// SPDX-License-Identifier: BSD-3-Clause OR GPL-2.0 /* Copyright (c) 2019-2020 Marvell International Ltd. All rights reserved */ #include #include #include #include #include #include #include #include #include "prestera.h" #define PRESTERA_MSG_MAX_SIZE 1500 #define PRESTERA_SUPP_FW_MAJ_VER 3 #define PRESTERA_SUPP_FW_MIN_VER 0 #define PRESTERA_PREV_FW_MAJ_VER 2 #define PRESTERA_PREV_FW_MIN_VER 0 #define PRESTERA_FW_PATH_FMT "mrvl/prestera/mvsw_prestera_fw-v%u.%u.img" #define PRESTERA_FW_HDR_MAGIC 0x351D9D06 #define PRESTERA_FW_DL_TIMEOUT_MS 50000 #define PRESTERA_FW_BLK_SZ 1024 #define PRESTERA_FW_VER_MAJ_MUL 1000000 #define PRESTERA_FW_VER_MIN_MUL 1000 #define PRESTERA_FW_VER_MAJ(v) ((v) / PRESTERA_FW_VER_MAJ_MUL) #define PRESTERA_FW_VER_MIN(v) \ (((v) - (PRESTERA_FW_VER_MAJ(v) * PRESTERA_FW_VER_MAJ_MUL)) / \ PRESTERA_FW_VER_MIN_MUL) #define PRESTERA_FW_VER_PATCH(v) \ ((v) - (PRESTERA_FW_VER_MAJ(v) * PRESTERA_FW_VER_MAJ_MUL) - \ (PRESTERA_FW_VER_MIN(v) * PRESTERA_FW_VER_MIN_MUL)) enum prestera_pci_bar_t { PRESTERA_PCI_BAR_FW = 2, PRESTERA_PCI_BAR_PP = 4, }; struct prestera_fw_header { __be32 magic_number; __be32 version_value; u8 reserved[8]; }; struct prestera_ldr_regs { u32 ldr_ready; u32 pad1; u32 ldr_img_size; u32 ldr_ctl_flags; u32 ldr_buf_offs; u32 ldr_buf_size; u32 ldr_buf_rd; u32 pad2; u32 ldr_buf_wr; u32 ldr_status; }; #define PRESTERA_LDR_REG_OFFSET(f) offsetof(struct prestera_ldr_regs, f) #define PRESTERA_LDR_READY_MAGIC 0xf00dfeed #define PRESTERA_LDR_STATUS_IMG_DL BIT(0) #define PRESTERA_LDR_STATUS_START_FW BIT(1) #define PRESTERA_LDR_STATUS_INVALID_IMG BIT(2) #define PRESTERA_LDR_STATUS_NOMEM BIT(3) #define PRESTERA_LDR_REG_BASE(fw) ((fw)->ldr_regs) #define PRESTERA_LDR_REG_ADDR(fw, reg) (PRESTERA_LDR_REG_BASE(fw) + (reg)) /* fw loader registers */ #define PRESTERA_LDR_READY_REG PRESTERA_LDR_REG_OFFSET(ldr_ready) #define PRESTERA_LDR_IMG_SIZE_REG PRESTERA_LDR_REG_OFFSET(ldr_img_size) #define PRESTERA_LDR_CTL_REG PRESTERA_LDR_REG_OFFSET(ldr_ctl_flags) #define PRESTERA_LDR_BUF_SIZE_REG PRESTERA_LDR_REG_OFFSET(ldr_buf_size) #define PRESTERA_LDR_BUF_OFFS_REG PRESTERA_LDR_REG_OFFSET(ldr_buf_offs) #define PRESTERA_LDR_BUF_RD_REG PRESTERA_LDR_REG_OFFSET(ldr_buf_rd) #define PRESTERA_LDR_BUF_WR_REG PRESTERA_LDR_REG_OFFSET(ldr_buf_wr) #define PRESTERA_LDR_STATUS_REG PRESTERA_LDR_REG_OFFSET(ldr_status) #define PRESTERA_LDR_CTL_DL_START BIT(0) #define PRESTERA_EVT_QNUM_MAX 4 struct prestera_fw_evtq_regs { u32 rd_idx; u32 pad1; u32 wr_idx; u32 pad2; u32 offs; u32 len; }; struct prestera_fw_regs { u32 fw_ready; u32 pad; u32 cmd_offs; u32 cmd_len; u32 evt_offs; u32 evt_qnum; u32 cmd_req_ctl; u32 cmd_req_len; u32 cmd_rcv_ctl; u32 cmd_rcv_len; u32 fw_status; u32 rx_status; struct prestera_fw_evtq_regs evtq_list[PRESTERA_EVT_QNUM_MAX]; }; #define PRESTERA_FW_REG_OFFSET(f) offsetof(struct