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freebsd-dev/sys/compat/cloudabi/cloudabi_thread.c

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Import the CloudABI datatypes and create a system call table. CloudABI is a pure capability-based runtime environment for UNIX. It works similar to Capsicum, except that processes already run in capabilities mode on startup. All functionality that conflicts with this model has been omitted, making it a compact binary interface that can be supported by other operating systems without too much effort. CloudABI is 'secure by default'; the idea is that it should be safe to run arbitrary third-party binaries without requiring any explicit hardware virtualization (Bhyve) or namespace virtualization (Jails). The rights of an application are purely determined by the set of file descriptors that you grant it on startup. The datatypes and constants used by CloudABI's C library (cloudlibc) are defined in separate files called syscalldefs_mi.h (pointer size independent) and syscalldefs_md.h (pointer size dependent). We import these files in sys/contrib/cloudabi and wrap around them in cloudabi*_syscalldefs.h. We then add stubs for all of the system calls in sys/compat/cloudabi or sys/compat/cloudabi64, depending on whether the system call depends on the pointer size. We only have nine system calls that depend on the pointer size. If we ever want to support 32-bit binaries, we can simply add sys/compat/cloudabi32 and implement these nine system calls again. The next step is to send in code reviews for the individual system call implementations, but also add a sysentvec, to allow CloudABI executabled to be started through execve(). More information about CloudABI: - GitHub: https://github.com/NuxiNL/cloudlibc - Talk at BSDCan: https://www.youtube.com/watch?v=SVdF84x1EdA Differential Revision: https://reviews.freebsd.org/D2848 Reviewed by: emaste, brooks Obtained from: https://github.com/NuxiNL/freebsd
2015-07-09 07:20:15 +00:00
/*-
* Copyright (c) 2015 Nuxi, https://nuxi.nl/
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
Implement thread_tcb_set() and thread_yield(). The first system call is used to set the user TLS address. Right now this system call is invoked by the C library for both the initial thread and additional threads unconditionally, but in the future we'll only call this if the architecture does not support this. On recent x86-64 CPUs we could use the WRFSBASE instruction. This system call was erroneously placed in sys/compat/cloudabi64, even though it does not depend on any pointer size dependent datastructure. Move it to the right place. Obtained from: https://github.com/NuxiNL/freebsd
2015-07-14 15:11:50 +00:00
#include <sys/param.h>
#include <sys/proc.h>
#include <sys/sched.h>
Add a futex implementation for CloudABI. Summary: CloudABI provides two different types of futex objects: read-write locks and condition variables. There is no need to provide separate support for once objects and thread joining, as these are efficiently simulated by blocking on a read-write lock. Mutexes simply use read-write locks. Condition variables always have a lock object associated to them. They always know to which lock a thread needs to be migrated if woken up. This allows us to implement requeueing. A broadcast on a condition variable will never cause multiple threads to be woken up at once. They will be woken up iteratively. This implementation still has lots of room for improvement. Locking is coarse and right now we use linked lists to store all of the locks and condition variables, instead of using a hash table. The primary goal of this implementation was to behave correctly. Performance will be improved as we go. Test Plan: This futex implementation has been in use for the last couple of months and seems to work pretty well. All of the cloudlibc and libc++ unit tests seem to pass. Reviewers: dchagin, kib, vangyzen Subscribers: imp Differential Revision: https://reviews.freebsd.org/D3148
2015-07-27 10:07:29 +00:00
#include <sys/syscallsubr.h>
Implement thread_tcb_set() and thread_yield(). The first system call is used to set the user TLS address. Right now this system call is invoked by the C library for both the initial thread and additional threads unconditionally, but in the future we'll only call this if the architecture does not support this. On recent x86-64 CPUs we could use the WRFSBASE instruction. This system call was erroneously placed in sys/compat/cloudabi64, even though it does not depend on any pointer size dependent datastructure. Move it to the right place. Obtained from: https://github.com/NuxiNL/freebsd
2015-07-14 15:11:50 +00:00
Replace the CloudABI system call table by a machine generated version. The type definitions and constants that were used by COMPAT_CLOUDABI64 are a literal copy of some headers stored inside of CloudABI's C library, cloudlibc. What is annoying is that we can't make use of cloudlibc's system call list, as the format is completely different and doesn't provide enough information. It had to be synced in manually. We recently decided to solve this (and some other problems) by moving the ABI definitions into a separate file: https://github.com/NuxiNL/cloudabi/blob/master/cloudabi.txt This file is processed by a pile of Python scripts to generate the header files like before, documentation (markdown), but in our case more importantly: a FreeBSD system call table. This change discards the old files in sys/contrib/cloudabi and replaces them by the latest copies, which requires some minor changes here and there. Because cloudabi.txt also enforces consistent names of the system call arguments, we have to patch up a small number of system call implementations to use the new argument names. The new header files can also be included directly in FreeBSD kernel space without needing any includes/defines, so we can now remove cloudabi_syscalldefs.h and cloudabi64_syscalldefs.h. Patch up the sources to include the definitions directly from sys/contrib/cloudabi instead.
