/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_IB_MGT_IBMF_IBMF_H #define _SYS_IB_MGT_IBMF_IBMF_H #pragma ident "%Z%%M% %I% %E% SMI" /* * This file defines the IBMF client interface. */ #ifdef __cplusplus extern "C" { #endif #include #include #include #include #include #include #include /* IBMF API function return values */ #define IBMF_SUCCESS 0 /* successful call */ #define IBMF_FAILURE -1 /* ibmf internal error */ #define IBMF_PORT_IN_USE -2 /* class already registered */ #define IBMF_BAD_CLASS -3 /* bad class specified */ #define IBMF_BAD_HANDLE -4 /* bad ibmf handle */ #define IBMF_BAD_QP_HANDLE -5 /* bad QP handle */ #define IBMF_BAD_NODE -6 /* bad node specified to reg */ #define IBMF_BAD_PORT -7 /* bad port specified to reg */ #define IBMF_BAD_PORT_STATE -8 /* port in incorrect state */ #define IBMF_BAD_VERSION -9 /* bad IBMF version */ #define IBMF_BAD_FLAGS -10 /* bad IBMF flags */ #define IBMF_BAD_SIZE -11 /* bad data size in message */ #define IBMF_BAD_RMPP_OPT -12 /* more than one class used */ #define IBMF_BUSY -13 /* resources held by client */ #define IBMF_NO_RESOURCES -14 /* no resources */ #define IBMF_NOT_SUPPORTED -15 /* function not supported */ #define IBMF_PARTIAL_TRANSFER -16 /* excess response data */ #define IBMF_UNEXP_TRANS_RECVD -17 /* unexpected trans received */ #define IBMF_TRANS_TIMEOUT -18 /* transaction timed out */ #define IBMF_TRANS_FAILURE -19 /* transaction failure */ #define IBMF_NO_MEMORY -20 /* could not alloc memory */ #define IBMF_REQ_INVALID -21 /* request was invalid */ #define IBMF_NO_RECORDS -22 /* no records match query */ #define IBMF_TOO_MANY_RECORDS -23 /* too many recs match query */ #define IBMF_INVALID_GID -24 /* invalid gid in sa request */ #define IBMF_INSUFF_COMPS -25 /* insufficient components */ #define IBMF_UNSUPP_METHOD -26 /* unsupported method */ #define IBMF_UNSUPP_METHOD_ATTR -27 /* unsupp. method/attrbute */ #define IBMF_INVALID_FIELD -28 /* invalid field in MAD */ #define IBMF_INVALID_ARG -29 /* invalid function argument */ #define IBMF_CB_REGISTERED -30 /* callback already regd */ #define IBMF_CB_NOT_REGISTERED -31 /* callback not registered */ #define IBMF_TRANSPORT_FAILURE -32 /* a transport call failed */ #define IBMF_TID_IN_USE -33 /* client's TID in use */ /* flags to ibmf_alloc_msg() */ #define IBMF_ALLOC_SLEEP 0 #define IBMF_ALLOC_NOSLEEP 1 /* * IBMF version */ #define IBMF_VERSION 1 typedef struct _ibmf_handle_dummy *ibmf_handle_t; typedef struct _ibmf_qp_dummy *ibmf_qp_handle_t; /* * IBMF default QP handles */ #define IBMF_QP_HANDLE_DEFAULT (ibmf_qp_handle_t)0 /* * ir_client_type */ typedef enum _ibmf_client_type_t { SUBN_AGENT = 0x00010001, SUBN_MANAGER = 0x00020001, SUBN_ADM_AGENT = 0x00010003, SUBN_ADM_MANAGER = 0x00020003, PERF_AGENT = 0x00010004, PERF_MANAGER = 0x00020004, BM_AGENT = 0x00010005, BM_MANAGER = 0x00020005, DEV_MGT_AGENT = 0x00010006, DEV_MGT_MANAGER = 0x00020006, COMM_MGT_MANAGER_AGENT = 0x00030007, SNMP_MANAGER_AGENT = 0x00030008, VENDOR_09_MANAGER_AGENT = 0x00030009, VENDOR_0A_MANAGER_AGENT = 0x0003000A, VENDOR_0B_MANAGER_AGENT = 0x0003000B, VENDOR_0C_MANAGER_AGENT = 0x0003000C, VENDOR_0D_MANAGER_AGENT = 0x0003000D, VENDOR_0E_MANAGER_AGENT = 0x0003000E, VENDOR_0F_MANAGER_AGENT = 0x0003000F, VENDOR_30_MANAGER_AGENT = 0x00030030, VENDOR_31_MANAGER_AGENT = 0x00030031, VENDOR_32_MANAGER_AGENT = 0x00030032, VENDOR_33_MANAGER_AGENT = 0x00030033, VENDOR_34_MANAGER_AGENT = 0x00030034, VENDOR_35_MANAGER_AGENT = 0x00030035, VENDOR_36_MANAGER_AGENT = 0x00030036, VENDOR_37_MANAGER_AGENT = 0x00030037, VENDOR_38_MANAGER_AGENT = 0x00030038, VENDOR_39_MANAGER_AGENT = 0x00030039, VENDOR_3A_MANAGER_AGENT = 0x0003003A, VENDOR_3B_MANAGER_AGENT = 0x0003003B, VENDOR_3C_MANAGER_AGENT = 0x0003003C, VENDOR_3D_MANAGER_AGENT = 0x0003003D, VENDOR_3E_MANAGER_AGENT = 0x0003003E, VENDOR_3F_MANAGER_AGENT = 0x0003003F, VENDOR_40_MANAGER_AGENT = 0x00030040, VENDOR_41_MANAGER_AGENT = 0x00030041, VENDOR_42_MANAGER_AGENT = 0x00030042, VENDOR_43_MANAGER_AGENT = 0x00030043, VENDOR_44_MANAGER_AGENT = 0x00030044, VENDOR_45_MANAGER_AGENT = 0x00030045, VENDOR_46_MANAGER_AGENT = 0x00030046, VENDOR_47_MANAGER_AGENT = 0x00030047, VENDOR_48_MANAGER_AGENT = 0x00030048, VENDOR_49_MANAGER_AGENT = 0x00030049, VENDOR_4A_MANAGER_AGENT = 0x0003004A, VENDOR_4B_MANAGER_AGENT = 0x0003004B, VENDOR_4C_MANAGER_AGENT = 0x0003004C, VENDOR_4D_MANAGER_AGENT = 0x0003004D, VENDOR_4E_MANAGER_AGENT = 0x0003004E, VENDOR_4F_MANAGER_AGENT = 0x0003004F, APPLICATION_10_MANAGER_AGENT = 0x00030010, APPLICATION_11_MANAGER_AGENT = 0x00030011, APPLICATION_12_MANAGER_AGENT = 0x00030012, APPLICATION_13_MANAGER_AGENT = 