prestera_fw_regs, f) #define PRESTERA_FW_READY_MAGIC 0xcafebabe /* fw registers */ #define PRESTERA_FW_READY_REG PRESTERA_FW_REG_OFFSET(fw_ready) #define PRESTERA_CMD_BUF_OFFS_REG PRESTERA_FW_REG_OFFSET(cmd_offs) #define PRESTERA_CMD_BUF_LEN_REG PRESTERA_FW_REG_OFFSET(cmd_len) #define PRESTERA_EVT_BUF_OFFS_REG PRESTERA_FW_REG_OFFSET(evt_offs) #define PRESTERA_EVT_QNUM_REG PRESTERA_FW_REG_OFFSET(evt_qnum) #define PRESTERA_CMD_REQ_CTL_REG PRESTERA_FW_REG_OFFSET(cmd_req_ctl) #define PRESTERA_CMD_REQ_LEN_REG PRESTERA_FW_REG_OFFSET(cmd_req_len) #define PRESTERA_CMD_RCV_CTL_REG PRESTERA_FW_REG_OFFSET(cmd_rcv_ctl) #define PRESTERA_CMD_RCV_LEN_REG PRESTERA_FW_REG_OFFSET(cmd_rcv_len) #define PRESTERA_FW_STATUS_REG PRESTERA_FW_REG_OFFSET(fw_status) #define PRESTERA_RX_STATUS_REG PRESTERA_FW_REG_OFFSET(rx_status) /* PRESTERA_CMD_REQ_CTL_REG flags */ #define PRESTERA_CMD_F_REQ_SENT BIT(0) #define PRESTERA_CMD_F_REPL_RCVD BIT(1) /* PRESTERA_CMD_RCV_CTL_REG flags */ #define PRESTERA_CMD_F_REPL_SENT BIT(0) #define PRESTERA_FW_EVT_CTL_STATUS_MASK GENMASK(1, 0) #define PRESTERA_FW_EVT_CTL_STATUS_ON 0 #define PRESTERA_FW_EVT_CTL_STATUS_OFF 1 #define PRESTERA_EVTQ_REG_OFFSET(q, f) \ (PRESTERA_FW_REG_OFFSET(evtq_list) + \ (q) * sizeof(struct prestera_fw_evtq_regs) + \ offsetof(struct prestera_fw_evtq_regs, f)) #define PRESTERA_EVTQ_RD_IDX_REG(q) PRESTERA_EVTQ_REG_OFFSET(q, rd_idx) #define PRESTERA_EVTQ_WR_IDX_REG(q) PRESTERA_EVTQ_REG_OFFSET(q, wr_idx) #define PRESTERA_EVTQ_OFFS_REG(q) PRESTERA_EVTQ_REG_OFFSET(q, offs) #define PRESTERA_EVTQ_LEN_REG(q) PRESTERA_EVTQ_REG_OFFSET(q, len) #define PRESTERA_FW_REG_BASE(fw) ((fw)->dev.ctl_regs) #define PRESTERA_FW_REG_ADDR(fw, reg) PRESTERA_FW_REG_BASE((fw)) + (reg) #define PRESTERA_FW_CMD_DEFAULT_WAIT_MS 30000 #define PRESTERA_FW_READY_WAIT_MS 20000 struct prestera_fw_evtq { u8 __iomem *addr; size_t len; }; struct prestera_fw { struct prestera_fw_rev rev_supp; const struct firmware *bin; struct workqueue_struct *wq; struct prestera_device dev; u8 __iomem *ldr_regs; u8 __iomem *ldr_ring_buf; u32 ldr_buf_len; u32 ldr_wr_idx; struct mutex cmd_mtx; /* serialize access to dev->send_req */ size_t cmd_mbox_len; u8 __iomem *cmd_mbox; struct prestera_fw_evtq evt_queue[PRESTERA_EVT_QNUM_MAX]; u8 evt_qnum; struct work_struct evt_work; u8 __iomem *evt_buf; u8 *evt_msg; }; static int prestera_fw_load(struct prestera_fw *fw); static void prestera_fw_write(struct prestera_fw *fw, u32 reg, u32 val) { writel(val, PRESTERA_FW_REG_ADDR(fw, reg)); } static u32 prestera_fw_read(struct prestera_fw *fw, u32 reg) { return readl(PRESTERA_FW_REG_ADDR(fw, reg)); } static u32 prestera_fw_evtq_len(struct prestera_fw *fw, u8 qid) { return fw->evt_queue[qid].len; } static u32 prestera_fw_evtq_avail(struct prestera_fw *fw, u8 qid) { u32 wr_idx = prestera_fw_read(fw, PRESTERA_EVTQ_WR_IDX_REG(qid)); u32 