2016-03-24 21:47:15 +00:00
#include <contrib/cloudabi/cloudabi_types_common.h>
Import the CloudABI datatypes and create a system call table. CloudABI is a pure capability-based runtime environment for UNIX. It works similar to Capsicum, except that processes already run in capabilities mode on startup. All functionality that conflicts with this model has been omitted, making it a compact binary interface that can be supported by other operating systems without too much effort. CloudABI is 'secure by default'; the idea is that it should be safe to run arbitrary third-party binaries without requiring any explicit hardware virtualization (Bhyve) or namespace virtualization (Jails). The rights of an application are purely determined by the set of file descriptors that you grant it on startup. The datatypes and constants used by CloudABI's C library (cloudlibc) are defined in separate files called syscalldefs_mi.h (pointer size independent) and syscalldefs_md.h (pointer size dependent). We import these files in sys/contrib/cloudabi and wrap around them in cloudabi*_syscalldefs.h. We then add stubs for all of the system calls in sys/compat/cloudabi or sys/compat/cloudabi64, depending on whether the system call depends on the pointer size. We only have nine system calls that depend on the pointer size. If we ever want to support 32-bit binaries, we can simply add sys/compat/cloudabi32 and implement these nine system calls again. The next step is to send in code reviews for the individual system call implementations, but also add a sysentvec, to allow CloudABI executabled to be started through execve(). More information about CloudABI: - GitHub: https://github.com/NuxiNL/cloudlibc - Talk at BSDCan: https://www.youtube.com/watch?v=SVdF84x1EdA Differential Revision: https://reviews.freebsd.org/D2848 Reviewed by: emaste, brooks Obtained from: https://github.com/NuxiNL/freebsd
2015-07-09 07:20:15 +00:00
#include <compat/cloudabi/cloudabi_proto.h>
int
cloudabi_sys_thread_exit(struct thread *td,
struct cloudabi_sys_thread_exit_args *uap)
{
Add a futex implementation for CloudABI. Summary: CloudABI provides two different types of futex objects: read-write locks and condition variables. There is no need to provide separate support for once objects and thread joining, as these are efficiently simulated by blocking on a read-write lock. Mutexes simply use read-write locks. Condition variables always have a lock object associated to them. They always know to which lock a thread needs to be migrated if woken up. This allows us to implement requeueing. A broadcast on a condition variable will never cause multiple threads to be woken up at once. They will be woken up iteratively. This implementation still has lots of room for improvement. Locking is coarse and right now we use linked lists to store all of the locks and condition variables, instead of using a hash table. The primary goal of this implementation was to behave correctly. Performance will be improved as we go. Test Plan: This futex implementation has been in use for the last couple of months and seems to work pretty well. All of the cloudlibc and libc++ unit tests seem to pass. Reviewers: dchagin, kib, vangyzen Subscribers: imp Differential Revision: https://reviews.freebsd.org/D3148
2015-07-27 10:07:29 +00:00
struct cloudabi_sys_lock_unlock_args cloudabi_sys_lock_unlock_args = {
.lock = uap->lock,
.scope = uap->scope,
};
Import the CloudABI datatypes and create a system call table. CloudABI is a pure capability-based runtime environment for UNIX. It works similar to Capsicum, except that processes already run in capabilities mode on startup. All functionality that conflicts with this model has been omitted, making it a compact binary interface that can be supported by other operating systems without too much effort. CloudABI is 'secure by default'; the idea is that it should be safe to run arbitrary third-party binaries without requiring any explicit hardware virtualization (Bhyve) or namespace virtualization (Jails). The rights of an application are purely determined by the set of file descriptors that you grant it on startup. The datatypes and constants used by CloudABI's C library (cloudlibc) are defined in separate files called syscalldefs_mi.h (pointer size independent) and syscalldefs_md.h (pointer size dependent). We import these files in sys/contrib/cloudabi and wrap around them in cloudabi*_syscalldefs.h. We then add stubs for all of the system calls in sys/compat/cloudabi or sys/compat/cloudabi64, depending on whether the system call depends on the pointer size. We only have nine system calls that depend on the pointer size. If we ever want to support 32-bit binaries, we can simply add sys/compat/cloudabi32 and implement these nine system calls again. The next step is to send in code reviews for the individual system call implementations, but also add a sysentvec, to allow CloudABI executabled to be started through execve(). More information about CloudABI: - GitHub: https://github.com/NuxiNL/cloudlibc - Talk at BSDCan: https://www.youtube.com/watch?v=SVdF84x1EdA Differential Revision: https://reviews.freebsd.org/D2848 Reviewed by: emaste, brooks Obtained from: https://github.com/NuxiNL/freebsd
