table of contents
fi_domain(3) | #VERSION# | fi_domain(3) |
NAME¶
fi_domain - Open a fabric access domain
SYNOPSIS¶
-
#include <rdma/fabric.h> #include <rdma/fi_domain.h> int fi_domain(struct fid_fabric *fabric, struct fi_info *info,
struct fid_domain **domain, void *context); int fi_domain2(struct fid_fabric *fabric, struct fi_info *info,
struct fid_domain **domain, uint64_t flags, void *context); int fi_close(struct fid *domain); int fi_domain_bind(struct fid_domain *domain, struct fid *eq,
uint64_t flags); int fi_open_ops(struct fid *domain, const char *name, uint64_t flags,
void **ops, void *context); int fi_set_ops(struct fid *domain, const char *name, uint64_t flags,
void *ops, void *context);
ARGUMENTS¶
- fabric
- Fabric domain
- info
- Fabric information, including domain capabilities and attributes.
- domain
- An opened access domain.
- context
- User specified context associated with the domain. This context is returned as part of any asynchronous event associated with the domain.
- eq
- Event queue for asynchronous operations initiated on the domain.
- name
- Name associated with an interface.
- ops
- Fabric interface operations.
DESCRIPTION¶
An access domain typically refers to a physical or virtual NIC or hardware port; however, a domain may span across multiple hardware components for fail-over or data striping purposes. A domain defines the boundary for associating different resources together. Fabric resources belonging to the same domain may share resources.
fi_domain¶
Opens a fabric access domain, also referred to as a resource domain. Fabric domains are identified by a name. The properties of the opened domain are specified using the info parameter.
fi_domain2¶
Similar to fi_domain, but accepts an extra parameter flags. Mainly used for opening peer domain. See fi_peer(3).
fi_open_ops¶
fi_open_ops is used to open provider specific interfaces. Provider interfaces may be used to access low-level resources and operations that are specific to the opened resource domain. The details of domain interfaces are outside the scope of this documentation.
fi_set_ops¶
fi_set_ops assigns callbacks that a provider should invoke in place of performing selected tasks. This allows users to modify or control a provider’s default behavior. Conceptually, it allows the user to hook specific functions used by a provider and replace it with their own.
The operations being modified are identified using a well-known character string, passed as the name parameter. The format of the ops parameter is dependent upon the name value. The ops parameter will reference a structure containing the callbacks and other fields needed by the provider to invoke the user’s functions.
If a provider accepts the override, it will return FI_SUCCESS. If the override is unknown or not supported, the provider will return -FI_ENOSYS. Overrides should be set prior to allocating resources on the domain.
The following fi_set_ops operations and corresponding callback structures are defined.
FI_SET_OPS_HMEM_OVERRIDE – Heterogeneous Memory Overrides
HMEM override allows users to override HMEM related operations a provider may perform. Currently, the scope of the HMEM override is to allow a user to define the memory movement functions a provider should use when accessing a user buffer. The user-defined memory movement functions need to account for all the different HMEM iface types a provider may encounter.
All objects allocated against a domain will inherit this override.
The following is the HMEM override operation name and structure.
-
#define FI_SET_OPS_HMEM_OVERRIDE "hmem_override_ops" struct fi_hmem_override_ops {
size_t size;
ssize_t (*copy_from_hmem_iov)(void *dest, size_t size,
enum fi_hmem_iface iface, uint64_t device, const struct iovec *hmem_iov,
size_t hmem_iov_count, uint64_t hmem_iov_offset);
ssize_t (*copy_to_hmem_iov)(enum fi_hmem_iface iface, uint64_t device,
const struct iovec *hmem_iov, size_t hmem_iov_count,
uint64_t hmem_iov_offset, const void *src, size_t size); };
All fields in struct fi_hmem_override_ops must be set (non-null) to a valid value.
- size
- This should be set to the sizeof(struct fi_hmem_override_ops). The size field is used for forward and backward compatibility purposes.
