/* * Intel Wireless WiMAX Connection 2400m * Firmware uploader * * * Copyright (C) 2007-2008 Intel Corporation. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 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. * * Neither the name of Intel Corporation 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. * * * Intel Corporation <linux-wimax@intel.com> * Yanir Lubetkin <yanirx.lubetkin@intel.com> * Inaky Perez-Gonzalez <inaky.perez-gonzalez@intel.com> * - Initial implementation * * * THE PROCEDURE * * The 2400m and derived devices work in two modes: boot-mode or * normal mode. In boot mode we can execute only a handful of commands * targeted at uploading the firmware and launching it. * * The 2400m enters boot mode when it is first connected to the * system, when it crashes and when you ask it to reboot. There are * two submodes of the boot mode: signed and non-signed. Signed takes * firmwares signed with a certain private key, non-signed takes any * firmware. Normal hardware takes only signed firmware. * * On boot mode, in USB, we write to the device using the bulk out * endpoint and read from it in the notification endpoint. In SDIO we * talk to it via the write address and read from the read address. * * Upon entrance to boot mode, the device sends (preceded with a few * zero length packets (ZLPs) on the notification endpoint in USB) a * reboot barker (4 le32 words with the same value). We ack it by * sending the same barker to the device. The device acks with a * reboot ack barker (4 le32 words with value I2400M_ACK_BARKER) and * then is fully booted. At this point we can upload the firmware. * * Note that different iterations of the device and EEPROM * configurations will send different [re]boot barkers; these are * collected in i2400m_barker_db along with the firmware * characteristics they require. * * This process is accomplished by the i2400m_bootrom_init() * function. All the device interaction happens through the * i2400m_bm_cmd() [boot mode command]. Special return values will * indicate if the device did reset during the process. * * After this, we read the MAC address and then (if needed) * reinitialize the device. We need to read it ahead of time because * in the future, we might not upload the firmware until userspace * 'ifconfig up's the device. * * We can then upload the firmware file. The file is composed of a BCF * header (basic data, keys and signatures) and a list of write * commands and payloads. Optionally more BCF headers might follow the * main payload. We first upload the header [i2400m_dnload_init()] and * then pass the commands and payloads verbatim to the i2400m_bm_cmd() * function [i2400m_dnload_bcf()]. Then we tell the device to jump to * the new firmware [i2400m_dnload_finalize()]. * * Once firmware is uploaded, we are good to go :) * * When we don't know in which mode we are, we first try by sending a * warm reset request that will take us to boot-mode. If we time out * waiting for a reboot barker, that means maybe we are already in * boot mode, so we send a reboot barker. * * COMMAND EXECUTION * * This code (and process) is single threaded; for executing commands, * we post a URB to the notification endpoint, post the command, wait * for data on the notification buffer. We don't need to worry about * others as we know we are the only ones in there. * * BACKEND IMPLEMENTATION * * This code is bus-generic; the bus-specific driver provides back end * implementations to send a boot mode command to the device and to * read an acknolwedgement from it (or an asynchronous notification) * from it. * * FIRMWARE LOADING * * Note that in some cases, we can't just load a firmware file (for * example, when resuming). For that, we might cache the firmware * file. Thus, when doing the bootstrap, if there is a cache firmware * file, it is used; if not, loading from disk is attempted. * * ROADMAP * * i2400m_barker_db_init Called by i2400m_driver_init() * i2400m_barker_db_add * * i2400m_barker_db_exit Called by i2400m_driver_exit() * * i2400m_dev_bootstrap Called by __i2400m_dev_start() * request_firmware * i2400m_fw_bootstrap * i2400m_fw_check * i2400m_fw_hdr_check * i2400m_fw_dnload * release_firmware * * i2400m_fw_dnload * i2400m_bootrom_init * i2400m_bm_cmd * i2400m_reset * i2400m_dnload_init * i2400m_dnload_init_signed * i2400m_dnload_init_nonsigned * i2400m_download_chunk * i2400m_bm_cmd * i2400m_dnload_bcf * i2400m_bm_cmd * i2400m_dnload_finalize * i2400m_bm_cmd * * i2400m_bm_cmd * i2400m->bus_bm_cmd_send() * i2400m->bus_bm_wait_for_ack * __i2400m_bm_ack_verify * i2400m_is_boot_barker * * i2400m_bm_cmd_prepare Used by bus-drivers to prep * commands before sending * * i2400m_pm_notifier Called on Power Management events * i2400m_fw_cache * i2400m_fw_uncache */ #include <linux/firmware.h> #include <linux/sched.h> #include <linux/slab.h> #include <linux/usb.h> #include "i2400m.h" #define D_SUBMODULE fw #include "debug-levels.h" static const __le32 i2400m_ACK_BARKER[4] = { cpu_to_le32(I2400M_ACK_BARKER), cpu_to_le32(I2400M_ACK_BARKER), cpu_to_le32(I2400M_ACK_BARKER), cpu_to_le32(I2400M_ACK_BARKER) }; /** * Prepare a boot-mode command for delivery * * @cmd: pointer to bootrom header to prepare * * Computes checksum if so needed. After calling this function, DO NOT * modify the command or header as the checksum won't work anymore. * * We do it from here because some times we cannot do it in the * original context the command was sent (it is a const), so when we * copy it to our staging buffer, we add the checksum there. */ void i2400m_bm_cmd_prepare(struct i2400m_bootrom_header *cmd) { if (i2400m_brh_get_use_checksum(cmd)) { int i; u32 checksum = 0; const u32 *checksum_ptr = (void *) cmd->payload; for (i = 0; i < cmd->data_size / 4; i++) checksum += cpu_to_le32(*checksum_ptr++); checksum += cmd->command + cmd->target_addr + cmd->data_size; cmd->block_checksum = cpu_to_le32(checksum); } } EXPORT_SYMBOL_GPL(i2400m_bm_cmd_prepare); /* * Database of known barkers. * * A barker is what the device sends indicating he is ready to be * bootloaded. Different versions of the device will send different * barkers. Depending on the barker, it might mean the device wants * some kind of firmware or the other. */ static struct i2400m_barker_db { __le32 data[4]; } *i2400m_barker_db; static size_t i2400m_barker_db_used, i2400m_barker_db_size; static int i2400m_zrealloc_2x(void **ptr, size_t *_count, size_t el_size, gfp_t gfp_flags) { size_t old_count = *_count, new_count = old_count ? 