/* * Copyright (c) 2023-2024 Ian Marco Moffett and the Osmora Team. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of Hyra nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include __MODULE_NAME("nvme"); __KERNEL_META("$Hyra$: nvme.c, Ian Marco Moffett, " "NVMe driver"); #define COMMAND_SIZE 64 /* In bytes (defined by spec) */ #define CAP_MPSMIN(caps) ((caps >> 48) & 0xF) #define CAP_MPSMAX(caps) ((caps >> 52) & 0xF) #define CAP_TIMEOUT(caps) ((caps >> 24) & 0xFF) #define CAP_STRIDE(caps) ((caps >> 32) & 0xF) #define CAP_MQES(caps) (caps & 0xFFFF) #define CAP_CSS(caps) (caps & 0xFF) #define STATUS_READY(status) (status & 1) #define CONFIG_EN __BIT(0) #define CONFIG_CSS_SHIFT 4 #define CONFIG_IOSQES_SHIFT 16 #define CONFIG_IOCQES_SHIFT 20 static struct pci_device *nvme_dev; static struct timer driver_tmr; static TAILQ_HEAD(,nvme_ns) namespaces; static inline int is_4k_aligned(void *ptr) { return ((uintptr_t)ptr & (0x1000 - 1)) == 0; } /* * Poll CSTS.RDY to equal `val' * * Returns `val' on success, returns < 0 value * upon failure. */ static int nvme_poll_ready(struct nvme_bar *bar, uint8_t val) { uint8_t timeout = CAP_TIMEOUT(bar->caps); uint8_t time_waited = 0; do { if (STATUS_READY(bar->status) == val) { /* Done waiting */ break; } /* * If CSTS.RDY hasn't changed, we can try to wait a * little longer. * * XXX: The spec states that CAP.TO (Timeout) is in 500 * millisecond units. */ if (time_waited < timeout) { driver_tmr.msleep(500); ++time_waited; } else { return -1; } } while (1); return val; } /* * Create an NVMe queue. */ static int nvme_create_queue(struct nvme_state *s, struct nvme_queue *queue, size_t id) { struct nvme_bar *bar = s->bar; const size_t PAGESZ = vm_get_page_size(); const uint8_t DBSTRIDE = CAP_STRIDE(bar->caps); const uint16_t SLOTS = CAP_MQES(bar->caps); queue->sq = dynalloc_memalign(sizeof(void *) * SLOTS, 0x1000); queue->cq = dynalloc_memalign(sizeof(void *) * SLOTS, 0x1000); if (queue->sq == NULL) { return -1; } if (queue->cq == NULL) { dynfree(queue->sq); return -1; } memset(queue->sq, 0, sizeof(void *) * SLOTS); memset(queue->cq, 0, sizeof(void *) * SLOTS); queue->sq_head = 0; queue->sq_tail = 0; queue->size = SLOTS; queue->sq_db = PHYS_TO_VIRT((uintptr_t)bar + PAGESZ + (2 * id * (4 << DBSTRIDE))); queue->cq_db = PHYS_TO_VIRT((uintptr_t)bar + PAGESZ + ((2 * id + 1) * (4 << DBSTRIDE))); queue->cq_phase = 1; return 0; } /* * Submit a command * * @queue: Target queue. * @cmd: Command to submit */ static void nvme_submit_cmd(struct nvme_queue *queue, struct nvme_cmd cmd) { /* Submit the command to the queue */ queue->sq[queue->sq_tail++] = cmd; if (queue->sq_tail >= queue->size) { queue->sq_tail = 0; } *(queue->sq_db) = queue->sq_tail; } /* * Submit a command and poll for completion * * @queue: Target queue. * @cmd: Command to submit */ static int nvme_poll_submit_cmd(struct nvme_queue *queue, struct nvme_cmd cmd) { uint16_t status; size_t spins = 0; nvme_submit_cmd(queue, cmd); /* * Wait for the current command to complete by * polling the phase bit. */ while (1) { status = queue->cq[queue->cq_head].status; if ((status & 1) == queue->cq_phase) { /* * The phase bit matches the phase for the most * recently submitted command, the command has completed. */ break; } if ((status & ~1) != 0) { KDEBUG("NVMe cmd error (bits=0x%x)\n", status >> 1); break; } if (spins > 5) { /* Attempts exhausted */ KERR("Hang on phase bit poll, giving