2015-07-09 07:20:15 +00:00
Add a futex implementation for CloudABI. Summary: CloudABI provides two different types of futex objects: read-write locks and condition variables. There is no need to provide separate support for once objects and thread joining, as these are efficiently simulated by blocking on a read-write lock. Mutexes simply use read-write locks. Condition variables always have a lock object associated to them. They always know to which lock a thread needs to be migrated if woken up. This allows us to implement requeueing. A broadcast on a condition variable will never cause multiple threads to be woken up at once. They will be woken up iteratively. This implementation still has lots of room for improvement. Locking is coarse and right now we use linked lists to store all of the locks and condition variables, instead of using a hash table. The primary goal of this implementation was to behave correctly. Performance will be improved as we go. Test Plan: This futex implementation has been in use for the last couple of months and seems to work pretty well. All of the cloudlibc and libc++ unit tests seem to pass. Reviewers: dchagin, kib, vangyzen Subscribers: imp Differential Revision: https://reviews.freebsd.org/D3148
2015-07-27 10:07:29 +00:00
/* Wake up joining thread. */
cloudabi_sys_lock_unlock(td, &cloudabi_sys_lock_unlock_args);
/*
* Attempt to terminate the thread. Terminate the process if
* it's the last thread.
*/
kern_thr_exit(td);
exit1(td, 0, 0);
/* NOTREACHED */
Import the CloudABI datatypes and create a system call table. CloudABI is a pure capability-based runtime environment for UNIX. It works similar to Capsicum, except that processes already run in capabilities mode on startup. All functionality that conflicts with this model has been omitted, making it a compact binary interface that can be supported by other operating systems without too much effort. CloudABI is 'secure by default'; the idea is that it should be safe to run arbitrary third-party binaries without requiring any explicit hardware virtualization (Bhyve) or namespace virtualization (Jails). The rights of an application are purely determined by the set of file descriptors that you grant it on startup. The datatypes and constants used by CloudABI's C library (cloudlibc) are defined in separate files called syscalldefs_mi.h (pointer size independent) and syscalldefs_md.h (pointer size dependent). We import these files in sys/contrib/cloudabi and wrap around them in cloudabi*_syscalldefs.h. We then add stubs for all of the system calls in sys/compat/cloudabi or sys/compat/cloudabi64, depending on whether the system call depends on the pointer size. We only have nine system calls that depend on the pointer size. If we ever want to support 32-bit binaries, we can simply add sys/compat/cloudabi32 and implement these nine system calls again. The next step is to send in code reviews for the individual system call implementations, but also add a sysentvec, to allow CloudABI executabled to be started through execve(). More information about CloudABI: - GitHub: https://github.com/NuxiNL/cloudlibc - Talk at BSDCan: https://www.youtube.com/watch?v=SVdF84x1EdA Differential Revision: https://reviews.freebsd.org/D2848 Reviewed by: emaste, brooks Obtained from: https://github.com/NuxiNL/freebsd
2015-07-09 07:20:15 +00:00
}
Implement thread_tcb_set() and thread_yield(). The first system call is used to set the user TLS address. Right now this system call is invoked by the C library for both the initial thread and additional threads unconditionally, but in the future we'll only call this if the architecture does not support this. On recent x86-64 CPUs we could use the WRFSBASE instruction. This system call was erroneously placed in sys/compat/cloudabi64, even though it does not depend on any pointer size dependent datastructure. Move it to the right place. Obtained from: https://github.com/NuxiNL/freebsd
2015-07-14 15:11:50 +00:00
int
