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io_uring_setup(2) Linux Programmer's Manual io_uring_setup(2)

NAME

io_uring_setup - setup a context for performing asynchronous I/O

SYNOPSIS

#include <liburing.h>
int io_uring_setup(u32 entries, struct io_uring_params *p);

DESCRIPTION

The io_uring_setup(2) system call sets up a submission queue (SQ) and completion queue (CQ) with at least entries entries, and returns a file descriptor which can be used to perform subsequent operations on the io_uring instance. The submission and completion queues are shared between userspace and the kernel, which eliminates the need to copy data when initiating and completing I/O.

params is used by the application to pass options to the kernel, and by the kernel to convey information about the ring buffers.


struct io_uring_params {

__u32 sq_entries;
__u32 cq_entries;
__u32 flags;
__u32 sq_thread_cpu;
__u32 sq_thread_idle;
__u32 features;
__u32 wq_fd;
__u32 resv[3];
struct io_sqring_offsets sq_off;
struct io_cqring_offsets cq_off; };

The flags, sq_thread_cpu, and sq_thread_idle fields are used to configure the io_uring instance. flags is a bit mask of 0 or more of the following values ORed together:

Perform busy-waiting for an I/O completion, as opposed to getting notifications via an asynchronous IRQ (Interrupt Request). The file system (if any) and block device must support polling in order for this to work. Busy-waiting provides lower latency, but may consume more CPU resources than interrupt driven I/O. Currently, this feature is usable only on a file descriptor opened using the O_DIRECT flag. When a read or write is submitted to a polled context, the application must poll for completions on the CQ ring by calling io_uring_enter(2). It is illegal to mix and match polled and non-polled I/O on an io_uring instance.

When this flag is specified, a kernel thread is created to perform submission queue polling. An io_uring instance configured in this way enables an application to issue I/O without ever context switching into the kernel. By using the submission queue to fill in new submission queue entries and watching for completions on the completion queue, the application can submit and reap I/Os without doing a single system call.

If the kernel thread is idle for more than sq_thread_idle milliseconds, it will set the IORING_SQ_NEED_WAKEUP bit in the flags field of the struct io_sq_ring. When this happens, the application must call io_uring_enter(2) to wake the kernel thread. If I/O is kept busy, the kernel thread will never sleep. An application making use of this feature will need to guard the io_uring_enter(2) call with the following code sequence:


/*

* Ensure that the wakeup flag is read after the tail pointer
* has been written. It's important to use memory load acquire
* semantics for the flags read, as otherwise the application
* and the kernel might not agree on the consistency of the
* wakeup flag.
*/ unsigned flags = atomic_load_relaxed(sq_ring->flags); if (flags & IORING_SQ_NEED_WAKEUP)
io_uring_enter(fd, 0, 0, IORING_ENTER_SQ_WAKEUP);

where sq_ring is a submission queue ring setup using the struct io_sqring_offsets described below.