0x00030013, APPLICATION_14_MANAGER_AGENT = 0x00030014, APPLICATION_15_MANAGER_AGENT = 0x00030015, APPLICATION_16_MANAGER_AGENT = 0x00030016, APPLICATION_17_MANAGER_AGENT = 0x00030017, APPLICATION_18_MANAGER_AGENT = 0x00030018, APPLICATION_19_MANAGER_AGENT = 0x00030019, APPLICATION_1A_MANAGER_AGENT = 0x0003001A, APPLICATION_1B_MANAGER_AGENT = 0x0003001B, APPLICATION_1C_MANAGER_AGENT = 0x0003001C, APPLICATION_1D_MANAGER_AGENT = 0x0003001D, APPLICATION_1E_MANAGER_AGENT = 0x0003001E, APPLICATION_1F_MANAGER_AGENT = 0x0003001F, APPLICATION_20_MANAGER_AGENT = 0x00030020, APPLICATION_21_MANAGER_AGENT = 0x00030021, APPLICATION_22_MANAGER_AGENT = 0x00030022, APPLICATION_23_MANAGER_AGENT = 0x00030023, APPLICATION_24_MANAGER_AGENT = 0x00030024, APPLICATION_25_MANAGER_AGENT = 0x00030025, APPLICATION_26_MANAGER_AGENT = 0x00030026, APPLICATION_27_MANAGER_AGENT = 0x00030027, APPLICATION_28_MANAGER_AGENT = 0x00030028, APPLICATION_29_MANAGER_AGENT = 0x00030029, APPLICATION_2A_MANAGER_AGENT = 0x0003002A, APPLICATION_2B_MANAGER_AGENT = 0x0003002B, APPLICATION_2C_MANAGER_AGENT = 0x0003002C, APPLICATION_2D_MANAGER_AGENT = 0x0003002D, APPLICATION_2E_MANAGER_AGENT = 0x0003002E, APPLICATION_2F_MANAGER_AGENT = 0x0003002F, UNIVERSAL_CLASS = 0x00040001 } ibmf_client_type_t; /* * ibmf_retrans_t data type is used to specify the maximum values * of the retransmission parameters, number of retries, * response time value, round trip travel time, and transaction timeout. * * The retries value must be provided by the client * for all the transaction types enumerated by ibmf_trans_t. * The retries value will be used to retry any section of * the underlying transmission and reception protocol that * are time bound by timers. * * The response time value must be specified for all transaction types except an * unsequenced, non-RMPP send (see the table below). * The response time value is the length of processing time for the * responder to process the requested transaction, from the point of receiving * the last request packet, to the point of returning the first response packet. * This value is interpreted in microseconds. * If the response time value is zero, an implementation default is used. * * The round trip time must be specified for all transaction types except an * unsequenced, non-RMPP send (see the table below). * The round trip travel time is the maximum time it should take a packet * to travel from the requester to the responder and back to the requester. * This value does not include the processing time at the responder. * This value is interpreted in microseconds. * If the round trip time value is zero, an implementation default is used. * * The transaction timeout should be specified for all transactions * using RMPP to receive a message. * Since, it is not possible for the client to know the size of the * response, IBMF will calculate a reasonable transaction timeout after * receiving the first RMPP data packet of the response at which time the * size of the message will be known. If this value is greater than the * client's transaction timeout parameter the client's value will be used. * If the client's transaction timeout parameter is 0 the calculated value will * be used. * This value is interpreted in microseconds. * If the transaction timeout value is zero, an implementation default is used. * * See Section 13.6.3.1, of the InfiniBand Architecture Specification, * Volume 1, Release 1.1 for details on how to deduce this value. * * The following table describes the retrans parameters needed for * the various ibmf_msg_transport() flag combinations. * * ibmf_msg_transport() flags retries rtv/rttv trans_to * No Flags ignored ignored ignored * Sequenced Flag required required required * RMPP Flag required required ignored * RMPP + Sequenced Flags required required optional */ typedef struct _ibmf_retrans_t { uint32_t retrans_retries; /* number of retries */ uint32_t retrans_rtv; /* response time value */ uint32_t retrans_rttv; /* round trip travel time */ uint32_t retrans_trans_to; /* transaction timeout */ } ibmf_retrans_t; typedef struct _ibmf_register_info { ib_guid_t ir_ci_guid; uint_t ir_port_num; ibmf_client_type_t ir_client_class; } ibmf_register_info_t; typedef enum _ibmf_impl_caps { IBMF_DEF_QP_HDL_P_KEY_ANY = 0x0001, IBMF_DEF_QP_HDL_Q_KEY_ANY = 0x0002, IBMF_NON_DEF_QP_HDL_P_KEY_ANY = 0x0004, IBMF_NON_DEF_QP_HDL_Q_KEY_ANY = 0x0008 } ibmf_impl_caps_t; /* * Defines for channel interface events. * IBMF_CI_OFFLINE : * Indication to the client that it must cease all ibmf activity * (after any current activity has terminated). The client must * release all ibmf resources and unregister from ibmf