2 * old_count : 2, old_size = el_size * old_count, new_size = el_size * new_count; void *nptr = krealloc(*ptr, new_size, gfp_flags); if (nptr) { /* zero the other half or the whole thing if old_count * was zero */ if (old_size == 0) memset(nptr, 0, new_size); else memset(nptr + old_size, 0, old_size); *_count = new_count; *ptr = nptr; return 0; } else return -ENOMEM; } /* * Add a barker to the database * * This cannot used outside of this module and only at at module_init * time. This is to avoid the need to do locking. */ static int i2400m_barker_db_add(u32 barker_id) { int result; struct i2400m_barker_db *barker; if (i2400m_barker_db_used >= i2400m_barker_db_size) { result = i2400m_zrealloc_2x( (void **) &i2400m_barker_db, &i2400m_barker_db_size, sizeof(i2400m_barker_db[0]), GFP_KERNEL); if (result < 0) return result; } barker = i2400m_barker_db + i2400m_barker_db_used++; barker->data[0] = le32_to_cpu(barker_id); barker->data[1] = le32_to_cpu(barker_id); barker->data[2] = le32_to_cpu(barker_id); barker->data[3] = le32_to_cpu(barker_id); return 0; } void i2400m_barker_db_exit(void) { kfree(i2400m_barker_db); i2400m_barker_db = NULL; i2400m_barker_db_size = 0; i2400m_barker_db_used = 0; } /* * Helper function to add all the known stable barkers to the barker * database. */ static int i2400m_barker_db_known_barkers(void) { int result; result = i2400m_barker_db_add(I2400M_NBOOT_BARKER); if (result < 0) goto error_add; result = i2400m_barker_db_add(I2400M_SBOOT_BARKER); if (result < 0) goto error_add; result = i2400m_barker_db_add(I2400M_SBOOT_BARKER_6050); if (result < 0) goto error_add; error_add: return result; } /* * Initialize the barker database * * This can only be used from the module_init function for this * module; this is to avoid the need to do locking. * * @options: command line argument with extra barkers to * recognize. This is a comma-separated list of 32-bit hex * numbers. They are appended to the existing list. Setting 0 * cleans the existing list and starts a new one. */ int i2400m_barker_db_init(const char *_options) { int result; char *options = NULL, *options_orig, *token; i2400m_barker_db = NULL; i2400m_barker_db_size = 0; i2400m_barker_db_used = 0; result = i2400m_barker_db_known_barkers(); if (result < 0) goto error_add; /* parse command line options from i2400m.barkers */ if (_options != NULL) { unsigned barker; options_orig = kstrdup(_options, GFP_KERNEL); if (options_orig == NULL) goto error_parse; options = options_orig; while ((token = strsep(&options, ",")) != NULL) { if (*token == '\0') /* eat joint commas */ continue; if (sscanf(token, "%x", &barker) != 1 || barker > 0xffffffff) { printk(KERN_ERR "%s: can't recognize " "i2400m.barkers value '%s' as " "a 32-bit number\n", __func__, token); result = -EINVAL; goto error_parse; } if (barker == 0) { /* clean list and start new */ i2400m_barker_db_exit(); continue; } result = i2400m_barker_db_add(barker); if (result < 0) goto error_add; } kfree(options_orig); } return 0; error_parse: error_add: kfree(i2400m_barker_db); return result; } /* * Recognize a boot barker * * @buf: buffer where the boot barker. * @buf_size: size of the buffer (has to be 16 bytes). It is passed * here so the function can check it for the caller. * * Note that as a side effect, upon identifying the obtained boot * barker, this function will set i2400m->barker to point to the right * barker database entry. Subsequent calls to the function will result * in verifying that the same type of boot barker is returned when the * device [re]boots (as long as the same device instance is used). * * Return: 0 if @buf matches a known boot barker. -ENOENT if the * buffer in @buf doesn't match any boot barker in the database or * -EILSEQ if the buffer doesn't have the right size. */ int i2400m_is_boot_barker(struct i2400m *i2400m, const void *buf, size_t buf_size) { int result; struct device *dev = i2400m_dev(i2400m); struct i2400m_barker_db *barker; int i; result = -ENOENT; if (buf_size != sizeof(i2400m_barker_db[i].data)) return result; /* Short circuit if we have already discovered the barker * associated with the device. */ if (i2400m->barker && !memcmp(buf, i2400m->barker, sizeof(i2400m->barker->data))) { unsigned index = (i2400m->barker - i2400m_barker_db) / sizeof(*i2400m->barker); d_printf(2, dev, "boot barker cache-confirmed #%u/%08x\n", index, le32_to_cpu(i2400m->barker->data[0])); return 0; } for (i = 0; i < i2400m_barker_db_used; i++) { barker = &i2400m_barker_db[i]; BUILD_BUG_ON(sizeof(barker->data) != 16); if (memcmp(buf, barker->data, sizeof(barker->data))) continue; if (i2400m->barker == NULL) { i2400m->barker = barker; d_printf(1, dev, "boot barker set to #%u/%08x\n", i, le32_to_cpu(barker->data[0])); if (barker->data[0] == le32_to_cpu(I2400M_NBOOT_BARKER)) i2400m->sboot = 0; else i2400m->sboot = 1; } else if (i2400m->barker != barker) { dev_err(dev, "HW inconsistency: device " "reports a different boot barker " "than set (from %08x to %08x)\n", le32_to_cpu(i2400m->barker->data[0]), le32_to_cpu(barker->data[0])); result = -EIO; } else d_printf(2, dev, "boot barker confirmed #%u/%08x\n", i, le32_to_cpu(barker->data[0])); result = 0; break; } return