680 lines
21 KiB
Groff
680 lines
21 KiB
Groff
.\" Copyright (c) 2002 Packet Design, LLC.
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.\" All rights reserved.
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.\"
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.\" Subject to the following obligations and disclaimer of warranty,
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.\" use and redistribution of this software, in source or object code
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.\" forms, with or without modifications are expressly permitted by
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.\" Packet Design; provided, however, that:
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.\"
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.\" (i) Any and all reproductions of the source or object code
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.\" must include the copyright notice above and the following
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.\" disclaimer of warranties; and
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.\" (ii) No rights are granted, in any manner or form, to use
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.\" Packet Design trademarks, including the mark "PACKET DESIGN"
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.\" on advertising, endorsements, or otherwise except as such
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.\" appears in the above copyright notice or in the software.
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.\"
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.\" THIS SOFTWARE IS BEING PROVIDED BY PACKET DESIGN "AS IS", AND
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.\" TO THE MAXIMUM EXTENT PERMITTED BY LAW, PACKET DESIGN MAKES NO
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.\" REPRESENTATIONS OR WARRANTIES, EXPRESS OR IMPLIED, REGARDING
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.\" THIS SOFTWARE, INCLUDING WITHOUT LIMITATION, ANY AND ALL IMPLIED
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.\" WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE,
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.\" OR NON-INFRINGEMENT. PACKET DESIGN DOES NOT WARRANT, GUARANTEE,
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.\" OR MAKE ANY REPRESENTATIONS REGARDING THE USE OF, OR THE RESULTS
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.\" OF THE USE OF THIS SOFTWARE IN TERMS OF ITS CORRECTNESS, ACCURACY,
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.\" RELIABILITY OR OTHERWISE. IN NO EVENT SHALL PACKET DESIGN BE
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.\" LIABLE FOR ANY DAMAGES RESULTING FROM OR ARISING OUT OF ANY USE
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.\" OF THIS SOFTWARE, INCLUDING WITHOUT LIMITATION, ANY DIRECT,
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.\" INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, PUNITIVE, OR CONSEQUENTIAL
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.\" DAMAGES, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES, LOSS OF
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.\" USE, DATA OR PROFITS, HOWEVER CAUSED AND UNDER ANY THEORY OF
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.\" LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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.\" (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF
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.\" THE USE OF THIS SOFTWARE, EVEN IF PACKET DESIGN IS ADVISED OF
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.\" THE POSSIBILITY OF SUCH DAMAGE.
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.\"
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.\" $FreeBSD$
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.\"
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.Dd February 13, 2007
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.Dt KSE 2
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.Os
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.Sh NAME
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.Nm kse
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.Nd "kernel support for user threads"
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.Sh LIBRARY
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.Lb libc
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.Sh SYNOPSIS
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.In sys/types.h
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.In sys/kse.h
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.Ft int
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.Fn kse_create "struct kse_mailbox *mbx" "int sys-scope"
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.Ft int
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.Fn kse_exit void
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.Ft int
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.Fn kse_release "struct timespec *timeout"
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.Ft int
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.Fn kse_switchin "struct kse_thr_mailbox *tmbx" "int flags"
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.Ft int
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.Fn kse_thr_interrupt "struct kse_thr_mailbox *tmbx" "int cmd" "long data"
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.Ft int
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.Fn kse_wakeup "struct kse_mailbox *mbx"
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.Sh DESCRIPTION
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These system calls implement kernel support for multi-threaded processes.
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.\"
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.Ss Overview
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.\"
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Traditionally, user threading has been implemented in one of two ways:
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either all threads are managed in user space and the kernel is unaware
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of any threading (also known as
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.Dq "N to 1" ) ,
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or else separate processes sharing
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a common memory space are created for each thread (also known as
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.Dq "N to N" ) .
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These approaches have advantages and disadvantages:
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.Bl -column "- Cannot utilize multiple CPUs" "+ Can utilize multiple CPUs"
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.It Sy "User threading Kernel threading"
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.It "+ Lightweight - Heavyweight"
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.It "+ User controls scheduling - Kernel controls scheduling"
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.It "- Syscalls must be wrapped + No syscall wrapping required"
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.It "- Cannot utilize multiple CPUs + Can utilize multiple CPUs"
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.El
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.Pp
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The KSE system is a
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hybrid approach that achieves the advantages of both the user and kernel
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threading approaches.