up (cmd error)\n"); break; } /* Not done, give it some more time */ driver_tmr.msleep(150); ++spins; } ++queue->cq_head; if (queue->cq_head >= queue->size) { queue->cq_head = 0; queue->cq_phase = !queue->cq_phase; } /* Tell the controller that `head' updated */ *(queue->cq_db) = queue->cq_head; return 0; } /* * Create an I/O queue for a specific namespace. * * @ns: Namespace * @id: I/O queue ID */ static int nvme_create_ioq(struct nvme_ns *ns, size_t id) { struct nvme_queue *ioq = &ns->ioq; struct nvme_state *cntl = ns->cntl; struct nvme_bar *bar = cntl->bar; struct nvme_cmd cmd = {0}; size_t mqes = CAP_MQES(bar->caps); struct nvme_create_iocq_cmd *create_iocq; struct nvme_create_iosq_cmd *create_iosq; int status; if ((status = nvme_create_queue(ns->cntl, ioq, id)) != 0) { return status; } create_iocq = &cmd.create_iocq; create_iocq->opcode = NVME_OP_CREATE_IOCQ; create_iocq->qflags |= __BIT(0); /* Physically contiguous */ create_iocq->qsize = mqes; create_iocq->qid = id; create_iocq->prp1 = VIRT_TO_PHYS(ns->ioq.cq); if ((status = nvme_poll_submit_cmd(&cntl->adminq, cmd)) != 0) { return status; } create_iosq = &cmd.create_iosq; create_iosq->opcode = NVME_OP_CREATE_IOSQ; create_iosq->qflags |= __BIT(0); /* Physically contiguous */ create_iosq->qsize = mqes; create_iosq->cqid = id; create_iosq->sqid = id; create_iosq->prp1 = VIRT_TO_PHYS(ns->ioq.sq); return nvme_poll_submit_cmd(&cntl->adminq, cmd); } /* * Issue an identify command for the current * controller. * * XXX: `id' must be aligned on a 4k byte boundary to avoid * crossing a page boundary. This keeps the implementation * as simple as possible here. */ static int nvme_identify(struct nvme_state *state, struct nvme_id *id) { struct nvme_cmd cmd = {0}; struct nvme_identify_cmd *identify = &cmd.identify; /* Ensure `id' is aligned on a 4k byte boundary */ if (!is_4k_aligned(id)) { return -1; } identify->opcode = NVME_OP_IDENTIFY; identify->nsid = 0; identify->cns = 1; /* Identify controller */ identify->prp1 = VIRT_TO_PHYS(id); identify->prp2 = 0; /* No need, data address is 4k aligned */ return nvme_poll_submit_cmd(&state->adminq, cmd); } /* * Get identify data for namespace * * @id_ns: Data will be written to this pointer via DMA. * @nsid: Namespace ID. * * XXX: `id_ns' must be 4k aligned. */ static int nvme_id_ns(struct nvme_state *s, struct nvme_id_ns *id_ns, uint16_t nsid) { struct nvme_cmd cmd = {0}; struct nvme_identify_cmd *identify = &cmd.identify; if (!is_4k_aligned(id_ns)) { return -1; } identify->opcode = NVME_OP_IDENTIFY; identify->nsid = nsid; identify->cns = 0; identify->prp1 = VIRT_TO_PHYS(id_ns); return nvme_poll_submit_cmd(&s->adminq, cmd); } /* * Init a namespace. * * @nsid: Namespace ID */ static int nvme_init_ns(struct nvme_state *state, uint16_t nsid) { struct nvme_ns *ns = NULL; struct nvme_id_ns *id_ns = NULL; uint8_t lba_format; int status = 0; ns = dynalloc(sizeof(struct nvme_ns)); if (ns == NULL) { status = -1; goto done; } id_ns = dynalloc_memalign(sizeof(struct nvme_id_ns), 0x1000); if ((status = nvme_id_ns(state, id_ns, nsid)) != 0) { dynfree(ns); goto done; } lba_format = id_ns->flbas & 0xF; ns->lba_fmt = id_ns->lbaf[lba_format]; ns->nsid = nsid; ns->lba_bsize = 1 << ns->lba_fmt.ds; ns->size = id_ns->size; ns->cntl = state; nvme_create_ioq(ns, ns->nsid); TAILQ_INSERT_TAIL(&namespaces, ns, link); done: if (id_ns != NULL) dynfree(id_ns); return status; } static int