Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Sudeep Dutt | 5320 | 96.24% | 4 | 36.36% |
Sudip Mukherjee | 108 | 1.95% | 1 | 9.09% |
Ashutosh Dixit | 51 | 0.92% | 1 | 9.09% |
Nikhil P Rao | 35 | 0.63% | 1 | 9.09% |
Lee Jones | 10 | 0.18% | 1 | 9.09% |
Thomas Gleixner | 2 | 0.04% | 1 | 9.09% |
Hu Haowen | 1 | 0.02% | 1 | 9.09% |
Christoph Hellwig | 1 | 0.02% | 1 | 9.09% |
Total | 5528 | 11 |
// SPDX-License-Identifier: GPL-2.0-only /* * Intel MIC Platform Software Stack (MPSS) * * Copyright(c) 2014 Intel Corporation. * * Intel SCIF driver. */ #include "../bus/scif_bus.h" #include "scif_peer_bus.h" #include "scif_main.h" #include "scif_nodeqp.h" #include "scif_map.h" /* ************************************************************************ * SCIF node Queue Pair (QP) setup flow: * * 1) SCIF driver gets probed with a scif_hw_dev via the scif_hw_bus * 2) scif_setup_qp(..) allocates the local qp and calls * scif_setup_qp_connect(..) which allocates and maps the local * buffer for the inbound QP * 3) The local node updates the device page with the DMA address of the QP * 4) A delayed work is scheduled (qp_dwork) which periodically reads if * the peer node has updated its QP DMA address * 5) Once a valid non zero address is found in the QP DMA address field * in the device page, the local node maps the remote node's QP, * updates its outbound QP and sends a SCIF_INIT message to the peer * 6) The SCIF_INIT message is received by the peer node QP interrupt bottom * half handler by calling scif_init(..) * 7) scif_init(..) registers a new SCIF peer node by calling * scif_peer_register_device(..) which signifies the addition of a new * SCIF node * 8) On the mgmt node, P2P network setup/teardown is initiated if all the * remote nodes are online via scif_p2p_setup(..) * 9) For P2P setup, the host maps the remote nodes' aperture and memory * bars and sends a SCIF_NODE_ADD message to both nodes * 10) As part of scif_nodeadd, both nodes set up their local inbound * QPs and send a SCIF_NODE_ADD_ACK to the mgmt node * 11) As part of scif_node_add_ack(..) the mgmt node forwards the * SCIF_NODE_ADD_ACK to the remote nodes * 12) As part of scif_node_add_ack(..) the remote nodes update their * outbound QPs, make sure they can access memory on the remote node * and then add a new SCIF peer node by calling * scif_peer_register_device(..) which signifies the addition of a new * SCIF node. * 13) The SCIF network is now established across all nodes. * ************************************************************************ * SCIF node QP teardown flow (initiated by non mgmt node): * * 1) SCIF driver gets a remove callback with a scif_hw_dev via the scif_hw_bus * 2) The device page QP DMA address field is updated with 0x0 * 3) A non mgmt node now cleans up all local data structures and sends a * SCIF_EXIT message to the peer and waits for a SCIF_EXIT_ACK * 4) As part of scif_exit(..) handling scif_disconnect_node(..) is called * 5) scif_disconnect_node(..) sends a SCIF_NODE_REMOVE message to all the * peers and waits for a SCIF_NODE_REMOVE_ACK * 6) As part of scif_node_remove(..) a remote node unregisters the peer * node from the SCIF network and sends a SCIF_NODE_REMOVE_ACK * 7) When the mgmt node has received all the SCIF_NODE_REMOVE_ACKs * it sends itself a node remove message whose handling cleans up local * data structures and unregisters the peer node from the SCIF network * 8) The mgmt node sends a SCIF_EXIT_ACK * 9) Upon receipt of the SCIF_EXIT_ACK the node initiating the teardown * completes the SCIF remove routine * 10) The SCIF network is now torn down for the node initiating the * teardown sequence * ************************************************************************ * SCIF node QP teardown flow (initiated by mgmt node): * * 1) SCIF driver gets a remove callback with a scif_hw_dev via the scif_hw_bus * 2) The device page QP DMA address field is updated with 0x0 * 3) The mgmt node calls scif_disconnect_node(..) * 4) scif_disconnect_node(..) sends a SCIF_NODE_REMOVE message to all the peers * and waits for a SCIF_NODE_REMOVE_ACK * 5) As part of scif_node_remove(..) a remote node unregisters the peer * node from the SCIF network and sends a SCIF_NODE_REMOVE_ACK * 6) When the mgmt node has received all the SCIF_NODE_REMOVE_ACKs * it unregisters the peer node from the SCIF network * 7) The mgmt node sends a SCIF_EXIT message and waits for a SCIF_EXIT_ACK. * 8) A non mgmt node upon receipt of a SCIF_EXIT message calls scif_stop(..) * which would clean up local data structures for all SCIF nodes and * then send a SCIF_EXIT_ACK back to the mgmt node * 9) Upon receipt of the SCIF_EXIT_ACK the the mgmt node sends itself a node * remove message whose handling cleans up