upper 32 bits
* are derived from the sequence numbers available in the ringbuffer.
*/
u64 valid_seq = max_t(u64, seq, prb_first_valid_seq(prb));
atomic_long_set(&ACCESS_PRIVATE(con, nbcon_seq), __u64seq_to_ulseq(valid_seq));
}
/**
* nbcon_seq_try_update - Try to update the console sequence number
* @ctxt: Pointer to an acquire context that contains
* all information about the acquire mode
* @new_seq: The new sequence number to set
*
* @ctxt->seq is updated to the new value of @con::nbcon_seq (expanded to
* the 64bit value). This could be a different value than @new_seq if
* nbcon_seq_force() was used or the current context no longer owns the
* console. In the later case, it will stop printing anyway.
*/
static void nbcon_seq_try_update(struct nbcon_context *ctxt, u64 new_seq)
{
unsigned long nbcon_seq = __u64seq_to_ulseq(ctxt->seq);
struct console *con = ctxt->console;
if (atomic_long_try_cmpxchg(&ACCESS_PRIVATE(con, nbcon_seq), &nbcon_seq,
__u64seq_to_ulseq(new_seq))) {
ctxt->seq = new_seq;
} else {
ctxt->seq = nbcon_seq_read(con);
}
}
/**
* nbcon_context_try_acquire_direct - Try to acquire directly
* @ctxt: The context of the caller
* @cur: The current console state
*
* Acquire the console when it is released. Also acquire the console when
* the current owner has a lower priority and the console is in a safe state.
*
* Return: 0 on success. Otherwise, an error code on failure. Also @cur
* is updated to the latest state when failed to modify it.
*
* Errors:
*
* -EPERM: A panic is in progress and this is not the panic CPU.
* Or the current owner or waiter has the same or higher
* priority. No acquire method can be successful in
* this case.
*
* -EBUSY: The current owner has a lower priority but the console
* in an unsafe state. The caller should try using
* the handover acquire method.
*/
static int nbcon_context_try_acquire_direct(struct nbcon_context *ctxt,
struct nbcon_state *cur)
{
unsigned int cpu = smp_processor_id();
struct console *con = ctxt->console;
struct nbcon_state new;
do {
/*
* Panic does not imply that the console is owned. However, it
* is critical that non-panic CPUs during panic are unable to
* acquire ownership in order to satisfy the assumptions of
* nbcon_waiter_matches(). In particular, the assumption that
* lower priorities are ignored during panic.
*/
if (other_cpu_in_panic())
return -EPERM;
if (ctxt->prio <= cur->prio || ctxt->prio <= cur->req_prio)
return -EPERM;
if (cur->unsafe)
return -EBUSY;
/*
* The console should never be safe for a direct acquire
* if an unsafe hostile takeover has ever happened.
*/
WARN_ON_ONCE(cur->unsafe_takeover);
new.atom = cur->atom;
new.prio = ctxt->prio;
new.req_prio = NBCON_PRIO_NONE;
new.unsafe = cur->unsafe_takeover;
new.cpu = cpu;
} while (!nbcon_state_try_cmpxchg(con, cur, &new));
return 0;
}
static bool nbcon_waiter_matches(struct nbcon_state *cur, int expected_prio)
{
/*
* The request context is well defined by the @req_prio because:
*
* - Only a context with a priority higher than the owner can become
* a waiter.
* - Only a context with a priority higher than the waiter can
* directly take over the request.
* - There are only three priorities.
* - Only one CPU is allowed to request PANIC priority.
* - Lower priorities are ignored during panic() until reboot.
*
* As a result, the following scenario is *not* possible:
*
* 1. This context is currently a waiter.
* 2. Another context with a higher priority than this context
* directly takes ownership.
* 3. The higher priority context releases the ownership.
* 4. Another lower priority context takes the ownership.
* 5. Another context with the same priority as this context
* creates a request and starts waiting.
*
* Event #1 implies this context is EMERGENCY.
* Event #2 implies the new context is PANIC.
* Event #3 occurs when panic() has flushed the console.
* Events #4 and #5 are not possible due to the other_cpu_in_panic()
* check in nbcon_context_try_acquire_direct().
*/
return (cur->req_prio == expected_prio);
}
/**
* nbcon_context_try_acquire_requested - Try to acquire after having
* requested a handover
* @ctxt: The context of the caller
* @cur: The current console state
*
* This is a helper function for nbcon_context_try_acquire_handover().
* It is called when the console is in an unsafe state. The current
* owner will release the console on exit from the unsafe region.
*
* Return: 0 on success and @cur is updated to the new console state.
* Otherwise an error code on failure.
*
* Errors:
*
* -EPERM: A panic is in progress and this is not the panic CPU
* or this context is no longer the waiter.
*
* -EBUSY: The console is still locked. The caller should
* continue waiting.
*
* Note: The caller must still remove the request when an error has occurred
* except when this context is no longer the waiter.
*/
static int nbcon_context_try_acquire_requested(struct nbcon_context *ctxt,
struct nbcon_state *cur)
{
unsigned int cpu = smp_processor_id();
struct console *con = ctxt->console;
struct nbcon_state new;
/* Note that the caller must still remove the request! */
if (other_cpu_in_panic())
return -EPERM;
/*
* Note that the waiter will also change if there was an unsafe
* hostile takeover.
*/
if (!nbcon_waiter_matches(cur, ctxt->prio))
return -EPERM;
/* If still locked, caller should continue waiting. */
if (cur->prio != NBCON_PRIO_NONE)
return -EBUSY;
/*
* The previous owner should have never released ownership
* in an unsafe region.
*/
WARN_ON_ONCE(cur->unsafe);
new.atom = cur->atom;
new.prio = ctxt->prio;
new.req_prio = NBCON_PRIO_NONE;
new.unsafe = cur->unsafe_takeover;
new.cpu = cpu;
if (!nbcon_state_try_cmpxchg(con, cur, &new)) {
/*
* The acquire could fail only when it has been taken
* over by a higher priority context.
*/
WARN_ON_ONCE(nbcon_waiter_matches(cur, ctxt->prio));
return -EPERM;
}
/* Handover success. This context now owns the console. */
return 0;
}
/**
* nbcon_context_try_acquire_handover - Try to acquire via handover
* @ctxt: The context of the caller
* @cur: The current console state
*
* The function must be called only when the context has higher priority
* than the current owner and the console is in an unsafe state.
