/* fc.c: Generic Fibre Channel and FC4 SCSI driver. * * Copyright (C) 1997,1998,1999 Jakub Jelinek (jj@ultra.linux.cz) * Copyright (C) 1997,1998 Jirka Hanika (geo@ff.cuni.cz) * * There are two kinds of Fibre Channel adapters used in Linux. Either * the adapter is "smart" and does all FC bookkeeping by itself and * just presents a standard SCSI interface to the operating system * (that's e.g. the case with Qlogic FC cards), or leaves most of the FC * bookkeeping to the OS (e.g. soc, socal). Drivers for the former adapters * will look like normal SCSI drivers (with the exception of max_id will be * usually 127), the latter on the other side allows SCSI, IP over FC and other * protocols. This driver tree is for the latter adapters. * * This file should support both Point-to-Point and Arbitrated Loop topologies. * * Sources: * Fibre Channel Physical & Signaling Interface (FC-PH), dpANS, 1994 * dpANS Fibre Channel Protocol for SCSI (X3.269-199X), Rev. 012, 1995 * Fibre Channel Arbitrated Loop (FC-AL), Rev. 4.5, 1995 * Fibre Channel Private Loop SCSI Direct Attach (FC-PLDA), Rev. 2.1, 1997 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "fcp_impl.h" #include /* #define FCDEBUG */ #define fc_printk printk ("%s: ", fc->name); printk #ifdef FCDEBUG #define FCD(x) fc_printk x; #define FCND(x) printk ("FC: "); printk x; #else #define FCD(x) #define FCND(x) #endif #ifdef __sparc__ #define dma_alloc_consistent(d,s,p) sbus_alloc_consistent(d,s,p) #define dma_free_consistent(d,s,v,h) sbus_free_consistent(d,s,v,h) #define dma_map_single(d,v,s,dir) sbus_map_single(d,v,s,dir) #define dma_unmap_single(d,h,s,dir) sbus_unmap_single(d,h,s,dir) #define dma_map_sg(d,s,n,dir) sbus_map_sg(d,s,n,dir) #define dma_unmap_sg(d,s,n,dir) sbus_unmap_sg(d,s,n,dir) #else #define dma_alloc_consistent(d,s,p) pci_alloc_consistent(d,s,p) #define dma_free_consistent(d,s,v,h) pci_free_consistent(d,s,v,h) #define dma_map_single(d,v,s,dir) pci_map_single(d,v,s,dir) #define dma_unmap_single(d,h,s,dir) pci_unmap_single(d,h,s,dir) #define dma_map_sg(d,s,n,dir) pci_map_sg(d,s,n,dir) #define dma_unmap_sg(d,s,n,dir) pci_unmap_sg(d,s,n,dir) #endif #define FCP_CMND(SCpnt) ((fcp_cmnd *)&(SCpnt->SCp)) #define FC_SCMND(SCpnt) ((fc_channel *)(SCpnt->device->host->hostdata[0])) #define SC_FCMND(fcmnd) ((Scsi_Cmnd *)((long)fcmnd - (long)&(((Scsi_Cmnd *)0)->SCp))) static int fcp_scsi_queue_it(fc_channel *, Scsi_Cmnd *, fcp_cmnd *, int); void fcp_queue_empty(fc_channel *); static void fcp_scsi_insert_queue (fc_channel *fc, fcp_cmnd *fcmd) { if (!fc->scsi_que) { fc->scsi_que = fcmd; fcmd->next = fcmd; fcmd->prev = fcmd; } else { fc->scsi_que->prev->next = fcmd; fcmd->prev = fc->scsi_que->prev; fc->scsi_que->prev = fcmd; fcmd->next = fc->scsi_que; } } static void fcp_scsi_remove_queue (fc_channel *fc, fcp_cmnd *fcmd) { if (fcmd == fcmd->next) { fc->scsi_que = NULL; return; } if (fcmd == fc->scsi_que) fc->scsi_que = fcmd->next; fcmd->prev->next = fcmd->next; fcmd->next->prev = fcmd->prev; } fc_channel *fc_channels = NULL; #define LSMAGIC 620829043 typedef struct { /* Must be first */ struct semaphore sem; int magic; int count; logi *logi; fcp_cmnd *fcmds; atomic_t todo; struct timer_list timer; unsigned char grace[0]; } ls; #define LSOMAGIC 654907799 typedef struct { /* Must be first */ struct semaphore sem; int magic; int count; fcp_cmnd *fcmds; atomic_t todo; struct timer_list timer; } lso; #define LSEMAGIC 84482456 typedef struct { /* Must be first */ struct semaphore sem; int magic; int status; struct timer_list timer; } lse; static void fcp_login_timeout(unsigned long data) { ls *l = (ls *)data; FCND(("Login timeout\n")) up(&l->sem); } static void fcp_login_done(fc_channel *fc, int i, int status) { fcp_cmnd *fcmd; logi *plogi; fc_hdr *fch; ls *l = (ls *)fc->ls; FCD(("Login