Before version 5.11 of the Linux kernel, to successfully use this feature, the application must register a set of files to be used for IO through io_uring_register(2) using the IORING_REGISTER_FILES opcode. Failure to do so will result in submitted IO being errored with EBADF. The presence of this feature can be detected by the IORING_FEAT_SQPOLL_NONFIXED feature flag. In version 5.11 and later, it is no longer necessary to register files to use this feature. 5.11 also allows using this as non-root, if the user has the CAP_SYS_NICE capability.
If this flag is specified, then the poll thread will be bound to the cpu set in the sq_thread_cpu field of the struct io_uring_params. This flag is only meaningful when IORING_SETUP_SQPOLL is specified. When cgroup setting cpuset.cpus changes (typically in container environment), the bounded cpu set may be changed as well.
Create the completion queue with struct io_uring_params.cq_entries entries. The value must be greater than entries, and may be rounded up to the next power-of-two.
If this flag is specified, and if entries exceeds IORING_MAX_ENTRIES , then entries will be clamped at IORING_MAX_ENTRIES . If the flag IORING_SETUP_SQPOLL is set, and if the value of struct io_uring_params.cq_entries exceeds IORING_MAX_CQ_ENTRIES , then it will be clamped at IORING_MAX_CQ_ENTRIES .
This flag should be set in conjunction with struct io_uring_params.wq_fd being set to an existing io_uring ring file descriptor. When set, the io_uring instance being created will share the asynchronous worker thread backend of the specified io_uring ring, rather than create a new separate thread pool.
If this flag is specified, the io_uring ring starts in a disabled state. In this state, restrictions can be registered, but submissions are not allowed. See io_uring_register(2) for details on how to enable the ring. Available since 5.10.
Normally io_uring stops submitting a batch of request, if one of these requests results in an error. This can cause submission of less than what is expected, if a request ends in error while being submitted. If the ring is created with this flag, io_uring_enter(2) will continue submitting requests even if it encounters an error submitting a request. CQEs are still posted for errored request regardless of whether or not this flag is set at ring creation time, the only difference is if the submit sequence is halted or continued when an error is observed. Available since 5.18.
By default, io_uring will interrupt a task running in userspace when a completion event comes in. This is to ensure that completions run in a timely manner. For a lot of use cases, this is overkill and can cause reduced performance from both the inter-processor interrupt used to do this, the kernel/user transition, the needless interruption of the tasks userspace activities, and reduced batching if completions come in at a rapid rate. Most applications don't need the forceful interruption, as the events are processed at any kernel/user transition. The exception are setups where the application uses multiple threads operating on the same ring, where the application waiting on completions isn't the one that submitted them. For most other use cases, setting this flag will improve performance. Available since 5.19.
Used in conjunction with IORING_SETUP_COOP_TASKRUN, this provides a flag, IORING_SQ_TASKRUN, which is set in the SQ ring flags whenever completions are pending that should be processed. liburing will check for this flag even when doing io_uring_peek_cqe(3) and enter the kernel to process them, and applications can do the same. This makes IORING_SETUP_TASKRUN_FLAG safe to use even when applications rely on a peek style operation on the CQ ring to see if anything might be pending to reap. Available since 5.19.
If set, io_uring will use 128-byte SQEs rather than the normal 64-byte sized variant. This is a requirement for using certain request types, as of 5.19 only the IORING_OP_URING_CMD passthrough command for NVMe passthrough needs this. Available since 5.19.
If set, io_uring will use 32-byte CQEs rather than the normal 16-byte sized variant. This is a requirement for using certain request types, as of 5.19 only the IORING_OP_URING_CMD passthrough command for NVMe passthrough needs this. Available since 5.19.
A hint to the kernel that only a single task (or thread) will submit requests, which is used for internal optimisations. The submission task is either the task that created the ring, or if IORING_SETUP_R_DISABLED is specified then it is the task that enables the ring through io_uring_register(2). The kernel enforces this rule, failing requests with -EEXIST if the restriction is violated. Note that when IORING_SETUP_SQPOLL is set it is considered that the polling task is doing all submissions on behalf of the userspace and so it always complies with the rule disregarding how many userspace tasks do io_uring_enter(2). Available since 6.0.
By default, io_uring will process all outstanding work at the end of any system call or thread interrupt. This can delay the application from making other progress. Setting this flag will hint to io_uring that it should defer work until an io_uring_enter(2) call with the IORING_ENTER_GETEVENTS flag set. This allows the application to request work to run just before it wants to process completions. This flag requires the IORING_SETUP_SINGLE_ISSUER flag to be set, and also enforces that the call to io_uring_enter(2) is called from the same thread that submitted requests. Note that if this flag is set then it is the application's responsibility to periodically trigger work (for example via any of the CQE waiting functions) or else completions may not be delivered. Available since 6.1.

If no flags are specified, the io_uring instance is setup for interrupt driven I/O. I/O may be submitted using io_uring_enter(2) and can be reaped by polling the completion queue.

The resv array must be initialized to zero.

features is filled in by the kernel, which specifies various features supported by current kernel version.