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The underlying philosophy of the KSE system is to give kernel support
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for user threading without taking away any of the user threading library's
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ability to make scheduling decisions.
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A kernel-to-user upcall mechanism is used to pass control to the user
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threading library whenever a scheduling decision needs to be made.
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An arbitrarily number of user threads are multiplexed onto a fixed number of
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virtual CPUs supplied by the kernel.
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This can be thought of as an
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.Dq "N to M"
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threading scheme.
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.Pp
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Some general implications of this approach include:
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.Bl -bullet
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.It
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The user process can run multiple threads simultaneously on multi-processor
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machines.
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The kernel grants the process virtual CPUs to schedule as it
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wishes; these may run concurrently on real CPUs.
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.It
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All operations that block in the kernel become asynchronous, allowing
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the user process to schedule another thread when any thread blocks.
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.El
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.\"
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.Ss Definitions
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.\"
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KSE allows a user process to have multiple
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.Sy threads
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of execution in existence at the same time, some of which may be blocked
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in the kernel while others may be executing or blocked in user space.
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A
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.Sy "kernel scheduling entity"
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(KSE) is a
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.Dq "virtual CPU"
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granted to the process for the purpose of executing threads.
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A thread that is currently executing is always associated with
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exactly one KSE, whether executing in user space or in the kernel.
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The KSE is said to be
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.Sy assigned
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to the thread.
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KSEs (a user abstraction) are implemented on top
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of kernel threads using an 'upcall' entity.
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.Pp
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The KSE becomes
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.Sy unassigned ,
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and the associated thread is suspended, when the KSE has an associated
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.Sy mailbox ,
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(see below) the thread has an associated
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.Sy thread mailbox ,
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(also see below) and any of the following occurs:
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.Bl -bullet
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.It
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The thread invokes a system call that blocks.
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.It
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The thread makes any other demand of the kernel that cannot be immediately
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satisfied, e.g., touches a page of memory that needs to be fetched from disk,
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causing a page fault.
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.It
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Another thread that was previously blocked in the kernel completes its
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work in the kernel (or is
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.Sy interrupted )
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and becomes ready to return to user space, and the current thread is returning
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to user space.
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.It
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A signal is delivered to the process, and this KSE is chosen to deliver it.
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.El
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.Pp
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In other words, as soon as there is a scheduling decision to be made,
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the KSE becomes unassigned, because the kernel does not presume to know
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how the process' other runnable threads should be scheduled.
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Unassigned KSEs always return to user space as soon as possible via
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the
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.Sy upcall
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mechanism (described below), allowing the user process to decide how
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that KSE should be utilized next.
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KSEs always complete as much work as possible in the kernel before
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becoming unassigned.
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.Pp
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Individual KSEs within a process are effectively indistinguishable,
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and any KSE in a process may be assigned by the kernel to any runnable
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(in the kernel) thread associated with that process.
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In practice, the kernel attempts to preserve the affinity between threads
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and actual CPUs to optimize cache behavior, but this is invisible to the
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user process.
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(Affinity is not yet fully implemented.)
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.Pp
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Each KSE has a unique
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.Sy "KSE mailbox"
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supplied by the user process.
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A mailbox consists of a control structure containing a pointer to an
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.Sy "upcall function"
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and a user stack.
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The KSE invokes this function whenever it becomes unassigned.
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The kernel updates this structure with information about threads that have
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become runnable and signals that have been delivered before each upcall.
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Upcalls may be temporarily blocked by the user thread scheduling code
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during critical sections.
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.Pp
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Each user thread has a unique
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.Sy "thread mailbox"
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as well.
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Threads are referred to using pointers to these mailboxes when communicating
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between the kernel and the user thread scheduler.
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Each KSE's mailbox contains a pointer to the mailbox of the user thread
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that the KSE is currently executing.
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This pointer is saved when the thread blocks in the kernel.