local data structures and * destroys any P2P mappings. * 10) The SCIF hardware device for which a remove callback was received is now * disconnected from the SCIF network. */ /* * Initializes "local" data structures for the QP. Allocates the QP * ring buffer (rb) and initializes the "in bound" queue. */ int scif_setup_qp_connect(struct scif_qp *qp, dma_addr_t *qp_offset, int local_size, struct scif_dev *scifdev) { void *local_q = qp->inbound_q.rb_base; int err = 0; u32 tmp_rd = 0; spin_lock_init(&qp->send_lock); spin_lock_init(&qp->recv_lock); /* Allocate rb only if not already allocated */ if (!local_q) { local_q = kzalloc(local_size, GFP_KERNEL); if (!local_q) { err = -ENOMEM; return err; } } err = scif_map_single(&qp->local_buf, local_q, scifdev, local_size); if (err) goto kfree; /* * To setup the inbound_q, the buffer lives locally, the read pointer * is remote and the write pointer is local. */ scif_rb_init(&qp->inbound_q, &tmp_rd, &qp->local_write, local_q, get_count_order(local_size)); /* * The read pointer is NULL initially and it is unsafe to use the ring * buffer til this changes! */ qp->inbound_q.read_ptr = NULL; err = scif_map_single(qp_offset, qp, scifdev, sizeof(struct scif_qp)); if (err) goto unmap; qp->local_qp = *qp_offset; return err; unmap: scif_unmap_single(qp->local_buf, scifdev, local_size); qp->local_buf = 0; kfree: kfree(local_q); return err; } /* When the other side has already done it's allocation, this is called */ int scif_setup_qp_accept(struct scif_qp *qp, dma_addr_t *qp_offset, dma_addr_t phys, int local_size, struct scif_dev *scifdev) { void *local_q; void *remote_q; struct scif_qp *remote_qp; int remote_size; int err = 0; spin_lock_init(&qp->send_lock); spin_lock_init(&qp->recv_lock); /* Start by figuring out where we need to point */ remote_qp = scif_ioremap(phys, sizeof(struct scif_qp), scifdev); if (!remote_qp) return -EIO; qp->remote_qp = remote_qp; if (qp->remote_qp->magic != SCIFEP_MAGIC) { err = -EIO; goto iounmap; } qp->remote_buf = remote_qp->local_buf; remote_size = qp->remote_qp->inbound_q.size; remote_q = scif_ioremap(qp->remote_buf, remote_size, scifdev); if (!remote_q) { err = -EIO; goto iounmap; } qp->remote_qp->local_write = 0; /* * To setup the outbound_q, the buffer lives in remote memory, * the read pointer is local, the write pointer is remote */ scif_rb_init(&qp->outbound_q, &qp->local_read, &qp->remote_qp->local_write, remote_q, get_count_order(remote_size)); local_q = kzalloc(local_size, GFP_KERNEL); if (!local_q) { err = -ENOMEM; goto iounmap_1; } err = scif_map_single(&qp->local_buf, local_q, scifdev, local_size); if (err) goto kfree; qp->remote_qp->local_read = 0; /* * To setup the inbound_q, the buffer lives locally, the read pointer * is remote and the write pointer is local */ scif_rb_init(&qp->inbound_q, &qp->remote_qp->local_read, &qp->local_write, local_q, get_count_order(local_size)); err = scif_map_single(qp_offset, qp, scifdev, sizeof(struct scif_qp)); if (err) goto unmap; qp->local_qp = *qp_offset; return err; unmap: scif_unmap_single(qp->local_buf, scifdev, local_size); qp->local_buf = 0; kfree: kfree(local_q); iounmap_1: scif_iounmap(remote_q, remote_size, scifdev); qp->outbound_q.rb_base = NULL; iounmap: scif_iounmap(qp->remote_qp, sizeof(struct scif_qp), scifdev); qp->remote_qp = NULL; return err; } int scif_setup_qp_connect_response(struct scif_dev *scifdev, struct scif_qp *qp, u64 payload) { int err = 0; void *r_buf; int remote_size; phys_addr_t tmp_phys; qp->remote_qp = scif_ioremap(payload, sizeof(struct scif_qp), scifdev); if (!qp->remote_qp) { err = -ENOMEM; goto error; } if (qp->remote_qp->magic != SCIFEP_MAGIC) { dev_err(&scifdev->sdev->dev, "SCIFEP_MAGIC mismatch between self %d remote %d\n", scif_dev[scif_info.nodeid].node, scifdev->node); err = -ENODEV; goto error; } tmp_phys = qp->remote_qp->local_buf; remote_size = qp->remote_qp->inbound_q.size; r_buf = scif_ioremap(tmp_phys, remote_size, scifdev); if (!r_buf) return -EIO; qp->local_read = 0; scif_rb_init(&qp->outbound_q, &qp->local_read, &qp->remote_qp->local_write, r_buf, get_count_order(remote_size)); /* * Because the node QP may already be processing an INIT message, set * the read pointer so the cached read offset isn't lost */ qp->remote_qp->local_read = qp->inbound_q.current_read_offset; /* * resetup the inbound_q now that we know where the * inbound_read really is. */ scif_rb_init(&qp->inbound_q, &qp->remote_qp->local_read, &qp->local_write, qp->inbound_q.rb_base, get_count_order(qp->inbound_q.size)); error: return err; } static __always_inline void scif_send_msg_intr(struct scif_dev *scifdev) { struct scif_hw_dev *sdev = scifdev->sdev; if (scifdev_is_p2p(scifdev)) sdev->hw_ops->send_p2p_intr(sdev, scifdev->rdb, &scifdev->mmio); else