* It is the case when nbcon_context_try_acquire_direct() returns -EBUSY.
*
* The function sets "req_prio" field to make the current owner aware of
* the request. Then it waits until the current owner releases the console,
* or an even higher context takes over the request, or timeout expires.
*
* The current owner checks the "req_prio" field on exit from the unsafe
* region and releases the console. It does not touch the "req_prio" field
* so that the console stays reserved for the waiter.
*
* Return: 0 on success. Otherwise, an error code on failure. Also @cur
* is updated to the latest state when failed to modify it.
*
* Errors:
*
* -EPERM: A panic is in progress and this is not the panic CPU.
* Or a higher priority context has taken over the
* console or the handover request.
*
* -EBUSY: The current owner is on the same CPU so that the hand
* shake could not work. Or the current owner is not
* willing to wait (zero timeout). Or the console does
* not enter the safe state before timeout passed. The
* caller might still use the unsafe hostile takeover
* when allowed.
*
* -EAGAIN: @cur has changed when creating the handover request.
* The caller should retry with direct acquire.
*/
static int nbcon_context_try_acquire_handover(struct nbcon_context *ctxt,
struct nbcon_state *cur)
{
unsigned int cpu = smp_processor_id();
struct console *con = ctxt->console;
struct nbcon_state new;
int timeout;
int request_err = -EBUSY;
/*
* Check that the handover is called when the direct acquire failed
* with -EBUSY.
*/
WARN_ON_ONCE(ctxt->prio <= cur->prio || ctxt->prio <= cur->req_prio);
WARN_ON_ONCE(!cur->unsafe);
/* Handover is not possible on the same CPU. */
if (cur->cpu == cpu)
return -EBUSY;
/*
* Console stays unsafe after an unsafe takeover until re-initialized.
* Waiting is not going to help in this case.
*/
if (cur->unsafe_takeover)
return -EBUSY;
/* Is the caller willing to wait? */
if (ctxt->spinwait_max_us == 0)
return -EBUSY;
/*
* Setup a request for the handover. The caller should try to acquire
* the console directly when the current state has been modified.
*/
new.atom = cur->atom;
new.req_prio = ctxt->prio;
if (!nbcon_state_try_cmpxchg(con, cur, &new))
return -EAGAIN;
cur->atom = new.atom;
/* Wait until there is no owner and then acquire the console. */
for (timeout = ctxt->spinwait_max_us; timeout >= 0; timeout--) {
/* On successful acquire, this request is cleared. */
request_err = nbcon_context_try_acquire_requested(ctxt, cur);
if (!request_err)
return 0;
/*
* If the acquire should be aborted, it must be ensured
* that the request is removed before returning to caller.
*/
if (request_err == -EPERM)
break;
udelay(1);
/* Re-read the state because some time has passed. */
nbcon_state_read(con, cur);
}
/* Timed out or aborted. Carefully remove handover request. */
do {
/*
* No need to remove request if there is a new waiter. This
* can only happen if a higher priority context has taken over
* the console or the handover request.
*/
if (!nbcon_waiter_matches(cur, ctxt->prio))
return -EPERM;
/* Unset request for handover. */
new.atom = cur->atom;
new.req_prio = NBCON_PRIO_NONE;
if (nbcon_state_try_cmpxchg(con, cur, &new)) {
/*
* Request successfully unset. Report failure of
* acquiring via handover.
*/
cur->atom = new.atom;
return request_err;
}
/*
* Unable to remove request. Try to acquire in case
* the owner has released the lock.
*/
} while (nbcon_context_try_acquire_requested(ctxt, cur));
/* Lucky timing. The acquire succeeded while removing the request. */
return 0;
}
/**
* nbcon_context_try_acquire_hostile - Acquire via unsafe hostile takeover
* @ctxt: The context of the caller
* @cur: The current console state
*
* Acquire the console even in the unsafe state.
*
* It can be permitted by setting the 'allow_unsafe_takeover' field only
* by the final attempt to flush messages in panic().
*
* Return: 0 on success. -EPERM when not allowed by the context.
*/
static int nbcon_context_try_acquire_hostile(struct nbcon_context *ctxt,
struct nbcon_state *cur)
{
unsigned int cpu = smp_processor_id();
struct console *con = ctxt->console;
struct nbcon_state new;
if (!ctxt->allow_unsafe_takeover)
return -EPERM;
/* Ensure caller is allowed to perform unsafe hostile takeovers. */
if (WARN_ON_ONCE(ctxt->prio != NBCON_PRIO_PANIC))
return -EPERM;
/*
* Check that try_acquire_direct() and try_acquire_handover() returned
* -EBUSY in the right situation.
*/
WARN_ON_ONCE(ctxt->prio <= cur->prio || ctxt->prio <= cur->req_prio);
WARN_ON_ONCE(cur->unsafe != true);
do {
new.atom = cur->atom;
new.cpu = cpu;
new.prio = ctxt->prio;
new.unsafe |= cur->unsafe_takeover;
new.unsafe_takeover |= cur->unsafe;
} while (!nbcon_state_try_cmpxchg(con, cur, &new));
return 0;
}
static struct printk_buffers panic_nbcon_pbufs;
/**
* nbcon_context_try_acquire - Try to acquire nbcon console
* @ctxt: The context of the caller
*
* Context: Under @ctxt->con->device_lock() or local_irq_save().
* Return: True if the console was acquired. False otherwise.
*
* If the caller allowed an unsafe hostile takeover, on success the
* caller should check the current console state to see if it is
* in an unsafe state. Otherwise, on success the caller may assume
* the console is not in an unsafe state.