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.Pp
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Whenever a thread blocked in the kernel is ready to return to user space,
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it is added to the process's list of
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.Sy completed
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threads.
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This list is presented to the user code at the next upcall as a linked list
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of thread mailboxes.
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.Pp
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There is a kernel-imposed limit on the number of threads in a process
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that may be simultaneously blocked in the kernel (this number is not
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currently visible to the user).
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When this limit is reached, upcalls are blocked and no work is performed
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for the process until one of the threads completes (or a signal is
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received).
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.\"
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.Ss Managing KSEs
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.\"
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To become multi-threaded, a process must first invoke
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.Fn kse_create .
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The
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.Fn kse_create
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system call
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creates a new KSE (except for the very first invocation; see below).
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The KSE will be associated with the mailbox pointed to by
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.Fa mbx .
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If
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.Fa sys_scope
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is non-zero, then the new thread will be counted as a system scope
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thread. Other things must be done as well to make a system scope thread
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so this is not sufficient (yet).
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System scope variables are not covered
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in detail in this manual page yet, but briefly, they never perform
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upcalls and do not return to the user thread scheduler.
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Once launched they run autonomously.
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The pthreads library knows how to make system
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scope threads and users are encouraged to use the library interface.
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.Pp
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Each process initially has a single KSE executing a single user thread.
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Since the KSE does not have an associated mailbox, it must remain assigned
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to the thread and does not perform any upcalls.
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(It is by definition a system scope thread).
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The result is the traditional, unthreaded mode of operation.
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Therefore, as a special case, the first call to
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.Fn kse_create
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by this initial thread with
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.Fa sys_scope
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equal to zero does not create a new KSE; instead, it simply associates the
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current KSE with the supplied KSE mailbox, and no immediate upcall results.
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However, an upcall will be triggered the next time the thread blocks and
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the required conditions are met.
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.Pp
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The kernel does not allow more KSEs to exist in a process than the
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number of physical CPUs in the system (this number is available as the
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.Xr sysctl 3
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variable
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.Va hw.ncpu ) .
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Having more KSEs than CPUs would not add any value to the user process,
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as the additional KSEs would just compete with each other for access to
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the real CPUs.
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Since the extra KSEs would always be side-lined, the result
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to the application would be exactly the same as having fewer KSEs.
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There may however be arbitrarily many user threads, and it is up to the
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user thread scheduler to handle mapping the application's user threads
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onto the available KSEs.
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.Pp
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The
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.Fn kse_exit
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system call
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causes the KSE assigned to the currently running thread to be destroyed.
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If this KSE is the last one in the process, there must be no remaining
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threads associated with that process blocked in the kernel.
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This system call does not return unless there is an error.
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Calling
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.Fn kse_exit
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from the last thread is the same as calling
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.Fn exit .
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.Pp
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The
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.Fn kse_release
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system call
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is used to
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.Dq park
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the KSE assigned to the currently running thread when it is not needed,
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e.g., when there are more available KSEs than runnable user threads.
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The thread converts to an upcall but does not get scheduled until
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there is a new reason to do so, e.g., a previously
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blocked thread becomes runnable, or the timeout expires.
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If successful,
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.Fn kse_release
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does not return to the caller.
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.Pp
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The
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.Fn kse_switchin
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system call can be used by the UTS, when it has selected a new thread,
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to switch to the context of that thread.
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The use of
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.Fn kse_switchin
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is machine dependent.
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Some platforms do not need a system call to switch to a new context,
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while others require its use in particular cases.
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.Pp
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The
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.Fn kse_wakeup
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system call
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is the opposite of
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.Fn kse_release .
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It causes the (parked) KSE associated with the mailbox pointed to by
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.Fa mbx
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to be woken up, causing it to upcall.
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If the KSE has already woken up for another reason, this system call has no
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effect.
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The
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.Fa mbx
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argument
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may be
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.Dv NULL
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to specify
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.Dq "any KSE in the current process" .
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.Pp
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The
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.Fn kse_thr_interrupt
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system call
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is used to interrupt a currently blocked thread.
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The thread must either be blocked in the kernel or assigned to a KSE
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(i.e., executing).