result; } EXPORT_SYMBOL_GPL(i2400m_is_boot_barker); /* * Verify the ack data received * * Given a reply to a boot mode command, chew it and verify everything * is ok. * * @opcode: opcode which generated this ack. For error messages. * @ack: pointer to ack data we received * @ack_size: size of that data buffer * @flags: I2400M_BM_CMD_* flags we called the command with. * * Way too long function -- maybe it should be further split */ static ssize_t __i2400m_bm_ack_verify(struct i2400m *i2400m, int opcode, struct i2400m_bootrom_header *ack, size_t ack_size, int flags) { ssize_t result = -ENOMEM; struct device *dev = i2400m_dev(i2400m); d_fnstart(8, dev, "(i2400m %p opcode %d ack %p size %zu)\n", i2400m, opcode, ack, ack_size); if (ack_size < sizeof(*ack)) { result = -EIO; dev_err(dev, "boot-mode cmd %d: HW BUG? notification didn't " "return enough data (%zu bytes vs %zu expected)\n", opcode, ack_size, sizeof(*ack)); goto error_ack_short; } result = i2400m_is_boot_barker(i2400m, ack, ack_size); if (result >= 0) { result = -ERESTARTSYS; d_printf(6, dev, "boot-mode cmd %d: HW boot barker\n", opcode); goto error_reboot; } if (ack_size == sizeof(i2400m_ACK_BARKER) && memcmp(ack, i2400m_ACK_BARKER, sizeof(*ack)) == 0) { result = -EISCONN; d_printf(3, dev, "boot-mode cmd %d: HW reboot ack barker\n", opcode); goto error_reboot_ack; } result = 0; if (flags & I2400M_BM_CMD_RAW) goto out_raw; ack->data_size = le32_to_cpu(ack->data_size); ack->target_addr = le32_to_cpu(ack->target_addr); ack->block_checksum = le32_to_cpu(ack->block_checksum); d_printf(5, dev, "boot-mode cmd %d: notification for opcode %u " "response %u csum %u rr %u da %u\n", opcode, i2400m_brh_get_opcode(ack), i2400m_brh_get_response(ack), i2400m_brh_get_use_checksum(ack), i2400m_brh_get_response_required(ack), i2400m_brh_get_direct_access(ack)); result = -EIO; if (i2400m_brh_get_signature(ack) != 0xcbbc) { dev_err(dev, "boot-mode cmd %d: HW BUG? wrong signature " "0x%04x\n", opcode, i2400m_brh_get_signature(ack)); goto error_ack_signature; } if (opcode != -1 && opcode != i2400m_brh_get_opcode(ack)) { dev_err(dev, "boot-mode cmd %d: HW BUG? " "received response for opcode %u, expected %u\n", opcode, i2400m_brh_get_opcode(ack), opcode); goto error_ack_opcode; } if (i2400m_brh_get_response(ack) != 0) { /* failed? */ dev_err(dev, "boot-mode cmd %d: error; hw response %u\n", opcode, i2400m_brh_get_response(ack)); goto error_ack_failed; } if (ack_size < ack->data_size + sizeof(*ack)) { dev_err(dev, "boot-mode cmd %d: SW BUG " "driver provided only %zu bytes for %zu bytes " "of data\n", opcode, ack_size, (size_t) le32_to_cpu(ack->data_size) + sizeof(*ack)); goto error_ack_short_buffer; } result = ack_size; /* Don't you love this stack of empty targets? Well, I don't * either, but it helps track exactly who comes in here and * why :) */ error_ack_short_buffer: error_ack_failed: error_ack_opcode: error_ack_signature: out_raw: error_reboot_ack: error_reboot: error_ack_short: d_fnend(8, dev, "(i2400m %p opcode %d ack %p size %zu) = %d\n", i2400m, opcode, ack, ack_size, (int) result); return result; } /** * i2400m_bm_cmd - Execute a boot mode command * * @cmd: buffer containing the command data (pointing at the header). * This data can be ANYWHERE (for USB, we will copy it to an * specific buffer). Make sure everything is in proper little * endian. * * A raw buffer can be also sent, just cast it and set flags to * I2400M_BM_CMD_RAW. * * This function will generate a checksum for you if the * checksum bit in the command is set (unless I2400M_BM_CMD_RAW * is set). * * You can use the i2400m->bm_cmd_buf to stage your commands and * send them. * * If NULL, no command is sent (we just wait for an ack). * * @cmd_size: size of the command. Will be auto padded to the * bus-specific drivers padding requirements. * * @ack: buffer where to place the acknowledgement. If it is a regular * command response, all fields will be returned with the right, * native endianess. * * You *cannot* use i2400m->bm_ack_buf for this buffer. * * @ack_size: size of @ack, 16 aligned; you need to provide at least * sizeof(*ack) bytes and then enough to contain the return data * from the command * * @flags: see I2400M_BM_CMD_* above. * * @returns: bytes received by the notification; if < 0, an errno code * denoting an error or: * * -ERESTARTSYS The device has rebooted * * Executes a boot-mode command and waits for a response, doing basic * validation on it; if a zero length response is received, it retries * waiting for a response until a non-zero one is received (timing out * after %I2400M_BOOT_RETRIES retries). */ static ssize_t i2400m_bm_cmd(struct i2400m *i2400m, const struct i2400m_bootrom_header *cmd, size_t cmd_size, struct i2400m_bootrom_header *ack, size_t ack_size, int flags) { ssize_t result = -ENOMEM, rx_bytes; struct device *dev = i2400m_dev(i2400m); int opcode = cmd == NULL ? -1 : i2400m_brh_get_opcode(cmd); d_fnstart(6, dev, "(i2400m %p cmd %p size %zu ack %p size %zu)\n", i2400m, cmd, cmd_size, ack, ack_size); BUG_ON(ack_size < sizeof(*ack)); BUG_ON(i2400m->boot_mode == 0); if (cmd != NULL) { /* send the command */ result = i2400m->bus_bm_cmd_send(i2400m, cmd, cmd_size, flags); if (result < 0) goto error_cmd_send; if ((flags & I2400M_BM_CMD_RAW) == 0) d_printf(5, dev, "boot-mode cmd %d csum %u rr %u da %u: " "addr 0x%04x size %u block csum 0x%04x\n", opcode, i2400m_brh_get_use_checksum(cmd), i2400m_brh_get_response_required(cmd), i2400m_brh_get_direct_access(cmd), cmd->target_addr, cmd->data_size, cmd->block_checksum); } result = i2400m->bus_bm_wait_for_ack(i2400m, ack, ack_size); if (result < 0) { dev_err(dev, "boot-mode cmd %d: error waiting for an ack: %d\n", opcode, (int) result); /* bah, %zd doesn't work */ goto error_wait_for_ack; } rx_bytes = result; /* verify the ack and read more if necessary [result is the * final amount of bytes we get