Provided by: libfabric-dev_1.17.0-3ubuntu1_amd64 bug

NAME

       fi_msg - Message data transfer operations

       fi_recv / fi_recvv / fi_recvmsg
              Post a buffer to receive an incoming message

       fi_send  / fi_sendv / fi_sendmsg fi_inject / fi_senddata : Initiate an operation to send a
       message

SYNOPSIS

              #include <rdma/fi_endpoint.h>

              ssize_t fi_recv(struct fid_ep *ep, void * buf, size_t len,
                  void *desc, fi_addr_t src_addr, void *context);

              ssize_t fi_recvv(struct fid_ep *ep, const struct iovec *iov, void **desc,
                  size_t count, fi_addr_t src_addr, void *context);

              ssize_t fi_recvmsg(struct fid_ep *ep, const struct fi_msg *msg,
                  uint64_t flags);

              ssize_t fi_send(struct fid_ep *ep, const void *buf, size_t len,
                  void *desc, fi_addr_t dest_addr, void *context);

              ssize_t fi_sendv(struct fid_ep *ep, const struct iovec *iov,
                  void **desc, size_t count, fi_addr_t dest_addr, void *context);

              ssize_t fi_sendmsg(struct fid_ep *ep, const struct fi_msg *msg,
                  uint64_t flags);

              ssize_t fi_inject(struct fid_ep *ep, const void *buf, size_t len,
                  fi_addr_t dest_addr);

              ssize_t fi_senddata(struct fid_ep *ep, const void *buf, size_t len,
                  void *desc, uint64_t data, fi_addr_t dest_addr, void *context);

              ssize_t fi_injectdata(struct fid_ep *ep, const void *buf, size_t len,
                  uint64_t data, fi_addr_t dest_addr);

ARGUMENTS

       ep     Fabric endpoint on which to initiate send or post receive buffer.

       buf    Data buffer to send or receive.

       len    Length of data buffer to send or receive, specified in bytes.  Valid transfers  are
              from 0 bytes up to the endpoint’s max_msg_size.

       iov    Vectored data buffer.

       count  Count of vectored data entries.

       desc   Descriptor associated with the data buffer.  See fi_mr(3).

       data   Remote CQ data to transfer with the sent message.

       dest_addr
              Destination address for connectionless transfers.  Ignored for connected endpoints.

       src_addr
              Source  address  to  receive  from  for  connectionless transfers.  Applies only to
              connectionless endpoints with the FI_DIRECTED_RECV  capability  enabled,  otherwise
              this field is ignored.  If set to FI_ADDR_UNSPEC, any source address may match.

       msg    Message descriptor for send and receive operations.

       flags  Additional flags to apply for the send or receive operation.

       context
              User  specified pointer to associate with the operation.  This parameter is ignored
              if the operation will not generate a  successful  completion,  unless  an  op  flag
              specifies the context parameter be used for required input.

DESCRIPTION

       The  send functions – fi_send, fi_sendv, fi_sendmsg, fi_inject, and fi_senddata – are used
       to transmit a message from one endpoint to another endpoint.  The main difference  between
       send  functions  are  the  number  and  type  of  parameters  that  they  accept as input.
       Otherwise, they perform the same general function.  Messages sent using fi_msg  operations
       are received by a remote endpoint into a buffer posted to receive such messages.

       The  receive functions – fi_recv, fi_recvv, fi_recvmsg – post a data buffer to an endpoint
       to receive inbound messages.  Similar to the send operations, receive  operations  operate
       asynchronously.   Users  should  not  touch  the  posted  data buffer(s) until the receive
       operation has completed.

       An endpoint must be enabled before an application can post send or receive  operations  to
       it.   For  connected  endpoints,  receive buffers may be posted prior to connect or accept
       being called on the endpoint.  This ensures that buffers are available to receive incoming
       data immediately after the connection has been established.

       Completed message operations are reported to the user through one or more event collectors
       associated with the endpoint.  Users  provide  context  which  are  associated  with  each
       operation,  and  is  returned  to the user as part of the event completion.  See fi_cq for
       completion event details.

   fi_send
       The call fi_send transfers the data contained in  the  user-specified  data  buffer  to  a
       remote endpoint, with message boundaries being maintained.

   fi_sendv
       The  fi_sendv  call  adds  support  for  a  scatter-gather  list to fi_send.  The fi_sendv
       transfers the set of data buffers referenced by the iov parameter to a remote endpoint  as
       a single message.