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The thread is then marked as interrupted.
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As soon as the thread invokes an interruptible system call (or immediately
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for threads already blocked in one), the thread will be made runnable again,
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even though the kernel operation may not have completed.
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The effect on the interrupted system call is the same as if it had been
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interrupted by a signal; typically this means an error is returned with
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.Va errno
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set to
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.Er EINTR .
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.\"
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.Ss Signals
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.\"
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The current implementation creates a special signal thread.
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Kernel threads (KSEs) in a process mask all signals, and only the signal
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thread waits for signals to be delivered to the process, the signal thread
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is responsible
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for dispatching signals to user threads.
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.Pp
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A downside of this is that if a multiplexed thread
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calls the
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.Fn execve
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syscall, its signal mask and pending signals may not be
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available in the kernel.
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They are stored
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in userland and the kernel does not know where to get them, however
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.Tn POSIX
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requires them to be restored and passed them to new process.
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Just setting the mask for the thread before calling
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.Fn execve
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is only a
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close approximation to the problem as it does not re-deliver back to the kernel
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any pending signals that the old process may have blocked, and it allows a
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window in which new signals may be delivered to the process between the setting
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of the mask and the
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.Fn execve .
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.Pp
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For now this problem has been solved by adding a special combined
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.Fn kse_thr_interrupt Ns / Ns Fn execve
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mode to the
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.Fn kse_thr_interrupt
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syscall.
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The
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.Fn kse_thr_interrupt
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syscall has a sub command
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.Dv KSE_INTR_EXECVE ,
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that allows it to accept a
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.Vt kse_execv_args
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structure, and allowing it to adjust the signals and then atomically
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convert into an
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.Fn execve
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call.
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Additional pending signals and the correct signal mask can be passed
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to the kernel in this way.
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The thread library overrides the
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.Fn execve
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syscall
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and translates it into
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.Fn kse_intr_interrupt
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call, allowing a multiplexed thread
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to restore pending signals and the correct signal mask before doing the
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.Fn exec .
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This solution to the problem may change.
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.\"
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.Ss KSE Mailboxes
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.\"
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Each KSE has a unique mailbox for user-kernel communication defined in
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.In sys/kse.h .
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Some of the fields there are:
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.Pp
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.Va km_version
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describes the version of this structure and must be equal to
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.Dv KSE_VER_0 .
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.Va km_udata
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is an opaque pointer ignored by the kernel.
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.Pp
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.Va km_func
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points to the KSE's upcall function;
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it will be invoked using
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.Va km_stack ,
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which must remain valid for the lifetime of the KSE.
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.Pp
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.Va km_curthread
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always points to the thread that is currently assigned to this KSE if any,
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or
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.Dv NULL
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otherwise.
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This field is modified by both the kernel and the user process as follows.
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.Pp
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When
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.Va km_curthread
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is not
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.Dv NULL ,
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it is assumed to be pointing at the mailbox for the currently executing
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thread, and the KSE may be unassigned, e.g., if the thread blocks in the
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kernel.
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The kernel will then save the contents of
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.Va km_curthread
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with the blocked thread, set
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.Va km_curthread
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to
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.Dv NULL ,
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and upcall to invoke
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.Fn km_func .
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.Pp
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When
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.Va km_curthread
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is
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.Dv NULL ,
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the kernel will never perform any upcalls with this KSE; in other words,
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the KSE remains assigned to the thread even if it blocks.
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.Va km_curthread
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must be
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.Dv NULL
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while the KSE is executing critical user thread scheduler
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code that would be disrupted by an intervening upcall;
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in particular, while
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.Fn km_func
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itself is executing.
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.Pp
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Before invoking
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.Fn km_func
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in any upcall, the kernel always sets
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.Va km_curthread
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to
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.Dv NULL .
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Once the user thread scheduler has chosen a new thread to run,
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it should point
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.Va km_curthread
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at the thread's mailbox, re-enabling upcalls, and then resume the thread.
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.Em Note :
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modification of
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.Va km_curthread
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by the user thread scheduler must be atomic
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with the loading of the context of the new thread, to avoid
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the situation where the thread context area
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may be modified by a blocking async operation, while there
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is still valid information to be read out of it.
