Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Jakub Kiciński | 4154 | 85.33% | 23 | 65.71% |
Dirk van der Merwe | 646 | 13.27% | 8 | 22.86% |
David Brunecz | 64 | 1.31% | 2 | 5.71% |
Robin Murphy | 3 | 0.06% | 1 | 2.86% |
Simon Horman | 1 | 0.02% | 1 | 2.86% |
Total | 4868 | 35 |
// SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause) /* Copyright (C) 2015-2018 Netronome Systems, Inc. */ /* * nfp_nsp.c * Author: Jakub Kicinski <jakub.kicinski@netronome.com> * Jason McMullan <jason.mcmullan@netronome.com> */ #include <asm/unaligned.h> #include <linux/bitfield.h> #include <linux/delay.h> #include <linux/firmware.h> #include <linux/kernel.h> #include <linux/kthread.h> #include <linux/overflow.h> #include <linux/sizes.h> #include <linux/slab.h> #define NFP_SUBSYS "nfp_nsp" #include "nfp.h" #include "nfp_cpp.h" #include "nfp_nsp.h" #define NFP_NSP_TIMEOUT_DEFAULT 30 #define NFP_NSP_TIMEOUT_BOOT 30 /* Offsets relative to the CSR base */ #define NSP_STATUS 0x00 #define NSP_STATUS_MAGIC GENMASK_ULL(63, 48) #define NSP_STATUS_MAJOR GENMASK_ULL(47, 44) #define NSP_STATUS_MINOR GENMASK_ULL(43, 32) #define NSP_STATUS_CODE GENMASK_ULL(31, 16) #define NSP_STATUS_RESULT GENMASK_ULL(15, 8) #define NSP_STATUS_BUSY BIT_ULL(0) #define NSP_COMMAND 0x08 #define NSP_COMMAND_OPTION GENMASK_ULL(63, 32) #define NSP_COMMAND_CODE GENMASK_ULL(31, 16) #define NSP_COMMAND_DMA_BUF BIT_ULL(1) #define NSP_COMMAND_START BIT_ULL(0) /* CPP address to retrieve the data from */ #define NSP_BUFFER 0x10 #define NSP_BUFFER_CPP GENMASK_ULL(63, 40) #define NSP_BUFFER_ADDRESS GENMASK_ULL(39, 0) #define NSP_DFLT_BUFFER 0x18 #define NSP_DFLT_BUFFER_CPP GENMASK_ULL(63, 40) #define NSP_DFLT_BUFFER_ADDRESS GENMASK_ULL(39, 0) #define NSP_DFLT_BUFFER_CONFIG 0x20 #define NSP_DFLT_BUFFER_DMA_CHUNK_ORDER GENMASK_ULL(63, 58) #define NSP_DFLT_BUFFER_SIZE_4KB GENMASK_ULL(15, 8) #define NSP_DFLT_BUFFER_SIZE_MB GENMASK_ULL(7, 0) #define NFP_CAP_CMD_DMA_SG 0x28 #define NSP_MAGIC 0xab10 #define NSP_MAJOR 0 #define NSP_MINOR 8 #define NSP_CODE_MAJOR GENMASK(15, 12) #define NSP_CODE_MINOR GENMASK(11, 0) #define NFP_FW_LOAD_RET_MAJOR GENMASK(15, 8) #define NFP_FW_LOAD_RET_MINOR GENMASK(23, 16) #define NFP_HWINFO_LOOKUP_SIZE GENMASK(11, 0) #define NFP_VERSIONS_SIZE GENMASK(11, 0) #define NFP_VERSIONS_CNT_OFF 0 #define NFP_VERSIONS_BSP_OFF 2 #define NFP_VERSIONS_CPLD_OFF 6 #define NFP_VERSIONS_APP_OFF 10 #define NFP_VERSIONS_BUNDLE_OFF 14 #define NFP_VERSIONS_UNDI_OFF 18 #define NFP_VERSIONS_NCSI_OFF 22 #define NFP_VERSIONS_CFGR_OFF 26 #define NSP_SFF_EEPROM_BLOCK_LEN 8 enum nfp_nsp_cmd { SPCODE_NOOP = 0, /* No operation */ SPCODE_SOFT_RESET = 1, /* Soft reset the NFP */ SPCODE_FW_DEFAULT = 2, /* Load default (UNDI) FW */ SPCODE_PHY_INIT = 3, /* Initialize the PHY */ SPCODE_MAC_INIT = 4, /* Initialize the MAC */ SPCODE_PHY_RXADAPT = 5, /* Re-run PHY RX Adaptation */ SPCODE_FW_LOAD = 6, /* Load fw from buffer, len in option */ SPCODE_ETH_RESCAN = 7, /* Rescan ETHs, write ETH_TABLE to buf */ SPCODE_ETH_CONTROL = 8, /* Update media config from buffer */ SPCODE_NSP_WRITE_FLASH = 11, /* Load and flash image from buffer */ SPCODE_NSP_SENSORS = 12, /* Read NSP sensor(s) */ SPCODE_NSP_IDENTIFY = 13, /* Read NSP version */ SPCODE_FW_STORED = 16, /* If no FW loaded, load flash app FW */ SPCODE_HWINFO_LOOKUP = 17, /* Lookup HWinfo with overwrites etc. */ SPCODE_HWINFO_SET = 18, /* Set HWinfo entry */ SPCODE_FW_LOADED = 19, /* Is application firmware loaded */ SPCODE_VERSIONS = 21, /* Report FW versions */ SPCODE_READ_SFF_EEPROM = 22, /* Read module EEPROM */ }; struct nfp_nsp_dma_buf { __le32 chunk_cnt; __le32 reserved[3]; struct { __le32 size; __le32 reserved; __le64 addr; } descs[]; }; static const struct { int code; const char *msg; } nsp_errors[] = { { 6010, "could not map to phy for port" }, { 6011, "not an allowed rate/lanes for port" }, { 6012, "not an allowed rate/lanes for port" }, { 6013, "high/low error, change other port first" }, { 6014, "config not found in flash" }, }; struct nfp_nsp { struct nfp_cpp *cpp; struct nfp_resource *res; struct { u16 major; u16 minor; } ver; /* Eth table config state */ bool modified; unsigned int idx; void *entries; }; /** * struct nfp_nsp_command_arg - NFP command argument structure * @code: NFP SP Command Code * @dma: @buf points to a host buffer, not NSP buffer * @timeout_sec:Timeout value to wait for completion in seconds * @option: NFP SP Command Argument * @buf: NFP SP Buffer Address * @error_cb: Callback for interpreting option if error occurred * @error_quiet:Don't print command error/warning. Protocol errors are still * logged. */ struct nfp_nsp_command_arg { u16 code; bool dma; unsigned int timeout_sec; u32 option; u64 buf; void (*error_cb)(struct nfp_nsp *state, u32 ret_val); bool error_quiet; }; /** * struct nfp_nsp_command_buf_arg - NFP command with buffer argument structure * @arg: NFP command argument structure * @in_buf: Buffer with data for input * @in_size: Size of @in_buf * @out_buf: Buffer for output data * @out_size: Size of @out_buf */ struct nfp_nsp_command_buf_arg { struct nfp_nsp_command_arg arg; const void *in_buf; unsigned int in_size; void *out_buf; unsigned int out_size; }; struct nfp_cpp *nfp_nsp_cpp(struct nfp_nsp *state) { return state->cpp; } bool nfp_nsp_config_modified(struct nfp_nsp *state) { return state->modified; } void nfp_nsp_config_set_modified(struct nfp_nsp *state, bool modified) { state->modified = modified; } void *nfp_nsp_config_entries(struct nfp_nsp *state) { return state->entries; } unsigned int nfp_nsp_config_idx(struct nfp_nsp *state) { return state->idx; } void nfp_nsp_config_set_state(struct nfp_nsp *state, void *entries, unsigned int idx) { state->entries = entries; state->idx = idx; } void nfp_nsp_config_clear_state(struct nfp_nsp *state) { state->entries = NULL; state->idx = 0; } static void nfp_nsp_print_extended_error(struct nfp_nsp *state, u32 ret_val) { int i; if (!ret_val) return; for (i = 0; i < ARRAY_SIZE(nsp_errors); i++) if (ret_val == nsp_errors[i].code) nfp_err(state->cpp, "err msg: %s\n", nsp_errors[i].msg); } static int nfp_nsp_check(struct nfp_nsp *state) { struct nfp_cpp *cpp = state->cpp; u64 nsp_status, reg; u32 nsp_cpp; int err; nsp_cpp = nfp_resource_cpp_id(state->res); nsp_status = nfp_resource_address(state->res) + NSP_STATUS; err = nfp_cpp_readq(cpp, nsp_cpp, nsp_status, ®); if (err < 0) return err; if (FIELD_GET(NSP_STATUS_MAGIC, reg) != NSP_MAGIC) { nfp_err(cpp, "Cannot detect NFP Service Processor\n"); return -ENODEV; } state->ver.major = FIELD_GET(NSP_STATUS_MAJOR, reg); state->ver.minor = FIELD_GET(NSP_STATUS_MINOR, reg); if (state->ver.major != NSP_MAJOR) { nfp_err(cpp, "Unsupported ABI %hu.