   fi_sendmsg
       The  fi_sendmsg  call  supports  data  transfers  over  both  connected and connectionless
       endpoints, with the ability to control the send operation per  call  through  the  use  of
       flags.  The fi_sendmsg function takes a struct fi_msg as input.

              struct fi_msg {
                  const struct iovec *msg_iov; /* scatter-gather array */
                  void               **desc;   /* local request descriptors */
                  size_t             iov_count;/* # elements in iov */
                  fi_addr_t          addr;     /* optional endpoint address */
                  void               *context; /* user-defined context */
                  uint64_t           data;     /* optional message data */
              };

   fi_inject
       The   send   inject   call   is  an  optimized  version  of  fi_send  with  the  following
       characteristics.  The data buffer is available for reuse immediately on  return  from  the
       call, and no CQ entry will be written if the transfer completes successfully.

       Conceptually,  this means that the fi_inject function behaves as if the FI_INJECT transfer
       flag were set, selective completions are  enabled,  and  the  FI_COMPLETION  flag  is  not
       specified.   Note that the CQ entry will be suppressed even if the default behavior of the
       endpoint is to write CQ entries for all successful completions.  See the flags  discussion
       below  for  more  details.   The requested message size that can be used with fi_inject is
       limited by inject_size.

   fi_senddata
       The send data call is similar to fi_send, but allows for the sending  of  remote  CQ  data
       (see FI_REMOTE_CQ_DATA flag) as part of the transfer.

   fi_injectdata
       The inject data call is similar to fi_inject, but allows for the sending of remote CQ data
       (see FI_REMOTE_CQ_DATA flag) as part of the transfer.

   fi_recv
       The fi_recv call posts a data buffer to the receive queue of the  corresponding  endpoint.
       Posted  receives  are  searched  in  the order in which they were posted in order to match
       sends.  Message boundaries are maintained.  The order in which the  receives  complete  is
       dependent  on  the endpoint type and protocol.  For connectionless endpoints, the src_addr
       parameter can be used to indicate that a buffer should be posted to receive incoming  data
       from a specific remote endpoint.

   fi_recvv
       The  fi_recvv  call adds support for a scatter-gather list to fi_recv.  The fi_recvv posts
       the set of data buffers referenced by the iov parameter to a receive incoming data.

   fi_recvmsg
       The fi_recvmsg call supports  posting  buffers  over  both  connected  and  connectionless
       endpoints,  with  the ability to control the receive operation per call through the use of
       flags.  The fi_recvmsg function takes a struct fi_msg as input.

FLAGS

       The fi_recvmsg and fi_sendmsg calls allow the user to specify flags which can  change  the
       default  message  handling  of the endpoint.  Flags specified with fi_recvmsg / fi_sendmsg
       override most flags previously configured with  the  endpoint,  except  where  noted  (see
       fi_endpoint.3).  The following list of flags are usable with fi_recvmsg and/or fi_sendmsg.

       FI_REMOTE_CQ_DATA
              Applies  to fi_sendmsg and fi_senddata.  Indicates that remote CQ data is available
              and should be sent as part of the request.  See fi_getinfo for  additional  details
              on FI_REMOTE_CQ_DATA.

       FI_CLAIM
              Applies  to posted receive operations for endpoints configured for FI_BUFFERED_RECV
              or FI_VARIABLE_MSG.  This flag is used to retrieve a message that was  buffered  by
              the provider.  See the Buffered Receives section for details.

       FI_COMPLETION
              Indicates  that a completion entry should be generated for the specified operation.
              The endpoint must be bound to a completion queue with FI_SELECTIVE_COMPLETION  that
              corresponds to the specified operation, or this flag is ignored.

       FI_DISCARD
              Applies  to posted receive operations for endpoints configured for FI_BUFFERED_RECV
              or FI_VARIABLE_MSG.  This flag is used to free a message that was buffered  by  the
              provider.  See the Buffered Receives section for details.

       FI_MORE
              Indicates  that  the  user  has additional requests that will immediately be posted
              after the current call returns.  Use  of  this  flag  may  improve  performance  by
              enabling the provider to optimize its access to the fabric hardware.

       FI_INJECT
              Applies  to fi_sendmsg.  Indicates that the outbound data buffer should be returned
              to user immediately after the send call returns, even if the operation  is  handled
              asynchronously.   This may require that the underlying provider implementation copy
              the data into a local buffer and transfer out of that buffer.  This flag  can  only
              be used with messages smaller than inject_size.