sdev->hw_ops->send_intr(sdev, scifdev->rdb); } int scif_qp_response(phys_addr_t phys, struct scif_dev *scifdev) { int err = 0; struct scifmsg msg; err = scif_setup_qp_connect_response(scifdev, scifdev->qpairs, phys); if (!err) { /* * Now that everything is setup and mapped, we're ready * to tell the peer about our queue's location */ msg.uop = SCIF_INIT; msg.dst.node = scifdev->node; err = scif_nodeqp_send(scifdev, &msg); } return err; } void scif_send_exit(struct scif_dev *scifdev) { struct scifmsg msg; int ret; scifdev->exit = OP_IN_PROGRESS; msg.uop = SCIF_EXIT; msg.src.node = scif_info.nodeid; msg.dst.node = scifdev->node; ret = scif_nodeqp_send(scifdev, &msg); if (ret) goto done; /* Wait for a SCIF_EXIT_ACK message */ wait_event_timeout(scif_info.exitwq, scifdev->exit == OP_COMPLETED, SCIF_NODE_ALIVE_TIMEOUT); done: scifdev->exit = OP_IDLE; } int scif_setup_qp(struct scif_dev *scifdev) { int err = 0; int local_size; struct scif_qp *qp; local_size = SCIF_NODE_QP_SIZE; qp = kzalloc(sizeof(*qp), GFP_KERNEL); if (!qp) { err = -ENOMEM; return err; } qp->magic = SCIFEP_MAGIC; scifdev->qpairs = qp; err = scif_setup_qp_connect(qp, &scifdev->qp_dma_addr, local_size, scifdev); if (err) goto free_qp; /* * We're as setup as we can be. The inbound_q is setup, w/o a usable * outbound q. When we get a message, the read_ptr will be updated, * and we will pull the message. */ return err; free_qp: kfree(scifdev->qpairs); scifdev->qpairs = NULL; return err; } static void scif_p2p_freesg(struct scatterlist *sg) { kfree(sg); } static struct scatterlist * scif_p2p_setsg(phys_addr_t pa, int page_size, int page_cnt) { struct scatterlist *sg; struct page *page; int i; sg = kcalloc(page_cnt, sizeof(struct scatterlist), GFP_KERNEL); if (!sg) return NULL; sg_init_table(sg, page_cnt); for (i = 0; i < page_cnt; i++) { page = pfn_to_page(pa >> PAGE_SHIFT); sg_set_page(&sg[i], page, page_size, 0); pa += page_size; } return sg; } /* Init p2p mappings required to access peerdev from scifdev */ static struct scif_p2p_info * scif_init_p2p_info(struct scif_dev *scifdev, struct scif_dev *peerdev) { struct scif_p2p_info *p2p; int num_mmio_pages, num_aper_pages, sg_page_shift, err, num_aper_chunks; struct scif_hw_dev *psdev = peerdev->sdev; struct scif_hw_dev *sdev = scifdev->sdev; num_mmio_pages = psdev->mmio->len >> PAGE_SHIFT; num_aper_pages = psdev->aper->len >> PAGE_SHIFT; p2p = kzalloc(sizeof(*p2p), GFP_KERNEL); if (!p2p) return NULL; p2p->ppi_sg[SCIF_PPI_MMIO] = scif_p2p_setsg(psdev->mmio->pa, PAGE_SIZE, num_mmio_pages); if (!p2p->ppi_sg[SCIF_PPI_MMIO]) goto free_p2p; p2p->sg_nentries[SCIF_PPI_MMIO] = num_mmio_pages; sg_page_shift = get_order(min(psdev->aper->len, (u64)(1 << 30))); num_aper_chunks = num_aper_pages >> (sg_page_shift - PAGE_SHIFT); p2p->ppi_sg[SCIF_PPI_APER] = scif_p2p_setsg(psdev->aper->pa, 1 << sg_page_shift, num_aper_chunks); p2p->sg_nentries[SCIF_PPI_APER] = num_aper_chunks; err = dma_map_sg(&sdev->dev, p2p->ppi_sg[SCIF_PPI_MMIO], num_mmio_pages, PCI_DMA_BIDIRECTIONAL); if (err != num_mmio_pages) goto scif_p2p_free; err = dma_map_sg(&sdev->dev, p2p->ppi_sg[SCIF_PPI_APER], num_aper_chunks, PCI_DMA_BIDIRECTIONAL); if (err != num_aper_chunks) goto dma_unmap; p2p->ppi_da[SCIF_PPI_MMIO] = sg_dma_address(p2p->ppi_sg[SCIF_PPI_MMIO]); p2p->ppi_da[SCIF_PPI_APER] = sg_dma_address(p2p->ppi_sg[SCIF_PPI_APER]); p2p->ppi_len[SCIF_PPI_MMIO] = num_mmio_pages; p2p->ppi_len[SCIF_PPI_APER] = num_aper_pages; p2p->ppi_peer_id = peerdev->node; return p2p; dma_unmap: dma_unmap_sg(&sdev->dev, p2p->ppi_sg[SCIF_PPI_MMIO], p2p->sg_nentries[SCIF_PPI_MMIO], DMA_BIDIRECTIONAL); scif_p2p_free: scif_p2p_freesg(p2p->ppi_sg[SCIF_PPI_MMIO]); scif_p2p_freesg(p2p->ppi_sg[SCIF_PPI_APER]); free_p2p: kfree(p2p); return NULL; } /* Uninitialize and release resources from a p2p mapping */ static void scif_deinit_p2p_info(struct scif_dev *scifdev, struct scif_p2p_info *p2p) { struct scif_hw_dev *sdev = scifdev->sdev; dma_unmap_sg(&sdev->dev, p2p->ppi_sg[SCIF_PPI_MMIO], p2p->sg_nentries[SCIF_PPI_MMIO], DMA_BIDIRECTIONAL); dma_unmap_sg(&sdev->dev, p2p->ppi_sg[SCIF_PPI_APER], p2p->sg_nentries[SCIF_PPI_APER], DMA_BIDIRECTIONAL); scif_p2p_freesg(p2p->ppi_sg[SCIF_PPI_MMIO]); scif_p2p_freesg(p2p->ppi_sg[SCIF_PPI_APER]); kfree(p2p); } /** * scif_node_connect: Respond to SCIF_NODE_CONNECT interrupt message * @scifdev: SCIF device * @dst: Destination node * * Connect the src and dst node by setting up the p2p connection * between them. Management node here acts like a proxy. */ static void scif_node_connect(struct scif_dev *scifdev, int dst) { struct scif_dev *dev_j = scifdev; struct scif_dev *dev_i = NULL; struct scif_p2p_info *p2p_ij = NULL; /* bus addr for j from i */ struct scif_p2p_info *p2p_ji = NULL; /* bus addr for i from j */ struct scif_p2p_info *p2p; struct list_head *pos, *tmp; struct scifmsg msg; int err; u64 tmppayload; if (dst < 1 || dst > scif_info.maxid) return; dev_i = &scif_dev[dst]; if (!