%hu\n", state->ver.major, state->ver.minor); return -EINVAL; } if (state->ver.minor < NSP_MINOR) { nfp_err(cpp, "ABI too old to support NIC operation (%u.%hu < %u.%u), please update the management FW on the flash\n", NSP_MAJOR, state->ver.minor, NSP_MAJOR, NSP_MINOR); return -EINVAL; } if (reg & NSP_STATUS_BUSY) { nfp_err(cpp, "Service processor busy!\n"); return -EBUSY; } return 0; } /** * nfp_nsp_open() - Prepare for communication and lock the NSP resource. * @cpp: NFP CPP Handle */ struct nfp_nsp *nfp_nsp_open(struct nfp_cpp *cpp) { struct nfp_resource *res; struct nfp_nsp *state; int err; res = nfp_resource_acquire(cpp, NFP_RESOURCE_NSP); if (IS_ERR(res)) return (void *)res; state = kzalloc(sizeof(*state), GFP_KERNEL); if (!state) { nfp_resource_release(res); return ERR_PTR(-ENOMEM); } state->cpp = cpp; state->res = res; err = nfp_nsp_check(state); if (err) { nfp_nsp_close(state); return ERR_PTR(err); } return state; } /** * nfp_nsp_close() - Clean up and unlock the NSP resource. * @state: NFP SP state */ void nfp_nsp_close(struct nfp_nsp *state) { nfp_resource_release(state->res); kfree(state); } u16 nfp_nsp_get_abi_ver_major(struct nfp_nsp *state) { return state->ver.major; } u16 nfp_nsp_get_abi_ver_minor(struct nfp_nsp *state) { return state->ver.minor; } static int nfp_nsp_wait_reg(struct nfp_cpp *cpp, u64 *reg, u32 nsp_cpp, u64 addr, u64 mask, u64 val, u32 timeout_sec) { const unsigned long wait_until = jiffies + timeout_sec * HZ; int err; for (;;) { const unsigned long start_time = jiffies; err = nfp_cpp_readq(cpp, nsp_cpp, addr, reg); if (err < 0) return err; if ((*reg & mask) == val) return 0; msleep(25); if (time_after(start_time, wait_until)) return -ETIMEDOUT; } } /** * __nfp_nsp_command() - Execute a command on the NFP Service Processor * @state: NFP SP state * @arg: NFP command argument structure * * Return: 0 for success with no result * * positive value for NSP completion with a result code * * -EAGAIN if the NSP is not yet present * -ENODEV if the NSP is not a supported model * -EBUSY if the NSP is stuck * -EINTR if interrupted while waiting for completion * -ETIMEDOUT if the NSP took longer than @timeout_sec seconds to complete */ static int __nfp_nsp_command(struct nfp_nsp *state, const struct nfp_nsp_command_arg *arg) { u64 reg, ret_val, nsp_base, nsp_buffer, nsp_status, nsp_command; struct nfp_cpp *cpp = state->cpp; u32 nsp_cpp; int err; nsp_cpp = nfp_resource_cpp_id(state->res); nsp_base = nfp_resource_address(state->res); nsp_status = nsp_base + NSP_STATUS; nsp_command = nsp_base + NSP_COMMAND; nsp_buffer = nsp_base + NSP_BUFFER; err = nfp_nsp_check(state); if (err) return err; err = nfp_cpp_writeq(cpp, nsp_cpp, nsp_buffer, arg->buf); if (err < 0) return err; err = nfp_cpp_writeq(cpp, nsp_cpp, nsp_command, FIELD_PREP(NSP_COMMAND_OPTION, arg->option) | FIELD_PREP(NSP_COMMAND_CODE, arg->code) | FIELD_PREP(NSP_COMMAND_DMA_BUF, arg->dma) | FIELD_PREP(NSP_COMMAND_START, 