linux_dsm_epyc7002/include/linux/nvme-fc-driver.h

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/*
* Copyright (c) 2016, Avago Technologies
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*/
#ifndef _NVME_FC_DRIVER_H
#define _NVME_FC_DRIVER_H 1
/*
* ********************** LLDD FC-NVME Host API ********************
*
* For FC LLDD's that are the NVME Host role.
*
* ******************************************************************
*/
/* FC Port role bitmask - can merge with FC Port Roles in fc transport */
#define FC_PORT_ROLE_NVME_INITIATOR 0x10
#define FC_PORT_ROLE_NVME_TARGET 0x20
#define FC_PORT_ROLE_NVME_DISCOVERY 0x40
/**
* struct nvme_fc_port_info - port-specific ids and FC connection-specific
* data element used during NVME Host role
* registrations
*
* Static fields describing the port being registered:
* @node_name: FC WWNN for the port
* @port_name: FC WWPN for the port
* @port_role: What NVME roles are supported (see FC_PORT_ROLE_xxx)
* @dev_loss_tmo: maximum delay for reconnects to an association on
* this device. Used only on a remoteport.
*
* Initialization values for dynamic port fields:
* @port_id: FC N_Port_ID currently assigned the port. Upper 8 bits must
* be set to 0.
*/
struct nvme_fc_port_info {
u64 node_name;
u64 port_name;
u32 port_role;
u32 port_id;
u32 dev_loss_tmo;
};
/**
* struct nvmefc_ls_req - Request structure passed from NVME-FC transport
* to LLDD in order to perform a NVME FC-4 LS
* request and obtain a response.
*
* Values set by the NVME-FC layer prior to calling the LLDD ls_req
* entrypoint.
* @rqstaddr: pointer to request buffer
* @rqstdma: PCI DMA address of request buffer
* @rqstlen: Length, in bytes, of request buffer
* @rspaddr: pointer to response buffer
* @rspdma: PCI DMA address of response buffer
* @rsplen: Length, in bytes, of response buffer
* @timeout: Maximum amount of time, in seconds, to wait for the LS response.
* If timeout exceeded, LLDD to abort LS exchange and complete
* LS request with error status.
* @private: pointer to memory allocated alongside the ls request structure
* that is specifically for the LLDD to use while processing the
* request. The length of the buffer corresponds to the
* lsrqst_priv_sz value specified in the nvme_fc_port_template
* supplied by the LLDD.
* @done: The callback routine the LLDD is to invoke upon completion of
* the LS request. req argument is the pointer to the original LS
* request structure. Status argument must be 0 upon success, a
* negative errno on failure (example: -ENXIO).
*/
struct nvmefc_ls_req {
void *rqstaddr;
dma_addr_t rqstdma;
u32 rqstlen;
void *rspaddr;
dma_addr_t rspdma;
u32 rsplen;
u32 timeout;
void *private;
void (*done)(struct nvmefc_ls_req *req, int status);
} __aligned(sizeof(u64)); /* alignment for other things alloc'd with */
enum nvmefc_fcp_datadir {
NVMEFC_FCP_NODATA, /* payload_length and sg_cnt will be zero */
NVMEFC_FCP_WRITE,
NVMEFC_FCP_READ,
};
/**
* struct nvmefc_fcp_req - Request structure passed from NVME-FC transport
* to LLDD in order to perform a NVME FCP IO operation.
*
* Values set by the NVME-FC layer prior to calling the LLDD fcp_io
* entrypoint.
* @cmdaddr: pointer to the FCP CMD IU buffer
* @rspaddr: pointer to the FCP RSP IU buffer
* @cmddma: PCI DMA address of the FCP CMD IU buffer
* @rspdma: PCI DMA address of the FCP RSP IU buffer
* @cmdlen: Length, in bytes, of the FCP CMD IU buffer
* @rsplen: Length, in bytes, of the FCP RSP IU buffer
* @payload_length: Length of DATA_IN or DATA_OUT payload data to transfer
* @sg_table: scatter/gather structure for payload data
* @first_sgl: memory for 1st scatter/gather list segment for payload data
* @sg_cnt: number of elements in the scatter/gather list
* @io_dir: direction of the FCP request (see NVMEFC_FCP_xxx)
* @sqid: The nvme SQID the command is being issued on
* @done: The callback routine the LLDD is to invoke upon completion of
* the FCP operation. req argument is the pointer to the original
* FCP IO operation.
* @private: pointer to memory allocated alongside the FCP operation
* request structure that is specifically for the LLDD to use
* while processing the operation. The length of the buffer
* corresponds to the fcprqst_priv_sz value specified in the
* nvme_fc_port_template supplied by the LLDD.
*
* Values set by the LLDD indicating completion status of the FCP operation.
* Must be set prior to calling the done() callback.
* @transferred_length: amount of payload data, in bytes, that were
* transferred. Should equal payload_length on success.
* @rcv_rsplen: length, in bytes, of the FCP RSP IU received.
* @status: Completion status of the FCP operation. must be 0 upon success,
* negative errno value upon failure (ex: -EIO). Note: this is
* NOT a reflection of the NVME CQE completion status. Only the
* status of the FCP operation at the NVME-FC level.
*/
struct nvmefc_fcp_req {
void *cmdaddr;
void *rspaddr;
dma_addr_t cmddma;
dma_addr_t rspdma;
u16 cmdlen;
u16 rsplen;
u32 payload_length;
struct sg_table sg_table;
struct scatterlist *first_sgl;
int sg_cnt;
enum nvmefc_fcp_datadir io_dir;
__le16 sqid;
void (*done)(struct nvmefc_fcp_req *req);
void *private;
u32 transferred_length;
u16 rcv_rsplen;
u32 status;
} __aligned(sizeof(u64)); /* alignment for other things alloc'd with */
/*
* Direct copy of fc_port_state enum. For later merging
*/
enum nvme_fc_obj_state {
FC_OBJSTATE_UNKNOWN,
FC_OBJSTATE_NOTPRESENT,
FC_OBJSTATE_ONLINE,
FC_OBJSTATE_OFFLINE, /* User has taken Port Offline */
FC_OBJSTATE_BLOCKED,
FC_OBJSTATE_BYPASSED,
FC_OBJSTATE_DIAGNOSTICS,
FC_OBJSTATE_LINKDOWN,
FC_OBJSTATE_ERROR,
FC_OBJSTATE_LOOPBACK,
FC_OBJSTATE_DELETED,
};
/**
* struct nvme_fc_local_port - structure used between NVME-FC transport and
* a LLDD to reference a local NVME host port.