- copy_from_hmem_iov
- Copy data from the device/hmem to host memory. This function should return a negative fi_errno on error, or the number of bytes copied on success.
- copy_to_hmem_iov
- Copy data from host memory to the device/hmem. This function should return a negative fi_errno on error, or the number of bytes copied on success.
fi_domain_bind¶
Associates an event queue with the domain. An event queue bound to a domain will be the default EQ associated with asynchronous control events that occur on the domain or active endpoints allocated on a domain. This includes CM events. Endpoints may direct their control events to alternate EQs by binding directly with the EQ.
Binding an event queue to a domain with the FI_REG_MR flag indicates that the provider should perform all memory registration operations asynchronously, with the completion reported through the event queue. If an event queue is not bound to the domain with the FI_REG_MR flag, then memory registration requests complete synchronously.
See fi_av_bind(3), fi_ep_bind(3), fi_mr_bind(3), fi_pep_bind(3), and fi_scalable_ep_bind(3) for more information.
fi_close¶
The fi_close call is used to release all resources associated with a domain or interface. All objects associated with the opened domain must be released prior to calling fi_close, otherwise the call will return -FI_EBUSY.
DOMAIN ATTRIBUTES¶
The fi_domain_attr structure defines the set of attributes associated with a domain.
-
struct fi_domain_attr {
struct fid_domain *domain;
char *name;
enum fi_threading threading;
enum fi_progress control_progress;
enum fi_progress data_progress;
enum fi_resource_mgmt resource_mgmt;
enum fi_av_type av_type;
int mr_mode;
size_t mr_key_size;
size_t cq_data_size;
size_t cq_cnt;
size_t ep_cnt;
size_t tx_ctx_cnt;
size_t rx_ctx_cnt;
size_t max_ep_tx_ctx;
size_t max_ep_rx_ctx;
size_t max_ep_stx_ctx;
size_t max_ep_srx_ctx;
size_t cntr_cnt;
size_t mr_iov_limit;
uint64_t caps;
uint64_t mode;
uint8_t *auth_key;
size_t auth_key_size;
size_t max_err_data;
size_t mr_cnt;
uint32_t tclass; };
domain¶
On input to fi_getinfo, a user may set this to an opened domain instance to restrict output to the given domain. On output from fi_getinfo, if no domain was specified, but the user has an opened instance of the named domain, this will reference the first opened instance. If no instance has been opened, this field will be NULL.
The domain instance returned by fi_getinfo should only be considered valid if the application does not close any domain instances from another thread while fi_getinfo is being processed.
Name¶
The name of the access domain.
Multi-threading Support (threading)¶
The threading model specifies the level of serialization required of an application when using the libfabric data transfer interfaces. Control interfaces are always considered thread safe, and may be accessed by multiple threads. Applications which can guarantee serialization in their access of provider allocated resources and interfaces enables a provider to eliminate lower-level locks.
- FI_THREAD_COMPLETION
- The completion threading model is intended for providers that make use of manual progress. Applications must serialize access to all objects that are associated through the use of having a shared completion structure. This includes endpoint, transmit context, receive context, completion queue, counter, wait set, and poll set objects.
For example, threads must serialize access to an endpoint and its bound completion queue(s) and/or counters. Access to endpoints that share the same completion queue must also be serialized.
The use of FI_THREAD_COMPLETION can increase parallelism over FI_THREAD_SAFE, but requires the use of isolated resources.
- FI_THREAD_DOMAIN
- A domain serialization model requires applications to serialize access to all objects belonging to a domain.
- FI_THREAD_ENDPOINT
- The endpoint threading model is similar to FI_THREAD_FID, but with the added restriction that serialization is required when accessing the same endpoint, even if multiple transmit and receive contexts are used. Conceptually, FI_THREAD_ENDPOINT maps well to providers that implement fabric services in hardware but use a single command queue to access different data flows.