*/
static bool nbcon_context_try_acquire(struct nbcon_context *ctxt)
{
unsigned int cpu = smp_processor_id();
struct console *con = ctxt->console;
struct nbcon_state cur;
int err;
nbcon_state_read(con, &cur);
try_again:
err = nbcon_context_try_acquire_direct(ctxt, &cur);
if (err != -EBUSY)
goto out;
err = nbcon_context_try_acquire_handover(ctxt, &cur);
if (err == -EAGAIN)
goto try_again;
if (err != -EBUSY)
goto out;
err = nbcon_context_try_acquire_hostile(ctxt, &cur);
out:
if (err)
return false;
/* Acquire succeeded. */
/* Assign the appropriate buffer for this context. */
if (atomic_read(&panic_cpu) == cpu)
ctxt->pbufs = &panic_nbcon_pbufs;
else
ctxt->pbufs = con->pbufs;
/* Set the record sequence for this context to print. */
ctxt->seq = nbcon_seq_read(ctxt->console);
return true;
}
static bool nbcon_owner_matches(struct nbcon_state *cur, int expected_cpu,
int expected_prio)
{
/*
* A similar function, nbcon_waiter_matches(), only deals with
* EMERGENCY and PANIC priorities. However, this function must also
* deal with the NORMAL priority, which requires additional checks
* and constraints.
*
* For the case where preemption and interrupts are disabled, it is
* enough to also verify that the owning CPU has not changed.
*
* For the case where preemption or interrupts are enabled, an
* external synchronization method *must* be used. In particular,
* the driver-specific locking mechanism used in device_lock()
* (including disabling migration) should be used. It prevents
* scenarios such as:
*
* 1. [Task A] owns a context with NBCON_PRIO_NORMAL on [CPU X] and
* is scheduled out.
* 2. Another context takes over the lock with NBCON_PRIO_EMERGENCY
* and releases it.
* 3. [Task B] acquires a context with NBCON_PRIO_NORMAL on [CPU X]
* and is scheduled out.
* 4. [Task A] gets running on [CPU X] and sees that the console is
* still owned by a task on [CPU X] with NBON_PRIO_NORMAL. Thus
* [Task A] thinks it is the owner when it is not.
*/
if (cur->prio != expected_prio)
return false;
if (cur->cpu != expected_cpu)
return false;
return true;
}
/**
* nbcon_context_release - Release the console
* @ctxt: The nbcon context from nbcon_context_try_acquire()
*/
static void nbcon_context_release(struct nbcon_context *ctxt)
{
unsigned int cpu = smp_processor_id();
struct console *con = ctxt->console;
struct nbcon_state cur;
struct nbcon_state new;
nbcon_state_read(con, &cur);
do {
if (!nbcon_owner_matches(&cur, cpu, ctxt->prio))
break;
new.atom = cur.atom;
new.prio = NBCON_PRIO_NONE;
/*
* If @unsafe_takeover is set, it is kept set so that
* the state remains permanently unsafe.
*/
new.unsafe |= cur.unsafe_takeover;
} while (!nbcon_state_try_cmpxchg(con, &cur, &new));
ctxt->pbufs = NULL;
}
/**
* nbcon_context_can_proceed - Check whether ownership can proceed
* @ctxt: The nbcon context from nbcon_context_try_acquire()
* @cur: The current console state
*
* Return: True if this context still owns the console. False if
* ownership was handed over or taken.
*
* Must be invoked when entering the unsafe state to make sure that it still
* owns the lock. Also must be invoked when exiting the unsafe context
* to eventually free the lock for a higher priority context which asked
* for the friendly handover.
*
* It can be called inside an unsafe section when the console is just
* temporary in safe state instead of exiting and entering the unsafe
* state.
*
* Also it can be called in the safe context before doing an expensive
* safe operation. It does not make sense to do the operation when
* a higher priority context took the lock.
*
* When this function returns false then the calling context no longer owns
* the console and is no longer allowed to go forward. In this case it must
* back out immediately and carefully. The buffer content is also no longer
* trusted since it no longer belongs to the calling context.
*/
static bool nbcon_context_can_proceed(struct nbcon_context *ctxt, struct nbcon_state *cur)
{
unsigned int cpu = smp_processor_id();
/* Make sure this context still owns the console. */
if (!nbcon_owner_matches(cur, cpu, ctxt->prio))
return false;
/* The console owner can proceed if there is no waiter. */
if (cur->req_prio == NBCON_PRIO_NONE)
return true;
/*
* A console owner within an unsafe region is always allowed to
* proceed, even if there are waiters. It can perform a handover
* when exiting the unsafe region. Otherwise the waiter will
* need to perform an unsafe hostile takeover.
*/
if (cur->unsafe)
return true;
/* Waiters always have higher priorities than owners. */
WARN_ON_ONCE(cur->req_prio <= cur->prio);
/*
* Having a safe point for take over and eventually a few
* duplicated characters or a full line is way better than a
* hostile takeover. Post processing can take care of the garbage.
* Release and hand over.
*/
nbcon_context_release(ctxt);
/*
* It is not clear whether the waiter really took over ownership. The
* outermost callsite must make the final decision whether console
* ownership is needed for it to proceed. If yes, it must reacquire
* ownership (possibly hostile) before carefully proceeding.
*
* The calling context no longer owns the console so go back all the
* way instead of trying to implement reacquire heuristics in tons of
* places.
*/
return false;
}
/**
* nbcon_can_proceed - Check whether ownership can proceed
* @wctxt: The write context that was handed to the write function
*
* Return: True if this context still owns the console. False if
* ownership was handed over or taken.
*
* It is used in nbcon_enter_unsafe() to make sure that it still owns the
* lock. Also it is used in nbcon_exit_unsafe() to eventually free the lock
* for a higher priority context which asked for the friendly handover.
*
* It can be called inside an unsafe section when the console is just
* temporary in safe state instead of exiting and entering the unsafe state.
*
* Also it can be called in the safe context before doing an expensive safe
* operation. It does not make sense to do the operation when a higher
* priority context took the lock.
*
* When this function returns false then the calling context no longer owns
* the console and is no longer allowed to go forward. In this case it must
* back out immediately and carefully. The buffer content is also no longer
* trusted since it no longer belongs to the calling context.