* Allocated/created by the nvme_fc_register_localport()
* transport interface.
*
* Fields with static values for the port. Initialized by the
* port_info struct supplied to the registration call.
* @port_num: NVME-FC transport host port number
* @port_role: NVME roles are supported on the port (see FC_PORT_ROLE_xxx)
* @node_name: FC WWNN for the port
* @port_name: FC WWPN for the port
* @private: pointer to memory allocated alongside the local port
* structure that is specifically for the LLDD to use.
* The length of the buffer corresponds to the local_priv_sz
* value specified in the nvme_fc_port_template supplied by
* the LLDD.
* @dev_loss_tmo: maximum delay for reconnects to an association on
* this device. To modify, lldd must call
* nvme_fc_set_remoteport_devloss().
*
* Fields with dynamic values. Values may change base on link state. LLDD
* may reference fields directly to change them. Initialized by the
* port_info struct supplied to the registration call.
* @port_id: FC N_Port_ID currently assigned the port. Upper 8 bits must
* be set to 0.
* @port_state: Operational state of the port.
*/
struct nvme_fc_local_port {
/* static/read-only fields */
u32 port_num;
u32 port_role;
u64 node_name;
u64 port_name;
void *private;
/* dynamic fields */
u32 port_id;
enum nvme_fc_obj_state port_state;
} __aligned(sizeof(u64)); /* alignment for other things alloc'd with */
/**
* struct nvme_fc_remote_port - structure used between NVME-FC transport and
* a LLDD to reference a remote NVME subsystem port.
* Allocated/created by the nvme_fc_register_remoteport()
* transport interface.
*
* Fields with static values for the port. Initialized by the
* port_info struct supplied to the registration call.
* @port_num: NVME-FC transport remote subsystem port number
* @port_role: NVME roles are supported on the port (see FC_PORT_ROLE_xxx)
* @node_name: FC WWNN for the port
* @port_name: FC WWPN for the port
* @localport: pointer to the NVME-FC local host port the subsystem is
* connected to.
* @private: pointer to memory allocated alongside the remote port
* structure that is specifically for the LLDD to use.
* The length of the buffer corresponds to the remote_priv_sz
* value specified in the nvme_fc_port_template supplied by
* the LLDD.
*
* Fields with dynamic values. Values may change base on link or login
* state. LLDD may reference fields directly to change them. Initialized by
* the port_info struct supplied to the registration call.
* @port_id: FC N_Port_ID currently assigned the port. Upper 8 bits must
* be set to 0.
* @port_state: Operational state of the remote port. Valid values are
* ONLINE or UNKNOWN.
*/
struct nvme_fc_remote_port {
/* static fields */
u32 port_num;
u32 port_role;
u64 node_name;
u64 port_name;
struct nvme_fc_local_port *localport;
void *private;
u32 dev_loss_tmo;
/* dynamic fields */
u32 port_id;
enum nvme_fc_obj_state port_state;
} __aligned(sizeof(u64)); /* alignment for other things alloc'd with */
/**
* struct nvme_fc_port_template - structure containing static entrypoints and
* operational parameters for an LLDD that supports NVME host
* behavior. Passed by reference in port registrations.
* NVME-FC transport remembers template reference and may
* access it during runtime operation.
*
* Host/Initiator Transport Entrypoints/Parameters:
*
* @localport_delete: The LLDD initiates deletion of a localport via
* nvme_fc_deregister_localport(). However, the teardown is
* asynchronous. This routine is called upon the completion of the
* teardown to inform the LLDD that the localport has been deleted.
* Entrypoint is Mandatory.
*
* @remoteport_delete: The LLDD initiates deletion of a remoteport via
* nvme_fc_deregister_remoteport(). However, the teardown is
* asynchronous. This routine is called upon the completion of the
* teardown to inform the LLDD that the remoteport has been deleted.
* Entrypoint is Mandatory.
*
* @create_queue: Upon creating a host<->controller association, queues are
* created such that they can be affinitized to cpus/cores. This
* callback into the LLDD to notify that a controller queue is being
* created. The LLDD may choose to allocate an associated hw queue
* or map it onto a shared hw queue. Upon return from the call, the
* LLDD specifies a handle that will be given back to it for any
* command that is posted to the controller queue. The handle can
* be used by the LLDD to map quickly to the proper hw queue for
* command execution. The mask of cpu's that will map to this queue
* at the block-level is also passed in. The LLDD should use the
* queue id and/or cpu masks to ensure proper affinitization of the
* controller queue to the hw queue.
* Entrypoint is Optional.
*
* @delete_queue: This is the inverse of the crete_queue. During
* host<->controller association teardown, this routine is called
* when a controller queue is being terminated. Any association with
* a hw queue should be termined. If there is a unique hw queue, the
* hw queue should be torn down.
* Entrypoint is Optional.
*
* @poll_queue: Called to poll for the completion of an io on a blk queue.
* Entrypoint is Optional.
*
* @ls_req: Called to issue a FC-NVME FC-4 LS service request.
* The nvme_fc_ls_req structure will fully describe the buffers for
* the request payload and where to place the response payload. The
* LLDD is to allocate an exchange, issue the LS request, obtain the
* LS response, and call the "done" routine specified in the request
* structure (argument to done is the ls request structure itself).
* Entrypoint is Mandatory.