- FI_THREAD_FID
- A fabric descriptor (FID) serialization model requires applications to serialize access to individual fabric resources associated with data transfer operations and completions. Multiple threads must be serialized when accessing the same endpoint, transmit context, receive context, completion queue, counter, wait set, or poll set. Serialization is required only by threads accessing the same object.
For example, one thread may be initiating a data transfer on an endpoint, while another thread reads from a completion queue associated with the endpoint.
Serialization to endpoint access is only required when accessing the same endpoint data flow. Multiple threads may initiate transfers on different transmit contexts of the same endpoint without serializing, and no serialization is required between the submission of data transmit requests and data receive operations.
In general, FI_THREAD_FID allows the provider to be implemented without needing internal locking when handling data transfers. Conceptually, FI_THREAD_FID maps well to providers that implement fabric services in hardware and provide separate command queues to different data flows.
- FI_THREAD_SAFE
- A thread safe serialization model allows a multi-threaded application to access any allocated resources through any interface without restriction. All providers are required to support FI_THREAD_SAFE.
- FI_THREAD_UNSPEC
- This value indicates that no threading model has been defined. It may be used on input hints to the fi_getinfo call. When specified, providers will return a threading model that allows for the greatest level of parallelism.
Progress Models (control_progress / data_progress)¶
Progress is the ability of the underlying implementation to complete processing of an asynchronous request. In many cases, the processing of an asynchronous request requires the use of the host processor. For example, a received message may need to be matched with the correct buffer, or a timed out request may need to be retransmitted. For performance reasons, it may be undesirable for the provider to allocate a thread for this purpose, which will compete with the application threads.
Control progress indicates the method that the provider uses to make progress on asynchronous control operations. Control operations are functions which do not directly involve the transfer of application data between endpoints. They include address vector, memory registration, and connection management routines.
Data progress indicates the method that the provider uses to make progress on data transfer operations. This includes message queue, RMA, tagged messaging, and atomic operations, along with their completion processing.
Progress frequently requires action being taken at both the transmitting and receiving sides of an operation. This is often a requirement for reliable transfers, as a result of retry and acknowledgement processing.
To balance between performance and ease of use, two progress models are defined.
- FI_PROGRESS_AUTO
- This progress model indicates that the provider will make forward progress on an asynchronous operation without further intervention by the application. When FI_PROGRESS_AUTO is provided as output to fi_getinfo in the absence of any progress hints, it often indicates that the desired functionality is implemented by the provider hardware or is a standard service of the operating system.
It is recommended that providers support FI_PROGRESS_AUTO. However, if a provider does not natively support automatic progress, forcing the use of FI_PROGRESS_AUTO may result in threads being allocated below the fabric interfaces.
Note that prior versions of the library required providers to support FI_PROGRESS_AUTO. However, in some cases progress threads cannot be blocked when communication is idle, which results in threads spinning in progress functions. As a result, those providers only supported FI_PROGRESS_MANUAL.
- FI_PROGRESS_MANUAL
- This progress model indicates that the provider requires the use of an application thread to complete an asynchronous request. When manual progress is set, the provider will attempt to advance an asynchronous operation forward when the application attempts to wait on or read an event queue, completion queue, or counter where the completed operation will be reported. Progress also occurs when the application processes a poll or wait set that has been associated with the event or completion queue.
Only wait operations defined by the fabric interface will result in an operation progressing. Operating system or external wait functions, such as select, poll, or pthread routines, cannot.
Manual progress requirements not only apply to endpoints that initiate transmit operations, but also to endpoints that may be the target of such operations. This holds true even if the target endpoint will not generate completion events for the operations. For example, an endpoint that acts purely as the target of RMA or atomic operations that uses manual progress may still need application assistance to process received operations.
- FI_PROGRESS_UNSPEC
- This value indicates that no progress model has been defined. It may be used on input hints to the fi_getinfo call.