*/
bool nbcon_can_proceed(struct nbcon_write_context *wctxt)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(wctxt, ctxt);
struct console *con = ctxt->console;
struct nbcon_state cur;
nbcon_state_read(con, &cur);
return nbcon_context_can_proceed(ctxt, &cur);
}
EXPORT_SYMBOL_GPL(nbcon_can_proceed);
#define nbcon_context_enter_unsafe(c) __nbcon_context_update_unsafe(c, true)
#define nbcon_context_exit_unsafe(c) __nbcon_context_update_unsafe(c, false)
/**
* __nbcon_context_update_unsafe - Update the unsafe bit in @con->nbcon_state
* @ctxt: The nbcon context from nbcon_context_try_acquire()
* @unsafe: The new value for the unsafe bit
*
* Return: True if the unsafe state was updated and this context still
* owns the console. Otherwise false if ownership was handed
* over or taken.
*
* This function allows console owners to modify the unsafe status of the
* console.
*
* When this function returns false then the calling context no longer owns
* the console and is no longer allowed to go forward. In this case it must
* back out immediately and carefully. The buffer content is also no longer
* trusted since it no longer belongs to the calling context.
*
* Internal helper to avoid duplicated code.
*/
static bool __nbcon_context_update_unsafe(struct nbcon_context *ctxt, bool unsafe)
{
struct console *con = ctxt->console;
struct nbcon_state cur;
struct nbcon_state new;
nbcon_state_read(con, &cur);
do {
/*
* The unsafe bit must not be cleared if an
* unsafe hostile takeover has occurred.
*/
if (!unsafe && cur.unsafe_takeover)
goto out;
if (!nbcon_context_can_proceed(ctxt, &cur))
return false;
new.atom = cur.atom;
new.unsafe = unsafe;
} while (!nbcon_state_try_cmpxchg(con, &cur, &new));
cur.atom = new.atom;
out:
return nbcon_context_can_proceed(ctxt, &cur);
}
static void nbcon_write_context_set_buf(struct nbcon_write_context *wctxt,
char *buf, unsigned int len)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(wctxt, ctxt);
struct console *con = ctxt->console;
struct nbcon_state cur;
wctxt->outbuf = buf;
wctxt->len = len;
nbcon_state_read(con, &cur);
wctxt->unsafe_takeover = cur.unsafe_takeover;
}
/**
* nbcon_enter_unsafe - Enter an unsafe region in the driver
* @wctxt: The write context that was handed to the write function
*
* Return: True if this context still owns the console. False if
* ownership was handed over or taken.
*
* When this function returns false then the calling context no longer owns
* the console and is no longer allowed to go forward. In this case it must
* back out immediately and carefully. The buffer content is also no longer
* trusted since it no longer belongs to the calling context.
*/
bool nbcon_enter_unsafe(struct nbcon_write_context *wctxt)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(wctxt, ctxt);
bool is_owner;
is_owner = nbcon_context_enter_unsafe(ctxt);
if (!is_owner)
nbcon_write_context_set_buf(wctxt, NULL, 0);
return is_owner;
}
EXPORT_SYMBOL_GPL(nbcon_enter_unsafe);
/**
* nbcon_exit_unsafe - Exit an unsafe region in the driver
* @wctxt: The write context that was handed to the write function
*
* Return: True if this context still owns the console. False if
* ownership was handed over or taken.
*
* When this function returns false then the calling context no longer owns
* the console and is no longer allowed to go forward. In this case it must
* back out immediately and carefully. The buffer content is also no longer
* trusted since it no longer belongs to the calling context.
*/
bool nbcon_exit_unsafe(struct nbcon_write_context *wctxt)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(wctxt, ctxt);
bool ret;
ret = nbcon_context_exit_unsafe(ctxt);
if (!ret)
nbcon_write_context_set_buf(wctxt, NULL, 0);
return ret;
}
EXPORT_SYMBOL_GPL(nbcon_exit_unsafe);
/**
* nbcon_reacquire_nobuf - Reacquire a console after losing ownership
* while printing
* @wctxt: The write context that was handed to the write callback
*
* Since ownership can be lost at any time due to handover or takeover, a
* printing context _must_ be prepared to back out immediately and
* carefully. However, there are scenarios where the printing context must
* reacquire ownership in order to finalize or revert hardware changes.
*
* This function allows a printing context to reacquire ownership using the
* same priority as its previous ownership.
*
* Note that after a successful reacquire the printing context will have no
* output buffer because that has been lost. This function cannot be used to
* resume printing.
*/
void nbcon_reacquire_nobuf(struct nbcon_write_context *wctxt)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(wctxt, ctxt);
while (!nbcon_context_try_acquire(ctxt))
cpu_relax();
nbcon_write_context_set_buf(wctxt, NULL, 0);
}
EXPORT_SYMBOL_GPL(nbcon_reacquire_nobuf);
/**
* nbcon_emit_next_record - Emit a record in the acquired context
* @wctxt: The write context that will be handed to the write function
* @use_atomic: True if the write_atomic() callback is to be used
*
* Return: True if this context still owns the console. False if
* ownership was handed over or taken.
*
* When this function returns false then the calling context no longer owns
* the console and is no longer allowed to go forward. In this case it must
* back out immediately and carefully. The buffer content is also no longer
* trusted since it no longer belongs to the calling context. If the caller
* wants to do more it must reacquire the console first.
*
* When true is returned, @wctxt->ctxt.backlog indicates whether there are
* still records pending in the ringbuffer,
*/
static bool nbcon_emit_next_record(struct nbcon_write_context *wctxt, bool use_atomic)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(wctxt, ctxt);
struct console *con = ctxt->console;
bool is_extended = console_srcu_read_flags(con) & CON_EXTENDED;
struct printk_message pmsg = {
.pbufs = ctxt->pbufs,
};
unsigned long con_dropped;
struct nbcon_state cur;
unsigned long dropped;
unsigned long ulseq;
/*
* This function should never be called for consoles that have not
* implemented the necessary callback for writing: i.e. legacy
* consoles and, when atomic, nbcon consoles with no write_atomic().
* Handle it as if ownership was lost and try to continue.
*
* Note that for nbcon consoles the write_thread() callback is
* mandatory and was already checked in nbcon_alloc().
*/
if (WARN_ON_ONCE((use_atomic && !con->write_atomic) ||
!(console_srcu_read_flags(con) & CON_NBCON))) {
nbcon_context_release(ctxt);
return false;
}
/*
* The printk buffers are filled within an unsafe section. This
* prevents NBCON_PRIO_NORMAL and NBCON_PRIO_EMERGENCY from
* clobbering each other.