*
* @fcp_io: called to issue a FC-NVME I/O request. The I/O may be for
* an admin queue or an i/o queue. The nvmefc_fcp_req structure will
* fully describe the io: the buffer containing the FC-NVME CMD IU
* (which contains the SQE), the sg list for the payload if applicable,
* and the buffer to place the FC-NVME RSP IU into. The LLDD will
* complete the i/o, indicating the amount of data transferred or
* any transport error, and call the "done" routine specified in the
* request structure (argument to done is the fcp request structure
* itself).
* Entrypoint is Mandatory.
*
* @ls_abort: called to request the LLDD to abort the indicated ls request.
* The call may return before the abort has completed. After aborting
* the request, the LLDD must still call the ls request done routine
* indicating an FC transport Aborted status.
* Entrypoint is Mandatory.
*
* @fcp_abort: called to request the LLDD to abort the indicated fcp request.
* The call may return before the abort has completed. After aborting
* the request, the LLDD must still call the fcp request done routine
* indicating an FC transport Aborted status.
* Entrypoint is Mandatory.
*
* @max_hw_queues: indicates the maximum number of hw queues the LLDD
* supports for cpu affinitization.
* Value is Mandatory. Must be at least 1.
*
* @max_sgl_segments: indicates the maximum number of sgl segments supported
* by the LLDD
* Value is Mandatory. Must be at least 1. Recommend at least 256.
*
* @max_dif_sgl_segments: indicates the maximum number of sgl segments
* supported by the LLDD for DIF operations.
* Value is Mandatory. Must be at least 1. Recommend at least 256.
*
* @dma_boundary: indicates the dma address boundary where dma mappings
* will be split across.
* Value is Mandatory. Typical value is 0xFFFFFFFF to split across
* 4Gig address boundarys
*
* @local_priv_sz: The LLDD sets this field to the amount of additional
* memory that it would like fc nvme layer to allocate on the LLDD's
* behalf whenever a localport is allocated. The additional memory
* area solely for the of the LLDD and its location is specified by
* the localport->private pointer.
* Value is Mandatory. Allowed to be zero.
*
* @remote_priv_sz: The LLDD sets this field to the amount of additional
* memory that it would like fc nvme layer to allocate on the LLDD's
* behalf whenever a remoteport is allocated. The additional memory
* area solely for the of the LLDD and its location is specified by
* the remoteport->private pointer.
* Value is Mandatory. Allowed to be zero.
*
* @lsrqst_priv_sz: The LLDD sets this field to the amount of additional
* memory that it would like fc nvme layer to allocate on the LLDD's
* behalf whenever a ls request structure is allocated. The additional
* memory area solely for the of the LLDD and its location is
* specified by the ls_request->private pointer.
* Value is Mandatory. Allowed to be zero.
*
* @fcprqst_priv_sz: The LLDD sets this field to the amount of additional
* memory that it would like fc nvme layer to allocate on the LLDD's
* behalf whenever a fcp request structure is allocated. The additional
* memory area solely for the of the LLDD and its location is
* specified by the fcp_request->private pointer.
* Value is Mandatory. Allowed to be zero.
*/
struct nvme_fc_port_template {
/* initiator-based functions */
void (*localport_delete)(struct nvme_fc_local_port *);
void (*remoteport_delete)(struct nvme_fc_remote_port *);
int (*create_queue)(struct nvme_fc_local_port *,
unsigned int qidx, u16 qsize,
void **handle);
void (*delete_queue)(struct nvme_fc_local_port *,
unsigned int qidx, void *handle);
void (*poll_queue)(struct nvme_fc_local_port *, void *handle);
int (*ls_req)(struct nvme_fc_local_port *,
struct nvme_fc_remote_port *,
struct nvmefc_ls_req *);
int (*fcp_io)(struct nvme_fc_local_port *,
struct nvme_fc_remote_port *,
void *hw_queue_handle,
struct nvmefc_fcp_req *);
void (*ls_abort)(struct nvme_fc_local_port *,
struct nvme_fc_remote_port *,
struct nvmefc_ls_req *);
void (*fcp_abort)(struct nvme_fc_local_port *,
struct nvme_fc_remote_port *,
void *hw_queue_handle,
struct nvmefc_fcp_req *);
u32 max_hw_queues;
u16 max_sgl_segments;
u16 max_dif_sgl_segments;
u64 dma_boundary;
/* sizes of additional private data for data structures */
u32 local_priv_sz;
u32 remote_priv_sz;
u32 lsrqst_priv_sz;
u32 fcprqst_priv_sz;
};
/*
* Initiator/Host functions
*/
int nvme_fc_register_localport(struct nvme_fc_port_info *pinfo,
struct nvme_fc_port_template *template,
struct device *dev,
struct nvme_fc_local_port **lport_p);
int nvme_fc_unregister_localport(struct nvme_fc_local_port *localport);
int nvme_fc_register_remoteport(struct nvme_fc_local_port *localport,
struct nvme_fc_port_info *pinfo,
struct nvme_fc_remote_port **rport_p);
int nvme_fc_unregister_remoteport(struct nvme_fc_remote_port *remoteport);
void nvme_fc_rescan_remoteport(struct nvme_fc_remote_port *remoteport);
int nvme_fc_set_remoteport_devloss(struct nvme_fc_remote_port *remoteport,
u32 dev_loss_tmo);
/*
* *************** LLDD FC-NVME Target/Subsystem API ***************
*
* For FC LLDD's that are the NVME Subsystem role
*
* ******************************************************************
*/
/**
* struct nvmet_fc_port_info - port-specific ids and FC connection-specific
* data element used during NVME Subsystem role
* registrations
*
* Static fields describing the port being registered:
* @node_name: FC WWNN for the port
* @port_name: FC WWPN for the port
*
* Initialization values for dynamic port fields:
* @port_id: FC N_Port_ID currently assigned the port. Upper 8 bits must
* be set to 0.
*/
struct nvmet_fc_port_info {
u64 node_name;
u64 port_name;
u32 port_id;
};
/**
* struct nvmefc_tgt_ls_req - Structure used between LLDD and NVMET-FC
* layer to represent the exchange context for
* a FC-NVME Link Service (LS).