done %d %d\n", i, status)) if (i < l->count) { if (fc->state == FC_STATE_FPORT_OK) { FCD(("Additional FPORT_OK received with status %d\n", status)) return; } switch (status) { case FC_STATUS_OK: /* Oh, we found a fabric */ case FC_STATUS_P_RJT: /* Oh, we haven't found any */ fc->state = FC_STATE_FPORT_OK; fcmd = l->fcmds + i; plogi = l->logi + 3 * i; dma_unmap_single (fc->dev, fcmd->cmd, 3 * sizeof(logi), DMA_BIDIRECTIONAL); plogi->code = LS_PLOGI; memcpy (&plogi->nport_wwn, &fc->wwn_nport, sizeof(fc_wwn)); memcpy (&plogi->node_wwn, &fc->wwn_node, sizeof(fc_wwn)); memcpy (&plogi->common, fc->common_svc, sizeof(common_svc_parm)); memcpy (&plogi->class1, fc->class_svcs, 3*sizeof(svc_parm)); fch = &fcmd->fch; fcmd->token += l->count; FILL_FCHDR_RCTL_DID(fch, R_CTL_ELS_REQ, fc->did); FILL_FCHDR_SID(fch, fc->sid); #ifdef FCDEBUG { int i; unsigned *x = (unsigned *)plogi; printk ("logi: "); for (i = 0; i < 21; i++) printk ("%08x ", x[i]); printk ("\n"); } #endif fcmd->cmd = dma_map_single (fc->dev, plogi, 3 * sizeof(logi), DMA_BIDIRECTIONAL); fcmd->rsp = fcmd->cmd + 2 * sizeof(logi); if (fc->hw_enque (fc, fcmd)) printk ("FC: Cannot enque PLOGI packet on %s\n", fc->name); break; case FC_STATUS_ERR_OFFLINE: fc->state = FC_STATE_MAYBEOFFLINE; FCD (("FC is offline %d\n", l->grace[i])) break; default: printk ("FLOGI failed for %s with status %d\n", fc->name, status); /* Do some sort of error recovery here */ break; } } else { i -= l->count; if (fc->state != FC_STATE_FPORT_OK) { FCD(("Unexpected N-PORT rsp received")) return; } switch (status) { case FC_STATUS_OK: plogi = l->logi + 3 * i; dma_unmap_single (fc->dev, l->fcmds[i].cmd, 3 * sizeof(logi), DMA_BIDIRECTIONAL); if (!fc->wwn_dest.lo && !fc->wwn_dest.hi) { memcpy (&fc->wwn_dest, &plogi[1].node_wwn, sizeof(fc_wwn)); FCD(("Dest WWN %08x%08x\n", *(u32 *)&fc->wwn_dest, fc->wwn_dest.lo)) } else if (fc->wwn_dest.lo != plogi[1].node_wwn.lo || fc->wwn_dest.hi != plogi[1].node_wwn.hi) { printk ("%s: mismatch in wwns. Got %08x%08x, expected %08x%08x\n", fc->name, *(u32 *)&plogi[1].node_wwn, plogi[1].node_wwn.lo, *(u32 *)&fc->wwn_dest, fc->wwn_dest.lo); } fc->state = FC_STATE_ONLINE; printk ("%s: ONLINE\n", fc->name); if (atomic_dec_and_test (&l->todo)) up(&l->sem); break; case FC_STATUS_ERR_OFFLINE: fc->state = FC_STATE_OFFLINE; dma_unmap_single (fc->dev, l->fcmds[i].cmd, 3 * sizeof(logi), DMA_BIDIRECTIONAL); printk ("%s: FC is offline\n", fc->name); if (atomic_dec_and_test (&l->todo)) up(&l->sem); break; default: printk ("PLOGI failed for %s with status %d\n", fc->name, status); /* Do some sort of error recovery here */ break; } } } static void fcp_report_map_done(fc_channel *fc, int i, int status) { fcp_cmnd *fcmd; fc_hdr *fch; unsigned char j; ls *l = (ls *)fc->ls; fc_al_posmap *p; FCD(("Report map done %d %d\n", i, status)) switch (status) { case FC_STATUS_OK: /* Ok, let's have a fun on a loop */ dma_unmap_single (fc->dev, l->fcmds[i].cmd, 3 * sizeof(logi), DMA_BIDIRECTIONAL); p = (fc_al_posmap *)(l->logi + 3 * i); #ifdef FCDEBUG { u32 *u = (u32 *)p; FCD(("%08x\n", u[0])) u ++; FCD(("%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x\n", u[0],u[1],u[2],u[3],u[4],u[5],u[6],u[7])) } #endif if ((p->magic & 0xffff0000) != FC_AL_LILP || !p->len) { printk ("FC: Bad magic from REPORT_AL_MAP on %s - %08x\n", fc->name, p->magic); fc->state = FC_STATE_OFFLINE; } else { fc->posmap = (fcp_posmap *)kzalloc(sizeof(fcp_posmap)+p->len, GFP_KERNEL); if (!fc->posmap) { printk("FC: Not enough memory, offlining channel\n"); fc->state = FC_STATE_OFFLINE; } else { int k; /* FIXME: This is where SOCAL transfers our AL-PA. Keep it here till we found out what other cards do... */ fc->sid = (p->magic & 0xff); for (i = 0; i < p->len; i++) if (p->alpa[i] == fc->sid) break; k = p->len; if (i == p->len) i = 0; else { p->len--; i++; } fc->posmap->len = p->len; for (j = 0; j < p->len; j++) { if (i == k) i = 0; fc->posmap->list[j] = p->alpa[i++]; } fc->state = FC_STATE_ONLINE; } } printk ("%s: ONLINE\n", fc->name); if (atomic_dec_and_test (&l->todo)) up(&l->sem); break; case FC_STATUS_POINTTOPOINT: /* We're Point-to-Point, no AL... */ FCD(("SID %d DID %d\n", fc->sid, fc->did)) fcmd = l->fcmds + i; dma_unmap_single(fc->dev, fcmd->cmd, 3 * sizeof(logi), DMA_BIDIRECTIONAL); fch = &fcmd->fch; memset(l->logi + 3 * i, 0, 3 * sizeof(logi)); FILL_FCHDR_RCTL_DID(fch, R_CTL_ELS_REQ, FS_FABRIC_F_PORT); FILL_FCHDR_SID(fch, 0); FILL_FCHDR_TYPE_FCTL(fch, TYPE_EXTENDED_LS, F_CTL_FIRST_SEQ | F_CTL_SEQ_INITIATIVE); FILL_FCHDR_SEQ_DF_SEQ(fch, 0, 0, 0); FILL_FCHDR_OXRX(fch, 0xffff, 0xffff); fch->param = 0; l->logi [3 * i].code = LS_FLOGI; fcmd->cmd = dma_map_single (fc->dev, l->logi + 3 * i, 3 * sizeof(logi), DMA_BIDIRECTIONAL); fcmd->rsp = fcmd->cmd + sizeof(logi); fcmd->cmdlen = sizeof(logi); fcmd->rsplen = sizeof(logi); fcmd->data = (dma_addr_t)NULL; fcmd->class = FC_CLASS_SIMPLE; fcmd->proto = TYPE_EXTENDED_LS; if (fc->hw_enque (fc, fcmd)) printk ("FC: Cannot enque FLOGI packet on %s\n", fc->name); break; case FC_STATUS_ERR_OFFLINE: fc->state = FC_STATE_MAYBEOFFLINE; FCD (("FC is offline %d\n", l->grace[i])) break; default: printk ("FLOGI failed for %s with status %d\n", fc->name, status); /* Do some sort of error recovery here */ break; } } void fcp_register(fc_channel *fc, u8 type, int unregister) { int size, i; int slots = (fc->can_queue * 3) >> 1; FCND(("Going to %sregister\n", unregister ? "un" : "")) if (type == TYPE_SCSI_FCP) { if (!unregister) { fc->scsi_cmd_pool = (fcp_cmd *) dma_alloc_consistent (fc->dev, slots * (sizeof (fcp_cmd) + fc->rsp_size), &fc->dma_scsi_cmd); fc->scsi_rsp_pool = (char *)(fc->scsi_cmd_pool + slots); fc->dma_scsi_rsp = fc->dma_scsi_cmd + slots * sizeof (fcp_cmd); fc->scsi_bitmap_end = (slots + 63) & ~63; size = fc->scsi_bitmap_end / 8; fc->scsi_bitmap = kzalloc (size, GFP_KERNEL); set_bit (0, fc->scsi_bitmap); for (i = fc->can_queue; i < fc->scsi_bitmap_end; i++) set_bit (i, fc->scsi_bitmap); fc->scsi_free = fc->can_queue; fc->cmd_slots = (fcp_cmnd **)kzalloc(slots * sizeof(fcp_cmnd*), GFP_KERNEL); fc->abort_count = 0; } else { fc->scsi_name[0] = 0; kfree (fc->scsi_bitmap); kfree (fc->cmd_slots); FCND(("Unregistering\n")); #if 0 if (fc->rst_pkt) { if (fc->rst_pkt->eh_state == SCSI_STATE_UNUSED) kfree(fc->rst_pkt); else { /* Can't happen. Some memory would be lost. */ printk("FC: Reset in progress. Now?!"); } } #endif FCND(("Unregistered\n")); } } else printk ("FC: %segistering unknown type %02x\n", unregister ? "Unr" : "R", type); } static void fcp_scsi_done(Scsi_Cmnd *SCpnt); static inline void fcp_scsi_receive(fc_channel *fc, int token, int status, fc_hdr *fch) { fcp_cmnd *fcmd; fcp_rsp *rsp; int host_status; Scsi_Cmnd *SCpnt; int sense_len; int rsp_status; fcmd = fc->cmd_slots[token]; if (!fcmd) return; rsp = (fcp_rsp *) (fc->scsi_rsp_pool + fc->rsp_size * token); SCpnt = SC_FCMND(fcmd); if (SCpnt->done != fcp_scsi_done) return; rsp_status = rsp->fcp_status; FCD(("rsp_status %08x status %08x\n", rsp_status, status)) switch (status) { case FC_STATUS_OK: host_status=DID_OK; if (rsp_status & FCP_STATUS_RESID) { #ifdef FCDEBUG FCD(("Resid %d\n", rsp->fcp_resid)) { fcp_cmd *cmd = fc->scsi_cmd_pool + token; int i; printk ("Command "); for (i = 0; i < sizeof(fcp_cmd); i+=4) printk ("%08x ", *(u32 *)(((char *)cmd)+i)); printk ("\nResponse "); for (i = 0; i < fc->rsp_size; i+=4) printk ("%08x ", *(u32 *)(((char *)rsp)+i)); printk ("\n"); } #endif } if (rsp_status & FCP_STATUS_SENSE_LEN) { sense_len = rsp->fcp_sense_len; if (sense_len > sizeof(SCpnt->sense_buffer)) sense_len = sizeof(SCpnt->sense_buffer); memcpy(SCpnt->sense_buffer, ((char *)(rsp+1)), sense_len); } if (fcmd->data) { if (SCpnt->use_sg) dma_unmap_sg(fc->dev, (struct scatterlist *)SCpnt->request_buffer, SCpnt->use_sg, SCpnt->sc_data_direction); else dma_unmap_single(fc->dev, fcmd->data, SCpnt->request_bufflen, SCpnt->sc_data_direction); } break; default: host_status=DID_ERROR; /* FIXME */ FCD(("Wrong FC status %d for token %d\n", status, token)) break; } if (status_byte(rsp_status) == QUEUE_FULL) { printk ("%s: (%d,%d) Received rsp_status 0x%x\n", fc->name, SCpnt->device->channel, SCpnt->device->id, rsp_status); } SCpnt->result = (host_status << 16) | (rsp_status & 0xff); #ifdef FCDEBUG if (host_status || SCpnt->result || rsp_status) printk("FC: host_status %d, packet status %d\n", host_status, SCpnt->result); #endif SCpnt->done = fcmd->done; fcmd->done=NULL; clear_bit(token, fc->scsi_bitmap); fc->scsi_free++; FCD(("Calling scsi_done with %08x\n", SCpnt->result)) SCpnt->scsi_done(SCpnt); } void fcp_receive_solicited(fc_channel *fc, int proto, int token, int status, fc_hdr *fch) { int magic; FCD(("receive_solicited %d %d %d\n", proto, token, status)) switch (proto) { case TYPE_SCSI_FCP: fcp_scsi_receive(fc, token, status, fch); break; case TYPE_EXTENDED_LS: case PROTO_REPORT_AL_MAP: magic = 0; if (fc->ls) magic = ((ls *)(fc->ls))->magic; if (magic == LSMAGIC) { ls *l = (ls *)fc->ls; int i = (token >= l->count) ? token - l->count : token; /* Let's be sure */ if ((unsigned)i < l->count && l->fcmds[i].fc == fc) { if (proto == TYPE_EXTENDED_LS) fcp_login_done(fc, token, status); else fcp_report_map_done(fc, token, status); break; } } FCD(("fc %p fc->ls %p fc->cmd_slots %p\n", fc, fc->ls, fc->cmd_slots)) if (proto == TYPE_EXTENDED_LS && !fc->ls && fc->cmd_slots) { fcp_cmnd *fcmd; fcmd = fc->cmd_slots[token]; if (fcmd && fcmd->ls && ((ls *)(fcmd->ls))->magic == LSEMAGIC) { lse *l = (lse *)fcmd->ls; l->status = status; up (&l->sem); } } break; case PROTO_OFFLINE: if (fc->ls && ((lso *)(fc->ls))->magic == LSOMAGIC) { lso *l = (lso *)fc->ls; if ((unsigned)token < l->count && l->fcmds[token].fc == fc) { /* Wow, OFFLINE response arrived :) */ FCD(("OFFLINE Response arrived\n")) fc->state = FC_STATE_OFFLINE; if (atomic_dec_and_test (&l->todo)) up(&l->sem); } } break; default: break; } } void fcp_state_change(fc_channel *fc, int state) { FCD(("state_change %d %d\n", state, fc->state)) if (state == FC_STATE_ONLINE && fc->state == FC_STATE_MAYBEOFFLINE) fc->state = FC_STATE_UNINITED; else if (state == FC_STATE_ONLINE) printk (KERN_WARNING "%s: state change to ONLINE\n", fc->name); else printk (KERN_ERR "%s: state change to OFFLINE\n", fc->name); } int fcp_initialize(fc_channel *fcchain, int count) { fc_channel *fc; fcp_cmnd *fcmd; int i, retry, ret; ls *l; FCND(("fcp_inititialize %08lx\n", (long)fcp_init)) FCND(("fc_channels %08lx\n", (long)fc_channels)) FCND((" SID %d DID %d\n", fcchain->sid, fcchain->did)) l = kzalloc(sizeof (ls) + count, GFP_KERNEL); if (!l) { printk ("FC: Cannot allocate memory for initialization\n"); return -ENOMEM; } l->magic = LSMAGIC; l->count = count; FCND(("FCP Init for %d channels\n", count)) init_MUTEX_LOCKED(&l->sem); init_timer(&l->timer); l->timer.function = fcp_login_timeout; l->timer.data = (unsigned long)l; atomic_set (&l->todo, count); l->logi = kzalloc (count * 3 * sizeof(logi), GFP_KERNEL); l->fcmds = kzalloc (count * sizeof(fcp_cmnd), GFP_KERNEL); if (!l->logi || !l->fcmds) { kfree (l->logi); kfree (l->fcmds); kfree (l); printk ("FC: Cannot allocate DMA memory for initialization\n"); return -ENOMEM; } for (fc = fcchain, i = 0; fc && i < count; fc = fc->next, i++) { fc->state = FC_STATE_UNINITED; fc->rst_pkt = NULL; /* kmalloc when first used */ } /* First try if we are in a AL topology */ FCND(("Initializing REPORT_MAP packets\n")) for (fc = fcchain, i = 