Resource Management (resource_mgmt)¶
Resource management (RM) is provider and protocol support to protect against overrunning local and remote resources. This includes local and remote transmit contexts, receive contexts, completion queues, and source and target data buffers.
When enabled, applications are given some level of protection against overrunning provider queues and local and remote data buffers. Such support may be built directly into the hardware and/or network protocol, but may also require that checks be enabled in the provider software. By disabling resource management, an application assumes all responsibility for preventing queue and buffer overruns, but doing so may allow a provider to eliminate internal synchronization calls, such as atomic variables or locks.
It should be noted that even if resource management is disabled, the provider implementation and protocol may still provide some level of protection against overruns. However, such protection is not guaranteed. The following values for resource management are defined.
- FI_RM_DISABLED
- The provider is free to select an implementation and protocol that does not protect against resource overruns. The application is responsible for resource protection.
- FI_RM_ENABLED
- Resource management is enabled for this provider domain.
- FI_RM_UNSPEC
- This value indicates that no resource management model has been defined. It may be used on input hints to the fi_getinfo call.
The behavior of the various resource management options depends on whether the endpoint is reliable or unreliable, as well as provider and protocol specific implementation details, as shown in the following table. The table assumes that all peers enable or disable RM the same.
Resource | DGRAM EP-no RM | DGRAM EP-with RM | RDM/MSG EP-no RM | RDM/MSG EP-with RM |
Tx Ctx | undefined error | EAGAIN | undefined error | EAGAIN |
Rx Ctx | undefined error | EAGAIN | undefined error | EAGAIN |
Tx CQ | undefined error | EAGAIN | undefined error | EAGAIN |
Rx CQ | undefined error | EAGAIN | undefined error | EAGAIN |
Target EP | dropped | dropped | transmit error | retried |
No Rx Buffer | dropped | dropped | transmit error | retried |
Rx Buf Overrun | truncate or drop | truncate or drop | truncate or error | truncate or error |
Unmatched RMA | not applicable | not applicable | transmit error | transmit error |
RMA Overrun | not applicable | not applicable | transmit error | transmit error |
The resource column indicates the resource being accessed by a data transfer operation.
- Tx Ctx / Rx Ctx
- Refers to the transmit/receive contexts when a data transfer operation is submitted. When RM is enabled, attempting to submit a request will fail if the context is full. If RM is disabled, an undefined error (provider specific) will occur. Such errors should be considered fatal to the context, and applications must take steps to avoid queue overruns.
- Tx CQ / Rx CQ
- Refers to the completion queue associated with the Tx or Rx context when a local operation completes. When RM is disabled, applications must take care to ensure that completion queues do not get overrun. When an overrun occurs, an undefined, but fatal, error will occur affecting all endpoints associated with the CQ. Overruns can be avoided by sizing the CQs appropriately or by deferring the posting of a data transfer operation unless CQ space is available to store its completion. When RM is enabled, providers may use different mechanisms to prevent CQ overruns. This includes failing (returning -FI_EAGAIN) the posting of operations that could result in CQ overruns, or internally retrying requests (which will be hidden from the application). See notes at the end of this section regarding CQ resource management restrictions.
- Target EP / No Rx Buffer
- Target EP refers to resources associated with the endpoint that is the target of a transmit operation. This includes the target endpoint’s receive queue, posted receive buffers (no Rx buffers), the receive side completion queue, and other related packet processing queues. The defined behavior is that seen by the initiator of a request. For FI_EP_DGRAM endpoints, if the target EP queues are unable to accept incoming messages, received messages will be dropped. For reliable endpoints, if RM is disabled, the transmit operation will complete in error. A provider may choose to return an error completion with the error code FI_ENORX for that transmit operation so that it can be retried. If RM is enabled, the provider will internally retry the operation.