prior to * returning from the callback. * * NOTE1: It is expected that there will exist some higher level * management entity that will "wake up" the ibmf client once * the CI is available. The ibmf client may then register with the * available CI's nodeguid and portnumber. * * NOTE2: callback implementors must handle the case where the * callback is invoked AFTER the ibmf resources have been freed by * another thread. */ typedef enum ibmf_async_event_e { IBMF_CI_OFFLINE = 0x1 } ibmf_async_event_t; /* * ibmf_async_event_cb_t(): * IBMF's callback to clients to inform them of events such as * the ibmf services temporarily suspending or resuming. * This notification mechanism covers all asynchronous events * of interest that are not related to IB messages. * * NOTE: * It is possible for the callback function to be called before * ibmf_register() returns. When this happens, the entity doing the * ibmf_register() may see an ibmf_handle being passed to the * callback function that it does not recognize. * * Input arguments: * ibmf_handle - Handle to the IBMF interface * clnt_private - is an opaque handle to client specific data * event_type - specifies the event type the client is being notified of * * Output arguments: * None * * Return values: * None */ typedef void (*ibmf_async_event_cb_t)( ibmf_handle_t ibmf_handle, void *clnt_private, ibmf_async_event_t event_type); /* * ibmf_msg_cb_t(): * * This routine type is called by IBMF when an unsolicited message that * corresponds to one of the class registrants is received. An unsolicited * message is one that was not allocated by this client for the purpose * of executing a transaction using the ibmf_msg_transport() call. * Examples of unsolicited messages are traps, and requests from other * management entities. * * This routine type is also called by IBMF at the end of a transaction * specified in a call to ibmf_msg_transport(). * * When it is called as result of an incoming message: * * The recipient is expected to free the ibmf_msg_t passed in by * calling ibmf_free_msg(); this freeing should be done before the * client unregisters. * * The recipient is expected to not call any routines in the callback * that may block. * * Blocking within the callback is not allowed, but ibmf doesn't enforce * this. * * This routine may be called before ibmf_setup_async_cb() returns. * * * Input arguments: * Handle to the IBMF interface * Pointer to the Message sent or received * Callback arguments, specified at registration time (for async callbacks) * or specified to ibmf_msg_transport() * * Output arguments: * None * * Return values: * None */ typedef void (*ibmf_msg_cb_t)( ibmf_handle_t ibmf_handle, ibmf_msg_t *msgp, void *args); /* defines for im_msg_flags */ #define IBMF_MSG_FLAGS_GLOBAL_ADDRESS 0x00000010 /* has global addr */ /* * ibmf_register(): * * An agent needs to register before it can receive any management packets * and a manager needs to register before it can send/receive any management * packets. The registration is on a per port of the node basis. * * A client can register for one class per call to ibmf_register(). * The client should set ir_client_class component of the client_info argument * to the class it wants to register for. * ibmf_register() will fail if the class is already registered for, * with the error code IBMF_PORT_IN_USE. * * Note that for some classes, the client can register as agent or manager only * and agent+manager only. An exception to this rule is the UNIVERSAL_CLASS * described below. * * Clients that require to send/receive general UD traffic, * not limited to MADs, over a UD QP may do so by registering * with the UNIVERSAL_CLASS client type. * Unlike the other IBMF client types, any number of clients may * be simultaneously registered for the UNIVERSAL_CLASS on a port. * When registered with the UNIVERSAL_CLASS, a client should only use the * alternate QPs, and never use the default QP handle. * However, a client registered for any other client type may also use * the alternate QPs in addition to using the default QP handle. * IBMF implementations that do not support registration for the UNIVERSAL class * will return IBMF_NOT_SUPPORTED. * * NOTE on usage of qp handles: * * Some implementations support specifying any Q_Key and P_Key * combination when ibmf_qp_handle_t arg is set to IBMF_QP_HANDLE_DEFAULT * in the call to ibmf_msg_transport() and some implementations allow only * the default values of Q_Key (0x8001_0000) and P_Key (0xFFFF/0x7FFFF) * when ibmf_qp_handle_t arg is IBMF_QP_HANDLE_DEFAULT. The client can know * the behavior supported via ibmf_impl_caps_t arg on successful return