rd_idx = prestera_fw_read(fw, PRESTERA_EVTQ_RD_IDX_REG(qid)); return CIRC_CNT(wr_idx, rd_idx, prestera_fw_evtq_len(fw, qid)); } static void prestera_fw_evtq_rd_set(struct prestera_fw *fw, u8 qid, u32 idx) { u32 rd_idx = idx & (prestera_fw_evtq_len(fw, qid) - 1); prestera_fw_write(fw, PRESTERA_EVTQ_RD_IDX_REG(qid), rd_idx); } static u8 __iomem *prestera_fw_evtq_buf(struct prestera_fw *fw, u8 qid) { return fw->evt_queue[qid].addr; } static u32 prestera_fw_evtq_read32(struct prestera_fw *fw, u8 qid) { u32 rd_idx = prestera_fw_read(fw, PRESTERA_EVTQ_RD_IDX_REG(qid)); u32 val; val = readl(prestera_fw_evtq_buf(fw, qid) + rd_idx); prestera_fw_evtq_rd_set(fw, qid, rd_idx + 4); return val; } static ssize_t prestera_fw_evtq_read_buf(struct prestera_fw *fw, u8 qid, void *buf, size_t len) { u32 idx = prestera_fw_read(fw, PRESTERA_EVTQ_RD_IDX_REG(qid)); u8 __iomem *evtq_addr = prestera_fw_evtq_buf(fw, qid); u32 *buf32 = buf; int i; for (i = 0; i < len / 4; buf32++, i++) { *buf32 = readl_relaxed(evtq_addr + idx); idx = (idx + 4) & (prestera_fw_evtq_len(fw, qid) - 1); } prestera_fw_evtq_rd_set(fw, qid, idx); return i; } static u8 prestera_fw_evtq_pick(struct prestera_fw *fw) { int qid; for (qid = 0; qid < fw->evt_qnum; qid++) { if (prestera_fw_evtq_avail(fw, qid) >= 4) return qid; } return PRESTERA_EVT_QNUM_MAX; } static void prestera_fw_evt_ctl_status_set(struct prestera_fw *fw, u32 val) { u32 status = prestera_fw_read(fw, PRESTERA_FW_STATUS_REG); u32p_replace_bits(&status, val, PRESTERA_FW_EVT_CTL_STATUS_MASK); prestera_fw_write(fw, PRESTERA_FW_STATUS_REG, status); } static void prestera_fw_evt_work_fn(struct work_struct *work) { struct prestera_fw *fw; void *msg; u8 qid; fw = container_of(work, struct prestera_fw, evt_work); msg = fw->evt_msg; prestera_fw_evt_ctl_status_set(fw, PRESTERA_FW_EVT_CTL_STATUS_OFF); while ((qid = prestera_fw_evtq_pick(fw)) < PRESTERA_EVT_QNUM_MAX) { u32 idx; u32 len; len = prestera_fw_evtq_read32(fw, qid); idx = prestera_fw_read(fw, PRESTERA_EVTQ_RD_IDX_REG(qid)); WARN_ON(prestera_fw_evtq_avail(fw, qid) < len); if (WARN_ON(len > PRESTERA_MSG_MAX_SIZE)) { prestera_fw_evtq_rd_set(fw, qid, idx + len); continue; } prestera_fw_evtq_read_buf(fw, qid, msg, len); if (fw->dev.recv_msg) fw->dev.recv_msg(&fw->dev, msg, len); } prestera_fw_evt_ctl_status_set(fw, PRESTERA_FW_EVT_CTL_STATUS_ON); } static int prestera_fw_wait_reg32(struct prestera_fw *fw, u32 reg, u32 cmp, unsigned int waitms) { u8 __iomem *addr = PRESTERA_FW_REG_ADDR(fw, reg); u32 val; return readl_poll_timeout(addr, val, cmp == val, 1 * USEC_PER_MSEC, waitms * USEC_PER_MSEC); } static int prestera_fw_cmd_send(struct prestera_fw *fw, void *in_msg, size_t in_size, void *out_msg, size_t out_size, unsigned int waitms) { u32 ret_size; int err; if (!waitms) waitms = PRESTERA_FW_CMD_DEFAULT_WAIT_MS; if (ALIGN(in_size, 4) > fw->cmd_mbox_len) return -EMSGSIZE; /* wait for finish previous reply from FW */ err = prestera_fw_wait_reg32(fw, PRESTERA_CMD_RCV_CTL_REG, 0, 30); if (err) { dev_err(fw->dev.dev, "finish reply from FW is timed out\n"); return err; } prestera_fw_write(fw, PRESTERA_CMD_REQ_LEN_REG, in_size); memcpy_toio(fw->cmd_mbox, in_msg, in_size); prestera_fw_write(fw, PRESTERA_CMD_REQ_CTL_REG, PRESTERA_CMD_F_REQ_SENT); /* wait for reply from FW */ err = prestera_fw_wait_reg32(fw, PRESTERA_CMD_RCV_CTL_REG, PRESTERA_CMD_F_REPL_SENT, waitms); if (err) { dev_err(fw->dev.dev, "reply from FW is timed out\n"); goto cmd_exit; } ret_size = prestera_fw_read(fw, PRESTERA_CMD_RCV_LEN_REG); if (ret_size > out_size) { dev_err(fw->dev.dev, "ret_size (%u) > out_len(%zu)\n", ret_size, out_size); err = -EMSGSIZE; goto cmd_exit; } memcpy_fromio(out_msg, fw->cmd_mbox + in_size, ret_size); cmd_exit: prestera_fw_write(fw, PRESTERA_CMD_REQ_CTL_REG, PRESTERA_CMD_F_REPL_RCVD); return err; } static int prestera_fw_send_req(struct prestera_device *dev, void *in_msg, size_t in_size, void *out_msg, size_t out_size, unsigned int waitms) { struct prestera_fw *fw; ssize_t ret; fw = container_of(dev, struct prestera_fw, dev); mutex_lock(&fw->cmd_mtx); ret = prestera_fw_cmd_send(fw, in_msg, in_size, out_msg, out_size, waitms); mutex_unlock(&fw->cmd_mtx); return ret; } static int prestera_fw_init(struct prestera_fw *fw) { u8 __iomem *base; int err; u8 qid; fw->dev.send_req = prestera_fw_send_req; fw->ldr_regs = fw->dev.ctl_regs; err = prestera_fw_load(fw); if (err) return err; err = prestera_fw_wait_reg32(fw, PRESTERA_FW_READY_REG, PRESTERA_FW_READY_MAGIC, PRESTERA_FW_READY_WAIT_MS); if (err) { dev_err(fw->dev.dev, "FW failed to start\n"); return err; } base = fw->dev.ctl_regs; fw->cmd_mbox = base + prestera_fw_read(fw, PRESTERA_CMD_BUF_OFFS_REG); fw->cmd_mbox_len = prestera_fw_read(fw, PRESTERA_CMD_BUF_LEN_REG); mutex_init(&fw->cmd_mtx); fw->evt_buf = base + prestera_fw_read(fw, PRESTERA_EVT_BUF_OFFS_REG); fw->evt_qnum = prestera_fw_read(fw, PRESTERA_EVT_QNUM_REG); fw->evt_msg = kmalloc(PRESTERA_MSG_MAX_SIZE, GFP_KERNEL); if (!fw->evt_msg) return -ENOMEM; for (qid = 0; qid < fw->evt_qnum; qid++) { u32 offs = prestera_fw_read(fw, PRESTERA_EVTQ_OFFS_REG(qid)); struct prestera_fw_evtq *evtq = &fw->evt_queue[qid]; evtq->len = prestera_fw_read(fw, PRESTERA_EVTQ_LEN_REG(qid)); evtq->addr = fw->evt_buf + offs; } return 0; } static void prestera_fw_uninit(struct prestera_fw *fw) { kfree(fw->evt_msg); } static irqreturn_t prestera_pci_irq_handler(int irq, void *dev_id) { struct prestera_fw *fw = dev_id; if (prestera_fw_read(fw, PRESTERA_RX_STATUS_REG)) { prestera_fw_write(fw, PRESTERA_RX_STATUS_REG, 0); if (fw->dev.recv_pkt) fw->dev.recv_pkt(&fw->dev); } queue_work(fw->wq, &fw->evt_work); return IRQ_HANDLED; } static