       FI_MULTI_RECV
              Applies  to  posted receive operations.  This flag allows the user to post a single
              buffer that will receive multiple incoming messages.   Received  messages  will  be
              packed  into  the  receive  buffer until the buffer has been consumed.  Use of this
              flag may cause a single posted receive operation to  generate  multiple  events  as
              messages  are  placed  into  the  buffer.   The placement of received data into the
              buffer may be subjected to provider specific alignment restrictions.

       The buffer will be released by the provider when the available buffer  space  falls  below
       the  specified  minimum (see FI_OPT_MIN_MULTI_RECV).  Note that an entry to the associated
       receive completion queue will always be generated when the buffer has been consumed,  even
       if other receive completions have been suppressed (i.e. the Rx context has been configured
       for FI_SELECTIVE_COMPLETION).  See the FI_MULTI_RECV completion flag fi_cq(3).

       FI_INJECT_COMPLETE
              Applies to fi_sendmsg.  Indicates that a completion should be  generated  when  the
              source buffer(s) may be reused.

       FI_TRANSMIT_COMPLETE
              Applies  to  fi_sendmsg  and  fi_recvmsg.   For  sends, indicates that a completion
              should not be generated until the operation has been successfully  transmitted  and
              is no longer being tracked by the provider.  For receive operations, indicates that
              a completion may be generated as soon as the message  has  been  processed  by  the
              local  provider,  even  if  the  message  data may not be visible to all processing
              elements.  See fi_cq(3) for target side completion semantics.

       FI_DELIVERY_COMPLETE
              Applies to fi_sendmsg.  Indicates that a completion should be  generated  when  the
              operation has been processed by the destination.

       FI_FENCE
              Applies  to  transmits.   Indicates that the requested operation, also known as the
              fenced operation, and any operation posted  after  the  fenced  operation  will  be
              deferred  until  all  previous  operations  targeting  the  same peer endpoint have
              completed.  Operations posted after the fencing will see and/or replace the results
              of any operations initiated prior to the fenced operation.

       The  ordering of operations starting at the posting of the fenced operation (inclusive) to
       the posting of a subsequent fenced operation (exclusive) is controlled by  the  endpoint’s
       ordering semantics.

       FI_MULTICAST
              Applies  to  transmits.  This flag indicates that the address specified as the data
              transfer destination is a multicast  address.   This  flag  must  be  used  in  all
              multicast transfers, in conjunction with a multicast fi_addr_t.

Buffered Receives

       Buffered  receives  indicate  that  the  networking  layer  allocates and manages the data
       buffers used to receive network data transfers.  As a result, received  messages  must  be
       copied  from  the  network  buffers  into  application  buffers  for processing.  However,
       applications can avoid this copy if  they  are  able  to  process  the  message  in  place
       (directly from the networking buffers).

       Handling  buffered  receives  differs  based  on  the  size of the message being sent.  In
       general, smaller messages are passed directly to the application for processing.  However,
       for  large  messages,  an  application will only receive the start of the message and must
       claim the rest.  The details for how small messages are reported and large messages may be
       claimed are described below.

       When  a  provider  receives  a  message,  it  will  write an entry to the completion queue
       associated with the receiving endpoint.  For discussion purposes, the completion queue  is
       assumed  to  be  configured  for  FI_CQ_FORMAT_DATA.   Since  buffered  receives  are  not
       associated with application posted buffers, the CQ entry op_context will point to a struct
       fi_recv_context.

              struct fi_recv_context {
                  struct fid_ep *ep;
                  void *context;
              };

       The  `ep'  field will point to the receiving endpoint or Rx context, and `context' will be
       NULL.  The CQ entry’s `buf' will point to a provider managed buffer where the start of the
       received message is located, and `len' will be set to the total size of the message.

       The   maximum   sized   message   that   a   provider   can   buffer   is  limited  by  an
       FI_OPT_BUFFERED_LIMIT.  This threshold  can  be  obtained  and  may  be  adjusted  by  the
       application  using  the fi_getopt and fi_setopt calls, respectively.  Any adjustments must
       be made prior to enabling the endpoint.  The CQ entry `buf' will  point  to  a  buffer  of
       received  data.   If  the  sent  message  is larger than the buffered amount, the CQ entry
       `flags' will have the FI_MORE bit set.  When the FI_MORE bit is set, `buf' will  reference
       at least FI_OPT_BUFFERED_MIN bytes of data (see fi_endpoint.3 for more info).

       After  being  notified that a buffered receive has arrived, applications must either claim
       or discard the message.  Typically, small messages  are  processed  and  discarded,  while
       large  messages  are  claimed.   However,  an  application is free to claim or discard any
       message regardless of message size.