from * ibmf_register(). ibmf_impl_caps_t arg points to a bit mask of the * capabilities of the platform. If the implementation supports any * P_Key and/or Q_Key value with IBMF_QP_HANDLE_DEFAULT, then * IBMF_DEF_QP_HDL_P_KEY_ANY and/or IBMF_DEF_QP_HDL_Q_KEY_ANY will be set in * ibmf_impl_caps_t. * * Some implementations support specifying any P_Key and Q_Key combination on * a per-request basis when ibmf_qp_handle_t is set to an explicitly allocated * qp handle (the client specifies the P_Key/Q_Key value in ibmf_addr_info_t * argument). IBMA indicates this behavior by setting * IBMF_NON_DEF_QP_HDL_P_KEY_ANY and/or IBMF_NON_DEF_QP_HDL_Q_KEY_ANY in the * ibmf_impl_caps_t arg. In such an implementation, ibmf_modify_qp() does not * change anything in the transport and always returns IBMF_SUCCESS. * * When the implementation supports IBMF_DEF_QP_HDL_P_KEY_ANY and/or * IBMF_DEF_QP_HDL_Q_KEY_ANY, it may map IBMF_QP_HANDLE_DEFAULT to any qp * number(s) supported by the * underlying transport. The client can not not make any assumptions on this * mapping nor can it query ibmf for the qp num being used with * IBMF_QP_HANDLE_DEFAULT. There are cases where the client needs to have * explicit control over the qp number being used by ibmf (eg., agent * redirection). The client should explicitly allocate a qp using * ibmf_alloc_qp() in such cases. * * Also, IBMF_QP_HANDLE_DEFAULT can only be used when the class of the MAD * being sent using ibmf_msg_transport() is the same as the class the client * registered for. If a client wishes to send a MAD class other than the * one it registered for, it should explicitly allocate a qp and use that * qp while sending MADs. * * If the implementation supports * IBMF_DEF_QP_HDL_P_KEY_ANY/IBMF_DEF_QP_HDL_Q_KEY_ANY and/or * IBMF_NON_DEF_QP_HDL_P_KEY_ANY/IBMF_NON_DEF_QP_HDL_Q_KEY_ANY, it is the * implementation's responsibility to ensure that the * requested P_Key and Q_Key can be used by, with in resource limitations, * concurrent sends. * * Clients registering for classes that include an RMPP header in their * MADs must set the IBMF_REG_FLAG_RMPP flag when registering with IBMF. * This must be done regardless of whether the client intends to use * the RMPP protocol or not. The flag is an indicator to IBMF of the * presence of the RMPP header in the MAD. * * IBMF will always insure that receive buffer pointers are offsets into a * single contiguous buffer of memory. The im_msgbufs_recv.im_bufs_mad_hdr, * points to the start of the buffer. The other two pointers, * im_msgbufs_recv.im_bufs_cl_hdr, and im_msgbufs_recv.im_bufs_cl_data, * will point to class specific offsets within the buffer. * * Clients may provide a pointer to a callback function in the client_cb * argument. Implementations of ibmf that require the client_cb to * be specified should return IBMF_INVALID_ARG if the client_cb argument * is NULL. * * This interface may block * * Input arguments: * Pointer to client registration information * Version of the interface (IBMF_VERSION) * flags - set IBMF_REG_FLAG_RMPP if client supports RMPP MAD * set IBMF_REG_FLAG_NO_OFFLOAD for requiring that processing * not be offloaded onto a non-interrupt context thread * on send completions and receive completions. * (Processsing will be done in the interrupt context) * The default is to offload the processing to a * non-interrupt context thread(s). * set IBMF_REG_FLAG_SINGLE_OFFLOAD for requiring single * threaded processing if IBMF_REG_FLAG_NO_OFFLOAD * is not specified. The default is multi-threaded * processing. It is an error to set this flag if * IBMF_REG_FLAG_NO_OFFLOAD is set. * client_cb - callback to be called for asynchronous events that * are not related to IB messages * client_cb_args - opaque pointer to client private data area * * Output arguments: * Handle to the IBMF interface; used in subsequent interactions * Pointer to ibmf_impl_caps_t; gives capabilities of the platform * * Return values: * IBMF_SUCCESS - registration successful * IBMF_BAD_VERSION - registration failed due to invalid version * IBMF_PORT_IN_USE - registration failed - some entity already * registered for the class on the node/port * specified. * IBMF_BAD_CLASS - registration failed - invalid class * IBMF_BAD_PORT - registration failed - non existent port * IBMF_BAD_NODE - registration failed - non existent node * IBMF_BAD_FLAGS - IBMF_REG_FLAG_NO_OFFLOAD is specified with * IBMF_REG_FLAG_SINGLE_OFFLOAD * IBMF_INVALID_ARG - registration failed - invalid argument * IBMF_FAILURE - registration failed - ibmf internal error * IBMF_NO_RESOURCES - registration failed - not enough resources * IBMF_TRANSPORT_FAILURE - registration failed - transport call failed * */ int ibmf_register( ibmf_register_info_t *client_info, uint_t ibmf_version, uint_t flags, ibmf_async_event_cb_t client_cb, void *client_cb_args, ibmf_handle_t *ibmf_handle, ibmf_impl_caps_t *ibmf_impl_features); #define IBMF_REG_FLAG_RMPP 0x1 #define IBMF_REG_FLAG_NO_OFFLOAD 0x2 #define IBMF_REG_FLAG_SINGLE_OFFLOAD 0x4 /* * ibmf_unregister(): * * Unregister a previously established registration. * * This interface may block. * * The client should free any and all ibmf_msg_t's passed in all * "receive msg callbacks" before unregistering. Also, the client should * ensure that it is not trying to send any messages before calling this * routine. * * After successfully returning from this call, ibmf_handle should not be used * for any further interactions with the IBMF. * * Input arguments: * Handle to the IBMF interface * flags - unused (should be 0) * * Output arguments: * Handle to the IBMF interface; will be invalidated following * this call. * * Return values: * IBMF_SUCCESS - unregistration successful * IBMF_BAD_HANDLE - unregistration failed - invalid handle * passed in. * IBMF_BUSY - unregistration failed - client has not * freed all the resources (ibmf_msg_t's etc) * allocated by the IBMF, the client * has not removed all recv callbacks. * IBMF_INVALID_ARG - invalid argument * IBMF_FAILURE - ibmf internal error * IBMF_NO_RESOURCES - not enough resources * IBMF_TRANSPORT_FAILURE - transport call failed */ int ibmf_unregister( ibmf_handle_t *ibmf_handle, uint_t flags); /* * ibmf_setup_async_cb(): * * This routine establishes a callback that the IBMF invokes when a message * corresponding to the class corresponding to ibmf_handle is received. * It is an error to call this routine twice without an intervening * call to ibmf_tear_down_async_cb() for the same ibmf_qp_handle/ibmf_handle * combination. Only unsolicited message reception will result in this * callback being invoked. * * This interface may block. * * The callback routine could be invoked before this function returns. * * Input arguments: * Handle to the IBMF interface * IBMF QP handle (either allocated via ibmf_alloc_qp() or * IBMF_QP_HANDLE_DEFAULT) * Callback routine * Argument to be passed when the callback is invoked * flags - unused (should be 0) * * Output arguments: * None * * Return values: * IBMF_SUCCESS - Callback established successfully * IBMF_BAD_HANDLE - failure - invalid handle * IBMF_BAD_QP_HANDLE - failure - invalid qp handle * IBMF_CB_REGISTERED - failure - callback is already established * IBMF_INVALID_ARG - failure - invalid argument */ int ibmf_setup_async_cb( ibmf_handle_t ibmf_handle, ibmf_qp_handle_t ibmf_qp_handle, ibmf_msg_cb_t async_msg_cb, void *async_msg_cb_args, uint_t flags); /* * ibmf_tear_down_async_cb(): * * This routine removes the callback set up using ibmf_setup_async_cb. * There will not be any callbacks if messages are received after successful * return from this routine. There could be message received callbacks during * the execution of this routine. * * This interface may block. * * Input arguments: * Handle to the IBMF interface * IBMF QP handle (either allocated via ibmf_alloc_qp() or * IBMF_QP_HANDLE_DEFAULT) * flags - unused (should be 0) * * Output arguments: * None * * Return values: * IBMF_SUCCESS - call successful * IBMF_BAD_HANDLE - failure - invalid ibmf handle or qp handle * IBMF_BAD_QP_HANDLE - failure - invalid qp handle * IBMF_CB_NOT_REGISTERED - No callback currently registered * IBMF_INVALID_ARG - failure - invalid argument */ int ibmf_tear_down_async_cb( ibmf_handle_t ibmf_handle, ibmf_qp_handle_t ibmf_qp_handle, uint_t flags); /* * ibmf_msg_transport(): * * This interface does not block if a callback is specified. * * IBMF makes some preliminary checks and returns failure if the * checks fail. The callback, if any, is not called in this case. If the * checks pass, the message specified in msgp->im_msgbufs_send is relayed * down into the transport layer over as many MAD packets as necessary * to accommodate the entire message. The IBMF_MSG_TRANS_FLAG_RMPP flag is set * when the RMPP protocol should be used when sending out the message. * The IBMF_MSG_TRANS_FLAG_SEQ is set when the the transaction is a * sequenced transaction (send and receive) where the client expects a reply. * The transaction completion callback will be invoked when IBMF * is done processing the send operation and after having received the * complete response if one is due, with or without errors. * If no callback is specified, the routine blocks till the underlying * transport is done processing the send request and