nvme_disable_controller(struct nvme_state *state) { struct nvme_bar *bar = state->bar; if (__TEST(bar->config, CONFIG_EN)) { bar->config &= ~CONFIG_EN; } if (nvme_poll_ready(bar, 0) < 0) { KERR("Failed to disable controller\n"); return -1; } return 0; } /* * For debugging purposes, logs some information * found within the controller identify data structure. */ static void nvme_log_ctrl_id(struct nvme_id *id) { char mn[41] = {0}; char fr[9] = {0}; for (size_t i = 0; i < sizeof(id->mn); ++i) { mn[i] = id->mn[i]; } for (size_t i = 0; i < sizeof(id->fr); ++i) { fr[i] = id->fr[i]; } KDEBUG("NVMe model: %s\n", mn); KDEBUG("NVMe firmware revision: %s\n", fr); } /* * Fetch the list of namespace IDs * * @nsids_out: NSIDs will be written here via DMA. * * XXX: `nsids_out' must be 4k aligned. */ static int nvme_get_nsids(struct nvme_state *state, uint32_t *nsids_out) { struct nvme_cmd cmd = {0}; struct nvme_identify_cmd *identify = &cmd.identify; if (!is_4k_aligned(nsids_out)) { return -1; } identify->opcode = NVME_OP_IDENTIFY; identify->cns = 2; /* Active NSID list */ identify->prp1 = VIRT_TO_PHYS(nsids_out); return nvme_poll_submit_cmd(&state->adminq, cmd); } static int nvme_enable_controller(struct nvme_state *state) { struct nvme_bar *bar = state->bar; struct nvme_id *id; uint32_t *nsids; uint8_t max_sqes, max_cqes; if (!__TEST(bar->config, CONFIG_EN)) { bar->config |= CONFIG_EN; } if (nvme_poll_ready(bar, 1) < 0) { KERR("Failed to enable controller\n"); return -1; } id = dynalloc_memalign(sizeof(struct nvme_id), 0x1000); if (id == NULL) { return -1; } nsids = dynalloc_memalign(0x1000, 0x1000); if (nsids == NULL) { return -1; } nvme_identify(state, id); nvme_log_ctrl_id(id); nvme_get_nsids(state, nsids); /* * Before creating any I/O queues we need to set CC.IOCQES * and CC.IOSQES... Bits 3:0 is the minimum and bits 7:4 * is the maximum. We'll choose the maximum. */ max_sqes = id->sqes >> 4; max_cqes = id->cqes >> 4; bar->config |= (max_sqes << CONFIG_IOSQES_SHIFT); bar->config |= (max_cqes << CONFIG_IOCQES_SHIFT); /* Init NVMe namespaces */ for (size_t i = 0; i < id->nn; ++i) { if (nsids[i] != 0) { KINFO("Found NVMe namespace (id=%d)\n", nsids[i]); nvme_init_ns(state, nsids[i]); } } dynfree(nsids); dynfree(id); return 0; } static int nvme_init_controller(struct nvme_bar *bar) { struct nvme_state state = { . bar = bar }; struct nvme_queue *adminq = &state.adminq; uint16_t mqes = CAP_MQES(bar->caps); uint16_t cmdreg_bits = PCI_BUS_MASTERING | PCI_MEM_SPACE; pci_set_cmdreg(nvme_dev, cmdreg_bits); nvme_disable_controller(&state); nvme_create_queue(&state, adminq, 0); /* Setup admin submission and admin completion queues */ bar->aqa = (mqes | mqes << 16); bar->asq = VIRT_TO_PHYS(adminq->sq); bar->acq = VIRT_TO_PHYS(adminq->cq); return nvme_enable_controller(&state); } static int nvme_init(void) { struct nvme_bar *bar; struct pci_lookup nvme_lookup = { .pci_class = 1, .pci_subclass = 8 }; if (req_timer(TIMER_GP, &driver_tmr) != 0) { KERR("Failed to fetch general purpose timer\n"); return -1; } if (driver_tmr.msleep == NULL) { KERR("Timer does not have msleep()\n"); return -1; } nvme_dev = pci_get_device(nvme_lookup, PCI_CLASS | PCI_SUBCLASS); if (nvme_dev == NULL) { return -1; } bar = (struct nvme_bar *)(nvme_dev->bar[0] & ~7); KINFO("NVMe BAR0 @ 0x%p\n", bar); TAILQ_INIT(&namespaces); if (nvme_init_controller(bar) < 0) { return -1; } return 0; } DRIVER_EXPORT(nvme_init);