*
* The structure is allocated by the LLDD whenever a LS Request is received
* from the FC link. The address of the structure is passed to the nvmet-fc
* layer via the nvmet_fc_rcv_ls_req() call. The address of the structure
* will be passed back to the LLDD when the response is to be transmit.
* The LLDD is to use the address to map back to the LLDD exchange structure
* which maintains information such as the targetport the LS was received
* on, the remote FC NVME initiator that sent the LS, and any FC exchange
* context. Upon completion of the LS response transmit, the address of the
* structure will be passed back to the LS rsp done() routine, allowing the
* nvmet-fc layer to release dma resources. Upon completion of the done()
* routine, no further access will be made by the nvmet-fc layer and the
* LLDD can de-allocate the structure.
*
* Field initialization:
* At the time of the nvmet_fc_rcv_ls_req() call, there is no content that
* is valid in the structure.
*
* When the structure is used for the LLDD->xmt_ls_rsp() call, the nvmet-fc
* layer will fully set the fields in order to specify the response
* payload buffer and its length as well as the done routine to be called
* upon compeletion of the transmit. The nvmet-fc layer will also set a
* private pointer for its own use in the done routine.
*
* Values set by the NVMET-FC layer prior to calling the LLDD xmt_ls_rsp
* entrypoint.
* @rspbuf: pointer to the LS response buffer
* @rspdma: PCI DMA address of the LS response buffer
* @rsplen: Length, in bytes, of the LS response buffer
* @done: The callback routine the LLDD is to invoke upon completion of
* transmitting the LS response. req argument is the pointer to
* the original ls request.
* @nvmet_fc_private: pointer to an internal NVMET-FC layer structure used
* as part of the NVMET-FC processing. The LLDD is not to access
* this pointer.
*/
struct nvmefc_tgt_ls_req {
void *rspbuf;
dma_addr_t rspdma;
u16 rsplen;
void (*done)(struct nvmefc_tgt_ls_req *req);
void *nvmet_fc_private; /* LLDD is not to access !! */
};
/* Operations that NVME-FC layer may request the LLDD to perform for FCP */
enum {
NVMET_FCOP_READDATA = 1, /* xmt data to initiator */
NVMET_FCOP_WRITEDATA = 2, /* xmt data from initiator */
NVMET_FCOP_READDATA_RSP = 3, /* xmt data to initiator and send
* rsp as well
*/
NVMET_FCOP_RSP = 4, /* send rsp frame */
};
/**
* struct nvmefc_tgt_fcp_req - Structure used between LLDD and NVMET-FC
* layer to represent the exchange context and
* the specific FC-NVME IU operation(s) to perform
* for a FC-NVME FCP IO.
*
* Structure used between LLDD and nvmet-fc layer to represent the exchange
* context for a FC-NVME FCP I/O operation (e.g. a nvme sqe, the sqe-related
* memory transfers, and its assocated cqe transfer).
*
* The structure is allocated by the LLDD whenever a FCP CMD IU is received
* from the FC link. The address of the structure is passed to the nvmet-fc
* layer via the nvmet_fc_rcv_fcp_req() call. The address of the structure
* will be passed back to the LLDD for the data operations and transmit of
* the response. The LLDD is to use the address to map back to the LLDD
* exchange structure which maintains information such as the targetport
* the FCP I/O was received on, the remote FC NVME initiator that sent the
* FCP I/O, and any FC exchange context. Upon completion of the FCP target
* operation, the address of the structure will be passed back to the FCP
* op done() routine, allowing the nvmet-fc layer to release dma resources.
* Upon completion of the done() routine for either RSP or ABORT ops, no
* further access will be made by the nvmet-fc layer and the LLDD can
* de-allocate the structure.
*
* Field initialization:
* At the time of the nvmet_fc_rcv_fcp_req() call, there is no content that
* is valid in the structure.
*
* When the structure is used for an FCP target operation, the nvmet-fc
* layer will fully set the fields in order to specify the scattergather
* list, the transfer length, as well as the done routine to be called
* upon compeletion of the operation. The nvmet-fc layer will also set a
* private pointer for its own use in the done routine.
*
* Values set by the NVMET-FC layer prior to calling the LLDD fcp_op
* entrypoint.
* @op: Indicates the FCP IU operation to perform (see NVMET_FCOP_xxx)
* @hwqid: Specifies the hw queue index (0..N-1, where N is the
* max_hw_queues value from the LLD's nvmet_fc_target_template)
* that the operation is to use.
* @offset: Indicates the DATA_OUT/DATA_IN payload offset to be tranferred.
* Field is only valid on WRITEDATA, READDATA, or READDATA_RSP ops.
* @timeout: amount of time, in seconds, to wait for a response from the NVME
* host. A value of 0 is an infinite wait.
* Valid only for the following ops:
* WRITEDATA: caps the wait for data reception
* READDATA_RSP & RSP: caps wait for FCP_CONF reception (if used)
* @transfer_length: the length, in bytes, of the DATA_OUT or DATA_IN payload
* that is to be transferred.
* Valid only for the WRITEDATA, READDATA, or READDATA_RSP ops.
* @ba_rjt: Contains the BA_RJT payload that is to be transferred.
* Valid only for the NVMET_FCOP_BA_RJT op.
* @sg: Scatter/gather list for the DATA_OUT/DATA_IN payload data.
* Valid only for the WRITEDATA, READDATA, or READDATA_RSP ops.
* @sg_cnt: Number of valid entries in the scatter/gather list.
* Valid only for the WRITEDATA, READDATA, or READDATA_RSP ops.
* @rspaddr: pointer to the FCP RSP IU buffer to be transmit
* Used by RSP and READDATA_RSP ops
* @rspdma: PCI DMA address of the FCP RSP IU buffer
* Used by RSP and READDATA_RSP ops
* @rsplen: Length, in bytes, of the FCP RSP IU buffer
* Used by RSP and READDATA_RSP ops
* @done: The callback routine the LLDD is to invoke upon completion of
* the operation. req argument is the pointer to the original
* FCP subsystem op request.