_scifdev_alive(dev_i)) return; /* * If the p2p connection is already setup or in the process of setting * up then just ignore this request. The requested node will get * informed by SCIF_NODE_ADD_ACK or SCIF_NODE_ADD_NACK */ if (!list_empty(&dev_i->p2p)) { list_for_each_safe(pos, tmp, &dev_i->p2p) { p2p = list_entry(pos, struct scif_p2p_info, ppi_list); if (p2p->ppi_peer_id == dev_j->node) return; } } p2p_ij = scif_init_p2p_info(dev_i, dev_j); if (!p2p_ij) return; p2p_ji = scif_init_p2p_info(dev_j, dev_i); if (!p2p_ji) { scif_deinit_p2p_info(dev_i, p2p_ij); return; } list_add_tail(&p2p_ij->ppi_list, &dev_i->p2p); list_add_tail(&p2p_ji->ppi_list, &dev_j->p2p); /* * Send a SCIF_NODE_ADD to dev_i, pass it its bus address * as seen from dev_j */ msg.uop = SCIF_NODE_ADD; msg.src.node = dev_j->node; msg.dst.node = dev_i->node; msg.payload[0] = p2p_ji->ppi_da[SCIF_PPI_APER]; msg.payload[1] = p2p_ij->ppi_da[SCIF_PPI_MMIO]; msg.payload[2] = p2p_ij->ppi_da[SCIF_PPI_APER]; msg.payload[3] = p2p_ij->ppi_len[SCIF_PPI_APER] << PAGE_SHIFT; err = scif_nodeqp_send(dev_i, &msg); if (err) { dev_err(&scifdev->sdev->dev, "%s %d error %d\n", __func__, __LINE__, err); return; } /* Same as above but to dev_j */ msg.uop = SCIF_NODE_ADD; msg.src.node = dev_i->node; msg.dst.node = dev_j->node; tmppayload = msg.payload[0]; msg.payload[0] = msg.payload[2]; msg.payload[2] = tmppayload; msg.payload[1] = p2p_ji->ppi_da[SCIF_PPI_MMIO]; msg.payload[3] = p2p_ji->ppi_len[SCIF_PPI_APER] << PAGE_SHIFT; scif_nodeqp_send(dev_j, &msg); } static void scif_p2p_setup(void) { int i, j; if (!scif_info.p2p_enable) return; for (i = 1; i <= scif_info.maxid; i++) if (!_scifdev_alive(&scif_dev[i])) return; for (i = 1; i <= scif_info.maxid; i++) { for (j = 1; j <= scif_info.maxid; j++) { struct scif_dev *scifdev = &scif_dev[i]; if (i == j) continue; scif_node_connect(scifdev, j); } } } static char *message_types[] = {"BAD", "INIT", "EXIT", "SCIF_EXIT_ACK", "SCIF_NODE_ADD", "SCIF_NODE_ADD_ACK", "SCIF_NODE_ADD_NACK", "REMOVE_NODE", "REMOVE_NODE_ACK", "CNCT_REQ", "CNCT_GNT", "CNCT_GNTACK", "CNCT_GNTNACK", "CNCT_REJ", "DISCNCT", "DISCNT_ACK", "CLIENT_SENT", "CLIENT_RCVD", "SCIF_GET_NODE_INFO", "REGISTER", "REGISTER_ACK", "REGISTER_NACK", "UNREGISTER", "UNREGISTER_ACK", "UNREGISTER_NACK", "ALLOC_REQ", "ALLOC_GNT", "ALLOC_REJ", "FREE_PHYS", "FREE_VIRT", "MUNMAP", "MARK", "MARK_ACK", "MARK_NACK", "WAIT", "WAIT_ACK", "WAIT_NACK", "SIGNAL_LOCAL", "SIGNAL_REMOTE", "SIG_ACK", "SIG_NACK"}; static void scif_display_message(struct scif_dev *scifdev, struct scifmsg *msg, const char *label) { if (!scif_info.en_msg_log) return; if (msg->uop > SCIF_MAX_MSG) { dev_err(&scifdev->sdev->dev, "%s: unknown msg type %d\n", label, msg->uop); return; } dev_info(&scifdev->sdev->dev, "%s: msg type %s, src %d:%d, dest %d:%d payload 0x%llx:0x%llx:0x%llx:0x%llx\n", label, message_types[msg->uop], msg->src.node, msg->src.port, msg->dst.node, msg->dst.port, msg->payload[0], msg->payload[1], msg->payload[2], msg->payload[3]); } int _scif_nodeqp_send(struct scif_dev *scifdev, struct scifmsg *msg) { struct scif_qp *qp = scifdev->qpairs; int err = -ENOMEM, loop_cnt = 0; scif_display_message(scifdev, msg, "Sent"); if (!qp) { err = -EINVAL; goto error; } spin_lock(&qp->send_lock); while ((err = scif_rb_write(&qp->outbound_q, msg, sizeof(struct scifmsg)))) { mdelay(1); #define SCIF_NODEQP_SEND_TO_MSEC (3 * 1000) if (loop_cnt++ > (SCIF_NODEQP_SEND_TO_MSEC)) { err = -ENODEV; break; } } if (!err) scif_rb_commit(&qp->outbound_q); spin_unlock(&qp->send_lock); if (!err) { if (scifdev_self(scifdev)) /* * For loopback we need to emulate an interrupt by * queuing work for the queue handling real node * Qp interrupts. */ queue_work(scifdev->intr_wq, &scifdev->intr_bh); else scif_send_msg_intr(scifdev); } error: if (err) dev_dbg(&scifdev->sdev->dev, "%s %d error %d uop %d\n", __func__, __LINE__, err, msg->uop); return err; } /** * scif_nodeqp_send - Send a message on the node queue pair * @scifdev: Scif Device. * @msg: The message to be sent. */ int scif_nodeqp_send(struct scif_dev *scifdev, struct scifmsg *msg) { int err; struct device *spdev = NULL; if (msg->uop > SCIF_EXIT_ACK) { /* Don't send messages once the exit flow has begun */ if (OP_IDLE != scifdev->exit) return -ENODEV; spdev = scif_get_peer_dev(scifdev); if (IS_ERR(spdev)) { err = PTR_ERR(spdev); return err; } } err = _scif_nodeqp_send(scifdev, msg); if (msg->uop > SCIF_EXIT_ACK) scif_put_peer_dev(spdev); return err; } /* * scif_misc_handler: * * Work queue handler for servicing