received the complete * response, with or without errors * * When sending non-MAD traffic over the alternate QPs, * if the message data exceeds the maximum MTU supported, the call will fail * with the status IBMF_BAD_SIZE. * * NOTE: If the call is asynchronous, the callback may be invoked before * the call returns. The client should be prepared to handle this possibility. * * The message is sent to the address specified by msgp->im_local_addr and * msgp->im_global_addr (global address invalid for SMPs and is ignored). * Note that the desired Q_Key and P_Key can be specified via * msgp->im_local_addr. If the ibmf implementation does not support any * value of Q_Key/P_Key with IBMF_QP_HANDLE_DEFAULT, it is an error to specify * a Q_Key other than 0x8001_0000 and a P_Key other than 0xFFFF/0x7FFF when * ibmf_qp_handle_t arg is set IBMF_QP_HANDLE_DEFAULT. (See the NOTE in * ibmf_register() on what the platform supports.) In this case, when a q_key * value other than 0x8001_0000 and/or P_Key value other than * 0xFFFF/0x7FFF is desired, the client should allocate its own qp handle * with the desired values and use that in the ibmf_msg_transport() call. * ibmf_msg_transport() returns IBMF_BAD_HANDLE to flag the error. * * NOTE: If the qp handle is not the default handle (ie., not * IBMF_QP_HANDLE_DEFAULT), it is possible for some other thread to modify * P_Key and Q_Key value associated with the qp_handle while this function * is executing; this routine may return IBMF_BAD_HANDLE if that * happens. It is possible that the modification happens after this routine * validates the values, in which case no error may be flagged. * * NOTE: if the class of the MAD being sent is not the same as what the * ibmf_handle (obtained via ibmf_register()) corresponds to, ibmf_qp_handle * can not be set to IBMF_QP_HANDLE_DEFAULT. * * NOTE on notation: A message structure allocated by an ibmf_alloc_msg() * call or one returned in an unsolicted callback will be referred to as * "Message". When referring to a message in the general sense of the word, * it will be referred to as "message". * NOTE: Rules for reusing an IBMF Message: * Clients may reuse a Message, either provided by IBMF in an unsolicited * request, or one obtained through the ibmf_alloc_msg() call, for a * subsequent request from the client itself. The client may reuse a Message * to avoid the overhead of allocating a new Message and new send buffers. * To safely reuse Messages, the client must follow the rules listed below. * 1) Using the receive buffers to send the message header and data: * If the Message has been provided by IBMF in an unsolicited request, * it will have its receive buffers already allocated and pointed to by * im_msgbufs_recv pointers by IBMF. In such a case, a client may set * the im_msgbufs_send pointers to the values in the im_msgbufs_recv * thus reusing the buffer allocated by IBMF for the incoming Message. * However, this may be done only when the request from the client is * a non-sequenced operation i.e. IBMF_MSG_TRANS_FLAG_SEQ flag is not set. * An attempt to reuse the receive buffer for any other operation will * result in the failure of the ibmf_msg_transport() call with the error * status IBMF_REQ_INVALID. * 2) Providing send buffers to send the message header and data: * If the client provides its own send buffers for the message header and data, * the IBMF Message may be reused for both sequenced and non-sequenced * transactions. Any receive buffers that were allocated by IBMF from a * previous transaction, will be freed up once the Message is reused in an * ibmf_msg_transport() call. New receive buffers will be provided by IBMF * if the new transaction is a sequenced transaction. * * Input arguments: * Handle to the IBMF interface * IBMF QP handle (either allocated via ibmf_alloc_qp() or * IBMF_QP_HANDLE_DEFAULT [see the NOTE above regarding MAD class]) * Pointer to ibmf_msg_t to be sent * A pointer to ibmf_retrans_t to specify retries and timeout * values to use during the transaction. * Function to be called when the operation is done. * (the routine is blocking if this function is NULL). * Argument to be passed when the callback is invoked * flags - set IBMF_MSG_TRANS_FLAG_RMPP if send should use RMPP * set IBMF_MSG_TRANS_FLAG_SEQ if transaction is sequenced * * Output arguments: * None * * Return values: * IBMF_SUCCESS - If blocking call, the operation was * completed by the transport. For * non blocking call, the request passed basic * checks and the callback should be expected. * IBMF_BAD_HANDLE - operation failure - invalid ibmf handle * IBMF_BAD_QP_HANDLE - operation failure - invalid