*/
if (!nbcon_context_enter_unsafe(ctxt))
return false;
ctxt->backlog = printk_get_next_message(&pmsg, ctxt->seq, is_extended, true);
if (!ctxt->backlog)
return nbcon_context_exit_unsafe(ctxt);
/*
* @con->dropped is not protected in case of an unsafe hostile
* takeover. In that situation the update can be racy so
* annotate it accordingly.
*/
con_dropped = data_race(READ_ONCE(con->dropped));
dropped = con_dropped + pmsg.dropped;
if (dropped && !is_extended)
console_prepend_dropped(&pmsg, dropped);
/*
* If the previous owner was assigned the same record, this context
* has taken over ownership and is replaying the record. Prepend a
* message to let the user know the record is replayed.
*/
ulseq = atomic_long_read(&ACCESS_PRIVATE(con, nbcon_prev_seq));
if (__ulseq_to_u64seq(prb, ulseq) == pmsg.seq) {
console_prepend_replay(&pmsg);
} else {
/*
* Ensure this context is still the owner before trying to
* update @nbcon_prev_seq. Otherwise the value in @ulseq may
* not be from the previous owner and instead be some later
* value from the context that took over ownership.
*/
nbcon_state_read(con, &cur);
if (!nbcon_context_can_proceed(ctxt, &cur))
return false;
atomic_long_try_cmpxchg(&ACCESS_PRIVATE(con, nbcon_prev_seq), &ulseq,
__u64seq_to_ulseq(pmsg.seq));
}
if (!nbcon_context_exit_unsafe(ctxt))
return false;
/* For skipped records just update seq/dropped in @con. */
if (pmsg.outbuf_len == 0)
goto update_con;
/* Initialize the write context for driver callbacks. */
nbcon_write_context_set_buf(wctxt, &pmsg.pbufs->outbuf[0], pmsg.outbuf_len);
if (use_atomic)
con->write_atomic(con, wctxt);
else
con->write_thread(con, wctxt);
if (!wctxt->outbuf) {
/*
* Ownership was lost and reacquired by the driver. Handle it
* as if ownership was lost.
*/
nbcon_context_release(ctxt);
return false;
}
/*
* Ownership may have been lost but _not_ reacquired by the driver.
* This case is detected and handled when entering unsafe to update
* dropped/seq values.
*/
/*
* Since any dropped message was successfully output, reset the
* dropped count for the console.
*/
dropped = 0;
update_con:
/*
* The dropped count and the sequence number are updated within an
* unsafe section. This limits update races to the panic context and
* allows the panic context to win.
*/
if (!nbcon_context_enter_unsafe(ctxt))
return false;
if (dropped != con_dropped) {
/* Counterpart to the READ_ONCE() above. */
WRITE_ONCE(con->dropped, dropped);
}
nbcon_seq_try_update(ctxt, pmsg.seq + 1);
return nbcon_context_exit_unsafe(ctxt);
}
/*
* nbcon_emit_one - Print one record for an nbcon console using the
* specified callback
* @wctxt: An initialized write context struct to use for this context
* @use_atomic: True if the write_atomic() callback is to be used
*
* Return: True, when a record has been printed and there are still
* pending records. The caller might want to continue flushing.
*
* False, when there is no pending record, or when the console
* context cannot be acquired, or the ownership has been lost.
* The caller should give up. Either the job is done, cannot be
* done, or will be handled by the owning context.
*
* This is an internal helper to handle the locking of the console before
* calling nbcon_emit_next_record().
*/
static bool nbcon_emit_one(struct nbcon_write_context *wctxt, bool use_atomic)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(wctxt, ctxt);
struct console *con = ctxt->console;
unsigned long flags;
bool ret = false;
if (!use_atomic) {
con->device_lock(con, &flags);
/*
* Ensure this stays on the CPU to make handover and
* takeover possible.
*/
cant_migrate();
}
if (!nbcon_context_try_acquire(ctxt))
goto out;
/*
* nbcon_emit_next_record() returns false when the console was
* handed over or taken over. In both cases the context is no
* longer valid.
*
* The higher priority printing context takes over responsibility
* to print the pending records.
*/
if (!nbcon_emit_next_record(wctxt, use_atomic))
goto out;
nbcon_context_release(ctxt);
ret = ctxt->backlog;
out:
if (!use_atomic)
con->device_unlock(con, flags);
return ret;
}
/**
* nbcon_kthread_should_wakeup - Check whether a printer thread should wakeup
* @con: Console to operate on
* @ctxt: The nbcon context from nbcon_context_try_acquire()
*
* Return: True if the thread should shutdown or if the console is
* allowed to print and a record is available. False otherwise.
*
* After the thread wakes up, it must first check if it should shutdown before
* attempting any printing.
*/
static bool nbcon_kthread_should_wakeup(struct console *con, struct nbcon_context *ctxt)
{
bool ret = false;
short flags;
int cookie;
if (kthread_should_stop())
return true;
cookie = console_srcu_read_lock();
flags = console_srcu_read_flags(con);
if (console_is_usable(con, flags, false)) {
/* Bring the sequence in @ctxt up to date */
ctxt->seq = nbcon_seq_read(con);
ret = prb_read_valid(prb, ctxt->seq, NULL);
}
console_srcu_read_unlock(cookie);
return ret;
}
/**
* nbcon_kthread_func - The printer thread function
* @__console: Console to operate on
*
* Return: 0
*/
static int nbcon_kthread_func(void *__console)
{
struct console *con = __console;
struct nbcon_write_context wctxt = {
.ctxt.console = con,
.ctxt.prio = NBCON_PRIO_NORMAL,
};
struct nbcon_context *ctxt = &ACCESS_PRIVATE(&wctxt, ctxt);
short con_flags;
bool backlog;
int cookie;
wait_for_event:
/*
* Guarantee this task is visible on the rcuwait before
* checking the wake condition.
*
* The full memory barrier within set_current_state() of
* ___rcuwait_wait_event() pairs with the full memory
* barrier within rcuwait_has_sleeper().
*
* This pairs with rcuwait_has_sleeper:A and nbcon_kthread_wake:A.