in the ack] */ result = __i2400m_bm_ack_verify(i2400m, opcode, ack, ack_size, flags); if (result < 0) goto error_bad_ack; /* Don't you love this stack of empty targets? Well, I don't * either, but it helps track exactly who comes in here and * why :) */ result = rx_bytes; error_bad_ack: error_wait_for_ack: error_cmd_send: d_fnend(6, dev, "(i2400m %p cmd %p size %zu ack %p size %zu) = %d\n", i2400m, cmd, cmd_size, ack, ack_size, (int) result); return result; } /** * i2400m_download_chunk - write a single chunk of data to the device's memory * * @i2400m: device descriptor * @buf: the buffer to write * @buf_len: length of the buffer to write * @addr: address in the device memory space * @direct: bootrom write mode * @do_csum: should a checksum validation be performed */ static int i2400m_download_chunk(struct i2400m *i2400m, const void *chunk, size_t __chunk_len, unsigned long addr, unsigned int direct, unsigned int do_csum) { int ret; size_t chunk_len = ALIGN(__chunk_len, I2400M_PL_ALIGN); struct device *dev = i2400m_dev(i2400m); struct { struct i2400m_bootrom_header cmd; u8 cmd_payload[chunk_len]; } __packed *buf; struct i2400m_bootrom_header ack; d_fnstart(5, dev, "(i2400m %p chunk %p __chunk_len %zu addr 0x%08lx " "direct %u do_csum %u)\n", i2400m, chunk, __chunk_len, addr, direct, do_csum); buf = i2400m->bm_cmd_buf; memcpy(buf->cmd_payload, chunk, __chunk_len); memset(buf->cmd_payload + __chunk_len, 0xad, chunk_len - __chunk_len); buf->cmd.command = i2400m_brh_command(I2400M_BRH_WRITE, __chunk_len & 0x3 ? 0 : do_csum, __chunk_len & 0xf ? 0 : direct); buf->cmd.target_addr = cpu_to_le32(addr); buf->cmd.data_size = cpu_to_le32(__chunk_len); ret = i2400m_bm_cmd(i2400m, &buf->cmd, sizeof(buf->cmd) + chunk_len, &ack, sizeof(ack), 0); if (ret >= 0) ret = 0; d_fnend(5, dev, "(i2400m %p chunk %p __chunk_len %zu addr 0x%08lx " "direct %u do_csum %u) = %d\n", i2400m, chunk, __chunk_len, addr, direct, do_csum, ret); return ret; } /* * Download a BCF file's sections to the device * * @i2400m: device descriptor * @bcf: pointer to firmware data (first header followed by the * payloads). Assumed verified and consistent. * @bcf_len: length (in bytes) of the @bcf buffer. * * Returns: < 0 errno code on error or the offset to the jump instruction. * * Given a BCF file, downloads each section (a command and a payload) * to the device's address space. Actually, it just executes each * command i the BCF file. * * The section size has to be aligned to 4 bytes AND the padding has * to be taken from the firmware file, as the signature takes it into * account. */ static ssize_t i2400m_dnload_bcf(struct i2400m *i2400m, const struct i2400m_bcf_hdr *bcf, size_t bcf_len) { ssize_t ret; struct device *dev = i2400m_dev(i2400m); size_t offset, /* iterator offset */ data_size, /* Size of the data payload */ section_size, /* Size of the whole section (cmd + payload) */ section = 1; const struct i2400m_bootrom_header *bh; struct i2400m_bootrom_header ack; d_fnstart(3, dev, "(i2400m %p bcf %p bcf_len %zu)\n", i2400m, bcf, bcf_len); /* Iterate over the command blocks in the BCF file that start * after the header */ offset = le32_to_cpu(bcf->header_len) * sizeof(u32); while (1) { /* start sending the file */ bh = (void *) bcf + offset; data_size = le32_to_cpu(bh->data_size); section_size = ALIGN(sizeof(*bh) + data_size, 4); d_printf(7, dev, "downloading section #%zu (@%zu %zu B) to 0x%08x\n", section, offset, sizeof(*bh) + data_size, le32_to_cpu(bh->target_addr)); /* * We look for JUMP cmd from the bootmode header, * either I2400M_BRH_SIGNED_JUMP for secure boot * or I2400M_BRH_JUMP for unsecure boot, the last chunk * should be the bootmode header with JUMP cmd. */ if (i2400m_brh_get_opcode(bh) == I2400M_BRH_SIGNED_JUMP || i2400m_brh_get_opcode(bh) == I2400M_BRH_JUMP) { d_printf(5, dev, "jump found @%zu\n", offset); break; } if (offset + section_size > bcf_len) { dev_err(dev, "fw %s: bad section #%zu, " "end (@%zu) beyond EOF (@%zu)\n", i2400m->fw_name, section, offset + section_size, bcf_len); ret = -EINVAL; goto error_section_beyond_eof; } __i2400m_msleep(20); ret = i2400m_bm_cmd(i2400m, bh, section_size, &ack, sizeof(ack), I2400M_BM_CMD_RAW); if (ret < 0) { dev_err(dev, "fw %s: section #%zu (@%zu %zu B) " "failed %d\n", i2400m->fw_name, section, offset, sizeof(*bh) + data_size, (int) ret); goto error_send; } offset += section_size; section++; } ret = offset; error_section_beyond_eof: error_send: d_fnend(3, dev, "(i2400m %p bcf %p bcf_len %zu) = %d\n", i2400m, bcf, bcf_len, (int) ret); return ret; } /* * Indicate if the device emitted a reboot barker that indicates * "signed boot" */ static unsigned i2400m_boot_is_signed(struct i2400m *i2400m) { return likely(i2400m->sboot); } /* * Do the final steps of uploading firmware * * @bcf_hdr: BCF header we are actually using * @bcf: pointer to the firmware image (which matches the first header * that is followed by the actual payloads). * @offset: [byte] offset into @bcf for the command we need to send. * * Depending on the boot mode (signed vs non-signed), different * actions need to be taken. */ static int i2400m_dnload_finalize(struct i2400m *i2400m, const struct i2400m_bcf_hdr *bcf_hdr, const struct i2400m_bcf_hdr *bcf, size_t offset) { int ret = 0; struct device *dev = i2400m_dev(i2400m); struct i2400m_bootrom_header *cmd, ack; struct { struct i2400m_bootrom_header cmd; u8 cmd_pl[0]; } __packed *cmd_buf; size_t signature_block_offset, signature_block_size; d_fnstart(3, dev, "offset %zu\n", offset); cmd = (void *) bcf + offset; if (i2400m_boot_is_signed(i2400m) == 0) { struct i2400m_bootrom_header jump_ack; d_printf(1, dev, "unsecure boot, jumping to 0x%08x\n", le32_to_cpu(cmd->target_addr)); cmd_buf = i2400m->bm_cmd_buf; memcpy(&cmd_buf->cmd, cmd, sizeof(*cmd)); cmd = &cmd_buf->cmd; /* now cmd points to the actual bootrom_header in cmd_buf */ i2400m_brh_set_opcode(cmd, I2400M_BRH_JUMP); cmd->data_size = 0; ret = i2400m_bm_cmd(i2400m, cmd, sizeof(*cmd), &jump_ack, sizeof(jump_ack), 0); } else { d_printf(1, dev, "secure boot, jumping to 0x%08x\n", le32_to_cpu(cmd->target_addr)); cmd_buf = i2400m->bm_cmd_buf; memcpy(&cmd_buf->cmd, cmd, sizeof(*cmd)); signature_block_offset = sizeof(*bcf_hdr) + le32_to_cpu(bcf_hdr->key_size) * sizeof(u32) + le32_to_cpu(bcf_hdr->exponent_size) * sizeof(u32); signature_block_size = le32_to_cpu(bcf_hdr->modulus_size) * sizeof(u32); memcpy(cmd_buf->cmd_pl, (void *) bcf_hdr + signature_block_offset, signature_block_size); ret = i2400m_bm_cmd(i2400m, &cmd_buf->cmd, sizeof(cmd_buf->cmd) + signature_block_size, &ack, sizeof(ack), I2400M_BM_CMD_RAW); } d_fnend(3, dev, "returning %d\n", ret); return ret; } /** * i2400m_bootrom_init - Reboots a powered device into boot mode * * @i2400m: device descriptor * @flags: * I2400M_BRI_SOFT: a reboot barker has been seen * already, so don't wait for it. * * I2400M_BRI_NO_REBOOT: Don't send a reboot command, but wait * for a reboot barker notification. This is a one shot; if * the state machine needs to send a reboot command it will. * * Returns: * * < 0 errno code on error, 0 if ok. * * Description: * * Tries hard enough to put the device in boot-mode. There are two * main phases to this: * * a. (1) send a reboot command and (2) get a reboot barker * * b. (1) echo/ack the reboot sending the reboot barker back and (2) * getting an ack barker in return * * We want to skip (a) in some cases [soft]. The state machine is * horrible, but it is basically: on each phase, send what has to be * sent (if any), wait for the answer and act on the answer. We might * have to backtrack and retry, so we keep a max tries counter for * that. * * It sucks because we don't know ahead of time which is going to be * the reboot barker (the device might send different ones depending * on its EEPROM config) and once the device reboots and waits for the * echo/ack reboot barker being sent back, it doesn't understand * anything else. So we can be left at the point where we don't know * what to send to it -- cold reset and bus reset seem to have little * effect. So the function iterates (in this case) through all the * known barkers and tries them all until an ACK is * received. Otherwise, it gives up. * * If we get a timeout after sending a warm reset, we do it again. */ int i2400m_bootrom_init(struct i2400m *i2400m, enum i2400m_bri flags) { int result; struct device *dev = i2400m_dev(i2400m); struct i2400m_bootrom_header *cmd; struct i2400m_bootrom_header ack; int count = i2400m->bus_bm_retries; int ack_timeout_cnt = 1; unsigned i; BUILD_BUG_ON(sizeof(*cmd) != sizeof(i2400m_barker_db[0].data)); BUILD_BUG_ON(sizeof(ack) != sizeof(i2400m_ACK_BARKER)); d_fnstart(4, dev, "(i2400m %p flags 0x%08x)\n", i2400m, flags); result = -ENOMEM; cmd = i2400m->bm_cmd_buf; if (flags & I2400M_BRI_SOFT) goto do_reboot_ack; do_reboot: ack_timeout_cnt = 1; if (--count < 0) goto error_timeout; d_printf(4, dev, "device reboot: reboot command [%d # left]\n", count); if ((flags & I2400M_BRI_NO_REBOOT) == 0) i2400m_reset(i2400m, I2400M_RT_WARM); result = i2400m_bm_cmd(i2400m, NULL, 0, &ack, sizeof(ack), I2400M_BM_CMD_RAW); flags &= ~I2400M_BRI_NO_REBOOT; switch (result) { case -ERESTARTSYS: /* * at this point, i2400m_bm_cmd(), through * __i2400m_bm_ack_process(), has updated * i2400m->barker and we are good to go. */ d_printf(4, dev, "device reboot: got reboot barker\n"); break; case -EISCONN: /* we don't know how it got here...but we follow it */ d_printf(4, dev, "device reboot: got ack barker - whatever\n"); goto do_reboot; case -ETIMEDOUT: /* * Device has timed out, we might be in boot mode * already and expecting an ack; if we don't know what * the barker is, we just send them all. Cold reset * and bus reset don't work. Beats me. */ if (i2400m->barker != NULL) { dev_err(dev, "device boot: reboot barker timed out, " "trying (set) %08x echo/ack\n", le32_to_cpu(i2400m->barker->data[0])); goto do_reboot_ack; } for (i = 0; i < i2400m_barker_db_used; i++) { struct i2400m_barker_db *barker = &i2400m_barker_db[i]; memcpy(cmd, barker->data, sizeof(barker->data)); result = i2400m_bm_cmd(i2400m, cmd, sizeof(*cmd), &ack, sizeof(ack), I2400M_BM_CMD_RAW); if (result == -EISCONN) { dev_warn(dev, "device boot: got ack barker " "after sending echo/ack barker " "#%d/%08x; rebooting j.i.c.\n", i, le32_to_cpu(barker->data[0])); flags &= ~I2400M_BRI_NO_REBOOT; goto do_reboot; } } dev_err(dev, "device boot: tried all the echo/acks, could " "not get device to respond; giving up"); result = -ESHUTDOWN; case -EPROTO: case -ESHUTDOWN: /* dev is gone */ case -EINTR: /* user cancelled */ goto error_dev_gone; default: dev_err(dev, "device reboot: error %d while waiting " "for reboot barker - rebooting\n", result); d_dump(1, dev, &ack, result); goto do_reboot; } /* At this point we ack back with 4 REBOOT barkers and expect * 4 ACK barkers. This is ugly, as we send a raw command -- * hence the cast. _bm_cmd() will catch the reboot ack * notification and report it as -EISCONN. */ do_reboot_ack: d_printf(4, dev, "device reboot ack: sending ack [%d # left]\n", count); memcpy(cmd, i2400m->barker->data, sizeof(i2400m->barker->data)); result = i2400m_bm_cmd(i2400m, cmd, sizeof(*cmd), &ack, sizeof(ack), I2400M_BM_CMD_RAW); switch (result) { case -ERESTARTSYS: d_printf(4, dev, "reboot ack: got reboot barker - retrying\n"); if (--count < 0) goto error_timeout; goto do_reboot_ack; case -EISCONN: d_printf(4, dev, "reboot ack: got ack barker - good\n"); break; case -ETIMEDOUT: /* no response, maybe it is the other type? */ if (ack_timeout_cnt-- < 0) { d_printf(4, dev, "reboot ack timedout: retrying\n"); goto do_reboot_ack; } else { dev_err(dev, "reboot ack timedout too long: " "trying reboot\n"); goto do_reboot; } break; case -EPROTO: case -ESHUTDOWN: /* dev is gone */ goto error_dev_gone; default: dev_err(dev, "device reboot ack: error %d while waiting for " "reboot ack barker - rebooting\n", result); goto do_reboot; } d_printf(2, dev, "device reboot ack: got ack barker - boot done\n"); result = 0; exit_timeout: error_dev_gone: d_fnend(4, dev, "(i2400m %p flags 0x%08x) = %d\n", i2400m, flags, result); return result; error_timeout: dev_err(dev, "Timed out waiting for reboot ack\n"); result = -ETIMEDOUT; goto exit_timeout; } /* * Read the MAC addr * * The position this function reads is fixed in device memory and * always available, even without firmware. * * Note we specify we want to read only six bytes, but provide space * for 16, as we always get it rounded up. */ int i2400m_read_mac_addr(struct i2400m *i2400m) { int result; struct device *dev = i2400m_dev(i2400m); struct net_device *net_dev = i2400m->wimax_dev.net_dev; struct i2400m_bootrom_header *cmd; struct { struct i2400m_bootrom_header ack; u8 ack_pl[16]; } __packed ack_buf; d_fnstart(5, dev, "(i2400m %p)\n", i2400m); cmd = i2400m->bm_cmd_buf; cmd->command = i2400m_brh_command(I2400M_BRH_READ, 0, 1); cmd->target_addr = cpu_to_le32(0x00203fe8); cmd->data_size = cpu_to_le32(6); result = i2400m_bm_cmd(i2400m, cmd, sizeof(*cmd), &ack_buf.ack, sizeof(ack_buf), 0); if (result < 0) { dev_err(dev, "BM: read mac addr failed: %d\n", result); goto error_read_mac; } d_printf(2, dev, "mac addr is %pM\n", ack_buf.ack_pl); if (i2400m->bus_bm_mac_addr_impaired == 1) { ack_buf.ack_pl[0] = 0x00; ack_buf.ack_pl[1] = 0x16; ack_buf.ack_pl[2] = 0xd3; get_random_bytes(&ack_buf.ack_pl[3], 3); dev_err(dev, "BM is MAC addr impaired, faking MAC addr to " "mac addr is %pM\n", ack_buf.ack_pl); result = 0; } net_dev->addr_len = ETH_ALEN; memcpy(net_dev->perm_addr, ack_buf.ack_pl, ETH_ALEN); memcpy(net_dev->dev_addr, ack_buf.ack_pl, ETH_ALEN); error_read_mac: d_fnend(5, dev, "(i2400m %p) = %d\n", i2400m, result); return result; } /* * Initialize a non signed boot * * This implies sending some magic values to the device's memory. Note * we convert the values to little endian in the same array * declaration. */ static int i2400m_dnload_init_nonsigned(struct i2400m *i2400m) { unsigned i = 0; int ret = 0; struct device *dev = i2400m_dev(i2400m); d_fnstart(5, dev, "(i2400m %p)\n", i2400m); if (i2400m->bus_bm_pokes_table) { while (i2400m->bus_bm_pokes_table[i].address) { ret = i2400m_download_chunk( i2400m, &i2400m->bus_bm_pokes_table[i].data, sizeof(i2400m->bus_bm_pokes_table[i].data), i2400m->bus_bm_pokes_table[i].address, 1, 1); if (ret < 0) break; i++; } } d_fnend(5, dev, "(i2400m %p) = %d\n", i2400m, ret); return ret; } /* * Initialize the signed boot process * * @i2400m: device descriptor * * @bcf_hdr: pointer to the firmware header; assumes it is fully in * memory (it has gone through basic validation). * * Returns: 0 if ok, < 0 errno code on error, -ERESTARTSYS if the hw * rebooted. * * This writes the firmware BCF header to the device using the * HASH_PAYLOAD_ONLY command. */ static int i2400m_dnload_init_signed(struct i2400m *i2400m, const struct i2400m_bcf_hdr *bcf_hdr) { int ret; struct device *dev = i2400m_dev(i2400m); struct { struct i2400m_bootrom_header cmd; struct i2400m_bcf_hdr cmd_pl; } __packed *cmd_buf; struct i2400m_bootrom_header ack; d_fnstart(5, dev, "(i2400m %p bcf_hdr %p)\n", i2400m, bcf_hdr); cmd_buf = i2400m->bm_cmd_buf; cmd_buf->cmd.command = i2400m_brh_command(I2400M_BRH_HASH_PAYLOAD_ONLY, 0, 0); cmd_buf->cmd.target_addr = 0; cmd_buf->cmd.data_size = cpu_to_le32(sizeof(cmd_buf->cmd_pl)); memcpy(&cmd_buf->cmd_pl, bcf_hdr, sizeof(*bcf_hdr)); ret = i2400m_bm_cmd(i2400m, &cmd_buf->cmd, sizeof(*cmd_buf), &ack, sizeof(ack), 0); if (ret >= 0) ret = 0; d_fnend(5, dev, "(i2400m %p bcf_hdr %p) = %d\n", i2400m, bcf_hdr, ret); return ret; } /* * Initialize the firmware download at the device size * * Multiplex to the one that matters based on the device's mode * (signed or non-signed). */ static int i2400m_dnload_init(struct i2400m *i2400m, const struct i2400m_bcf_hdr *bcf_hdr) { int result; struct device *dev = i2400m_dev(i2400m); if (i2400m_boot_is_signed(i2400m)) { d_printf(1, dev, "signed boot\n"); result = i2400m_dnload_init_signed(i2400m, bcf_hdr); if (result == -ERESTARTSYS) return result; if (result < 0) dev_err(dev, "firmware %s: signed boot download " "initialization failed: %d\n", i2400m->fw_name, result); } else { /* non-signed boot process without pokes */ d_printf(1, dev, "non-signed boot\n"); result = i2400m_dnload_init_nonsigned(i2400m); if (result == -ERESTARTSYS) return result; if (result < 0) dev_err(dev, "firmware %s: non-signed download " "initialization failed: %d\n", i2400m->fw_name, result); } return result; } /* * Run consistency tests on the firmware file and load up headers * * Check for the firmware being made for the i2400m device, * etc...These checks are mostly informative, as the device will make * them too; but the driver's response is more informative on what * went wrong. * * This will also look at all the headers present on the firmware * file, and update i2400m->fw_bcf_hdr to point to them. */ static int i2400m_fw_hdr_check(struct i2400m *i2400m, const struct i2400m_bcf_hdr *bcf_hdr, size_t index, size_t offset) { struct device *dev = i2400m_dev(i2400m); unsigned module_type, header_len, major_version, minor_version, module_id, module_vendor, date, size; module_type = le32_to_cpu(bcf_hdr->module_type); header_len = sizeof(u32) * le32_to_cpu(bcf_hdr->header_len); major_version = (le32_to_cpu(bcf_hdr->header_version) & 0xffff0000) >> 16; minor_version = le32_to_cpu(bcf_hdr->header_version) & 0x0000ffff; module_id = le32_to_cpu(bcf_hdr->module_id); module_vendor = le32_to_cpu(bcf_hdr->module_vendor); date = le32_to_cpu(bcf_hdr->date); size = sizeof(u32) * le32_to_cpu(bcf_hdr->size); d_printf(1, dev, "firmware %s #%zd@%08zx: BCF header " "type:vendor:id 0x%x:%x:%x v%u.