0; fc && i < count; fc = fc->next, i++) { fcmd = l->fcmds + i; fc->login = fcmd; fc->ls = (void *)l; /* Assumes sizeof(fc_al_posmap) < 3 * sizeof(logi), which is true */ fcmd->cmd = dma_map_single (fc->dev, l->logi + 3 * i, 3 * sizeof(logi), DMA_BIDIRECTIONAL); fcmd->proto = PROTO_REPORT_AL_MAP; fcmd->token = i; fcmd->fc = fc; } for (retry = 0; retry < 8; retry++) { int nqueued = 0; FCND(("Sending REPORT_MAP/FLOGI/PLOGI packets\n")) for (fc = fcchain, i = 0; fc && i < count; fc = fc->next, i++) { if (fc->state == FC_STATE_ONLINE || fc->state == FC_STATE_OFFLINE) continue; disable_irq(fc->irq); if (fc->state == FC_STATE_MAYBEOFFLINE) { if (!l->grace[i]) { l->grace[i]++; FCD(("Grace\n")) } else { fc->state = FC_STATE_OFFLINE; enable_irq(fc->irq); dma_unmap_single (fc->dev, l->fcmds[i].cmd, 3 * sizeof(logi), DMA_BIDIRECTIONAL); if (atomic_dec_and_test (&l->todo)) goto all_done; } } ret = fc->hw_enque (fc, fc->login); enable_irq(fc->irq); if (!ret) { nqueued++; continue; } if (ret == -ENOSYS && fc->login->proto == PROTO_REPORT_AL_MAP) { /* Oh yes, this card handles Point-to-Point only, so let's try that. */ fc_hdr *fch; FCD(("SID %d DID %d\n", fc->sid, fc->did)) fcmd = l->fcmds + i; dma_unmap_single(fc->dev, fcmd->cmd, 3 * sizeof(logi), DMA_BIDIRECTIONAL); fch = &fcmd->fch; FILL_FCHDR_RCTL_DID(fch, R_CTL_ELS_REQ, FS_FABRIC_F_PORT); FILL_FCHDR_SID(fch, 0); FILL_FCHDR_TYPE_FCTL(fch, TYPE_EXTENDED_LS, F_CTL_FIRST_SEQ | F_CTL_SEQ_INITIATIVE); FILL_FCHDR_SEQ_DF_SEQ(fch, 0, 0, 0); FILL_FCHDR_OXRX(fch, 0xffff, 0xffff); fch->param = 0; l->logi [3 * i].code = LS_FLOGI; fcmd->cmd = dma_map_single (fc->dev, l->logi + 3 * i, 3 * sizeof(logi), DMA_BIDIRECTIONAL); fcmd->rsp = fcmd->cmd + sizeof(logi); fcmd->cmdlen = sizeof(logi); fcmd->rsplen = sizeof(logi); fcmd->data = (dma_addr_t)NULL; fcmd->class = FC_CLASS_SIMPLE; fcmd->proto = TYPE_EXTENDED_LS; } else printk ("FC: Cannot enque FLOGI/REPORT_MAP packet on %s\n", fc->name); } if (nqueued) { l->timer.expires = jiffies + 5 * HZ; add_timer(&l->timer); down(&l->sem); if (!atomic_read(&l->todo)) { FCND(("All channels answered in time\n")) break; /* All fc channels have answered us */ } } } all_done: for (fc = fcchain, i = 0; fc && i < count; fc = fc->next, i++) { fc->ls = NULL; switch (fc->state) { case FC_STATE_ONLINE: break; case FC_STATE_OFFLINE: break; default: dma_unmap_single (fc->dev, l->fcmds[i].cmd, 3 * sizeof(logi), DMA_BIDIRECTIONAL); break; } } del_timer(&l->timer); kfree (l->logi); kfree (l->fcmds); kfree (l); return 0; } int fcp_forceoffline(fc_channel *fcchain, int count) { fc_channel *fc; fcp_cmnd *fcmd; int i, ret; lso l; memset (&l, 0, sizeof(lso)); l.count = count; l.magic = LSOMAGIC; FCND(("FCP Force Offline for %d channels\n", count)) init_MUTEX_LOCKED(&l.sem); init_timer(&l.timer); l.timer.function = fcp_login_timeout; l.timer.data = (unsigned long)&l; atomic_set (&l.todo, count); l.fcmds = kzalloc (count * sizeof(fcp_cmnd), GFP_KERNEL); if (!l.fcmds) { printk ("FC: Cannot allocate memory for forcing offline\n"); return -ENOMEM; } FCND(("Initializing OFFLINE packets\n")) for (fc = fcchain, i = 0; fc && i < count; fc = fc->next, i++) { fc->state = FC_STATE_UNINITED; fcmd = l.fcmds + i; fc->login = fcmd; fc->ls = (void *)&l; fcmd->did = fc->did; fcmd->class = FC_CLASS_OFFLINE; fcmd->proto = PROTO_OFFLINE; fcmd->token = i; fcmd->fc = fc; disable_irq(fc->irq); ret = fc->hw_enque (fc, fc->login); enable_irq(fc->irq); if (ret) printk ("FC: Cannot enque OFFLINE packet on %s\n", fc->name); } l.timer.expires = jiffies + 5 * HZ; add_timer(&l.timer); down(&l.sem); del_timer(&l.timer); for (fc = fcchain, i = 0; fc && i < count; fc = fc->next, i++) fc->ls = NULL; kfree (l.fcmds); return 0; } int fcp_init(fc_channel *fcchain) { fc_channel *fc; int count=0; int ret; for (fc = fcchain; fc; fc = fc->next) { fc->fcp_register = fcp_register; count++; } ret = fcp_initialize (fcchain, count); if (ret) return ret; if (!fc_channels) fc_channels = fcchain; else { for (fc = fc_channels; fc->next; fc = fc->next); fc->next = fcchain; } return ret; } void fcp_release(fc_channel *fcchain, int count) /* count must > 0 */ { fc_channel *fc; fc_channel *fcx; for (fc = fcchain; --count && fc->next; fc = fc->next); if (count) { printk("FC: nothing to release\n"); return; } if (fc_channels == fcchain) fc_channels = fc->next; else { for (fcx = fc_channels; fcx->next != fcchain; fcx = fcx->next); fcx->next = fc->next; } fc->next = NULL; /* * We've just grabbed fcchain out of the fc_channel list * and zero-terminated it, while destroying the count. * * Freeing the fc's is the low level driver's responsibility. */ } static void fcp_scsi_done (Scsi_Cmnd *SCpnt) { if (FCP_CMND(SCpnt)->done) FCP_CMND(SCpnt)->done(SCpnt); } static int fcp_scsi_queue_it(fc_channel *fc, Scsi_Cmnd *SCpnt, fcp_cmnd *fcmd, int prepare) { long i; fcp_cmd *cmd; u32 fcp_cntl; if (prepare) { i = find_first_zero_bit (fc->scsi_bitmap, fc->scsi_bitmap_end); set_bit (i, fc->scsi_bitmap); fcmd->token = i; cmd = fc->scsi_cmd_pool + i; if (fc->encode_addr (SCpnt, cmd->fcp_addr, fc, fcmd)) { /* Invalid channel/id/lun and couldn't map it into fcp_addr */ clear_bit (i, fc->scsi_bitmap); SCpnt->result = (DID_BAD_TARGET << 16); SCpnt->scsi_done(SCpnt); return 0; } fc->scsi_free--; fc->cmd_slots[fcmd->token] = fcmd; if (SCpnt->device->tagged_supported) { if (jiffies - fc->ages[SCpnt->device->channel * fc->targets + SCpnt->device->id] > (5 * 60 * HZ)) { fc->ages[SCpnt->device->channel * fc->targets + SCpnt->device->id] = jiffies; fcp_cntl = FCP_CNTL_QTYPE_ORDERED; } else fcp_cntl = FCP_CNTL_QTYPE_SIMPLE; } else fcp_cntl = FCP_CNTL_QTYPE_UNTAGGED; if (!SCpnt->request_bufflen && !SCpnt->use_sg) { cmd->fcp_cntl = fcp_cntl; fcmd->data = (dma_addr_t)NULL; } else { switch (SCpnt->cmnd[0]) { case WRITE_6: case WRITE_10: case WRITE_12: cmd->fcp_cntl = (FCP_CNTL_WRITE | fcp_cntl); break; default: cmd->fcp_cntl = (FCP_CNTL_READ | fcp_cntl); break; } if (!SCpnt->use_sg) { cmd->fcp_data_len = SCpnt->request_bufflen; fcmd->data = dma_map_single (fc->dev, (char *)SCpnt->request_buffer, SCpnt->request_bufflen, SCpnt->sc_data_direction); } else { struct scatterlist *sg = (struct scatterlist *)SCpnt->request_buffer; int nents; FCD(("XXX: Use_sg %d %d\n", SCpnt->use_sg, sg->length)) nents = dma_map_sg (fc->dev, sg, SCpnt->use_sg, SCpnt->sc_data_direction); if (nents > 1) printk ("%s: SG for nents %d (use_sg %d) not handled yet\n", fc->name, nents, SCpnt->use_sg); fcmd->data = sg_dma_address(sg); cmd->fcp_data_len = sg_dma_len(sg); } } memcpy (cmd->fcp_cdb, SCpnt->cmnd, SCpnt->cmd_len); memset (cmd->fcp_cdb+SCpnt->cmd_len, 0, sizeof(cmd->fcp_cdb)-SCpnt->cmd_len); FCD(("XXX: %04x.%04x.%04x.%04x - %08x%08x%08x\n", cmd->fcp_addr[0], cmd->fcp_addr[1], cmd->fcp_addr[2], cmd->fcp_addr[3], *(u32 *)SCpnt->cmnd, *(u32 *)(SCpnt->cmnd+4), *(u32 *)(SCpnt->cmnd+8))) } FCD(("Trying to enque %p\n", fcmd)) if (!fc->scsi_que) { if (!fc->hw_enque (fc, fcmd)) { FCD(("hw_enque succeeded for %p\n", fcmd)) return 0; } } FCD(("Putting into que1 %p\n", fcmd)) fcp_scsi_insert_queue (fc, fcmd); return 0; } int fcp_scsi_queuecommand(Scsi_Cmnd *SCpnt, void (* done)(Scsi_Cmnd *)) { fcp_cmnd *fcmd = FCP_CMND(SCpnt); fc_channel *fc = FC_SCMND(SCpnt); FCD(("Entering SCSI queuecommand %p\n", fcmd)) if (SCpnt->done != fcp_scsi_done) { fcmd->done = SCpnt->done; SCpnt->done = fcp_scsi_done; SCpnt->scsi_done = done; fcmd->proto = TYPE_SCSI_FCP; if (!fc->scsi_free) { FCD(("FC: !scsi_free, putting cmd on ML queue\n")) #if (FCP_SCSI_USE_NEW_EH_CODE == 0) printk("fcp_scsi_queue_command: queue full, losing cmd, bad\n"); #endif return 