- Rx Buffer Overrun
- This refers to buffers posted to receive incoming tagged or untagged messages, with the behavior defined from the viewpoint of the sender. The behavior for handling received messages that are larger than the buffers provided by the application is provider specific. Providers may either truncate the message and report a successful completion, or fail the operation. For datagram endpoints, failed sends will result in the message being dropped. For reliable endpoints, send operations may complete successfully, yet be truncated at the receive side. This can occur when the target side buffers received data until an application buffer is made available. The completion status may also be dependent upon the completion model selected byt the application (e.g. FI_DELIVERY_COMPLETE versus FI_TRANSMIT_COMPLETE).
- Unmatched RMA / RMA Overrun
- Unmatched RMA and RMA overruns deal with the processing of RMA and atomic operations. Unlike send operations, RMA operations that attempt to access a memory address that is either not registered for such operations, or attempt to access outside of the target memory region will fail, resulting in a transmit error.
When a resource management error occurs on an endpoint, the endpoint is transitioned into a disabled state. Any operations which have not already completed will fail and be discarded. For connectionless endpoints, the endpoint must be re-enabled before it will accept new data transfer operations. For connected endpoints, the connection is torn down and must be re-established.
There is one notable restriction on the protections offered by resource management. This occurs when resource management is enabled on an endpoint that has been bound to completion queue(s) using the FI_SELECTIVE_COMPLETION flag. Operations posted to such an endpoint may specify that a successful completion should not generate a entry on the corresponding completion queue. (I.e. the operation leaves the FI_COMPLETION flag unset). In such situations, the provider is not required to reserve an entry in the completion queue to handle the case where the operation fails and does generate a CQ entry, which would effectively require tracking the operation to completion. Applications concerned with avoiding CQ overruns in the occurrence of errors must ensure that there is sufficient space in the CQ to report failed operations. This can typically be achieved by sizing the CQ to at least the same size as the endpoint queue(s) that are bound to it.
AV Type (av_type)¶
Specifies the type of address vectors that are usable with this domain. For additional details on AV type, see fi_av(3). The following values may be specified.
- FI_AV_MAP
- Only address vectors of type AV map are requested or supported.
- FI_AV_TABLE
- Only address vectors of type AV index are requested or supported.
- FI_AV_UNSPEC
- Any address vector format is requested and supported.
Address vectors are only used by connectionless endpoints. Applications that require the use of a specific type of address vector should set the domain attribute av_type to the necessary value when calling fi_getinfo. The value FI_AV_UNSPEC may be used to indicate that the provider can support either address vector format. In this case, a provider may return FI_AV_UNSPEC to indicate that either format is supportable, or may return another AV type to indicate the optimal AV type supported by this domain.
Memory Registration Mode (mr_mode)¶
Defines memory registration specific mode bits used with this domain. Full details on MR mode options are available in fi_mr(3). The following values may be specified.
- FI_MR_ALLOCATED
- Indicates that memory registration occurs on allocated data buffers, and physical pages must back all virtual addresses being registered.
- FI_MR_COLLECTIVE
- Requires data buffers passed to collective operations be explicitly registered for collective operations using the FI_COLLECTIVE flag.
- FI_MR_ENDPOINT
- Memory registration occurs at the endpoint level, rather than domain.
- FI_MR_LOCAL
- The provider is optimized around having applications register memory for locally accessed data buffers. Data buffers used in send and receive operations and as the source buffer for RMA and atomic operations must be registered by the application for access domains opened with this capability.
- FI_MR_MMU_NOTIFY
- Indicates that the application is responsible for notifying the provider when the page tables referencing a registered memory region may have been updated.
- FI_MR_PROV_KEY
- Memory registration keys are selected and returned by the provider.
- FI_MR_RAW
- The provider requires additional setup as part of their memory registration process. This mode is required by providers that use a memory key that is larger than 64-bits.
- FI_MR_RMA_EVENT
- Indicates that the memory regions associated with completion counters must be explicitly enabled after being bound to any counter.
- FI_MR_UNSPEC
- Defined for compatibility – library versions 1.4 and earlier. Setting mr_mode to 0 indicates that FI_MR_BASIC or FI_MR_SCALABLE are requested and supported.