*/
rcuwait_wait_event(&con->rcuwait,
nbcon_kthread_should_wakeup(con, ctxt),
TASK_INTERRUPTIBLE); /* LMM(nbcon_kthread_func:A) */
do {
if (kthread_should_stop())
return 0;
backlog = false;
/*
* Keep the srcu read lock around the entire operation so that
* synchronize_srcu() can guarantee that the kthread stopped
* or suspended printing.
*/
cookie = console_srcu_read_lock();
con_flags = console_srcu_read_flags(con);
if (console_is_usable(con, con_flags, false))
backlog = nbcon_emit_one(&wctxt, false);
console_srcu_read_unlock(cookie);
cond_resched();
} while (backlog);
goto wait_for_event;
}
/**
* nbcon_irq_work - irq work to wake console printer thread
* @irq_work: The irq work to operate on
*/
static void nbcon_irq_work(struct irq_work *irq_work)
{
struct console *con = container_of(irq_work, struct console, irq_work);
nbcon_kthread_wake(con);
}
static inline bool rcuwait_has_sleeper(struct rcuwait *w)
{
/*
* Guarantee any new records can be seen by tasks preparing to wait
* before this context checks if the rcuwait is empty.
*
* This full memory barrier pairs with the full memory barrier within
* set_current_state() of ___rcuwait_wait_event(), which is called
* after prepare_to_rcuwait() adds the waiter but before it has
* checked the wait condition.
*
* This pairs with nbcon_kthread_func:A.
*/
smp_mb(); /* LMM(rcuwait_has_sleeper:A) */
return rcuwait_active(w);
}
/**
* nbcon_kthreads_wake - Wake up printing threads using irq_work
*/
void nbcon_kthreads_wake(void)
{
struct console *con;
int cookie;
if (!printk_kthreads_running)
return;
cookie = console_srcu_read_lock();
for_each_console_srcu(con) {
if (!(console_srcu_read_flags(con) & CON_NBCON))
continue;
/*
* Only schedule irq_work if the printing thread is
* actively waiting. If not waiting, the thread will
* notice by itself that it has work to do.
*/
if (rcuwait_has_sleeper(&con->rcuwait))
irq_work_queue(&con->irq_work);
}
console_srcu_read_unlock(cookie);
}
/*
* nbcon_kthread_stop - Stop a console printer thread
* @con: Console to operate on
*/
void nbcon_kthread_stop(struct console *con)
{
lockdep_assert_console_list_lock_held();
if (!con->kthread)
return;
kthread_stop(con->kthread);
con->kthread = NULL;
}
/**
* nbcon_kthread_create - Create a console printer thread
* @con: Console to operate on
*
* Return: True if the kthread was started or already exists.
* Otherwise false and @con must not be registered.
*
* This function is called when it will be expected that nbcon consoles are
* flushed using the kthread. The messages printed with NBCON_PRIO_NORMAL
* will be no longer flushed by the legacy loop. This is why failure must
* be fatal for console registration.
*
* If @con was already registered and this function fails, @con must be
* unregistered before the global state variable @printk_kthreads_running
* can be set.
*/
bool nbcon_kthread_create(struct console *con)
{
struct task_struct *kt;
lockdep_assert_console_list_lock_held();
if (con->kthread)
return true;
kt = kthread_run(nbcon_kthread_func, con, "pr/%s%d", con->name, con->index);
if (WARN_ON(IS_ERR(kt))) {
con_printk(KERN_ERR, con, "failed to start printing thread\n");
return false;
}
con->kthread = kt;
/*
* It is important that console printing threads are scheduled
* shortly after a printk call and with generous runtime budgets.
*/
sched_set_normal(con->kthread, -20);
return true;
}
/* Track the nbcon emergency nesting per CPU. */
static DEFINE_PER_CPU(unsigned int, nbcon_pcpu_emergency_nesting);
static unsigned int early_nbcon_pcpu_emergency_nesting __initdata;
/**
* nbcon_get_cpu_emergency_nesting - Get the per CPU emergency nesting pointer
*
* Context: For reading, any context. For writing, any context which could
* not be migrated to another CPU.
* Return: Either a pointer to the per CPU emergency nesting counter of
* the current CPU or to the init data during early boot.
*
* The function is safe for reading per-CPU variables in any context because
* preemption is disabled if the current CPU is in the emergency state. See
* also nbcon_cpu_emergency_enter().
*/
static __ref unsigned int *nbcon_get_cpu_emergency_nesting(void)
{
/*
* The value of __printk_percpu_data_ready gets set in normal
* context and before SMP initialization. As a result it could
* never change while inside an nbcon emergency section.
*/
if (!printk_percpu_data_ready())
return &early_nbcon_pcpu_emergency_nesting;
return raw_cpu_ptr(&nbcon_pcpu_emergency_nesting);
}
/**
* nbcon_get_default_prio - The appropriate nbcon priority to use for nbcon
* printing on the current CPU
*
* Context: Any context.
* Return: The nbcon_prio to use for acquiring an nbcon console in this
* context for printing.
*
* The function is safe for reading per-CPU data in any context because
* preemption is disabled if the current CPU is in the emergency or panic
* state.
*/
enum nbcon_prio nbcon_get_default_prio(void)
{
unsigned int *cpu_emergency_nesting;
if (this_cpu_in_panic())
return NBCON_PRIO_PANIC;
cpu_emergency_nesting = nbcon_get_cpu_emergency_nesting();
if (*cpu_emergency_nesting)
return NBCON_PRIO_EMERGENCY;
return NBCON_PRIO_NORMAL;
}
/**
* nbcon_legacy_emit_next_record - Print one record for an nbcon console
* in legacy contexts
* @con: The console to print on
* @handover: Will be set to true if a printk waiter has taken over the
* console_lock, in which case the caller is no longer holding
* both the console_lock and the SRCU read lock. Otherwise it
* is set to false.
* @cookie: The cookie from the SRCU read lock.
* @use_atomic: Set true when called in an atomic or unknown context.
* It affects which nbcon callback will be used: write_atomic()
* or write_thread().
*
* When false, the write_thread() callback is used and would be
* called in a preemtible context unless disabled by the
* device_lock. The legacy handover is not allowed in this mode.
*
* Context: Any context except NMI.