miscellaneous SCIF tasks. * Examples include: * 1) Remote fence requests. * 2) Destruction of temporary registered windows * created during scif_vreadfrom()/scif_vwriteto(). * 3) Cleanup of zombie endpoints. */ void scif_misc_handler(struct work_struct *work) { scif_rma_handle_remote_fences(); scif_rma_destroy_windows(); scif_rma_destroy_tcw_invalid(); scif_cleanup_zombie_epd(); } /** * scif_init() - Respond to SCIF_INIT interrupt message * @scifdev: Remote SCIF device node * @msg: Interrupt message */ static __always_inline void scif_init(struct scif_dev *scifdev, struct scifmsg *msg) { /* * Allow the thread waiting for device page updates for the peer QP DMA * address to complete initializing the inbound_q. */ flush_delayed_work(&scifdev->qp_dwork); scif_peer_register_device(scifdev); if (scif_is_mgmt_node()) { mutex_lock(&scif_info.conflock); scif_p2p_setup(); mutex_unlock(&scif_info.conflock); } } /** * scif_exit() - Respond to SCIF_EXIT interrupt message * @scifdev: Remote SCIF device node * @unused: Interrupt message (unused) * * This function stops the SCIF interface for the node which sent * the SCIF_EXIT message and starts waiting for that node to * resetup the queue pair again. */ static __always_inline void scif_exit(struct scif_dev *scifdev, struct scifmsg *unused) { scifdev->exit_ack_pending = true; if (scif_is_mgmt_node()) scif_disconnect_node(scifdev->node, false); else scif_stop(scifdev); schedule_delayed_work(&scifdev->qp_dwork, msecs_to_jiffies(1000)); } /** * scif_exitack() - Respond to SCIF_EXIT_ACK interrupt message * @scifdev: Remote SCIF device node * @unused: Interrupt message (unused) * */ static __always_inline void scif_exit_ack(struct scif_dev *scifdev, struct scifmsg *unused) { scifdev->exit = OP_COMPLETED; wake_up(&scif_info.exitwq); } /** * scif_node_add() - Respond to SCIF_NODE_ADD interrupt message * @scifdev: Remote SCIF device node * @msg: Interrupt message * * When the mgmt node driver has finished initializing a MIC node queue pair it * marks the node as online. It then looks for all currently online MIC cards * and send a SCIF_NODE_ADD message to identify the ID of the new card for * peer to peer initialization * * The local node allocates its incoming queue and sends its address in the * SCIF_NODE_ADD_ACK message back to the mgmt node, the mgmt node "reflects" * this message to the new node */ static __always_inline void scif_node_add(struct scif_dev *scifdev, struct scifmsg *msg) { struct scif_dev *newdev; dma_addr_t qp_offset; int qp_connect; struct scif_hw_dev *sdev; dev_dbg(&scifdev->sdev->dev, "Scifdev %d:%d received NODE_ADD msg for node %d\n", scifdev->node, msg->dst.node, msg->src.node); dev_dbg(&scifdev->sdev->dev, "Remote address for this node's aperture %llx\n", msg->payload[0]); newdev = &scif_dev[msg->src.node]; newdev->node = msg->src.node; newdev->sdev = scif_dev[SCIF_MGMT_NODE].sdev; sdev = newdev->sdev; if (scif_setup_intr_wq(newdev)) { dev_err(&scifdev->sdev->dev, "failed to setup interrupts for %d\n", msg->src.node); goto interrupt_setup_error; } newdev->mmio.va = ioremap(msg->payload[1], sdev->mmio->len); if (!newdev->mmio.va) { dev_err(&scifdev->sdev->dev, "failed to map mmio for %d\n", msg->src.node); goto mmio_map_error; } newdev->qpairs = kzalloc(sizeof(*newdev->qpairs), GFP_KERNEL); if (!newdev->qpairs) goto qp_alloc_error; /* * Set the base address of the remote node's memory since it gets * added to qp_offset */ newdev->base_addr = msg->payload[0]; qp_connect = scif_setup_qp_connect(newdev->qpairs, &qp_offset, SCIF_NODE_QP_SIZE, newdev); if (qp_connect) { dev_err(&scifdev->sdev->dev, "failed to setup qp_connect %d\n", qp_connect); goto qp_connect_error; } newdev->db = sdev->hw_ops->next_db(sdev); newdev->cookie = sdev->hw_ops->request_irq(sdev, scif_intr_handler, "SCIF_INTR", newdev, newdev->db); if (IS_ERR(newdev->cookie)) goto qp_connect_error; newdev->qpairs->magic = SCIFEP_MAGIC; newdev->qpairs->qp_state = SCIF_QP_OFFLINE; msg->uop = SCIF_NODE_ADD_ACK; msg->dst.node = msg->src.node; msg->src.node = scif_info.nodeid; msg->payload[0] = qp_offset; msg->payload[2] = newdev->db; scif_nodeqp_send(&scif_dev[SCIF_MGMT_NODE], msg); return; qp_connect_error: kfree(newdev->qpairs); newdev->qpairs = NULL; qp_alloc_error: iounmap(newdev->mmio.va); newdev->mmio.va = NULL; mmio_map_error: interrupt_setup_error: dev_err(&scifdev->sdev->dev, "node add failed for node %d\n", msg->src.node); msg->uop = SCIF_NODE_ADD_NACK; msg->dst.node = msg->src.node; msg->src.node = scif_info.nodeid; scif_nodeqp_send(&scif_dev[SCIF_MGMT_NODE], msg); } void scif_poll_qp_state(struct work_struct *work) { #define SCIF_NODE_QP_RETRY 100 #define SCIF_NODE_QP_TIMEOUT 100 struct scif_dev *peerdev = container_of(work, struct