- FI_MR_VIRT_ADDR
- Registered memory regions are referenced by peers using the virtual address of the registered memory region, rather than a 0-based offset.
- FI_MR_BASIC
- Defined for compatibility – library versions 1.4 and earlier. Only basic memory registration operations are requested or supported. This mode is equivalent to the FI_MR_VIRT_ADDR, FI_MR_ALLOCATED, and FI_MR_PROV_KEY flags being set in later library versions. This flag may not be used in conjunction with other mr_mode bits.
- FI_MR_SCALABLE
- Defined for compatibility – library versions 1.4 and earlier. Only scalable memory registration operations are requested or supported. Scalable registration uses offset based addressing, with application selectable memory keys. For library versions 1.5 and later, this is the default if no mr_mode bits are set. This flag may not be used in conjunction with other mr_mode bits.
Buffers used in data transfer operations may require notifying the provider of their use before a data transfer can occur. The mr_mode field indicates the type of memory registration that is required, and when registration is necessary. Applications that require the use of a specific registration mode should set the domain attribute mr_mode to the necessary value when calling fi_getinfo. The value FI_MR_UNSPEC may be used to indicate support for any registration mode.
MR Key Size (mr_key_size)¶
Size of the memory region remote access key, in bytes. Applications that request their own MR key must select a value within the range specified by this value. Key sizes larger than 8 bytes require using the FI_RAW_KEY mode bit.
CQ Data Size (cq_data_size)¶
Applications may include a small message with a data transfer that is placed directly into a remote completion queue as part of a completion event. This is referred to as remote CQ data (sometimes referred to as immediate data). This field indicates the number of bytes that the provider supports for remote CQ data. If supported (non-zero value is returned), the minimum size of remote CQ data must be at least 4-bytes.
Completion Queue Count (cq_cnt)¶
The optimal number of completion queues supported by the domain, relative to any specified or default CQ attributes. The cq_cnt value may be a fixed value of the maximum number of CQs supported by the underlying hardware, or may be a dynamic value, based on the default attributes of an allocated CQ, such as the CQ size and data format.
Endpoint Count (ep_cnt)¶
The total number of endpoints supported by the domain, relative to any specified or default endpoint attributes. The ep_cnt value may be a fixed value of the maximum number of endpoints supported by the underlying hardware, or may be a dynamic value, based on the default attributes of an allocated endpoint, such as the endpoint capabilities and size. The endpoint count is the number of addressable endpoints supported by the provider. Providers return capability limits based on configured hardware maximum capabilities. Providers cannot predict all possible system limitations without posteriori knowledge acquired during runtime that will further limit these hardware maximums (e.g. application memory consumption, FD usage, etc.).
Transmit Context Count (tx_ctx_cnt)¶
The number of outbound command queues optimally supported by the provider. For a low-level provider, this represents the number of command queues to the hardware and/or the number of parallel transmit engines effectively supported by the hardware and caches. Applications which allocate more transmit contexts than this value will end up sharing underlying resources. By default, there is a single transmit context associated with each endpoint, but in an advanced usage model, an endpoint may be configured with multiple transmit contexts.
Receive Context Count (rx_ctx_cnt)¶
The number of inbound processing queues optimally supported by the provider. For a low-level provider, this represents the number hardware queues that can be effectively utilized for processing incoming packets. Applications which allocate more receive contexts than this value will end up sharing underlying resources. By default, a single receive context is associated with each endpoint, but in an advanced usage model, an endpoint may be configured with multiple receive contexts.
Maximum Endpoint Transmit Context (max_ep_tx_ctx)¶
The maximum number of transmit contexts that may be associated with an endpoint.
Maximum Endpoint Receive Context (max_ep_rx_ctx)¶
The maximum number of receive contexts that may be associated with an endpoint.
Maximum Sharing of Transmit Context (max_ep_stx_ctx)¶
The maximum number of endpoints that may be associated with a shared transmit context.