* @nvmet_fc_private: pointer to an internal NVMET-FC layer structure used
* as part of the NVMET-FC processing. The LLDD is not to
* reference this field.
*
* Values set by the LLDD indicating completion status of the FCP operation.
* Must be set prior to calling the done() callback.
* @transferred_length: amount of DATA_OUT payload data received by a
* a WRITEDATA operation. If not a WRITEDATA operation, value must
* be set to 0. Should equal transfer_length on success.
* @fcp_error: status of the FCP operation. Must be 0 on success; on failure
* must be a NVME_SC_FC_xxxx value.
*/
struct nvmefc_tgt_fcp_req {
u8 op;
u16 hwqid;
u32 offset;
u32 timeout;
u32 transfer_length;
struct fc_ba_rjt ba_rjt;
struct scatterlist *sg;
int sg_cnt;
void *rspaddr;
dma_addr_t rspdma;
u16 rsplen;
void (*done)(struct nvmefc_tgt_fcp_req *);
void *nvmet_fc_private; /* LLDD is not to access !! */
u32 transferred_length;
int fcp_error;
};
/* Target Features (Bit fields) LLDD supports */
enum {
NVMET_FCTGTFEAT_READDATA_RSP = (1 << 0),
/* Bit 0: supports the NVMET_FCPOP_READDATA_RSP op, which
* sends (the last) Read Data sequence followed by the RSP
* sequence in one LLDD operation. Errors during Data
* sequence transmit must not allow RSP sequence to be sent.
*/
NVMET_FCTGTFEAT_CMD_IN_ISR = (1 << 1),
/* Bit 2: When 0, the LLDD is calling the cmd rcv handler
* in a non-isr context, allowing the transport to finish
* op completion in the calling context. When 1, the LLDD
* is calling the cmd rcv handler in an ISR context,
* requiring the transport to transition to a workqueue
* for op completion.
*/
NVMET_FCTGTFEAT_OPDONE_IN_ISR = (1 << 2),
/* Bit 3: When 0, the LLDD is calling the op done handler
* in a non-isr context, allowing the transport to finish
* op completion in the calling context. When 1, the LLDD
* is calling the op done handler in an ISR context,
* requiring the transport to transition to a workqueue
* for op completion.
*/
};
/**
* struct nvmet_fc_target_port - structure used between NVME-FC transport and
* a LLDD to reference a local NVME subsystem port.
* Allocated/created by the nvme_fc_register_targetport()
* transport interface.
*
* Fields with static values for the port. Initialized by the
* port_info struct supplied to the registration call.
* @port_num: NVME-FC transport subsytem port number
* @node_name: FC WWNN for the port
* @port_name: FC WWPN for the port
* @private: pointer to memory allocated alongside the local port
* structure that is specifically for the LLDD to use.
* The length of the buffer corresponds to the target_priv_sz
* value specified in the nvme_fc_target_template supplied by
* the LLDD.
*
* Fields with dynamic values. Values may change base on link state. LLDD
* may reference fields directly to change them. Initialized by the
* port_info struct supplied to the registration call.
* @port_id: FC N_Port_ID currently assigned the port. Upper 8 bits must
* be set to 0.
* @port_state: Operational state of the port.
*/
struct nvmet_fc_target_port {
/* static/read-only fields */
u32 port_num;
u64 node_name;
u64 port_name;
void *private;
/* dynamic fields */
u32 port_id;
enum nvme_fc_obj_state port_state;
} __aligned(sizeof(u64)); /* alignment for other things alloc'd with */
/**
* struct nvmet_fc_target_template - structure containing static entrypoints
* and operational parameters for an LLDD that supports NVME
* subsystem behavior. Passed by reference in port
* registrations. NVME-FC transport remembers template
* reference and may access it during runtime operation.
*
* Subsystem/Target Transport Entrypoints/Parameters:
*
* @targetport_delete: The LLDD initiates deletion of a targetport via
* nvmet_fc_unregister_targetport(). However, the teardown is
* asynchronous. This routine is called upon the completion of the
* teardown to inform the LLDD that the targetport has been deleted.
* Entrypoint is Mandatory.
*
* @xmt_ls_rsp: Called to transmit the response to a FC-NVME FC-4 LS service.
* The nvmefc_tgt_ls_req structure is the same LLDD-supplied exchange
* structure specified in the nvmet_fc_rcv_ls_req() call made when
* the LS request was received. The structure will fully describe
* the buffers for the response payload and the dma address of the
* payload. The LLDD is to transmit the response (or return a non-zero
* errno status), and upon completion of the transmit, call the
* "done" routine specified in the nvmefc_tgt_ls_req structure
* (argument to done is the ls reqwuest structure itself).
* After calling the done routine, the LLDD shall consider the
* LS handling complete and the nvmefc_tgt_ls_req structure may
* be freed/released.
* Entrypoint is Mandatory.
*
* @fcp_op: Called to perform a data transfer or transmit a response.
* The nvmefc_tgt_fcp_req structure is the same LLDD-supplied
* exchange structure specified in the nvmet_fc_rcv_fcp_req() call
* made when the FCP CMD IU was received. The op field in the
* structure shall indicate the operation for the LLDD to perform
* relative to the io.
* NVMET_FCOP_READDATA operation: the LLDD is to send the
* payload data (described by sglist) to the host in 1 or
* more FC sequences (preferrably 1). Note: the fc-nvme layer
* may call the READDATA operation multiple times for longer
* payloads.
* NVMET_FCOP_WRITEDATA operation: the LLDD is to receive the
* payload data (described by sglist) from the host via 1 or
* more FC sequences (preferrably 1). The LLDD is to generate
* the XFER_RDY IU(s) corresponding to the data being requested.
* Note: the FC-NVME layer may call the WRITEDATA operation
* multiple times for longer payloads.