1; } return fcp_scsi_queue_it(fc, SCpnt, fcmd, 1); } return fcp_scsi_queue_it(fc, SCpnt, fcmd, 0); } void fcp_queue_empty(fc_channel *fc) { fcp_cmnd *fcmd; FCD(("Queue empty\n")) while ((fcmd = fc->scsi_que)) { /* The hw told us we can try again queue some packet */ if (fc->hw_enque (fc, fcmd)) break; fcp_scsi_remove_queue (fc, fcmd); } } int fcp_scsi_abort(Scsi_Cmnd *SCpnt) { /* Internal bookkeeping only. Lose 1 cmd_slots slot. */ fcp_cmnd *fcmd = FCP_CMND(SCpnt); fc_channel *fc = FC_SCMND(SCpnt); /* * We react to abort requests by simply forgetting * about the command and pretending everything's sweet. * This may or may not be silly. We can't, however, * immediately reuse the command's cmd_slots slot, * as its result may arrive later and we cannot * check whether it is the aborted one, can't we? * * Therefore, after the first few aborts are done, * we tell the scsi error handler to do something clever. * It will eventually call host reset, refreshing * cmd_slots for us. * * There is a theoretical chance that we sometimes allow * more than can_queue packets to the jungle this way, * but the worst outcome possible is a series of * more aborts and eventually the dev_reset catharsis. */ if (++fc->abort_count < (fc->can_queue >> 1)) { SCpnt->result = DID_ABORT; fcmd->done(SCpnt); printk("FC: soft abort\n"); return SUCCESS; } else { printk("FC: hard abort refused\n"); return FAILED; } } #if 0 void fcp_scsi_reset_done(Scsi_Cmnd *SCpnt) { fc_channel *fc = FC_SCMND(SCpnt); fc->rst_pkt->eh_state = SCSI_STATE_FINISHED; up(fc->rst_pkt->device->host->eh_action); } #endif #define FCP_RESET_TIMEOUT (2*HZ) int fcp_scsi_dev_reset(Scsi_Cmnd *SCpnt) { #if 0 /* broken junk, but if davem wants to compile this driver, let him.. */ unsigned long flags; fcp_cmd *cmd; fcp_cmnd *fcmd; fc_channel *fc = FC_SCMND(SCpnt); DECLARE_MUTEX_LOCKED(sem); if (!fc->rst_pkt) { fc->rst_pkt = (Scsi_Cmnd *) kmalloc(sizeof(SCpnt), GFP_KERNEL); if (!fc->rst_pkt) return FAILED; fcmd = FCP_CMND(fc->rst_pkt); fcmd->token = 0; cmd = fc->scsi_cmd_pool + 0; FCD(("Preparing rst packet\n")) fc->encode_addr (SCpnt, cmd->fcp_addr, fc, fcmd); fc->rst_pkt->device = SCpnt->device; fc->rst_pkt->cmd_len = 0; fc->cmd_slots[0] = fcmd; cmd->fcp_cntl = FCP_CNTL_QTYPE_ORDERED | FCP_CNTL_RESET; fcmd->data = (dma_addr_t)NULL; fcmd->proto = TYPE_SCSI_FCP; memcpy (cmd->fcp_cdb, SCpnt->cmnd, SCpnt->cmd_len); memset (cmd->fcp_cdb+SCpnt->cmd_len, 0, sizeof(cmd->fcp_cdb)-SCpnt->cmd_len); FCD(("XXX: %04x.%04x.%04x.%04x - %08x%08x%08x\n", cmd->fcp_addr[0], cmd->fcp_addr[1], cmd->fcp_addr[2], cmd->fcp_addr[3], *(u32 *)SCpnt->cmnd, *(u32 *)(SCpnt->cmnd+4), *(u32 *)(SCpnt->cmnd+8))) } else { fcmd = FCP_CMND(fc->rst_pkt); if (fc->rst_pkt->eh_state == SCSI_STATE_QUEUED) return FAILED; /* or SUCCESS. Only these */ } fc->rst_pkt->done = NULL; fc->rst_pkt->eh_state = SCSI_STATE_QUEUED; init_timer(&fc->rst_pkt->eh_timeout); fc->rst_pkt->eh_timeout.data = (unsigned long) fc->rst_pkt; fc->rst_pkt->eh_timeout.expires = jiffies + FCP_RESET_TIMEOUT; fc->rst_pkt->eh_timeout.function = (void (*)(unsigned long))fcp_scsi_reset_done; add_timer(&fc->rst_pkt->eh_timeout); /* * Set up the semaphore so we wait for the command to complete. */ fc->rst_pkt->device->host->eh_action = &sem; fc->rst_pkt->request->rq_status = RQ_SCSI_BUSY; fc->rst_pkt->done = fcp_scsi_reset_done; spin_lock_irqsave(SCpnt->device->host->host_lock, flags); fcp_scsi_queue_it(fc, fc->rst_pkt, fcmd, 0); spin_unlock_irqrestore(SCpnt->device->host->host_lock, flags); down(&sem); fc->rst_pkt->device->host->eh_action = NULL; del_timer(&fc->rst_pkt->eh_timeout); /* * See if timeout. If so, tell the host to forget about it. * In other words, we don't want a callback any more. */ if (fc->rst_pkt->eh_state == SCSI_STATE_TIMEOUT ) { fc->rst_pkt->eh_state = SCSI_STATE_UNUSED; return FAILED; } fc->rst_pkt->eh_state = SCSI_STATE_UNUSED; #endif return SUCCESS; } static int __fcp_scsi_host_reset(Scsi_Cmnd *SCpnt) { fc_channel *fc = FC_SCMND(SCpnt); fcp_cmnd *fcmd = FCP_CMND(SCpnt); int i; printk ("FC: host reset\n"); for (i=0; i < fc->can_queue; i++) { if (fc->cmd_slots[i] && SCpnt->result != DID_ABORT) { SCpnt->result = DID_RESET; fcmd->done(SCpnt); fc->cmd_slots[i] = NULL; } } fc->reset(fc); fc->abort_count = 0; if (fcp_initialize(fc, 1)) return SUCCESS; else return FAILED; } int fcp_scsi_host_reset(Scsi_Cmnd *SCpnt) { unsigned long flags; int rc; spin_lock_irqsave(SCpnt->device->host->host_lock, flags); rc = __fcp_scsi_host_reset(SCpnt); spin_unlock_irqrestore(SCpnt->device->host->host_lock, flags); return rc; } static int fcp_els_queue_it(fc_channel *fc, fcp_cmnd *fcmd) { long i; i = find_first_zero_bit (fc->scsi_bitmap, fc->scsi_bitmap_end); set_bit (i, fc->scsi_bitmap); fcmd->token = i; fc->scsi_free--; fc->cmd_slots[fcmd->token] = fcmd; return fcp_scsi_queue_it(fc, NULL, fcmd, 0); } static int fc_do_els(fc_channel *fc, unsigned int alpa, void *data, int len) { fcp_cmnd _fcmd, *fcmd; fc_hdr *fch; lse l; int i; fcmd = &_fcmd; memset(fcmd, 0, sizeof(fcp_cmnd)); FCD(("PLOGI SID %d DID %d\n", fc->sid, alpa)) fch = &fcmd->fch; FILL_FCHDR_RCTL_DID(fch, R_CTL_ELS_REQ, alpa); FILL_FCHDR_SID(fch, fc->sid); FILL_FCHDR_TYPE_FCTL(fch, TYPE_EXTENDED_LS, F_CTL_FIRST_SEQ | F_CTL_SEQ_INITIATIVE); FILL_FCHDR_SEQ_DF_SEQ(fch, 0, 0, 0); FILL_FCHDR_OXRX(fch, 0xffff, 0xffff); fch->param = 0; fcmd->cmd = dma_map_single (fc->dev, data, 2 * len, DMA_BIDIRECTIONAL); fcmd->rsp = fcmd->cmd + len; fcmd->cmdlen = len; fcmd->rsplen = len; fcmd->data = (dma_addr_t)NULL; fcmd->fc = fc; fcmd->class = FC_CLASS_SIMPLE; fcmd->proto = TYPE_EXTENDED_LS; memset (&l, 0, sizeof(lse)); l.magic = LSEMAGIC; init_MUTEX_LOCKED(&l.sem); l.timer.function = fcp_login_timeout; l.timer.data = (unsigned long)&l; l.status = FC_STATUS_TIMED_OUT; fcmd->ls = (void *)&l; disable_irq(fc->irq); fcp_els_queue_it(fc, fcmd); enable_irq(fc->irq); for (i = 0;;) { l.timer.expires = jiffies + 5 * HZ; add_timer(&l.timer); down(&l.sem); del_timer(&l.timer); if (l.status != FC_STATUS_TIMED_OUT) break; if (++i == 3) break; disable_irq(fc->irq); fcp_scsi_queue_it(fc, NULL, fcmd, 0); enable_irq(fc->irq); } clear_bit(fcmd->token, fc->scsi_bitmap); fc->scsi_free++; dma_unmap_single (fc->dev, fcmd->cmd, 2 * len, DMA_BIDIRECTIONAL); return l.status; } int fc_do_plogi(fc_channel *fc, unsigned char alpa, fc_wwn *node, fc_wwn *nport) { logi *l; int status; l = (logi *)kzalloc(2 * sizeof(logi), GFP_KERNEL); if (!l) return -ENOMEM; l->code = LS_PLOGI; memcpy (&l->nport_wwn, &fc->wwn_nport, sizeof(fc_wwn)); memcpy (&l->node_wwn, &fc->wwn_node, sizeof(fc_wwn)); memcpy (&l->common, fc->common_svc, sizeof(common_svc_parm)); memcpy (&l->class1, fc->class_svcs, 3*sizeof(svc_parm)); status = fc_do_els(fc, alpa, l, sizeof(logi)); if (status == FC_STATUS_OK) { if (l[1].code == LS_ACC) { #ifdef FCDEBUG u32 *u = (u32 *)&l[1].nport_wwn; FCD(("AL-PA %02x: Port WWN %08x%08x Node WWN %08x%08x\n", alpa, u[0], u[1], u[2], u[3])) #endif memcpy(nport, &l[1].nport_wwn, sizeof(fc_wwn)); memcpy(node, &l[1].node_wwn, sizeof(fc_wwn)); } else status = FC_STATUS_BAD_RSP; } kfree(l); return status; } typedef struct { unsigned int code; unsigned params[4]; } prli; int fc_do_prli(fc_channel *fc, unsigned char alpa) { prli *p; int status; p = (prli *)kzalloc(2 * sizeof(prli), GFP_KERNEL); if (!p) return -ENOMEM; p->code = LS_PRLI; p->params[0] = 0x08002000; p->params[3] = 0x00000022; status = fc_do_els(fc, alpa, p, sizeof(prli)); if (status == FC_STATUS_OK && p[1].code != LS_PRLI_ACC && p[1].code != LS_ACC) status = FC_STATUS_BAD_RSP; kfree(p); return status; } MODULE_LICENSE("GPL");