void prestera_ldr_write(struct prestera_fw *fw, u32 reg, u32 val) { writel(val, PRESTERA_LDR_REG_ADDR(fw, reg)); } static u32 prestera_ldr_read(struct prestera_fw *fw, u32 reg) { return readl(PRESTERA_LDR_REG_ADDR(fw, reg)); } static int prestera_ldr_wait_reg32(struct prestera_fw *fw, u32 reg, u32 cmp, unsigned int waitms) { u8 __iomem *addr = PRESTERA_LDR_REG_ADDR(fw, reg); u32 val; return readl_poll_timeout(addr, val, cmp == val, 10 * USEC_PER_MSEC, waitms * USEC_PER_MSEC); } static u32 prestera_ldr_wait_buf(struct prestera_fw *fw, size_t len) { u8 __iomem *addr = PRESTERA_LDR_REG_ADDR(fw, PRESTERA_LDR_BUF_RD_REG); u32 buf_len = fw->ldr_buf_len; u32 wr_idx = fw->ldr_wr_idx; u32 rd_idx; return readl_poll_timeout(addr, rd_idx, CIRC_SPACE(wr_idx, rd_idx, buf_len) >= len, 1 * USEC_PER_MSEC, 100 * USEC_PER_MSEC); } static int prestera_ldr_wait_dl_finish(struct prestera_fw *fw) { u8 __iomem *addr = PRESTERA_LDR_REG_ADDR(fw, PRESTERA_LDR_STATUS_REG); unsigned long mask = ~(PRESTERA_LDR_STATUS_IMG_DL); u32 val; int err; err = readl_poll_timeout(addr, val, val & mask, 10 * USEC_PER_MSEC, PRESTERA_FW_DL_TIMEOUT_MS * USEC_PER_MSEC); if (err) { dev_err(fw->dev.dev, "Timeout to load FW img [state=%d]", prestera_ldr_read(fw, PRESTERA_LDR_STATUS_REG)); return err; } return 0; } static void prestera_ldr_wr_idx_move(struct prestera_fw *fw, unsigned int n) { fw->ldr_wr_idx = (fw->ldr_wr_idx + (n)) & (fw->ldr_buf_len - 1); } static void prestera_ldr_wr_idx_commit(struct prestera_fw *fw) { prestera_ldr_write(fw, PRESTERA_LDR_BUF_WR_REG, fw->ldr_wr_idx); } static u8 __iomem *prestera_ldr_wr_ptr(struct prestera_fw *fw) { return fw->ldr_ring_buf + fw->ldr_wr_idx; } static int prestera_ldr_send(struct prestera_fw *fw, const u8 *buf, size_t len) { int err; int i; err = prestera_ldr_wait_buf(fw, len); if (err) { dev_err(fw->dev.dev, "failed wait for sending firmware\n"); return err; } for (i = 0; i < len; i += 4) { writel_relaxed(*(u32 *)(buf + i), prestera_ldr_wr_ptr(fw)); prestera_ldr_wr_idx_move(fw, 4); } prestera_ldr_wr_idx_commit(fw); return 0; } static int prestera_ldr_fw_send(struct prestera_fw *fw, const char *img, u32 fw_size) { u32 status; u32 pos; int err; err = prestera_ldr_wait_reg32(fw, PRESTERA_LDR_STATUS_REG, PRESTERA_LDR_STATUS_IMG_DL, 5 * MSEC_PER_SEC); if (err) { dev_err(fw->dev.dev, "Loader is not ready to load image\n"); return err; } for (pos = 0; pos < fw_size; pos += PRESTERA_FW_BLK_SZ) { if (pos + PRESTERA_FW_BLK_SZ > fw_size) break; err = prestera_ldr_send(fw, img + pos, PRESTERA_FW_BLK_SZ); if (err) return err; } if (pos < fw_size) { err = prestera_ldr_send(fw, img + pos, fw_size - pos); if (err) return err; } err = prestera_ldr_wait_dl_finish(fw); if (err) return err; status = prestera_ldr_read(fw, PRESTERA_LDR_STATUS_REG); switch (status) { case PRESTERA_LDR_STATUS_INVALID_IMG: dev_err(fw->dev.dev, "FW img has bad CRC\n"); return -EINVAL; case PRESTERA_LDR_STATUS_NOMEM: dev_err(fw->dev.dev, "Loader has no enough mem\n"); return -ENOMEM; } return 0; } static void prestera_fw_rev_parse(const struct prestera_fw_header *hdr, struct prestera_fw_rev *rev) { u32 version = be32_to_cpu(hdr->version_value); rev->maj = PRESTERA_FW_VER_MAJ(version); rev->min = PRESTERA_FW_VER_MIN(version); rev->sub = PRESTERA_FW_VER_PATCH(version); } static int prestera_fw_rev_check(struct prestera_fw *fw) { struct prestera_fw_rev *rev = &fw->dev.fw_rev; if (rev->maj == fw->rev_supp.maj && rev->min >= fw->rev_supp.min) return 0; dev_err(fw->dev.dev, "Driver supports FW version only '%u.%u.x'", fw->rev_supp.maj, fw->rev_supp.min); return -EINVAL; } static int prestera_fw_hdr_parse(struct prestera_fw *fw) { struct prestera_fw_rev *rev = &fw->dev.fw_rev; struct prestera_fw_header *hdr; u32 magic; hdr = (struct prestera_fw_header *)fw->bin->data; magic = be32_to_cpu(hdr->magic_number); if (magic != PRESTERA_FW_HDR_MAGIC) { dev_err(fw->dev.dev, "FW img hdr magic is invalid"); return -EINVAL; } prestera_fw_rev_parse(hdr, rev); dev_info(fw->dev.dev, "FW version '%u.%u.%u'\n", rev->maj, rev->min, rev->sub); return prestera_fw_rev_check(fw); } static int prestera_fw_get(struct prestera_fw *fw) { int ver_maj = PRESTERA_SUPP_FW_MAJ_VER; int ver_min = PRESTERA_SUPP_FW_MIN_VER; char fw_path[128]; int err; pick_fw_ver: snprintf(fw_path, sizeof(fw_path), PRESTERA_FW_PATH_FMT, ver_maj, ver_min); err = request_firmware_direct(&fw->bin, fw_path, fw->dev.dev); if (err) { if (ver_maj != PRESTERA_PREV_FW_MAJ_VER || ver_min != PRESTERA_PREV_FW_MIN_VER) { ver_maj = PRESTERA_PREV_FW_MAJ_VER; ver_min = PRESTERA_PREV_FW_MIN_VER; dev_warn(fw->dev.dev, "missing latest %s firmware, fall-back to previous %u.%u version\n", fw_path, ver_maj, ver_min); goto pick_fw_ver; } else { dev_err(fw->dev.dev, "failed to request previous firmware: %s\n", fw_path); return err; } } dev_info(fw->dev.dev, "Loading %s ...", fw_path); fw->rev_supp.maj = ver_maj; fw->rev_supp.min = ver_min; fw->rev_supp.sub = 0; return 0; } static void prestera_fw_put(struct prestera_fw *fw) { release_firmware(fw->bin); } static int prestera_fw_load(struct prestera_fw *fw) { size_t hlen = sizeof(struct prestera_fw_header); int err; err = prestera_ldr_wait_reg32(fw, PRESTERA_LDR_READY_REG, PRESTERA_LDR_READY_MAGIC, 5 * MSEC_PER_SEC); if (err) { dev_err(fw->dev.dev, "waiting for FW loader is timed out"); return err; } fw->ldr_ring_buf = fw->ldr_regs + prestera_ldr_read(fw, PRESTERA_LDR_BUF_OFFS_REG); fw->ldr_buf_len = prestera_ldr_read(fw, PRESTERA_LDR_BUF_SIZE_REG); fw->ldr_wr_idx = 0; err = prestera_fw_get(fw); if (err) return err; err = prestera_fw_hdr_parse(fw); if (err) { dev_err(fw->dev.dev, "FW image header is invalid\n"); goto