1)); if (err < 0) return err; /* Wait for NSP_COMMAND_START to go to 0 */ err = nfp_nsp_wait_reg(cpp, ®, nsp_cpp, nsp_command, NSP_COMMAND_START, 0, NFP_NSP_TIMEOUT_DEFAULT); if (err) { nfp_err(cpp, "Error %d waiting for code 0x%04x to start\n", err, arg->code); return err; } /* Wait for NSP_STATUS_BUSY to go to 0 */ err = nfp_nsp_wait_reg(cpp, ®, nsp_cpp, nsp_status, NSP_STATUS_BUSY, 0, arg->timeout_sec ?: NFP_NSP_TIMEOUT_DEFAULT); if (err) { nfp_err(cpp, "Error %d waiting for code 0x%04x to complete\n", err, arg->code); return err; } err = nfp_cpp_readq(cpp, nsp_cpp, nsp_command, &ret_val); if (err < 0) return err; ret_val = FIELD_GET(NSP_COMMAND_OPTION, ret_val); err = FIELD_GET(NSP_STATUS_RESULT, reg); if (err) { if (!arg->error_quiet) nfp_warn(cpp, "Result (error) code set: %d (%d) command: %d\n", -err, (int)ret_val, arg->code); if (arg->error_cb) arg->error_cb(state, ret_val); else nfp_nsp_print_extended_error(state, ret_val); return -err; } return ret_val; } static int nfp_nsp_command(struct nfp_nsp *state, u16 code) { const struct nfp_nsp_command_arg arg = { .code = code, }; return __nfp_nsp_command(state, &arg); } static int nfp_nsp_command_buf_def(struct nfp_nsp *nsp, struct nfp_nsp_command_buf_arg *arg) { struct nfp_cpp *cpp = nsp->cpp; u64 reg, cpp_buf; int err, ret; u32 cpp_id; err = nfp_cpp_readq(cpp, nfp_resource_cpp_id(nsp->res), nfp_resource_address(nsp->res) + NSP_DFLT_BUFFER, ®); if (err < 0) return err; cpp_id = FIELD_GET(NSP_DFLT_BUFFER_CPP, reg) << 8; cpp_buf = FIELD_GET(NSP_DFLT_BUFFER_ADDRESS, reg); if (arg->in_buf && arg->in_size) { err = nfp_cpp_write(cpp, cpp_id, cpp_buf, arg->in_buf, arg->in_size); if (err < 0) return err; } /* Zero out remaining part of the buffer */ if (arg->out_buf && arg->out_size && arg->out_size > arg->in_size) { err = nfp_cpp_write(cpp, cpp_id, cpp_buf + arg->in_size, arg->out_buf, arg->out_size - arg->in_size); if (err < 0) return err; } if (!FIELD_FIT(NSP_BUFFER_CPP, cpp_id >> 8) || !FIELD_FIT(NSP_BUFFER_ADDRESS, cpp_buf)) { nfp_err(cpp, "Buffer out of reach %08x %016llx\n", cpp_id, cpp_buf); return -EINVAL; } arg->arg.buf = FIELD_PREP(NSP_BUFFER_CPP, cpp_id >> 8) | FIELD_PREP(NSP_BUFFER_ADDRESS, cpp_buf); ret = __nfp_nsp_command(nsp, &arg->arg); if (ret < 0) return ret; if (arg->out_buf && arg->out_size) { err = nfp_cpp_read(cpp, cpp_id, cpp_buf, arg->out_buf, arg->out_size); if (err < 0) return err; } return ret; } static int nfp_nsp_command_buf_dma_sg(struct nfp_nsp *nsp, struct nfp_nsp_command_buf_arg *arg, unsigned int max_size, unsigned int chunk_order, unsigned int dma_order) { struct nfp_cpp *cpp = nsp->cpp; struct nfp_nsp_dma_buf *desc; struct { dma_addr_t dma_addr; unsigned long len; void *chunk; } *chunks; size_t chunk_size, dma_size; dma_addr_t dma_desc; struct device *dev; unsigned long off; int i, ret, nseg; size_t desc_sz; chunk_size = BIT_ULL(chunk_order); dma_size = BIT_ULL(dma_order); nseg = DIV_ROUND_UP(max_size, chunk_size); chunks = kcalloc(nseg, sizeof(*chunks), GFP_KERNEL); if (!chunks) return -ENOMEM; off = 0; ret = -ENOMEM; for (i = 0; i < nseg; i++) { unsigned long coff; chunks[i].chunk = kmalloc(chunk_size, GFP_KERNEL | __GFP_NOWARN); if (!chunks[i].chunk) goto exit_free_prev; chunks[i].len = min_t(u64, chunk_size, max_size - off); coff = 0; if (arg->in_size > off) { coff = min_t(u64, arg->in_size - off, chunk_size); memcpy(chunks[i].chunk, arg->in_buf + off, coff); } memset(chunks[i].chunk + coff, 0, chunk_size - coff); off += chunks[i].len; } dev = nfp_cpp_device(cpp)->parent; for (i = 0; i < nseg; i++) { dma_addr_t addr; addr = dma_map_single(dev, chunks[i].chunk, chunks[i].len, DMA_BIDIRECTIONAL); chunks[i].dma_addr = addr; ret = dma_mapping_error(dev, addr); if (ret) goto exit_unmap_prev; if (WARN_ONCE(round_down(addr, dma_size) != round_down(addr + chunks[i].len - 1, dma_size), "unaligned DMA address: %pad %lu %zd\n", &addr, chunks[i].len, dma_size)) { ret = -EFAULT; i++; goto exit_unmap_prev; } } desc_sz = struct_size(desc, descs, nseg); desc = kmalloc(desc_sz, GFP_KERNEL); if (!desc) { ret = -ENOMEM; goto exit_unmap_all; } desc->chunk_cnt = cpu_to_le32(nseg); for (i = 0; i < nseg; i++) { desc->descs[i].size = cpu_to_le32(chunks[i].len); desc->descs[i].addr = cpu_to_le64(chunks[i].dma_addr); } dma_desc = dma_map_single(dev, desc, desc_sz, DMA_TO_DEVICE); ret = dma_mapping_error(dev, dma_desc); if (ret) goto exit_free_desc; arg->arg.dma = true; arg->arg.buf = dma_desc; ret = __nfp_nsp_command(nsp, &arg->arg); if (ret < 0) goto exit_unmap_desc; i = 0; off = 0; while (off < arg->out_size) { unsigned int len; len = min_t(u64, chunks[i].len, arg->out_size - off); memcpy(arg->out_buf + off, chunks[i].chunk, len); off += len; i++; } exit_unmap_desc: dma_unmap_single(dev, dma_desc, desc_sz, DMA_TO_DEVICE); exit_free_desc: kfree(desc); exit_unmap_all: i = nseg; exit_unmap_prev: while (--i >= 0) dma_unmap_single(dev, chunks[i].dma_addr, chunks[i].len, DMA_BIDIRECTIONAL); i = nseg; exit_free_prev: while (--i >= 0) kfree(chunks[i].chunk); kfree(chunks); if (ret < 0) nfp_err(cpp, "NSP: SG DMA failed for command 0x%04x: %d (sz:%d cord:%d)\n", arg->arg.code, ret, max_size, chunk_order); return ret; } static int nfp_nsp_command_buf_dma(struct nfp_nsp *nsp, struct nfp_nsp_command_buf_arg *arg, unsigned int max_size, unsigned int dma_order) { unsigned int chunk_order, buf_order; struct nfp_cpp *cpp = nsp->cpp; bool sg_ok; u64 reg; int err; buf_order = order_base_2(roundup_pow_of_two(max_size)); err = nfp_cpp_readq(cpp, nfp_resource_cpp_id(nsp->res), nfp_resource_address(nsp->res) + NFP_CAP_CMD_DMA_SG, ®); if (err < 0) return err; sg_ok = reg & BIT_ULL(arg->arg.code - 1); if (!sg_ok) { if (buf_order > dma_order) { nfp_err(cpp, "NSP: can't service non-SG DMA for command 0x%04x\n", arg->arg.code); return -ENOMEM; } chunk_order = buf_order; } else { chunk_order = min_t(unsigned int, dma_order, PAGE_SHIFT); } return nfp_nsp_command_buf_dma_sg(nsp, arg, max_size, chunk_order, dma_order); } static int nfp_nsp_command_buf(struct nfp_nsp *nsp, struct nfp_nsp_command_buf_arg *arg) { unsigned int dma_order, def_size, max_size; struct nfp_cpp *cpp = nsp->cpp; u64 reg; int err; if (nsp->ver.minor < 13) { nfp_err(cpp, "NSP: Code 0x%04x with buffer not supported (ABI %hu.