%u (%u/%u B) built %08x\n", i2400m->fw_name, index, offset, module_type, module_vendor, module_id, major_version, minor_version, header_len, size, date); /* Hard errors */ if (major_version != 1) { dev_err(dev, "firmware %s #%zd@%08zx: major header version " "v%u.%u not supported\n", i2400m->fw_name, index, offset, major_version, minor_version); return -EBADF; } if (module_type != 6) { /* built for the right hardware? */ dev_err(dev, "firmware %s #%zd@%08zx: unexpected module " "type 0x%x; aborting\n", i2400m->fw_name, index, offset, module_type); return -EBADF; } if (module_vendor != 0x8086) { dev_err(dev, "firmware %s #%zd@%08zx: unexpected module " "vendor 0x%x; aborting\n", i2400m->fw_name, index, offset, module_vendor); return -EBADF; } if (date < 0x20080300) dev_warn(dev, "firmware %s #%zd@%08zx: build date %08x " "too old; unsupported\n", i2400m->fw_name, index, offset, date); return 0; } /* * Run consistency tests on the firmware file and load up headers * * Check for the firmware being made for the i2400m device, * etc...These checks are mostly informative, as the device will make * them too; but the driver's response is more informative on what * went wrong. * * This will also look at all the headers present on the firmware * file, and update i2400m->fw_hdrs to point to them. */ static int i2400m_fw_check(struct i2400m *i2400m, const void *bcf, size_t bcf_size) { int result; struct device *dev = i2400m_dev(i2400m); size_t headers = 0; const struct i2400m_bcf_hdr *bcf_hdr; const void *itr, *next, *top; size_t slots = 0, used_slots = 0; for (itr = bcf, top = itr + bcf_size; itr < top; headers++, itr = next) { size_t leftover, offset, header_len, size; leftover = top - itr; offset = itr - (const void *) bcf; if (leftover <= sizeof(*bcf_hdr)) { dev_err(dev, "firmware %s: %zu B left at @%zx, " "not enough for BCF header\n", i2400m->fw_name, leftover, offset); break; } bcf_hdr = itr; /* Only the first header is supposed to be followed by * payload */ header_len = sizeof(u32) * le32_to_cpu(bcf_hdr->header_len); size = sizeof(u32) * le32_to_cpu(bcf_hdr->size); if (headers == 0) next = itr + size; else next = itr + header_len; result = i2400m_fw_hdr_check(i2400m, bcf_hdr, headers, offset); if (result < 0) continue; if (used_slots + 1 >= slots) { /* +1 -> we need to account for the one we'll * occupy and at least an extra one for * always being NULL */ result = i2400m_zrealloc_2x( (void **) &i2400m->fw_hdrs, &slots, sizeof(i2400m->fw_hdrs[0]), GFP_KERNEL); if (result < 0) goto error_zrealloc; } i2400m->fw_hdrs[used_slots] = bcf_hdr; used_slots++; } if (headers == 0) { dev_err(dev, "firmware %s: no usable headers found\n", i2400m->fw_name); result = -EBADF; } else result = 0; error_zrealloc: return result; } /* * Match a barker to a BCF header module ID * * The device sends a barker which tells the firmware loader which * header in the BCF file has to be used. This does the matching. */ static unsigned i2400m_bcf_hdr_match(struct i2400m *i2400m, const struct i2400m_bcf_hdr *bcf_hdr) { u32 barker = le32_to_cpu(i2400m->barker->data[0]) & 0x7fffffff; u32 module_id = le32_to_cpu(bcf_hdr->module_id) & 0x7fffffff; /* high bit used for something else */ /* special case for 5x50 */ if (barker == I2400M_SBOOT_BARKER && module_id == 0) return 1; if (module_id == barker) return 1; return 0; } static const struct i2400m_bcf_hdr *i2400m_bcf_hdr_find(struct i2400m *i2400m) { struct device *dev = i2400m_dev(i2400m); const struct i2400m_bcf_hdr **bcf_itr, *bcf_hdr; unsigned i = 0; u32 barker = le32_to_cpu(i2400m->barker->data[0]); d_printf(2, dev, "finding BCF header for barker %08x\n", barker); if (barker == I2400M_NBOOT_BARKER) { bcf_hdr = i2400m->fw_hdrs[0]; d_printf(1, dev, "using BCF header #%u/%08x for non-signed " "barker\n", 0, le32_to_cpu(bcf_hdr->module_id)); return bcf_hdr; } for (bcf_itr = i2400m->fw_hdrs; *bcf_itr != NULL; bcf_itr++, i++) { bcf_hdr = *bcf_itr; if (i2400m_bcf_hdr_match(i2400m, bcf_hdr)) { d_printf(1, dev, "hit on BCF hdr #%u/%08x\n", i, le32_to_cpu(bcf_hdr->module_id)); return bcf_hdr; } else d_printf(1, dev, "miss on BCF hdr #%u/%08x\n", i, le32_to_cpu(bcf_hdr->module_id)); } dev_err(dev, "cannot find a matching BCF header for barker %08x\n", barker); return NULL; } /* * Download the firmware to the device * * @i2400m: device descriptor * @bcf: pointer to loaded (and minimally verified for consistency) * firmware * @bcf_size: size of the @bcf buffer (header plus payloads) * * The process for doing this is described in this file's header. * * Note we only reinitialize boot-mode if the flags say so. Some hw * iterations need it, some don't. In any case, if we loop, we always * need to reinitialize the boot room, hence the flags modification. */ static int i2400m_fw_dnload(struct i2400m *i2400m, const struct i2400m_bcf_hdr *bcf, size_t fw_size, enum i2400m_bri flags) { int ret = 0; struct device *dev = i2400m_dev(i2400m); int count = i2400m->bus_bm_retries; const struct i2400m_bcf_hdr *bcf_hdr; size_t bcf_size; d_fnstart(5, dev, "(i2400m %p bcf %p fw size %zu)\n", i2400m, bcf, fw_size); i2400m->boot_mode = 1; wmb(); /* Make sure other readers see it */ hw_reboot: if (count-- == 0) { ret = -ERESTARTSYS; dev_err(dev, "device rebooted too many times, aborting\n"); goto error_too_many_reboots; } if (flags & I2400M_BRI_MAC_REINIT) { ret = i2400m_bootrom_init(i2400m, flags); if (ret < 0) { dev_err(dev, "bootrom init failed: %d\n", ret); goto error_bootrom_init; } } flags |= I2400M_BRI_MAC_REINIT; /* * Initialize the download, push the bytes to the device and * then jump to the new firmware. Note @ret is passed with the * offset of the jump instruction to _dnload_finalize() * * Note we need to use the BCF header in the firmware image * that matches the barker that the device