qp handle or * q_key/p_key in msgp->ip_local_addr is * inconsistent with ibmf_qp_handle (for eg., * handle is IBMF_QP_HANDLE_DEFAULT and * Q_Key/P_Key is non-default and platform * doesn't support non-default keys on this * qp_handle or handle is IBMF_QP_HANDLE_DEFAULT * but MAD class is not the one specified to * ibmf_register()) * IBMF_BAD_PORT_STATE - operation failure - port in incorrect state * for packet transmission * IBMF_NO_RESOURCES - operation failure - temporarily out of * resources and call may succeed on a retry * IBMF_FAILURE - operation failure - unspecified error * IBMF_BAD_SIZE - data size in message to long for single UD pkt * IBMF_BAD_RMPP_OPT - the class or QP does not support RMPP * IBMF_PARTIAL_TRANSFER - only part of the received data was returned * to the client up to the message size limit. * IBMF_TRANS_TIMEOUT - transaction timed out * IBMF_TRANS_FAILURE - transaction failure * IBMF_REQ_INVALID - tried to reuse receive buffer for sending * message data in a sequenced operation. * IBMF_BUSY - message already being processed * IBMF_INVALID_ARG - invalid argument * IBMF_FAILURE - ibmf internal error * IBMF_NO_RESOURCES - not enough resources * IBMF_TRANSPORT_FAILURE - transport call failed * IBMF_BAD_SIZE - if msgp->im_msgbufs_send.im_bufs_mad_hdr * is NULL when ibmf_qp_handle is the default * QP handle, OR, if * msgp->im_msgbufs_send.im_bufs_mad_hdr * is NULL when ibmf_qp_handle is not the default * QP handle and the alternate QP is not being * used for RAW data traffic. */ int ibmf_msg_transport( ibmf_handle_t ibmf_handle, ibmf_qp_handle_t ibmf_qp_handle, ibmf_msg_t *msgp, ibmf_retrans_t *retrans, ibmf_msg_cb_t msg_cb, void *msg_cb_args, uint_t flags); #define IBMF_MSG_TRANS_FLAG_RMPP 0x1 #define IBMF_MSG_TRANS_FLAG_SEQ 0x2 /* * ibmf_alloc_msg(): * * Alloc memory to hold the message being sent out or being received. * The IBMF client must provide the buffers in im_msgbufs_send before * calling ibmf_msg_transport(). If this message is used in a sequenced * transaction response or an unsolicited transaction, IBMF will provide * the buffers in im_msgbufs_recv with the response, once the * transaction is complete. * The client is responsible for freeing the buffers pointed to in * im_msgbufs_send when they are no longer needed. IBMF will free the buffers * in im_msgbufs_send once ibmf_free_msg() is called by the client. * * This interface may block if IBMF_ALLOC_SLEEP is specified. * * Input arguments: * Handle to the IBMF interface * sleep flag - IBMF_ALLOC_SLEEP/IBMF_ALLOC_NOSLEEP * * Output arguments: * Pointer to the buffer allocated; may be NULL if system runs out * of memory and IBMF_ALLOC_NOSLEEP is specified. * * Return values: * IBMF_SUCCESS - allocation successful * IBMF_BAD_HANDLE - alloc failed - Invalid IBMF handle passed in * IBMF_BAD_FLAGS - allocation failed - invalid flags * IBMF_INVALID_ARG - allocation failed - invalid argument * IBMF_FAILURE - ibmf internal error * IBMF_NO_RESOURCES - not enough resources * IBMF_TRANSPORT_FAILURE - transport call failed */ int ibmf_alloc_msg( ibmf_handle_t ibmf_handle, int flag, ibmf_msg_t **ibmf_msgpp); /* * ibmf_free_msg(): * * Free message context. This message context is either allocated when * the client calls ibmf_alloc_msg() or is allocated by IBMF automatically in * response to incoming unsolicited messages. For all incoming messages, * solicited or unsolicited, IBMF will provide the buffers pointed to * in im_msgbufs_recv. In addition to freeing the message context, * IBMF is responsible for freeing any buffers allocated by itself, * and pointed to in im_msgbufs_recv when the client calls ibmf_free_msg(). * * This interface does not block * * Input arguments: * Handle to the IBMF interface * Pointer to the buffer to be freed * * Output arguments: * None * * Return values: * IBMF_SUCCESS - free successful * IBMF_BAD_HANDLE - free failed - Invalid IBMF handle passed in * IBMF_BUSY - free failed - message in use * IBMF_INVALID_ARG - free failed - invalid argument * IBMF_FAILURE - ibmf internal error * IBMF_NO_RESOURCES - not enough resources * IBMF_TRANSPORT_FAILURE - transport call failed */ int ibmf_free_msg( ibmf_handle_t ibmf_handle, ibmf_msg_t **ibmf_msgpp); /* * ibmf_alloc_qp(): * * Alloc a qp with the specified P_key and Q_key values. A pointer to * ibmf_qp_handle_t is returned if the call is successful. The qp is * associated with the port that ibmf_handle corresponds to. * * Non-special QPs may be tagged to send and receive * one of the three types of traffic, either non-MAD UD, or MADs with * RMPP or MADs without RMPP. * The tagging should be done when calling ibmf_alloc_qp() * by