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.Pp
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.Va km_completed
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points to a linked list of user threads that have completed their work
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in the kernel since the last upcall.
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The user thread scheduler should put these threads back into its
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own runnable queue.
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Each thread in a process that completes a kernel operation
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(synchronous or asynchronous) that results in an upcall is guaranteed to be
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linked into exactly one KSE's
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.Va km_completed
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list; which KSE in the group, however, is indeterminate.
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Furthermore, the completion will be reported in only one upcall.
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.Pp
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.Va km_sigscaught
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contains the list of signals caught by this process since the previous
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upcall to any KSE in the process.
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As long as there exists one or more KSEs with an associated mailbox in
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the user process, signals are delivered this way rather than the
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traditional way.
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(This has not been implemented and may change.)
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.Pp
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.Va km_timeofday
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is set by the kernel to the current system time before performing
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each upcall.
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.Pp
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.Va km_flags
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may contain any of the following bits OR'ed together:
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.Bl -tag -width indent
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.It Dv KMF_NOUPCALL
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Block upcalls from happening.
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The thread is in some critical section.
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.It Dv KMF_NOCOMPLETED , KMF_DONE , KMF_BOUND
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This thread should be considered to be permanently bound to
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its KSE, and treated much like a non-threaded process would be.
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It is a
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.Dq "long term"
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version of
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.Dv KMF_NOUPCALL
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in some ways.
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.It Dv KMF_WAITSIGEVENT
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Implement characteristics needed for the signal delivery thread.
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.El
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.\"
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.Ss Thread Mailboxes
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.\"
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Each user thread must have associated with it a unique
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.Vt "struct kse_thr_mailbox"
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as defined in
|
|
.In sys/kse.h .
|
|
It includes the following fields.
|
|
.Pp
|
|
.Va tm_udata
|
|
is an opaque pointer ignored by the kernel.
|
|
.Pp
|
|
.Va tm_context
|
|
stores the context for the thread when the thread is blocked in user space.
|
|
This field is also updated by the kernel before a completed thread is returned
|
|
to the user thread scheduler via
|
|
.Va km_completed .
|
|
.Pp
|
|
.Va tm_next
|
|
links the
|
|
.Va km_completed
|
|
threads together when returned by the kernel with an upcall.
|
|
The end of the list is marked with a
|
|
.Dv NULL
|
|
pointer.
|
|
.Pp
|
|
.Va tm_uticks
|
|
and
|
|
.Va tm_sticks
|
|
are time counters for user mode and kernel mode execution, respectively.
|
|
These counters count ticks of the statistics clock (see
|
|
.Xr clocks 7 ) .
|
|
While any thread is actively executing in the kernel, the corresponding
|
|
.Va tm_sticks
|
|
counter is incremented.
|
|
While any KSE is executing in user space and that KSE's
|
|
.Va km_curthread
|
|
pointer is not equal to
|
|
.Dv NULL ,
|
|
the corresponding
|
|
.Va tm_uticks
|
|
counter is incremented.
|
|
.Pp
|
|
.Va tm_flags
|
|
may contain any of the following bits OR'ed together:
|
|
.Bl -tag -width indent
|
|
.It Dv TMF_NOUPCALL
|
|
Similar to
|
|
.Dv KMF_NOUPCALL .
|
|
This flag inhibits upcalling for critical sections.
|
|
Some architectures require this to be in one place and some in the other.
|
|
.El
|
|
.Sh RETURN VALUES
|
|
The
|
|
.Fn kse_create ,
|
|
.Fn kse_wakeup ,
|
|
and
|
|
.Fn kse_thr_interrupt
|
|
system calls
|
|
return zero if successful.
|
|
The
|
|
.Fn kse_exit
|
|
and
|
|
.Fn kse_release
|
|
system calls
|
|
do not return if successful.
|
|
.Pp
|
|
All of these system calls return a non-zero error code in case of an error.
|
|
.Sh ERRORS
|
|
The
|
|
.Fn kse_create
|
|
system call
|
|
will fail if:
|
|
.Bl -tag -width Er
|
|
.It Bq Er ENXIO
|
|
There are already as many KSEs in the process as hardware processors.