scif_dev, p2p_dwork.work); struct scif_qp *qp = &peerdev->qpairs[0]; if (qp->qp_state != SCIF_QP_ONLINE || qp->remote_qp->qp_state != SCIF_QP_ONLINE) { if (peerdev->p2p_retry++ == SCIF_NODE_QP_RETRY) { dev_err(&peerdev->sdev->dev, "Warning: QP check timeout with state %d\n", qp->qp_state); goto timeout; } schedule_delayed_work(&peerdev->p2p_dwork, msecs_to_jiffies(SCIF_NODE_QP_TIMEOUT)); return; } return; timeout: dev_err(&peerdev->sdev->dev, "%s %d remote node %d offline, state = 0x%x\n", __func__, __LINE__, peerdev->node, qp->qp_state); qp->remote_qp->qp_state = SCIF_QP_OFFLINE; scif_peer_unregister_device(peerdev); scif_cleanup_scifdev(peerdev); } /** * scif_node_add_ack() - Respond to SCIF_NODE_ADD_ACK interrupt message * @scifdev: Remote SCIF device node * @msg: Interrupt message * * After a MIC node receives the SCIF_NODE_ADD_ACK message it send this * message to the mgmt node to confirm the sequence is finished. * */ static __always_inline void scif_node_add_ack(struct scif_dev *scifdev, struct scifmsg *msg) { struct scif_dev *peerdev; struct scif_qp *qp; struct scif_dev *dst_dev = &scif_dev[msg->dst.node]; dev_dbg(&scifdev->sdev->dev, "Scifdev %d received SCIF_NODE_ADD_ACK msg src %d dst %d\n", scifdev->node, msg->src.node, msg->dst.node); dev_dbg(&scifdev->sdev->dev, "payload %llx %llx %llx %llx\n", msg->payload[0], msg->payload[1], msg->payload[2], msg->payload[3]); if (scif_is_mgmt_node()) { /* * the lock serializes with scif_qp_response_ack. The mgmt node * is forwarding the NODE_ADD_ACK message from src to dst we * need to make sure that the dst has already received a * NODE_ADD for src and setup its end of the qp to dst */ mutex_lock(&scif_info.conflock); msg->payload[1] = scif_info.maxid; scif_nodeqp_send(dst_dev, msg); mutex_unlock(&scif_info.conflock); return; } peerdev = &scif_dev[msg->src.node]; peerdev->sdev = scif_dev[SCIF_MGMT_NODE].sdev; peerdev->node = msg->src.node; qp = &peerdev->qpairs[0]; if ((scif_setup_qp_connect_response(peerdev, &peerdev->qpairs[0], msg->payload[0]))) goto local_error; peerdev->rdb = msg->payload[2]; qp->remote_qp->qp_state = SCIF_QP_ONLINE; scif_peer_register_device(peerdev); schedule_delayed_work(&peerdev->p2p_dwork, 0); return; local_error: scif_cleanup_scifdev(peerdev); } /** * scif_node_add_nack: Respond to SCIF_NODE_ADD_NACK interrupt message * @scifdev: Remote SCIF device node * @msg: Interrupt message * * SCIF_NODE_ADD failed, so inform the waiting wq. */ static __always_inline void scif_node_add_nack(struct scif_dev *scifdev, struct scifmsg *msg) { if (scif_is_mgmt_node()) { struct scif_dev *dst_dev = &scif_dev[msg->dst.node]; dev_dbg(&scifdev->sdev->dev, "SCIF_NODE_ADD_NACK received from %d\n", scifdev->node); scif_nodeqp_send(dst_dev, msg); } } /** * scif_node_remove: Handle SCIF_NODE_REMOVE message * @scifdev: Remote SCIF device node * @msg: Interrupt message * * Handle node removal. */ static __always_inline void scif_node_remove(struct scif_dev *scifdev, struct scifmsg *msg) { int node = msg->payload[0]; struct scif_dev *scdev = &scif_dev[node]; scdev->node_remove_ack_pending = true; scif_handle_remove_node(node); } /** * scif_node_remove_ack: Handle SCIF_NODE_REMOVE_ACK message * @scifdev: Remote SCIF device node * @msg: Interrupt message * * The peer has acked a SCIF_NODE_REMOVE message. */ static __always_inline void scif_node_remove_ack(struct scif_dev *scifdev, struct scifmsg *msg) { struct scif_dev *sdev = &scif_dev[msg->payload[0]]; atomic_inc(&sdev->disconn_rescnt); wake_up(&sdev->disconn_wq); } /** * scif_get_node_info: Respond to SCIF_GET_NODE_INFO interrupt message * @scifdev: Remote SCIF device node * @msg: Interrupt message * * Retrieve node info i.e maxid and total from the mgmt node. */ static __always_inline void scif_get_node_info_resp(struct scif_dev *scifdev, struct scifmsg *msg) { if (scif_is_mgmt_node()) { swap(msg->dst.node, msg->src.node); mutex_lock(&scif_info.conflock); msg->payload[1] = scif_info.maxid; msg->payload[2] = scif_info.total; mutex_unlock(&scif_info.conflock); scif_nodeqp_send(scifdev, msg); } else { struct completion *node_info = (struct completion *)msg->payload[3]; mutex_lock(&scif_info.conflock); scif_info.maxid = msg->payload[1]; scif_info.total = msg->payload[2]; complete_all(node_info); mutex_unlock(&scif_info.conflock); } } static void scif_msg_unknown(struct scif_dev *scifdev, struct scifmsg *msg) { /* Bogus Node Qp Message? */ dev_err(&scifdev->sdev->dev, "Unknown message 0x%xn scifdev->node 0x%x\n", msg->uop, scifdev->node); } static void (*scif_intr_func[SCIF_MAX_MSG + 1]) (struct scif_dev *, struct scifmsg *msg) = { scif_msg_unknown, /* Error */ scif_init, /* SCIF_INIT */ scif_exit, /* SCIF_EXIT */ scif_exit_ack, /* SCIF_EXIT_ACK */ scif_node_add, /* SCIF_NODE_ADD */ scif_node_add_ack, /* SCIF_NODE_ADD_ACK */ scif_node_add_nack, /* SCIF_NODE_ADD_NACK */ scif_node_remove, /* SCIF_NODE_REMOVE */ scif_node_remove_ack, /* SCIF_NODE_REMOVE_ACK */ scif_cnctreq, /* SCIF_CNCT_REQ */ scif_cnctgnt, /* SCIF_CNCT_GNT */ scif_cnctgnt_ack, /* SCIF_CNCT_GNTACK */ scif_cnctgnt_nack, /* SCIF_CNCT_GNTNACK */ scif_cnctrej, /* SCIF_CNCT_REJ */ scif_discnct, /* SCIF_DISCNCT */ scif_discnt_ack, /* SCIF_DISCNT_ACK */ scif_clientsend, /* SCIF_CLIENT_SENT */ scif_clientrcvd, /* SCIF_CLIENT_RCVD */ scif_get_node_info_resp,/* SCIF_GET_NODE_INFO */ scif_recv_reg, /* SCIF_REGISTER */ scif_recv_reg_ack, /* SCIF_REGISTER_ACK */ scif_recv_reg_nack, /* SCIF_REGISTER_NACK */ scif_recv_unreg, /* SCIF_UNREGISTER */ scif_recv_unreg_ack, /* SCIF_UNREGISTER_ACK */ scif_recv_unreg_nack, /* SCIF_UNREGISTER_NACK */ scif_alloc_req, /* SCIF_ALLOC_REQ */ scif_alloc_gnt_rej, /* SCIF_ALLOC_GNT */ scif_alloc_gnt_rej, /* SCIF_ALLOC_REJ */ scif_free_virt, /* SCIF_FREE_VIRT */ scif_recv_munmap, /* SCIF_MUNMAP */ scif_recv_mark, /* SCIF_MARK */ scif_recv_mark_resp, /* SCIF_MARK_ACK */ scif_recv_mark_resp, /* SCIF_MARK_NACK */ scif_recv_wait, /* SCIF_WAIT */ scif_recv_wait_resp, /* SCIF_WAIT_ACK */ scif_recv_wait_resp, /* SCIF_WAIT_NACK */ scif_recv_sig_local, /* SCIF_SIG_LOCAL */ scif_recv_sig_remote, /* SCIF_SIG_REMOTE */ scif_recv_sig_resp, /* SCIF_SIG_ACK */ scif_recv_sig_resp, /* SCIF_SIG_NACK */ }; static int scif_max_msg_id = SCIF_MAX_MSG; /** * scif_nodeqp_msg_handler() - Common handler for node messages * @scifdev: Remote device to respond to * @qp: Remote memory pointer * @msg: The message to be handled. * * This routine calls the appropriate routine to handle a Node Qp * message receipt */ static void scif_nodeqp_msg_handler(struct scif_dev *scifdev, struct scif_qp *qp, struct scifmsg *msg) { scif_display_message(scifdev, msg, "Rcvd"); if (msg->uop > (u32)scif_max_msg_id) { /* Bogus Node Qp Message? */ dev_err(&scifdev->sdev->dev, "Unknown message 0x%xn scifdev->node 0x%x\n", msg->uop, scifdev->node); return; } scif_intr_func[msg->uop](scifdev, msg); } /** * scif_nodeqp_intrhandler() - Interrupt handler for node messages * @scifdev: Remote device to respond to * @qp: Remote memory pointer * * This routine is triggered by the interrupt mechanism. It reads * messages from the node queue RB and calls the Node QP Message handling * routine. */ void scif_nodeqp_intrhandler(struct scif_dev *scifdev, struct scif_qp *qp) { struct scifmsg msg; int read_size; do { read_size = scif_rb_get_next(&qp->inbound_q, &msg, sizeof(msg)); if (!read_size) break; scif_nodeqp_msg_handler(scifdev, qp, &msg); /* * The node queue pair is unmapped so skip the read pointer * update after receipt of a SCIF_EXIT_ACK */ if (SCIF_EXIT_ACK == msg.uop) break; scif_rb_update_read_ptr(&qp->inbound_q); } while (1); } /** * scif_loopb_wq_handler - Loopback Workqueue Handler. * @unused: loop back work (unused) * * This work queue routine is invoked by the loopback work queue handler. * It grabs the recv lock, dequeues any available messages from the head * of the loopback message list, calls the node QP message handler, * waits for it to return, then frees up this message and dequeues more * elements of the list if available. */ static void scif_loopb_wq_handler(struct work_struct *unused) { struct scif_dev *scifdev = scif_info.loopb_dev; struct scif_qp *qp = scifdev->qpairs; struct scif_loopb_msg *msg; do { msg = NULL; spin_lock(&qp->recv_lock); if (!list_empty(&scif_info.loopb_recv_q)) { msg = list_first_entry(&scif_info.loopb_recv_q, struct scif_loopb_msg, list); list_del(&msg->list); } spin_unlock(&qp->recv_lock); if (msg) { scif_nodeqp_msg_handler(scifdev, qp, &msg->msg); kfree(msg); } } while (msg); } /** * scif_loopb_msg_handler() - Workqueue handler for loopback messages. * @scifdev: SCIF device * @qp: Queue pair. * * This work queue routine is triggered when a loopback message is received. * * We need special handling for receiving Node Qp messages on a loopback SCIF * device via two workqueues for receiving messages. * * The reason we need the extra workqueue which is not required with *normal* * non-loopback SCIF devices is the potential classic deadlock described below: * * Thread A tries to send a message on a loopback SCIF device and blocks since * there is no space in the RB while it has the send_lock held or another * lock called lock X for example. * * Thread B: The Loopback Node QP message receive workqueue receives the message * and tries to send a message (eg an ACK) to the loopback SCIF device. It tries * to grab the send lock again or lock X and deadlocks with Thread A. The RB * cannot be drained any further due to this classic deadlock. * * In order to avoid