* NVMET_FCOP_READDATA_RSP operation: the LLDD is to send the
* payload data (described by sglist) to the host in 1 or
* more FC sequences (preferrably 1). If an error occurs during
* payload data transmission, the LLDD is to set the
* nvmefc_tgt_fcp_req fcp_error and transferred_length field, then
* consider the operation complete. On error, the LLDD is to not
* transmit the FCP_RSP iu. If all payload data is transferred
* successfully, the LLDD is to update the nvmefc_tgt_fcp_req
* transferred_length field and may subsequently transmit the
* FCP_RSP iu payload (described by rspbuf, rspdma, rsplen).
* If FCP_CONF is supported, the LLDD is to await FCP_CONF
* reception to confirm the RSP reception by the host. The LLDD
* may retramsit the FCP_RSP iu if necessary per FC-NVME. Upon
* transmission of the FCP_RSP iu if FCP_CONF is not supported,
* or upon success/failure of FCP_CONF if it is supported, the
* LLDD is to set the nvmefc_tgt_fcp_req fcp_error field and
* consider the operation complete.
* NVMET_FCOP_RSP: the LLDD is to transmit the FCP_RSP iu payload
* (described by rspbuf, rspdma, rsplen). If FCP_CONF is
* supported, the LLDD is to await FCP_CONF reception to confirm
* the RSP reception by the host. The LLDD may retramsit the
* FCP_RSP iu if FCP_CONF is not received per FC-NVME. Upon
* transmission of the FCP_RSP iu if FCP_CONF is not supported,
* or upon success/failure of FCP_CONF if it is supported, the
* LLDD is to set the nvmefc_tgt_fcp_req fcp_error field and
* consider the operation complete.
* Upon completing the indicated operation, the LLDD is to set the
* status fields for the operation (tranferred_length and fcp_error
* status) in the request, then call the "done" routine
* indicated in the fcp request. After the operation completes,
* regardless of whether the FCP_RSP iu was successfully transmit,
* the LLDD-supplied exchange structure must remain valid until the
* transport calls the fcp_req_release() callback to return ownership
* of the exchange structure back to the LLDD so that it may be used
* for another fcp command.
* Note: when calling the done routine for READDATA or WRITEDATA
* operations, the fc-nvme layer may immediate convert, in the same
* thread and before returning to the LLDD, the fcp operation to
* the next operation for the fcp io and call the LLDDs fcp_op
* call again. If fields in the fcp request are to be accessed post
* the done call, the LLDD should save their values prior to calling
* the done routine, and inspect the save values after the done
* routine.
* Returns 0 on success, -<errno> on failure (Ex: -EIO)
* Entrypoint is Mandatory.
*
nvmet_fc: Rework target side abort handling target transport: ---------------------- There are cases when there is a need to abort in-progress target operations (writedata) so that controller termination or errors can clean up. That can't happen currently as the abort is another target op type, so it can't be used till the running one finishes (and it may not). Solve by removing the abort op type and creating a separate downcall from the transport to the lldd to request an io to be aborted. The transport will abort ios on queue teardown or io errors. In general the transport tries to call the lldd abort only when the io state is idle. Meaning: ops that transmit data (readdata or rsp) will always finish their transmit (or the lldd will see a state on the link or initiator port that fails the transmit) and the done call for the operation will occur. The transport will wait for the op done upcall before calling the abort function, and as the io is idle, the io can be cleaned up immediately after the abort call; Similarly, ios that are not waiting for data or transmitting data must be in the nvmet layer being processed. The transport will wait for the nvmet layer completion before calling the abort function, and as the io is idle, the io can be cleaned up immediately after the abort call; As for ops that are waiting for data (writedata), they may be outstanding indefinitely if the lldd doesn't see a condition where the initiatior port or link is bad. In those cases, the transport will call the abort function and wait for the lldd's op done upcall for the operation, where it will then clean up the io. Additionally, if a lldd receives an ABTS and matches it to an outstanding request in the transport, A new new transport upcall was created to abort the outstanding request in the transport. The transport expects any outstanding op call (readdata or writedata) will completed by the lldd and the operation upcall made. The transport doesn't act on the reported abort (e.g. clean up the io) until an op done upcall occurs, a new op is attempted, or the nvmet layer completes the io processing. fcloop: ---------------------- Updated to support the new target apis. On fcp io aborts from the initiator, the loopback context is updated to NULL out the half that has completed. The initiator side is immediately called after the abort request with an io completion (abort status). On fcp io aborts from the target, the io is stopped and the initiator side sees it as an aborted io. Target side ops, perhaps in progress while the initiator side is done, continue but noop the data movement as there's no structure on the initiator side to reference. patch also contains: ---------------------- Revised lpfc to support the new abort api commonized rsp buffer syncing and nulling of private data based on calling paths. errors in op done calls don't take action on the fod. They're bad operations which implies the fod may be bad. Signed-off-by: James Smart <james.smart@broadcom.com> Signed-off-by: Sagi Grimberg <sagi@grimberg.me>
2017-04-12 01:32:31 +07:00
* @fcp_abort: Called by the transport to abort an active command.
* The command may be in-between operations (nothing active in LLDD)
* or may have an active WRITEDATA operation pending. The LLDD is to
* initiate the ABTS process for the command and return from the
* callback. The ABTS does not need to be complete on the command.
* The fcp_abort callback inherently cannot fail. After the
* fcp_abort() callback completes, the transport will wait for any
* outstanding operation (if there was one) to complete, then will
* call the fcp_req_release() callback to return the command's
* exchange context back to the LLDD.