%hu)\n", arg->arg.code, nsp->ver.major, nsp->ver.minor); return -EOPNOTSUPP; } err = nfp_cpp_readq(cpp, nfp_resource_cpp_id(nsp->res), nfp_resource_address(nsp->res) + NSP_DFLT_BUFFER_CONFIG, ®); if (err < 0) return err; /* Zero out undefined part of the out buffer */ if (arg->out_buf && arg->out_size && arg->out_size > arg->in_size) memset(arg->out_buf, 0, arg->out_size - arg->in_size); max_size = max(arg->in_size, arg->out_size); def_size = FIELD_GET(NSP_DFLT_BUFFER_SIZE_MB, reg) * SZ_1M + FIELD_GET(NSP_DFLT_BUFFER_SIZE_4KB, reg) * SZ_4K; dma_order = FIELD_GET(NSP_DFLT_BUFFER_DMA_CHUNK_ORDER, reg); if (def_size >= max_size) { return nfp_nsp_command_buf_def(nsp, arg); } else if (!dma_order) { nfp_err(cpp, "NSP: default buffer too small for command 0x%04x (%u < %u)\n", arg->arg.code, def_size, max_size); return -EINVAL; } return nfp_nsp_command_buf_dma(nsp, arg, max_size, dma_order); } int nfp_nsp_wait(struct nfp_nsp *state) { const unsigned long wait_until = jiffies + NFP_NSP_TIMEOUT_BOOT * HZ; int err; nfp_dbg(state->cpp, "Waiting for NSP to respond (%u sec max).\n", NFP_NSP_TIMEOUT_BOOT); for (;;) { const unsigned long start_time = jiffies; err = nfp_nsp_command(state, SPCODE_NOOP); if (err != -EAGAIN) break; if (msleep_interruptible(25)) { err = -ERESTARTSYS; break; } if (time_after(start_time, wait_until)) { err = -ETIMEDOUT; break; } } if (err) nfp_err(state->cpp, "NSP failed to respond %d\n", err); return err; } int nfp_nsp_device_soft_reset(struct nfp_nsp *state) { return nfp_nsp_command(state, SPCODE_SOFT_RESET); } int nfp_nsp_mac_reinit(struct nfp_nsp *state) { return nfp_nsp_command(state, SPCODE_MAC_INIT); } static void nfp_nsp_load_fw_extended_msg(struct nfp_nsp *state, u32 ret_val) { static const char * const major_msg[] = { /* 0 */ "Firmware from driver loaded", /* 1 */ "Firmware from flash loaded", /* 2 */ "Firmware loading failure", }; static const char * const minor_msg[] = { /* 0 */ "", /* 1 */ "no named partition on flash", /* 2 */ "error reading from flash", /* 3 */ "can not deflate", /* 4 */ "not a trusted file", /* 5 */ "can not parse FW file", /* 6 */ "MIP not found in FW file", /* 7 */ "null firmware name in MIP", /* 8 */ "FW version none", /* 9 */ "FW build number none", /* 10 */ "no FW selection policy HWInfo key found", /* 11 */ "static FW selection policy", /* 12 */ "FW version has precedence", /* 13 */ "different FW application load requested", /* 14 */ "development build", }; unsigned int major, minor; const char *level; major = FIELD_GET(NFP_FW_LOAD_RET_MAJOR, ret_val); minor = FIELD_GET(NFP_FW_LOAD_RET_MINOR, ret_val); if (!nfp_nsp_has_stored_fw_load(state)) return; /* Lower the message level in legacy case */ if (major == 0 && (minor == 0 || minor == 10)) level = KERN_DEBUG; else if (major == 2) level = KERN_ERR; else level = KERN_INFO; if (major >= ARRAY_SIZE(major_msg)) nfp_printk(level, state->cpp, "FW loading status: %x\n", ret_val); else if (minor >= ARRAY_SIZE(minor_msg)) nfp_printk(level, state->cpp, "%s, reason code: %d\n", major_msg[major], minor); else nfp_printk(level, state->cpp, "%s%c %s\n", major_msg[major], minor ? ',' : '.', minor_msg[minor]); } int nfp_nsp_load_fw(struct nfp_nsp *state, const struct firmware *fw) { struct nfp_nsp_command_buf_arg