deadlocks as mentioned above we have an extra level of * indirection achieved by having two workqueues. * 1) The first workqueue whose handler is scif_loopb_msg_handler reads * messages from the Node QP RB, adds them to a list and queues work for the * second workqueue. * * 2) The second workqueue whose handler is scif_loopb_wq_handler dequeues * messages from the list, handles them, frees up the memory and dequeues * more elements from the list if possible. */ int scif_loopb_msg_handler(struct scif_dev *scifdev, struct scif_qp *qp) { int read_size; struct scif_loopb_msg *msg; do { msg = kmalloc(sizeof(*msg), GFP_KERNEL); if (!msg) return -ENOMEM; read_size = scif_rb_get_next(&qp->inbound_q, &msg->msg, sizeof(struct scifmsg)); if (read_size != sizeof(struct scifmsg)) { kfree(msg); scif_rb_update_read_ptr(&qp->inbound_q); break; } spin_lock(&qp->recv_lock); list_add_tail(&msg->list, &scif_info.loopb_recv_q); spin_unlock(&qp->recv_lock); queue_work(scif_info.loopb_wq, &scif_info.loopb_work); scif_rb_update_read_ptr(&qp->inbound_q); } while (read_size == sizeof(struct scifmsg)); return read_size; } /** * scif_setup_loopback_qp - One time setup work for Loopback Node Qp. * @scifdev: SCIF device * * Sets up the required loopback workqueues, queue pairs and ring buffers */ int scif_setup_loopback_qp(struct scif_dev *scifdev) { int err = 0; void *local_q; struct scif_qp *qp; err = scif_setup_intr_wq(scifdev); if (err) goto exit; INIT_LIST_HEAD(&scif_info.loopb_recv_q); snprintf(scif_info.loopb_wqname, sizeof(scif_info.loopb_wqname), "SCIF LOOPB %d", scifdev->node); scif_info.loopb_wq = alloc_ordered_workqueue(scif_info.loopb_wqname, 0); if (!scif_info.loopb_wq) { err = -ENOMEM; goto destroy_intr; } INIT_WORK(&scif_info.loopb_work, scif_loopb_wq_handler); /* Allocate Self Qpair */ scifdev->qpairs = kzalloc(sizeof(*scifdev->qpairs), GFP_KERNEL); if (!scifdev->qpairs) { err = -ENOMEM; goto destroy_loopb_wq; } qp = scifdev->qpairs; qp->magic = SCIFEP_MAGIC; spin_lock_init(&qp->send_lock); spin_lock_init(&qp->recv_lock); local_q = kzalloc(SCIF_NODE_QP_SIZE, GFP_KERNEL); if (!local_q) { err = -ENOMEM; goto free_qpairs; } /* * For loopback the inbound_q and outbound_q are essentially the same * since the Node sends a message on the loopback interface to the * outbound_q which is then received on the inbound_q. */ scif_rb_init(&qp->outbound_q, &qp->local_read, &qp->local_write, local_q, get_count_order(SCIF_NODE_QP_SIZE)); scif_rb_init(&qp->inbound_q, &qp->local_read, &qp->local_write, local_q, get_count_order(SCIF_NODE_QP_SIZE)); scif_info.nodeid = scifdev->node; scif_peer_register_device(scifdev); scif_info.loopb_dev = scifdev; return err; free_qpairs: kfree(scifdev->qpairs); destroy_loopb_wq: destroy_workqueue(scif_info.loopb_wq); destroy_intr: scif_destroy_intr_wq(scifdev); exit: return err; } /** * scif_destroy_loopback_qp - One time uninit work for Loopback Node Qp * @scifdev: SCIF device * * Destroys the workqueues and frees up the Ring Buffer and Queue Pair memory. */ int scif_destroy_loopback_qp(struct scif_dev *scifdev) { scif_peer_unregister_device(scifdev); destroy_workqueue(scif_info.loopb_wq); scif_destroy_intr_wq(scifdev); kfree(scifdev->qpairs->outbound_q.rb_base); kfree(scifdev->qpairs); scifdev->sdev = NULL; scif_info.loopb_dev = NULL; return 0; } void scif_destroy_p2p(struct scif_dev *scifdev) { struct scif_dev *peer_dev; struct scif_p2p_info *p2p; struct list_head *pos, *tmp; int bd; mutex_lock(&scif_info.conflock); /* Free P2P mappings in the given node for all its peer nodes */ list_for_each_safe(pos, tmp, &scifdev->p2p) { p2p = list_entry(pos, struct scif_p2p_info, ppi_list); dma_unmap_sg(&scifdev->sdev->dev, p2p->ppi_sg[SCIF_PPI_MMIO], p2p->sg_nentries[SCIF_PPI_MMIO], DMA_BIDIRECTIONAL); dma_unmap_sg(&scifdev->sdev->dev, p2p->ppi_sg[SCIF_PPI_APER], p2p->sg_nentries[SCIF_PPI_APER], DMA_BIDIRECTIONAL); scif_p2p_freesg(p2p->ppi_sg[SCIF_PPI_MMIO]); scif_p2p_freesg(p2p->ppi_sg[SCIF_PPI_APER]); list_del(pos); kfree(p2p); } /* Free P2P mapping created in the peer nodes for the given node */ for (bd = SCIF_MGMT_NODE + 1; bd <= scif_info.maxid; bd++) { peer_dev = &scif_dev[bd]; list_for_each_safe(pos, tmp, &peer_dev->p2p) { p2p = list_entry(pos, struct scif_p2p_info, ppi_list); if (p2p->ppi_peer_id == scifdev->node) { dma_unmap_sg(&peer_dev->sdev->dev, p2p->ppi_sg[SCIF_PPI_MMIO], p2p->sg_nentries[SCIF_PPI_MMIO], DMA_BIDIRECTIONAL); dma_unmap_sg(&peer_dev->sdev->dev, p2p->ppi_sg[SCIF_PPI_APER], p2p->sg_nentries[SCIF_PPI_APER], DMA_BIDIRECTIONAL); scif_p2p_freesg(p2p->ppi_sg[SCIF_PPI_MMIO]); scif_p2p_freesg(p2p->ppi_sg[SCIF_PPI_APER]); list_del(pos); kfree(p2p); } } } mutex_unlock(&scif_info.conflock); }
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