sent when it * rebooted, so it has to be passed along. */ ret = -EBADF; bcf_hdr = i2400m_bcf_hdr_find(i2400m); if (bcf_hdr == NULL) goto error_bcf_hdr_find; ret = i2400m_dnload_init(i2400m, bcf_hdr); if (ret == -ERESTARTSYS) goto error_dev_rebooted; if (ret < 0) goto error_dnload_init; /* * bcf_size refers to one header size plus the fw sections size * indicated by the header,ie. if there are other extended headers * at the tail, they are not counted */ bcf_size = sizeof(u32) * le32_to_cpu(bcf_hdr->size); ret = i2400m_dnload_bcf(i2400m, bcf, bcf_size); if (ret == -ERESTARTSYS) goto error_dev_rebooted; if (ret < 0) { dev_err(dev, "fw %s: download failed: %d\n", i2400m->fw_name, ret); goto error_dnload_bcf; } ret = i2400m_dnload_finalize(i2400m, bcf_hdr, bcf, ret); if (ret == -ERESTARTSYS) goto error_dev_rebooted; if (ret < 0) { dev_err(dev, "fw %s: " "download finalization failed: %d\n", i2400m->fw_name, ret); goto error_dnload_finalize; } d_printf(2, dev, "fw %s successfully uploaded\n", i2400m->fw_name); i2400m->boot_mode = 0; wmb(); /* Make sure i2400m_msg_to_dev() sees boot_mode */ error_dnload_finalize: error_dnload_bcf: error_dnload_init: error_bcf_hdr_find: error_bootrom_init: error_too_many_reboots: d_fnend(5, dev, "(i2400m %p bcf %p size %zu) = %d\n", i2400m, bcf, fw_size, ret); return ret; error_dev_rebooted: dev_err(dev, "device rebooted, %d tries left\n", count); /* we got the notification already, no need to wait for it again */ flags |= I2400M_BRI_SOFT; goto hw_reboot; } static int i2400m_fw_bootstrap(struct i2400m *i2400m, const struct firmware *fw, enum i2400m_bri flags) { int ret; struct device *dev = i2400m_dev(i2400m); const struct i2400m_bcf_hdr *bcf; /* Firmware data */ d_fnstart(5, dev, "(i2400m %p)\n", i2400m); bcf = (void *) fw->data; ret = i2400m_fw_check(i2400m, bcf, fw->size); if (ret >= 0) ret = i2400m_fw_dnload(i2400m, bcf, fw->size, flags); if (ret < 0) dev_err(dev, "%s: cannot use: %d, skipping\n", i2400m->fw_name, ret); kfree(i2400m->fw_hdrs); i2400m->fw_hdrs = NULL; d_fnend(5, dev, "(i2400m %p) = %d\n", i2400m, ret); return ret; } /* Refcounted container for firmware data */ struct i2400m_fw { struct kref kref; const struct firmware *fw; }; static void i2400m_fw_destroy(struct kref *kref) { struct i2400m_fw *i2400m_fw = container_of(kref, struct i2400m_fw, kref); release_firmware(i2400m_fw->fw); kfree(i2400m_fw); } static struct i2400m_fw *i2400m_fw_get(struct i2400m_fw *i2400m_fw) { if (i2400m_fw != NULL && i2400m_fw != (void *) ~0) kref_get(&i2400m_fw->kref); return i2400m_fw; } static void i2400m_fw_put(struct i2400m_fw *i2400m_fw) { kref_put(&i2400m_fw->kref, i2400m_fw_destroy); } /** * i2400m_dev_bootstrap - Bring the device to a known state and upload firmware * * @i2400m: device descriptor * * Returns: >= 0 if ok, < 0 errno code on error. * * This sets up the firmware upload environment, loads the firmware * file from disk, verifies and then calls the firmware upload process * per se. * * Can be called either from probe, or after a warm reset. Can not be * called from within an interrupt. All the flow in this code is * single-threade; all I/Os are synchronous. */ int i2400m_dev_bootstrap(struct i2400m *i2400m, enum i2400m_bri flags) { int ret, itr; struct device *dev = i2400m_dev(i2400m); struct i2400m_fw *i2400m_fw; const struct i2400m_bcf_hdr *bcf; /* Firmware data */ const struct firmware *fw; const char *fw_name; d_fnstart(5, dev, "(i2400m %p)\n", i2400m); ret = -ENODEV; spin_lock(&i2400m->rx_lock); i2400m_fw = i2400m_fw_get(i2400m->fw_cached); spin_unlock(&i2400m->rx_lock); if (i2400m_fw == (void *) ~0) { dev_err(dev, "can't load firmware now!"); goto out; } else if (i2400m_fw != NULL) { dev_info(dev, "firmware %s: loading from cache\n", i2400m->fw_name); ret = i2400m_fw_bootstrap(i2400m, i2400m_fw->fw, flags); i2400m_fw_put(i2400m_fw); goto out; } /* Load firmware files to memory. */ for (itr = 0, bcf = NULL, ret = -ENOENT; ; itr++) { fw_name = i2400m->bus_fw_names[itr]; if (fw_name == NULL) { dev_err(dev, "Could not find a usable firmware image\n"); break; } d_printf(1, dev, "trying firmware %s (%d)\n", fw_name, itr); ret = request_firmware(&fw, fw_name, dev); if (ret < 0) { dev_err(dev, "fw %s: cannot load file: %d\n", fw_name, ret); continue; } i2400m->fw_name = fw_name; ret = i2400m_fw_bootstrap(i2400m, fw, flags); release_firmware(fw); if (ret >= 0) /* firmware loaded successfully */ break; i2400m->fw_name = NULL; } out: d_fnend(5, dev, "(i2400m %p) = %d\n", i2400m, ret); return ret; } EXPORT_SYMBOL_GPL(i2400m_dev_bootstrap); void i2400m_fw_cache(struct i2400m *i2400m) { int result; struct i2400m_fw *i2400m_fw; struct device *dev = i2400m_dev(i2400m); /* if there is anything there, free it -- now, this'd be weird */ spin_lock(&i2400m->rx_lock); i2400m_fw = i2400m->fw_cached; spin_unlock(&i2400m->rx_lock); if (i2400m_fw != NULL && i2400m_fw != (void *) ~0) { i2400m_fw_put(i2400m_fw); WARN(1, "%s:%u: still cached fw still present?\n", __func__, __LINE__); } if (i2400m->fw_name == NULL) { dev_err(dev, "firmware n/a: can't cache\n"); i2400m_fw = (void *) ~0; goto out; } i2400m_fw = kzalloc(sizeof(*i2400m_fw), GFP_ATOMIC); if (i2400m_fw == NULL) goto out; kref_init(&i2400m_fw->kref); result = request_firmware(&i2400m_fw->fw, i2400m->fw_name, dev); if (result < 0) { dev_err(dev, "firmware %s: failed to cache: %d\n", i2400m->fw_name, result); kfree(i2400m_fw); i2400m_fw = (void *) ~0; } else dev_info(dev, "firmware %s: cached\n", i2400m->fw_name); out: spin_lock(&i2400m->rx_lock); i2400m->fw_cached = i2400m_fw; spin_unlock(&i2400m->rx_lock); } void i2400m_fw_uncache(struct i2400m *i2400m) { struct i2400m_fw *i2400m_fw; spin_lock(&i2400m->rx_lock); i2400m_fw = i2400m->fw_cached; i2400m->fw_cached = NULL; spin_unlock(&i2400m->rx_lock); if (i2400m_fw != NULL && i2400m_fw != (void *) ~0) i2400m_fw_put(i2400m_fw); }