cloudabi_sys_thread_tcb_set(struct thread *td,
struct cloudabi_sys_thread_tcb_set_args *uap)
{
return (cpu_set_user_tls(td, uap->tcb));
}
Import the CloudABI datatypes and create a system call table. CloudABI is a pure capability-based runtime environment for UNIX. It works similar to Capsicum, except that processes already run in capabilities mode on startup. All functionality that conflicts with this model has been omitted, making it a compact binary interface that can be supported by other operating systems without too much effort. CloudABI is 'secure by default'; the idea is that it should be safe to run arbitrary third-party binaries without requiring any explicit hardware virtualization (Bhyve) or namespace virtualization (Jails). The rights of an application are purely determined by the set of file descriptors that you grant it on startup. The datatypes and constants used by CloudABI's C library (cloudlibc) are defined in separate files called syscalldefs_mi.h (pointer size independent) and syscalldefs_md.h (pointer size dependent). We import these files in sys/contrib/cloudabi and wrap around them in cloudabi*_syscalldefs.h. We then add stubs for all of the system calls in sys/compat/cloudabi or sys/compat/cloudabi64, depending on whether the system call depends on the pointer size. We only have nine system calls that depend on the pointer size. If we ever want to support 32-bit binaries, we can simply add sys/compat/cloudabi32 and implement these nine system calls again. The next step is to send in code reviews for the individual system call implementations, but also add a sysentvec, to allow CloudABI executabled to be started through execve(). More information about CloudABI: - GitHub: https://github.com/NuxiNL/cloudlibc - Talk at BSDCan: https://www.youtube.com/watch?v=SVdF84x1EdA Differential Revision: https://reviews.freebsd.org/D2848 Reviewed by: emaste, brooks Obtained from: https://github.com/NuxiNL/freebsd
2015-07-09 07:20:15 +00:00
int
cloudabi_sys_thread_yield(struct thread *td,
struct cloudabi_sys_thread_yield_args *uap)
{
Implement thread_tcb_set() and thread_yield(). The first system call is used to set the user TLS address. Right now this system call is invoked by the C library for both the initial thread and additional threads unconditionally, but in the future we'll only call this if the architecture does not support this. On recent x86-64 CPUs we could use the WRFSBASE instruction. This system call was erroneously placed in sys/compat/cloudabi64, even though it does not depend on any pointer size dependent datastructure. Move it to the right place. Obtained from: https://github.com/NuxiNL/freebsd
2015-07-14 15:11:50 +00:00
sched_relinquish(td);
return (0);
Import the CloudABI datatypes and create a system call table. CloudABI is a pure capability-based runtime environment for UNIX. It works similar to Capsicum, except that processes already run in capabilities mode on startup. All functionality that conflicts with this model has been omitted, making it a compact binary interface that can be supported by other operating systems without too much effort. CloudABI is 'secure by default'; the idea is that it should be safe to run arbitrary third-party binaries without requiring any explicit hardware virtualization (Bhyve) or namespace virtualization (Jails). The rights of an application are purely determined by the set of file descriptors that you grant it on startup. The datatypes and constants used by CloudABI's C library (cloudlibc) are defined in separate files called syscalldefs_mi.h (pointer size independent) and syscalldefs_md.h (pointer size dependent). We import these files in sys/contrib/cloudabi and wrap around them in cloudabi*_syscalldefs.h. We then add stubs for all of the system calls in sys/compat/cloudabi or sys/compat/cloudabi64, depending on whether the system call depends on the pointer size. We only have nine system calls that depend on the pointer size. If we ever want to support 32-bit binaries, we can simply add sys/compat/cloudabi32 and implement these nine system calls again. The next step is to send in code reviews for the individual system call implementations, but also add a sysentvec, to allow CloudABI executabled to be started through execve(). More information about CloudABI: - GitHub: https://github.com/NuxiNL/cloudlibc - Talk at BSDCan: https://www.youtube.com/watch?v=SVdF84x1EdA Differential Revision: https://reviews.freebsd.org/D2848 Reviewed by: emaste, brooks Obtained from: https://github.com/NuxiNL/freebsd
2015-07-09 07:20:15 +00:00
}
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