|
|
.It Bq Er EAGAIN
|
|
The user is not the super user, and the soft resource limit corresponding
|
|
to the
|
|
.Fa resource
|
|
argument
|
|
.Dv RLIMIT_NPROC
|
|
would be exceeded (see
|
|
.Xr getrlimit 2 ) .
|
|
.It Bq Er EFAULT
|
|
The
|
|
.Fa mbx
|
|
argument
|
|
points to an address which is not a valid part of the process address space.
|
|
.El
|
|
.Pp
|
|
The
|
|
.Fn kse_exit
|
|
system call
|
|
will fail if:
|
|
.Bl -tag -width Er
|
|
.It Bq Er EDEADLK
|
|
The current KSE is the last in its process and there are still one or more
|
|
threads associated with the process blocked in the kernel.
|
|
.It Bq Er ESRCH
|
|
The current KSE has no associated mailbox, i.e., the process is operating
|
|
in traditional, unthreaded mode (in this case use
|
|
.Xr _exit 2
|
|
to exit the process).
|
|
.El
|
|
.Pp
|
|
The
|
|
.Fn kse_release
|
|
system call
|
|
will fail if:
|
|
.Bl -tag -width Er
|
|
.It Bq Er ESRCH
|
|
The current KSE has no associated mailbox, i.e., the process is operating is
|
|
traditional, unthreaded mode.
|
|
.El
|
|
.Pp
|
|
The
|
|
.Fn kse_wakeup
|
|
system call
|
|
will fail if:
|
|
.Bl -tag -width Er
|
|
.It Bq Er ESRCH
|
|
The
|
|
.Fa mbx
|
|
argument
|
|
is not
|
|
.Dv NULL
|
|
and the mailbox pointed to by
|
|
.Fa mbx
|
|
is not associated with any KSE in the process.
|
|
.It Bq Er ESRCH
|
|
The
|
|
.Fa mbx
|
|
argument
|
|
is
|
|
.Dv NULL
|
|
and the current KSE has no associated mailbox, i.e., the process is operating
|
|
in traditional, unthreaded mode.
|
|
.El
|
|
.Pp
|
|
The
|
|
.Fn kse_thr_interrupt
|
|
system call
|
|
will fail if:
|
|
.Bl -tag -width Er
|
|
.It Bq Er ESRCH
|
|
The thread corresponding to
|
|
.Fa tmbx
|
|
is neither currently assigned to any KSE in the process nor blocked in the
|
|
kernel.
|
|
.El
|
|
.Sh SEE ALSO
|
|
.Xr rfork 2 ,
|
|
.Xr pthread 3 ,
|
|
.Xr ucontext 3
|
|
.Rs
|
|
.%A "Thomas E. Anderson"
|
|
.%A "Brian N. Bershad"
|
|
.%A "Edward D. Lazowska"
|
|
.%A "Henry M. Levy"
|
|
.%J "ACM Transactions on Computer Systems"
|
|
.%N Issue 1
|
|
.%V Volume 10
|
|
.%D February 1992
|
|
.%I ACM Press
|
|
.%P pp. 53-79
|
|
.%T "Scheduler activations: effective kernel support for the user-level management of parallelism"
|
|
.Re
|
|
.Sh HISTORY
|
|
The KSE system calls first appeared in
|
|
.Fx 5.0 .
|
|
.Sh AUTHORS
|
|
KSE was originally implemented by
|
|
.An -nosplit
|
|
.An "Julian Elischer" Aq julian@FreeBSD.org ,
|
|
with additional contributions by
|
|
.An "Jonathan Mini" Aq mini@FreeBSD.org ,
|
|
.An "Daniel Eischen" Aq deischen@FreeBSD.org ,
|
|
and
|
|
.An "David Xu" Aq davidxu@FreeBSD.org .
|
|
.Pp
|
|
This manual page was written by
|
|
.An "Archie Cobbs" Aq archie@FreeBSD.org .
|
|
.Sh BUGS
|
|
The KSE code is
|
|
.Ud
|