* Return: True, when a record has been printed and there are still
* pending records. The caller might want to continue flushing.
*
* False, when there is no pending record, or when the console
* context cannot be acquired, or the ownership has been lost.
* The caller should give up. Either the job is done, cannot be
* done, or will be handled by the owning context.
*
* This function is meant to be called by console_flush_all() to print records
* on nbcon consoles from legacy context (printing via console unlocking).
* Essentially it is the nbcon version of console_emit_next_record().
*/
bool nbcon_legacy_emit_next_record(struct console *con, bool *handover,
int cookie, bool use_atomic)
{
struct nbcon_write_context wctxt = { };
struct nbcon_context *ctxt = &ACCESS_PRIVATE(&wctxt, ctxt);
unsigned long flags;
bool progress;
ctxt->console = con;
ctxt->prio = nbcon_get_default_prio();
if (use_atomic) {
/*
* In an atomic or unknown context, use the same procedure as
* in console_emit_next_record(). It allows to handover.
*/
printk_safe_enter_irqsave(flags);
console_lock_spinning_enable();
stop_critical_timings();
}
progress = nbcon_emit_one(&wctxt, use_atomic);
if (use_atomic) {
start_critical_timings();
*handover = console_lock_spinning_disable_and_check(cookie);
printk_safe_exit_irqrestore(flags);
} else {
/* Non-atomic does not perform legacy spinning handovers. */
*handover = false;
}
return progress;
}
/**
* __nbcon_atomic_flush_pending_con - Flush specified nbcon console using its
* write_atomic() callback
* @con: The nbcon console to flush
* @stop_seq: Flush up until this record
* @allow_unsafe_takeover: True, to allow unsafe hostile takeovers
*
* Return: 0 if @con was flushed up to @stop_seq Otherwise, error code on
* failure.
*
* Errors:
*
* -EPERM: Unable to acquire console ownership.
*
* -EAGAIN: Another context took over ownership while printing.
*
* -ENOENT: A record before @stop_seq is not available.
*
* If flushing up to @stop_seq was not successful, it only makes sense for the
* caller to try again when -EAGAIN was returned. When -EPERM is returned,
* this context is not allowed to acquire the console. When -ENOENT is
* returned, it cannot be expected that the unfinalized record will become
* available.
*/
static int __nbcon_atomic_flush_pending_con(struct console *con, u64 stop_seq,
bool allow_unsafe_takeover)
{
struct nbcon_write_context wctxt = { };
struct nbcon_context *ctxt = &ACCESS_PRIVATE(&wctxt, ctxt);
int err = 0;
ctxt->console = con;
ctxt->spinwait_max_us = 2000;
ctxt->prio = nbcon_get_default_prio();
ctxt->allow_unsafe_takeover = allow_unsafe_takeover;
if (!nbcon_context_try_acquire(ctxt))
return -EPERM;
while (nbcon_seq_read(con) < stop_seq) {
/*
* nbcon_emit_next_record() returns false when the console was
* handed over or taken over. In both cases the context is no
* longer valid.
*/
if (!nbcon_emit_next_record(&wctxt, true))
return -EAGAIN;
if (!ctxt->backlog) {
/* Are there reserved but not yet finalized records? */
if (nbcon_seq_read(con) < stop_seq)
err = -ENOENT;
break;
}
}
nbcon_context_release(ctxt);
return err;
}
/**
* nbcon_atomic_flush_pending_con - Flush specified nbcon console using its
* write_atomic() callback
* @con: The nbcon console to flush
* @stop_seq: Flush up until this record
* @allow_unsafe_takeover: True, to allow unsafe hostile takeovers
*
* This will stop flushing before @stop_seq if another context has ownership.
* That context is then responsible for the flushing. Likewise, if new records
* are added while this context was flushing and there is no other context
* to handle the printing, this context must also flush those records.
*/
static void nbcon_atomic_flush_pending_con(struct console *con, u64 stop_seq,
bool allow_unsafe_takeover)
{
struct console_flush_type ft;
unsigned long flags;
int err;
again:
/*
* Atomic flushing does not use console driver synchronization (i.e.
* it does not hold the port lock for uart consoles). Therefore IRQs
* must be disabled to avoid being interrupted and then calling into
* a driver that will deadlock trying to acquire console ownership.
*/
local_irq_save(flags);
err = __nbcon_atomic_flush_pending_con(con, stop_seq, allow_unsafe_takeover);
local_irq_restore(flags);
/*
* If there was a new owner (-EPERM, -EAGAIN), that context is
* responsible for completing.
*
* Do not wait for records not yet finalized (-ENOENT) to avoid a
* possible deadlock. They will either get flushed by the writer or
* eventually skipped on panic CPU.
*/
if (err)
return;
/*
* If flushing was successful but more records are available, this
* context must flush those remaining records if the printer thread
* is not available do it.
*/
printk_get_console_flush_type(&ft);
if (!ft.nbcon_offload &&
prb_read_valid(prb, nbcon_seq_read(con), NULL)) {
stop_seq = prb_next_reserve_seq(prb);
goto again;
}
}
/**
* __nbcon_atomic_flush_pending - Flush all nbcon consoles using their
* write_atomic() callback
* @stop_seq: Flush up until this record
* @allow_unsafe_takeover: True, to allow unsafe hostile takeovers
*/
static void __nbcon_atomic_flush_pending(u64 stop_seq, bool allow_unsafe_takeover)
{
struct console *con;
int cookie;
cookie = console_srcu_read_lock();
for_each_console_srcu(con) {
short flags = console_srcu_read_flags(con);
if (!(flags & CON_NBCON))
continue;
if (!console_is_usable(con, flags, true))
continue;
if (nbcon_seq_read(con) >= stop_seq)
continue;
nbcon_atomic_flush_pending_con(con, stop_seq, allow_unsafe_takeover);
}
console_srcu_read_unlock(cookie);
}
/**
* nbcon_atomic_flush_pending - Flush all nbcon consoles using their
* write_atomic() callback
*
* Flush the backlog up through the currently newest record. Any new
* records added while flushing will not be flushed if there is another
* context available to handle the flushing. This is to avoid one CPU
* printing unbounded because other CPUs continue to add records.