out_release; } prestera_ldr_write(fw, PRESTERA_LDR_IMG_SIZE_REG, fw->bin->size - hlen); prestera_ldr_write(fw, PRESTERA_LDR_CTL_REG, PRESTERA_LDR_CTL_DL_START); err = prestera_ldr_fw_send(fw, fw->bin->data + hlen, fw->bin->size - hlen); out_release: prestera_fw_put(fw); return err; } static int prestera_pci_probe(struct pci_dev *pdev, const struct pci_device_id *id) { const char *driver_name = pdev->driver->name; struct prestera_fw *fw; int err; err = pcim_enable_device(pdev); if (err) return err; err = pcim_iomap_regions(pdev, BIT(PRESTERA_PCI_BAR_FW) | BIT(PRESTERA_PCI_BAR_PP), pci_name(pdev)); if (err) return err; err = dma_set_mask_and_coherent(&pdev->dev, DMA_BIT_MASK(30)); if (err) { dev_err(&pdev->dev, "fail to set DMA mask\n"); goto err_dma_mask; } pci_set_master(pdev); fw = devm_kzalloc(&pdev->dev, sizeof(*fw), GFP_KERNEL); if (!fw) { err = -ENOMEM; goto err_pci_dev_alloc; } fw->dev.ctl_regs = pcim_iomap_table(pdev)[PRESTERA_PCI_BAR_FW]; fw->dev.pp_regs = pcim_iomap_table(pdev)[PRESTERA_PCI_BAR_PP]; fw->dev.dev = &pdev->dev; pci_set_drvdata(pdev, fw); err = prestera_fw_init(fw); if (err) goto err_prestera_fw_init; dev_info(fw->dev.dev, "Prestera FW is ready\n"); fw->wq = alloc_workqueue("prestera_fw_wq", WQ_HIGHPRI, 1); if (!fw->wq) { err = -ENOMEM; goto err_wq_alloc; } INIT_WORK(&fw->evt_work, prestera_fw_evt_work_fn); err = pci_alloc_irq_vectors(pdev, 1, 1, PCI_IRQ_MSI); if (err < 0) { dev_err(&pdev->dev, "MSI IRQ init failed\n"); goto err_irq_alloc; } err = request_irq(pci_irq_vector(pdev, 0), prestera_pci_irq_handler, 0, driver_name, fw); if (err) { dev_err(&pdev->dev, "fail to request IRQ\n"); goto err_request_irq; } err = prestera_device_register(&fw->dev); if (err) goto err_prestera_dev_register; return 0; err_prestera_dev_register: free_irq(pci_irq_vector(pdev, 0), fw); err_request_irq: pci_free_irq_vectors(pdev); err_irq_alloc: destroy_workqueue(fw->wq); err_wq_alloc: prestera_fw_uninit(fw); err_prestera_fw_init: err_pci_dev_alloc: err_dma_mask: return err; } static void prestera_pci_remove(struct pci_dev *pdev) { struct prestera_fw *fw = pci_get_drvdata(pdev); prestera_device_unregister(&fw->dev); free_irq(pci_irq_vector(pdev, 0), fw); pci_free_irq_vectors(pdev); destroy_workqueue(fw->wq); prestera_fw_uninit(fw); } static const struct pci_device_id prestera_pci_devices[] = { { PCI_DEVICE(PCI_VENDOR_ID_MARVELL, 0xC804) }, { PCI_DEVICE(PCI_VENDOR_ID_MARVELL, 0xC80C) }, { PCI_DEVICE(PCI_VENDOR_ID_MARVELL, 0xCC1E) }, { } }; MODULE_DEVICE_TABLE(pci, prestera_pci_devices); static struct pci_driver prestera_pci_driver = { .name = "Prestera DX", .id_table = prestera_pci_devices, .probe = prestera_pci_probe, .remove = prestera_pci_remove, }; module_pci_driver(prestera_pci_driver); MODULE_LICENSE("Dual BSD/GPL"); MODULE_DESCRIPTION("Marvell Prestera switch PCI interface");