* Entrypoint is Mandatory.
nvmet_fc: Rework target side abort handling target transport: ---------------------- There are cases when there is a need to abort in-progress target operations (writedata) so that controller termination or errors can clean up. That can't happen currently as the abort is another target op type, so it can't be used till the running one finishes (and it may not). Solve by removing the abort op type and creating a separate downcall from the transport to the lldd to request an io to be aborted. The transport will abort ios on queue teardown or io errors. In general the transport tries to call the lldd abort only when the io state is idle. Meaning: ops that transmit data (readdata or rsp) will always finish their transmit (or the lldd will see a state on the link or initiator port that fails the transmit) and the done call for the operation will occur. The transport will wait for the op done upcall before calling the abort function, and as the io is idle, the io can be cleaned up immediately after the abort call; Similarly, ios that are not waiting for data or transmitting data must be in the nvmet layer being processed. The transport will wait for the nvmet layer completion before calling the abort function, and as the io is idle, the io can be cleaned up immediately after the abort call; As for ops that are waiting for data (writedata), they may be outstanding indefinitely if the lldd doesn't see a condition where the initiatior port or link is bad. In those cases, the transport will call the abort function and wait for the lldd's op done upcall for the operation, where it will then clean up the io. Additionally, if a lldd receives an ABTS and matches it to an outstanding request in the transport, A new new transport upcall was created to abort the outstanding request in the transport. The transport expects any outstanding op call (readdata or writedata) will completed by the lldd and the operation upcall made. The transport doesn't act on the reported abort (e.g. clean up the io) until an op done upcall occurs, a new op is attempted, or the nvmet layer completes the io processing. fcloop: ---------------------- Updated to support the new target apis. On fcp io aborts from the initiator, the loopback context is updated to NULL out the half that has completed. The initiator side is immediately called after the abort request with an io completion (abort status). On fcp io aborts from the target, the io is stopped and the initiator side sees it as an aborted io. Target side ops, perhaps in progress while the initiator side is done, continue but noop the data movement as there's no structure on the initiator side to reference. patch also contains: ---------------------- Revised lpfc to support the new abort api commonized rsp buffer syncing and nulling of private data based on calling paths. errors in op done calls don't take action on the fod. They're bad operations which implies the fod may be bad. Signed-off-by: James Smart <james.smart@broadcom.com> Signed-off-by: Sagi Grimberg <sagi@grimberg.me>
2017-04-12 01:32:31 +07:00
*
* @fcp_req_release: Called by the transport to return a nvmefc_tgt_fcp_req
* to the LLDD after all operations on the fcp operation are complete.
* This may be due to the command completing or upon completion of
* abort cleanup.
* Entrypoint is Mandatory.
*
* @defer_rcv: Called by the transport to signal the LLLD that it has
* begun processing of a previously received NVME CMD IU. The LLDD
* is now free to re-use the rcv buffer associated with the
* nvmefc_tgt_fcp_req.
* Entrypoint is Optional.
*
* @max_hw_queues: indicates the maximum number of hw queues the LLDD
* supports for cpu affinitization.
* Value is Mandatory. Must be at least 1.
*
* @max_sgl_segments: indicates the maximum number of sgl segments supported
* by the LLDD
* Value is Mandatory. Must be at least 1. Recommend at least 256.
*
* @max_dif_sgl_segments: indicates the maximum number of sgl segments
* supported by the LLDD for DIF operations.
* Value is Mandatory. Must be at least 1. Recommend at least 256.
*
* @dma_boundary: indicates the dma address boundary where dma mappings
* will be split across.
* Value is Mandatory. Typical value is 0xFFFFFFFF to split across
* 4Gig address boundarys
*
* @target_features: The LLDD sets bits in this field to correspond to
* optional features that are supported by the LLDD.
* Refer to the NVMET_FCTGTFEAT_xxx values.
* Value is Mandatory. Allowed to be zero.
*
* @target_priv_sz: The LLDD sets this field to the amount of additional
* memory that it would like fc nvme layer to allocate on the LLDD's
* behalf whenever a targetport is allocated. The additional memory
* area solely for the of the LLDD and its location is specified by
* the targetport->private pointer.
* Value is Mandatory. Allowed to be zero.
*/
struct nvmet_fc_target_template {
void (*targetport_delete)(struct nvmet_fc_target_port *tgtport);
int (*xmt_ls_rsp)(struct nvmet_fc_target_port *tgtport,
struct nvmefc_tgt_ls_req *tls_req);
int (*fcp_op)(struct nvmet_fc_target_port *tgtport,
struct nvmefc_tgt_fcp_req *fcpreq);
nvmet_fc: Rework target side abort handling target transport: ---------------------- There are cases when there is a need to abort in-progress target operations (writedata) so that controller termination or errors can clean up. That can't happen currently as the abort is another target op type, so it can't be used till the running one finishes (and it may not). Solve by removing the abort op type and creating a separate downcall from the transport to the lldd to request an io to be aborted. The transport will abort ios on queue teardown or io errors. In general the transport tries to call the lldd abort only when the io state is idle. Meaning: ops that transmit data (readdata or rsp) will always finish their transmit (or the lldd will see a state on the link or initiator port that fails the transmit) and the done call for the operation will occur. The transport will wait for the op done upcall before calling the abort function, and as the io is idle, the io can be cleaned up immediately after the abort call; Similarly, ios that are not waiting for data or transmitting data must be in the nvmet layer being processed. The transport will wait for the nvmet layer completion before calling the abort function, and as the io is idle, the io can be cleaned up immediately after the abort call; As for ops that are waiting for data (writedata), they may be outstanding indefinitely if the lldd doesn't see a condition where the initiatior port or link is bad. In those cases, the transport will call the abort function and wait for the lldd's op done upcall for the operation, where it will then clean up the io. Additionally, if a lldd receives an ABTS and matches it to an outstanding request in the transport, A new new transport upcall was created to abort the outstanding request in the transport. The transport expects any outstanding op call (readdata or writedata) will completed by the lldd and the operation upcall made. The transport doesn't act on the reported abort (e.g. clean up the io) until an op done upcall occurs, a new op is attempted, or the nvmet layer completes the io processing. fcloop: ---------------------- Updated to support the new target apis. On fcp io aborts from the initiator, the loopback context is updated to NULL out the half that has completed. The initiator side is immediately called after the abort request with an io completion (abort status). On fcp io aborts from the target, the io is stopped and the initiator side sees it as an aborted io. Target side ops, perhaps in progress while the initiator side is done, continue but noop the data movement as there's no structure on the initiator side to reference. patch also contains: ---------------------- Revised lpfc to support the new abort api commonized rsp buffer syncing and nulling of private data based on calling paths. errors in op done calls don't take action on the fod. They're bad operations which implies the fod may be bad. Signed-off-by: James Smart <james.smart@broadcom.com> Signed-off-by: Sagi Grimberg <sagi@grimberg.me>