       To claim a message, an application must post a receive operation with  the  FI_CLAIM  flag
       set.   The struct fi_recv_context returned as part of the notification must be provided as
       the receive operation’s context.  The struct fi_recv_context contains a  `context'  field.
       Applications  may  modify  this  field  prior  to  claiming  the  message.  When the claim
       operation completes, a  standard  receive  completion  entry  will  be  generated  on  the
       completion  queue.   The `context' of the associated CQ entry will be set to the `context'
       value passed in through the fi_recv_context structure, and the CQ entry  flags  will  have
       the FI_CLAIM bit set.

       Buffered  receives  that  are  not claimed must be discarded by the application when it is
       done processing the CQ entry data.  To discard a  message,  an  application  must  post  a
       receive  operation  with  the FI_DISCARD flag set.  The struct fi_recv_context returned as
       part of the notification must be provided as the receive operation’s  context.   When  the
       FI_DISCARD  flag  is  set  for a receive operation, the receive input buffer(s) and length
       parameters are ignored.

       IMPORTANT: Buffered receives must be claimed or discarded in a timely manner.  Failure  to
       do  so may result in increased memory usage for network buffering or communication stalls.
       Once a buffered receive has been claimed or discarded, the  original  CQ  entry  `buf'  or
       struct fi_recv_context data may no longer be accessed by the application.

       The  use  of the FI_CLAIM and FI_DISCARD operation flags is also described with respect to
       tagged message transfers in  fi_tagged.3.   Buffered  receives  of  tagged  messages  will
       include the message tag as part of the CQ entry, if available.

       The handling of buffered receives follows all message ordering restrictions assigned to an
       endpoint.  For example, completions may indicate the  order  in  which  received  messages
       arrived at the receiver based on the endpoint attributes.

Variable Length Messages

       Variable length messages, or simply variable messages, are transfers where the size of the
       message is unknown to the receiver prior to the message being sent.  It indicates that the
       recipient  of  a  message  does not know the amount of data to expect prior to the message
       arriving.  It is most commonly used when the size of  message  transfers  varies  greatly,
       with  very  large  messages  interspersed  with much smaller messages, making receive side
       message buffering difficult to manage.  Variable messages are not subject to  max  message
       length  restrictions  (i.e. struct  fi_ep_attr::max_msg_size limits), and may be up to the
       maximum value of size_t (e.g. SIZE_MAX) in length.

       Variable length messages support requests  that  the  provider  allocate  and  manage  the
       network  message buffers.  As a result, the application requirements and provider behavior
       is identical as those defined for supporting  the  FI_BUFFERED_RECV  mode  bit.   See  the
       Buffered Receive section above for details.  The main difference is that buffered receives
       are limited by the fi_ep_attr::max_msg_size threshold, whereas  variable  length  messages
       are not.

       Support for variable messages is indicated through the FI_VARIABLE_MSG capability bit.

NOTES

       If an endpoint has been configured with FI_MSG_PREFIX, the application must include buffer
       space of size msg_prefix_size, as specified by the endpoint attributes.  The prefix buffer
       must  occur  at the start of the data referenced by the buf parameter, or be referenced by
       the first IO vector.  Message prefix space cannot be split between  multiple  IO  vectors.
       The size of the prefix buffer should be included as part of the total buffer length.

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.

       See the discussion below for details handling FI_EAGAIN.

ERRORS

       -FI_EAGAIN
              Indicates that the underlying provider currently  lacks  the  resources  needed  to
              initiate  the  requested operation.  The reasons for a provider returning FI_EAGAIN
              are varied.  However, common reasons include  insufficient  internal  buffering  or
              full processing queues.

       Insufficient  internal  buffering  is often associated with operations that use FI_INJECT.
       In such cases, additional buffering may become available as posted operations complete.

       Full processing queues may be a temporary state related to local processing (for  example,
       a  large  message  is  being  transferred),  or may be the result of flow control.  In the
       latter case, the queues may remain blocked until additional resources are  made  available
       at the remote side of the transfer.

       In  all  cases,  the operation may be retried after additional resources become available.
       It is strongly recommended that applications check for transmit  and  receive  completions
       after  receiving  FI_EAGAIN  as a return value, independent of the operation which failed.
       This  is  particularly  important  in  cases  where  manual  progress  is   employed,   as
       acknowledgements  or  flow  control  messages  may need to be processed in order to resume
       execution.

SEE ALSO

       fi_getinfo(3), fi_endpoint(3), fi_domain(3), fi_cq(3)

AUTHORS

       OpenFabrics.