load_fw = { { .code = SPCODE_FW_LOAD, .option = fw->size, .error_cb = nfp_nsp_load_fw_extended_msg, }, .in_buf = fw->data, .in_size = fw->size, }; int ret; ret = nfp_nsp_command_buf(state, &load_fw); if (ret < 0) return ret; nfp_nsp_load_fw_extended_msg(state, ret); return 0; } int nfp_nsp_write_flash(struct nfp_nsp *state, const struct firmware *fw) { struct nfp_nsp_command_buf_arg write_flash = { { .code = SPCODE_NSP_WRITE_FLASH, .option = fw->size, .timeout_sec = 900, }, .in_buf = fw->data, .in_size = fw->size, }; return nfp_nsp_command_buf(state, &write_flash); } int nfp_nsp_read_eth_table(struct nfp_nsp *state, void *buf, unsigned int size) { struct nfp_nsp_command_buf_arg eth_rescan = { { .code = SPCODE_ETH_RESCAN, .option = size, }, .out_buf = buf, .out_size = size, }; return nfp_nsp_command_buf(state, ð_rescan); } int nfp_nsp_write_eth_table(struct nfp_nsp *state, const void *buf, unsigned int size) { struct nfp_nsp_command_buf_arg eth_ctrl = { { .code = SPCODE_ETH_CONTROL, .option = size, }, .in_buf = buf, .in_size = size, }; return nfp_nsp_command_buf(state, ð_ctrl); } int nfp_nsp_read_identify(struct nfp_nsp *state, void *buf, unsigned int size) { struct nfp_nsp_command_buf_arg identify = { { .code = SPCODE_NSP_IDENTIFY, .option = size, }, .out_buf = buf, .out_size = size, }; return nfp_nsp_command_buf(state, &identify); } int nfp_nsp_read_sensors(struct nfp_nsp *state, unsigned int sensor_mask, void *buf, unsigned int size) { struct nfp_nsp_command_buf_arg sensors = { { .code = SPCODE_NSP_SENSORS, .option = sensor_mask, }, .out_buf = buf, .out_size = size, }; return nfp_nsp_command_buf(state, &sensors); } int nfp_nsp_load_stored_fw(struct nfp_nsp *state) { const struct nfp_nsp_command_arg arg = { .code = SPCODE_FW_STORED, .error_cb = nfp_nsp_load_fw_extended_msg, }; int ret; ret = __nfp_nsp_command(state, &arg); if (ret < 0) return ret; nfp_nsp_load_fw_extended_msg(state, ret); return 0; } static int __nfp_nsp_hwinfo_lookup(struct nfp_nsp *state, void *buf, unsigned int size, bool optional) { struct nfp_nsp_command_buf_arg hwinfo_lookup = { { .code = SPCODE_HWINFO_LOOKUP, .option = size, .error_quiet = optional, }, .in_buf = buf, .in_size = size, .out_buf = buf, .out_size = size, }; return nfp_nsp_command_buf(state, &hwinfo_lookup); } int nfp_nsp_hwinfo_lookup(struct nfp_nsp *state, void *buf, unsigned int size) { int err; size = min_t(u32, size, NFP_HWINFO_LOOKUP_SIZE); err = __nfp_nsp_hwinfo_lookup(state, buf, size, false); if (err) return err; if (strnlen(buf, size) == size) { nfp_err(state->cpp, "NSP HWinfo value not NULL-terminated\n"); return -EINVAL; } return 0; } int nfp_nsp_hwinfo_lookup_optional(struct nfp_nsp *state, void *buf, unsigned int size, const char *default_val) { int err; /* Ensure that the default value is usable irrespective of whether * it is actually going to be used. */ if (strnlen(default_val, size) == size) return -EINVAL; if (!nfp_nsp_has_hwinfo_lookup(state)) { strcpy(buf, default_val); return 0; } size = min_t(u32, size, NFP_HWINFO_LOOKUP_SIZE); err = __nfp_nsp_hwinfo_lookup(state, buf, size, true); if (err) { if (err == -ENOENT) { strcpy(buf, default_val); return 