2017-04-12 01:32:31 +07:00
void (*fcp_abort)(struct nvmet_fc_target_port *tgtport,
struct nvmefc_tgt_fcp_req *fcpreq);
void (*fcp_req_release)(struct nvmet_fc_target_port *tgtport,
struct nvmefc_tgt_fcp_req *fcpreq);
nvmet_fc: add defer_req callback for deferment of cmd buffer return At queue creation, the transport allocates a local job struct (struct nvmet_fc_fcp_iod) for each possible element of the queue. When a new CMD is received from the wire, a jobs struct is allocated from the queue and then used for the duration of the command. The job struct contains buffer space for the wire command iu. Thus, upon allocation of the job struct, the cmd iu buffer is copied to the job struct and the LLDD may immediately free/reuse the CMD IU buffer passed in the call. However, in some circumstances, due to the packetized nature of FC and the api of the FC LLDD which may issue a hw command to send the wire response, but the LLDD may not get the hw completion for the command and upcall the nvmet_fc layer before a new command may be asynchronously received on the wire. In other words, its possible for the initiator to get the response from the wire, thus believe a command slot free, and send a new command iu. The new command iu may be received by the LLDD and passed to the transport before the LLDD had serviced the hw completion and made the teardown calls for the original job struct. As such, there is no available job struct available for the new io. E.g. it appears like the host sent more queue elements than the queue size. It didn't based on it's understanding. Rather than treat this as a hard connection failure queue the new request until the job struct does free up. As the buffer isn't copied as there's no job struct, a special return value must be returned to the LLDD to signify to hold off on recycling the cmd iu buffer. And later, when a job struct is allocated and the buffer copied, a new LLDD callback is introduced to notify the LLDD and allow it to recycle it's command iu buffer. Signed-off-by: James Smart <james.smart@broadcom.com> Reviewed-by: Johannes Thumshirn <jthumshirn@suse.de> Signed-off-by: Christoph Hellwig <hch@lst.de>
2017-08-02 05:12:39 +07:00
void (*defer_rcv)(struct nvmet_fc_target_port *tgtport,
struct nvmefc_tgt_fcp_req *fcpreq);
u32 max_hw_queues;
u16 max_sgl_segments;
u16 max_dif_sgl_segments;
u64 dma_boundary;
u32 target_features;
u32 target_priv_sz;
};
int nvmet_fc_register_targetport(struct nvmet_fc_port_info *portinfo,
struct nvmet_fc_target_template *template,
struct device *dev,
struct nvmet_fc_target_port **tgtport_p);
int nvmet_fc_unregister_targetport(struct nvmet_fc_target_port *tgtport);
int nvmet_fc_rcv_ls_req(struct nvmet_fc_target_port *tgtport,
struct nvmefc_tgt_ls_req *lsreq,
void *lsreqbuf, u32 lsreqbuf_len);
int nvmet_fc_rcv_fcp_req(struct nvmet_fc_target_port *tgtport,
struct nvmefc_tgt_fcp_req *fcpreq,
void *cmdiubuf, u32 cmdiubuf_len);
nvmet_fc: Rework target side abort handling target transport: ---------------------- There are cases when there is a need to abort in-progress target operations (writedata) so that controller termination or errors can clean up. That can't happen currently as the abort is another target op type, so it can't be used till the running one finishes (and it may not). Solve by removing the abort op type and creating a separate downcall from the transport to the lldd to request an io to be aborted. The transport will abort ios on queue teardown or io errors. In general the transport tries to call the lldd abort only when the io state is idle. Meaning: ops that transmit data (readdata or rsp) will always finish their transmit (or the lldd will see a state on the link or initiator port that fails the transmit) and the done call for the operation will occur. The transport will wait for the op done upcall before calling the abort function, and as the io is idle, the io can be cleaned up immediately after the abort call; Similarly, ios that are not waiting for data or transmitting data must be in the nvmet layer being processed. The transport will wait for the nvmet layer completion before calling the abort function, and as the io is idle, the io can be cleaned up immediately after the abort call; As for ops that are waiting for data (writedata), they may be outstanding indefinitely if the lldd doesn't see a condition where the initiatior port or link is bad. In those cases, the transport will call the abort function and wait for the lldd's op done upcall for the operation, where it will then clean up the io. Additionally, if a lldd receives an ABTS and matches it to an outstanding request in the transport, A new new transport upcall was created to abort the outstanding request in the transport. The transport expects any outstanding op call (readdata or writedata) will completed by the lldd and the operation upcall made. The transport doesn't act on the reported abort (e.g. clean up the io) until an op done upcall occurs, a new op is attempted, or the nvmet layer completes the io processing. fcloop: ---------------------- Updated to support the new target apis. On fcp io aborts from the initiator, the loopback context is updated to NULL out the half that has completed. The initiator side is immediately called after the abort request with an io completion (abort status). On fcp io aborts from the target, the io is stopped and the initiator side sees it as an aborted io. Target side ops, perhaps in progress while the initiator side is done, continue but noop the data movement as there's no structure on the initiator side to reference. patch also contains: ---------------------- Revised lpfc to support the new abort api commonized rsp buffer syncing and nulling of private data based on calling paths. errors in op done calls don't take action on the fod. They're bad operations which implies the fod may be bad. Signed-off-by: James Smart <james.smart@broadcom.com> Signed-off-by: Sagi Grimberg <sagi@grimberg.me>
2017-04-12 01:32:31 +07:00
void nvmet_fc_rcv_fcp_abort(struct nvmet_fc_target_port *tgtport,
struct nvmefc_tgt_fcp_req *fcpreq);
#endif /* _NVME_FC_DRIVER_H */