*/
void nbcon_atomic_flush_pending(void)
{
__nbcon_atomic_flush_pending(prb_next_reserve_seq(prb), false);
}
/**
* nbcon_atomic_flush_unsafe - Flush all nbcon consoles using their
* write_atomic() callback and allowing unsafe hostile takeovers
*
* Flush the backlog up through the currently newest record. Unsafe hostile
* takeovers will be performed, if necessary.
*/
void nbcon_atomic_flush_unsafe(void)
{
__nbcon_atomic_flush_pending(prb_next_reserve_seq(prb), true);
}
/**
* nbcon_cpu_emergency_enter - Enter an emergency section where printk()
* messages for that CPU are flushed directly
*
* Context: Any context. Disables preemption.
*
* When within an emergency section, printk() calls will attempt to flush any
* pending messages in the ringbuffer.
*/
void nbcon_cpu_emergency_enter(void)
{
unsigned int *cpu_emergency_nesting;
preempt_disable();
cpu_emergency_nesting = nbcon_get_cpu_emergency_nesting();
(*cpu_emergency_nesting)++;
}
/**
* nbcon_cpu_emergency_exit - Exit an emergency section
*
* Context: Within an emergency section. Enables preemption.
*/
void nbcon_cpu_emergency_exit(void)
{
unsigned int *cpu_emergency_nesting;
cpu_emergency_nesting = nbcon_get_cpu_emergency_nesting();
if (!WARN_ON_ONCE(*cpu_emergency_nesting == 0))
(*cpu_emergency_nesting)--;
preempt_enable();
}
/**
* nbcon_alloc - Allocate and init the nbcon console specific data
* @con: Console to initialize
*
* Return: True if the console was fully allocated and initialized.
* Otherwise @con must not be registered.
*
* When allocation and init was successful, the console must be properly
* freed using nbcon_free() once it is no longer needed.
*/
bool nbcon_alloc(struct console *con)
{
struct nbcon_state state = { };
/* The write_thread() callback is mandatory. */
if (WARN_ON(!con->write_thread))
return false;
rcuwait_init(&con->rcuwait);
init_irq_work(&con->irq_work, nbcon_irq_work);
atomic_long_set(&ACCESS_PRIVATE(con, nbcon_prev_seq), -1UL);
nbcon_state_set(con, &state);
/*
* Initialize @nbcon_seq to the highest possible sequence number so
* that practically speaking it will have nothing to print until a
* desired initial sequence number has been set via nbcon_seq_force().
*/
atomic_long_set(&ACCESS_PRIVATE(con, nbcon_seq), ULSEQ_MAX(prb));
if (con->flags & CON_BOOT) {
/*
* Boot console printing is synchronized with legacy console
* printing, so boot consoles can share the same global printk
* buffers.
*/
con->pbufs = &printk_shared_pbufs;
} else {
con->pbufs = kmalloc(sizeof(*con->pbufs), GFP_KERNEL);
if (!con->pbufs) {
con_printk(KERN_ERR, con, "failed to allocate printing buffer\n");
return false;
}
if (printk_kthreads_running) {
if (!nbcon_kthread_create(con)) {
kfree(con->pbufs);
con->pbufs = NULL;
return false;
}
}
}
return true;
}
/**
* nbcon_free - Free and cleanup the nbcon console specific data
* @con: Console to free/cleanup nbcon data
*/
void nbcon_free(struct console *con)
{
struct nbcon_state state = { };
if (printk_kthreads_running)
nbcon_kthread_stop(con);
nbcon_state_set(con, &state);
/* Boot consoles share global printk buffers. */
if (!(con->flags & CON_BOOT))
kfree(con->pbufs);
con->pbufs = NULL;
}
/**
* nbcon_device_try_acquire - Try to acquire nbcon console and enter unsafe
* section
* @con: The nbcon console to acquire
*
* Context: Under the locking mechanism implemented in
* @con->device_lock() including disabling migration.
* Return: True if the console was acquired. False otherwise.
*
* Console drivers will usually use their own internal synchronization
* mechasism to synchronize between console printing and non-printing
* activities (such as setting baud rates). However, nbcon console drivers
* supporting atomic consoles may also want to mark unsafe sections when
* performing non-printing activities in order to synchronize against their
* atomic_write() callback.
*
* This function acquires the nbcon console using priority NBCON_PRIO_NORMAL
* and marks it unsafe for handover/takeover.
*/
bool nbcon_device_try_acquire(struct console *con)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(con, nbcon_device_ctxt);
cant_migrate();
memset(ctxt, 0, sizeof(*ctxt));
ctxt->console = con;
ctxt->prio = NBCON_PRIO_NORMAL;
if (!nbcon_context_try_acquire(ctxt))
return false;
if (!nbcon_context_enter_unsafe(ctxt))
return false;
return true;
}
EXPORT_SYMBOL_GPL(nbcon_device_try_acquire);
/**
* nbcon_device_release - Exit unsafe section and release the nbcon console
* @con: The nbcon console acquired in nbcon_device_try_acquire()
*/
void nbcon_device_release(struct console *con)
{
struct nbcon_context *ctxt = &ACCESS_PRIVATE(con, nbcon_device_ctxt);
struct console_flush_type ft;
int cookie;
if (!nbcon_context_exit_unsafe(ctxt))
return;
nbcon_context_release(ctxt);
/*
* This context must flush any new records added while the console
* was locked if the printer thread is not available to do it. The
* console_srcu_read_lock must be taken to ensure the console is
* usable throughout flushing.
*/
cookie = console_srcu_read_lock();
printk_get_console_flush_type(&ft);
if (console_is_usable(con, console_srcu_read_flags(con), true) &&
!ft.nbcon_offload &&
prb_read_valid(prb, nbcon_seq_read(con), NULL)) {
/*
* If nbcon_atomic flushing is not available, fallback to
* using the legacy loop.
*/
if (ft.nbcon_atomic) {
__nbcon_atomic_flush_pending_con(con, prb_next_reserve_seq(prb), false);
} else if (ft.legacy_direct) {
if (console_trylock())
console_unlock();
} else if (ft.legacy_offload) {
printk_trigger_flush();
}
}
console_srcu_read_unlock(cookie);
}
EXPORT_SYMBOL_GPL(nbcon_device_release);