0; } nfp_err(state->cpp, "NSP HWinfo lookup failed: %d\n", err); return err; } if (strnlen(buf, size) == size) { nfp_err(state->cpp, "NSP HWinfo value not NULL-terminated\n"); return -EINVAL; } return 0; } int nfp_nsp_hwinfo_set(struct nfp_nsp *state, void *buf, unsigned int size) { struct nfp_nsp_command_buf_arg hwinfo_set = { { .code = SPCODE_HWINFO_SET, .option = size, }, .in_buf = buf, .in_size = size, }; return nfp_nsp_command_buf(state, &hwinfo_set); } int nfp_nsp_fw_loaded(struct nfp_nsp *state) { const struct nfp_nsp_command_arg arg = { .code = SPCODE_FW_LOADED, }; return __nfp_nsp_command(state, &arg); } int nfp_nsp_versions(struct nfp_nsp *state, void *buf, unsigned int size) { struct nfp_nsp_command_buf_arg versions = { { .code = SPCODE_VERSIONS, .option = min_t(u32, size, NFP_VERSIONS_SIZE), }, .out_buf = buf, .out_size = min_t(u32, size, NFP_VERSIONS_SIZE), }; return nfp_nsp_command_buf(state, &versions); } const char *nfp_nsp_versions_get(enum nfp_nsp_versions id, bool flash, const u8 *buf, unsigned int size) { static const u32 id2off[] = { [NFP_VERSIONS_BSP] = NFP_VERSIONS_BSP_OFF, [NFP_VERSIONS_CPLD] = NFP_VERSIONS_CPLD_OFF, [NFP_VERSIONS_APP] = NFP_VERSIONS_APP_OFF, [NFP_VERSIONS_BUNDLE] = NFP_VERSIONS_BUNDLE_OFF, [NFP_VERSIONS_UNDI] = NFP_VERSIONS_UNDI_OFF, [NFP_VERSIONS_NCSI] = NFP_VERSIONS_NCSI_OFF, [NFP_VERSIONS_CFGR] = NFP_VERSIONS_CFGR_OFF, }; unsigned int field, buf_field_cnt, buf_off; if (id >= ARRAY_SIZE(id2off) || !id2off[id]) return ERR_PTR(-EINVAL); field = id * 2 + flash; buf_field_cnt = get_unaligned_le16(buf); if (buf_field_cnt <= field) return ERR_PTR(-ENOENT); buf_off = get_unaligned_le16(buf + id2off[id] + flash * 2); if (!buf_off) return ERR_PTR(-ENOENT); if (buf_off >= size) return ERR_PTR(-EINVAL); if (strnlen(&buf[buf_off], size - buf_off) == size - buf_off) return ERR_PTR(-EINVAL); return (const char *)&buf[buf_off]; } static int __nfp_nsp_module_eeprom(struct nfp_nsp *state, void *buf, unsigned int size) { struct nfp_nsp_command_buf_arg module_eeprom = { { .code = SPCODE_READ_SFF_EEPROM, .option = size, }, .in_buf = buf, .in_size = size, .out_buf = buf, .out_size = size, }; return nfp_nsp_command_buf(state, &module_eeprom); } int nfp_nsp_read_module_eeprom(struct nfp_nsp *state, int eth_index, unsigned int offset, void *data, unsigned int len, unsigned int *read_len) { struct eeprom_buf { u8 metalen; __le16 length; __le16 offset; __le16 readlen; u8 eth_index; u8 data[]; } __packed *buf; int bufsz, ret; BUILD_BUG_ON(offsetof(struct eeprom_buf, data) % 8); /* Buffer must be large enough and rounded to the next block size. */ bufsz = struct_size(buf, data, round_up(len, NSP_SFF_EEPROM_BLOCK_LEN)); buf = kzalloc(bufsz, GFP_KERNEL); if (!buf) return -ENOMEM; buf->metalen = offsetof(struct eeprom_buf, data) / NSP_SFF_EEPROM_BLOCK_LEN; buf->length = cpu_to_le16(len); buf->offset = cpu_to_le16(offset); buf->eth_index = eth_index; ret = __nfp_nsp_module_eeprom(state, buf, bufsz); *read_len = min_t(unsigned int, len, le16_to_cpu(buf->readlen)); if (*read_len) memcpy(data, buf->data, *read_len); if (!ret && *read_len < len) ret = -EIO; kfree(buf); return ret; }
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