If this flag is set, the two SQ and CQ rings can be mapped with a single mmap(2) call. The SQEs must still be allocated separately. This brings the necessary mmap(2) calls down from three to two. Available since kernel 5.4.
If this flag is set, io_uring supports almost never dropping completion events. If a completion event occurs and the CQ ring is full, the kernel stores the event internally until such a time that the CQ ring has room for more entries. If this overflow condition is entered, attempting to submit more IO will fail with the -EBUSY error value, if it can't flush the overflown events to the CQ ring. If this happens, the application must reap events from the CQ ring and attempt the submit again. If the kernel has no free memory to store the event internally it will be visible by an increase in the overflow value on the cqring. Available since kernel 5.5. Additionally io_uring_enter(2) will return -EBADR the next time it would otherwise sleep waiting for completions (since kernel 5.19).

If this flag is set, applications can be certain that any data for async offload has been consumed when the kernel has consumed the SQE. Available since kernel 5.5.
If this flag is set, applications can specify offset == -1 with IORING_OP_{READV,WRITEV} , IORING_OP_{READ,WRITE}_FIXED , and IORING_OP_{READ,WRITE} to mean current file position, which behaves like preadv2(2) and pwritev2(2) with offset == -1. It'll use (and update) the current file position. This obviously comes with the caveat that if the application has multiple reads or writes in flight, then the end result will not be as expected. This is similar to threads sharing a file descriptor and doing IO using the current file position. Available since kernel 5.6.
If this flag is set, then io_uring guarantees that both sync and async execution of a request assumes the credentials of the task that called io_uring_enter(2) to queue the requests. If this flag isn't set, then requests are issued with the credentials of the task that originally registered the io_uring. If only one task is using a ring, then this flag doesn't matter as the credentials will always be the same. Note that this is the default behavior, tasks can still register different personalities through io_uring_register(2) with IORING_REGISTER_PERSONALITY and specify the personality to use in the sqe. Available since kernel 5.6.
If this flag is set, then io_uring supports using an internal poll mechanism to drive data/space readiness. This means that requests that cannot read or write data to a file no longer need to be punted to an async thread for handling, instead they will begin operation when the file is ready. This is similar to doing poll + read/write in userspace, but eliminates the need to do so. If this flag is set, requests waiting on space/data consume a lot less resources doing so as they are not blocking a thread. Available since kernel 5.7.
If this flag is set, the IORING_OP_POLL_ADD command accepts the full 32-bit range of epoll based flags. Most notably EPOLLEXCLUSIVE which allows exclusive (waking single waiters) behavior. Available since kernel 5.9.
If this flag is set, the IORING_SETUP_SQPOLL feature no longer requires the use of fixed files. Any normal file descriptor can be used for IO commands without needing registration. Available since kernel 5.11.
If this flag is set, then the io_uring_enter(2) system call supports passing in an extended argument instead of just the sigset_t of earlier kernels. This. extended argument is of type struct io_uring_getevents_arg and allows the caller to pass in both a sigset_t and a timeout argument for waiting on events. The struct layout is as follows:
struct io_uring_getevents_arg {

__u64 sigmask;
__u32 sigmask_sz;
__u32 pad;
__u64 ts; };

and a pointer to this struct must be passed in if IORING_ENTER_EXT_ARG is set in the flags for the enter system call. Available since kernel 5.11.

If this flag is set, io_uring is using native workers for its async helpers. Previous kernels used kernel threads that assumed the identity of the original io_uring owning task, but later kernels will actively create what looks more like regular process threads instead. Available since kernel 5.12.
If this flag is set, then io_uring supports a variety of features related to fixed files and buffers. In particular, it indicates that registered buffers can be updated in-place, whereas before the full set would have to be unregistered first. Available since kernel 5.13.
If this flag is set, then io_uring supports setting IOSQE_CQE_SKIP_SUCCESS in the submitted SQE, indicating that no CQE should be generated for this SQE if it executes normally. If an error happens processing the SQE, a CQE with the appropriate error value will still be generated. Available since kernel 5.17.
If this flag is set, then io_uring supports sane assignment of files for SQEs that have dependencies. For example, if a chain of SQEs are submitted with IOSQE_IO_LINK, then kernels without this flag will prepare the file for each link upfront. If a previous link opens a file with a known index, eg if direct descriptors are used with open or accept, then file assignment needs to happen post execution of that SQE. If this flag is set, then the kernel will defer file assignment until execution of a given request is started. Available since kernel 5.17.