Maximum Sharing of Receive Context (max_ep_srx_ctx)¶
The maximum number of endpoints that may be associated with a shared receive context.
Counter Count (cntr_cnt)¶
The optimal number of completion counters supported by the domain. The cq_cnt value may be a fixed value of the maximum number of counters supported by the underlying hardware, or may be a dynamic value, based on the default attributes of the domain.
MR IOV Limit (mr_iov_limit)¶
This is the maximum number of IO vectors (scatter-gather elements) that a single memory registration operation may reference.
Capabilities (caps)¶
Domain level capabilities. Domain capabilities indicate domain level features that are supported by the provider.
- FI_LOCAL_COMM
- At a conceptual level, this field indicates that the underlying device supports loopback communication. More specifically, this field indicates that an endpoint may communicate with other endpoints that are allocated from the same underlying named domain. If this field is not set, an application may need to use an alternate domain or mechanism (e.g. shared memory) to communicate with peers that execute on the same node.
- FI_REMOTE_COMM
- This field indicates that the underlying provider supports communication with nodes that are reachable over the network. If this field is not set, then the provider only supports communication between processes that execute on the same node – a shared memory provider, for example.
- FI_SHARED_AV
- Indicates that the domain supports the ability to share address vectors among multiple processes using the named address vector feature.
See fi_getinfo(3) for a discussion on primary versus secondary capabilities. All domain capabilities are considered secondary capabilities.
mode¶
The operational mode bit related to using the domain.
- FI_RESTRICTED_COMP
- This bit indicates that the domain limits completion queues and counters to only be used with endpoints, transmit contexts, and receive contexts that have the same set of capability flags.
Default authorization key (auth_key)¶
The default authorization key to associate with endpoint and memory registrations created within the domain. This field is ignored unless the fabric is opened with API version 1.5 or greater.
Default authorization key length (auth_key_size)¶
The length in bytes of the default authorization key for the domain. If set to 0, then no authorization key will be associated with endpoints and memory registrations created within the domain unless specified in the endpoint or memory registration attributes. This field is ignored unless the fabric is opened with API version 1.5 or greater.
Max Error Data Size (max_err_data)¶
: The maximum amount of error data, in bytes, that may be returned as part of a completion or event queue error. This value corresponds to the err_data_size field in struct fi_cq_err_entry and struct fi_eq_err_entry.
Memory Regions Count (mr_cnt)¶
The optimal number of memory regions supported by the domain, or endpoint if the mr_mode FI_MR_ENDPOINT bit has been set. The mr_cnt value may be a fixed value of the maximum number of MRs supported by the underlying hardware, or may be a dynamic value, based on the default attributes of the domain, such as the supported memory registration modes. Applications can set the mr_cnt on input to fi_getinfo, in order to indicate their memory registration requirements. Doing so may allow the provider to optimize any memory registration cache or lookup tables.
Traffic Class (tclass)¶
This specifies the default traffic class that will be associated any endpoints created within the domain. See fi_endpoint(3) for additional information.
RETURN VALUE¶
Returns 0 on success. On error, a negative value corresponding to fabric errno is returned. Fabric errno values are defined in rdma/fi_errno.h.
NOTES¶
Users should call fi_close to release all resources allocated to the fabric domain.
The following fabric resources are associated with domains: active endpoints, memory regions, completion event queues, and address vectors.
Domain attributes reflect the limitations and capabilities of the underlying hardware and/or software provider. They do not reflect system limitations, such as the number of physical pages that an application may pin or number of file descriptors that the application may open. As a result, the reported maximums may not be achievable, even on a lightly loaded systems, without an administrator configuring system resources appropriately for the installed provider(s).
SEE ALSO¶
fi_getinfo(3), fi_endpoint(3), fi_av(3), fi_eq(3), fi_mr(3) fi_peer(3)
AUTHORS¶
OpenFabrics.
2022-12-11 | Libfabric Programmer’s Manual |