setting the flags argument in the ibmf_alloc_qp() interface * function call to specifically defined values. * Only one, and at least one, of these flags must be specified. * * A client may specify the IBMF_ALT_QP_RAW_ONLY flag to limit * the QP to non-MAD UD traffic. If this flag is specified, and the * IBMF implementation supports this flag, the client may send * and receive MADs up to the maximum MTU supported on the link * connected to the chosen port. * * If any of the flag options are not supported by the IBMF implementation, * IBMF will return IBMF_NOT_SUPPORTED. * * This interface may block * * Input arguments: * Handle to the IBMF interface * P_Key * Q_Key * flags - IBMF_ALT_QP_MAD_NO_RMPP = MAD traffic only, * IBMF_ALT_QP_MAD_RMPP = RMPP MADs only, * IBMF_ALT_QP_RAW_ONLY = Non-MAD UD traffic only * * Output arguments: * Pointer to the qp handle * * Return values: * IBMF_SUCCESS - allocation successful * IBMF_BAD_HANDLE - alloc failed - Invalid IBMF handle passed in * IBMF_NO_RESOURCES - alloc failed - no resources for qp allocation * IBMF_BAD_FLAGS - allocation failed - bad flag combination * IBMF_NOT_SUPPORTED - allocation failed - unsupported traffic * IBMF_INVALID_ARG - allocation failed - invalid argument * IBMF_NO_RESOURCES - not enough resources * IBMF_TRANSPORT_FAILURE - transport call failed * */ int ibmf_alloc_qp( ibmf_handle_t ibmf_handle, ib_pkey_t p_key, ib_qkey_t q_key, uint_t flags, ibmf_qp_handle_t *ibmf_qp_handlep); /* Flags values for ibmf_alloc_qp() flags argument */ #define IBMF_ALT_QP_MAD_NO_RMPP 0x1 #define IBMF_ALT_QP_MAD_RMPP 0x2 #define IBMF_ALT_QP_RAW_ONLY 0x4 /* * ibmf_query_qp(): * * This function returns the P_Key, Q_Key, qp num and the port num that the * qp_handle corresponds to. It is possible that some other thread is * modifying the p_key and q_key for the qp_handle while this function is * executing or some other thread modifies the p_key/q_key values after the * function returns. * It is the callers responsibility to deal with these cases. * * This interface does not block. * * Input arguments: * Handle to the IBMF interface * IBMF qp handle (this can not be IBMF_QP_HANDLE_DEFAULT) * flags - unused (should be 0) * * Output arguments: * Pointer to QP num * Pointer to P_key * Pointer to Q_key * Pointer to the port num * * Return values: * IBMF_SUCCESS - call successful * IBMF_BAD_HANDLE - failure - Invalid IBMF handle * IBMF_BAD_QP_HANDLE - failure - Invalid qp handle * IBMF_INVALID_ARG - failure - invalid argument * IBMF_TRANSPORT_FAILURE - transport call failed */ int ibmf_query_qp( ibmf_handle_t ibmf_handle, ibmf_qp_handle_t ibmf_qp_handle, uint_t *qp_num, ib_pkey_t *p_key, ib_qkey_t *q_key, uint8_t *portnum, uint_t flags); /* * ibmf_modify_qp(): * * This function sets the p_key and q_key associated with the qp handle to the * values specified. * * This interface may block. * * Input arguments: * Handle to the IBMF interface * IBMF qp handle (this can not be IBMF_QP_HANDLE_DEFAULT) * P_key * Q_key * flags - unused (should be 0) * * Output arguments: * None * * Return values: * IBMF_SUCCESS - call successful * IBMF_BAD_HANDLE - failure - Invalid IBMF handle or qp handle * IBMF_BAD_QP_HANDLE - failure - Invalid qp handle * IBMF_INVALID_ARG - failure - invalid argument * IBMF_TRANSPORT_FAILURE - transport call failed */ int ibmf_modify_qp( ibmf_handle_t ibmf_handle, ibmf_qp_handle_t ibmf_qp_handle, ib_pkey_t p_key, ib_qkey_t q_key, uint_t flags); /* * ibmf_free_qp(): * * This function frees a qp allocated by ibmf_alloc_qp(). * The ibmf handle argument must be the same ibmf handle used in the * corresponding ibmf_alloc_qp() call. ibmf_unregister() for the ibmf * handle will not be allowed until all associated qps are freed. * The client must have already invoked ibmf_tear_down_recv_cb() * for this qp handle prior to calling ibmf_free_qp(), else IBMF_BUSY * will be returned. * * This interface may block. * * Input arguments: * Handle to the IBMF interface * IBMF qp handle pointer (this can not be IBMF_QP_HANDLE_DEFAULT) * flags - unused (should be 0) * * Output arguments: * IBMF qp handle; will be invalidated following successful return from * this call * * Return values: * IBMF_SUCCESS - call successful * IBMF_BAD_HANDLE - failure - Invalid IBMF handle or qp handle * IBMF_BAD_QP_HANDLE - failure - Invalid qp handle * IBMF_BUSY - failure - callback is active * IBMF_INVALID_ARG - failure - invalid argument * IBMF_TRANSPORT_FAILURE - transport call failed */ int ibmf_free_qp( ibmf_handle_t ibmf_handle, ibmf_qp_handle_t *ibmf_qp_handle, uint_t flags); #ifdef __cplusplus } #endif #endif /* _SYS_IB_MGT_IBMF_IBMF_H */