The rest of the fields in the struct io_uring_params are filled in by the kernel, and provide the information necessary to memory map the submission queue, completion queue, and the array of submission queue entries. sq_entries specifies the number of submission queue entries allocated. sq_off describes the offsets of various ring buffer fields:


struct io_sqring_offsets {

__u32 head;
__u32 tail;
__u32 ring_mask;
__u32 ring_entries;
__u32 flags;
__u32 dropped;
__u32 array;
__u32 resv[3]; };

Taken together, sq_entries and sq_off provide all of the information necessary for accessing the submission queue ring buffer and the submission queue entry array. The submission queue can be mapped with a call like:


ptr = mmap(0, sq_off.array + sq_entries * sizeof(__u32),

PROT_READ|PROT_WRITE, MAP_SHARED|MAP_POPULATE,
ring_fd, IORING_OFF_SQ_RING);

where sq_off is the io_sqring_offsets structure, and ring_fd is the file descriptor returned from io_uring_setup(2). The addition of sq_off.array to the length of the region accounts for the fact that the ring located at the end of the data structure. As an example, the ring buffer head pointer can be accessed by adding sq_off.head to the address returned from mmap(2):


head = ptr + sq_off.head;

The flags field is used by the kernel to communicate state information to the application. Currently, it is used to inform the application when a call to io_uring_enter(2) is necessary. See the documentation for the IORING_SETUP_SQPOLL flag above. The dropped member is incremented for each invalid submission queue entry encountered in the ring buffer.

The head and tail track the ring buffer state. The tail is incremented by the application when submitting new I/O, and the head is incremented by the kernel when the I/O has been successfully submitted. Determining the index of the head or tail into the ring is accomplished by applying a mask:


index = tail & ring_mask;

The array of submission queue entries is mapped with:


sqentries = mmap(0, sq_entries * sizeof(struct io_uring_sqe),

PROT_READ|PROT_WRITE, MAP_SHARED|MAP_POPULATE,
ring_fd, IORING_OFF_SQES);

The completion queue is described by cq_entries and cq_off shown here:


struct io_cqring_offsets {

__u32 head;
__u32 tail;
__u32 ring_mask;
__u32 ring_entries;
__u32 overflow;
__u32 cqes;
__u32 flags;
__u32 resv[3]; };

The completion queue is simpler, since the entries are not separated from the queue itself, and can be mapped with:


ptr = mmap(0, cq_off.cqes + cq_entries * sizeof(struct io_uring_cqe),

PROT_READ|PROT_WRITE, MAP_SHARED|MAP_POPULATE, ring_fd,
IORING_OFF_CQ_RING);

Closing the file descriptor returned by io_uring_setup(2) will free all resources associated with the io_uring context.

RETURN VALUE

io_uring_setup(2) returns a new file descriptor on success. The application may then provide the file descriptor in a subsequent mmap(2) call to map the submission and completion queues, or to the io_uring_register(2) or io_uring_enter(2) system calls.

On error, a negative error code is returned. The caller should not rely on errno variable.

ERRORS

params is outside your accessible address space.
The resv array contains non-zero data, p.flags contains an unsupported flag, entries is out of bounds, IORING_SETUP_SQ_AFF was specified, but IORING_SETUP_SQPOLL was not, or IORING_SETUP_CQSIZE was specified, but io_uring_params.cq_entries was invalid.
The per-process limit on the number of open file descriptors has been reached (see the description of RLIMIT_NOFILE in getrlimit(2)).
The system-wide limit on the total number of open files has been reached.
Insufficient kernel resources are available.
IORING_SETUP_SQPOLL was specified, but the effective user ID of the caller did not have sufficient privileges.

SEE ALSO

io_uring_register(2), io_uring_enter(2)

2019-01-29 Linux