// SPDX-License-Identifier: GPL-2.0-only /* * ISHTP firmware loader function * * Copyright (c) 2024, Intel Corporation. * * This module implements the functionality to load the main ISH firmware from the host, starting * with the Lunar Lake generation. It leverages a new method that enhances space optimization and * flexibility by dividing the ISH firmware into a bootloader and main firmware. * * Please refer to the [Documentation](Documentation/hid/intel-ish-hid.rst) for the details on * flows. * * Additionally, address potential error scenarios to ensure graceful failure handling. * - Firmware Image Not Found: * Occurs when `request_firmware()` cannot locate the firmware image. The ISH firmware will * remain in a state awaiting firmware loading from the host, with no further action from * the ISHTP driver. * Recovery: Re-insmod the ISH drivers allows for a retry of the firmware loading from the host. * * - DMA Buffer Allocation Failure: * This happens if allocating a DMA buffer during `prepare_dma_bufs()` fails. The ISH firmware * will stay in a waiting state, and the ISHTP driver will release any allocated DMA buffers and * firmware without further actions. * Recovery: Re-insmod the ISH drivers allows for a retry of the firmware loading from the host. * * - Incorrect Firmware Image: * Using an incorrect firmware image will initiate the firmware loading process but will * eventually be refused by the ISH firmware after three unsuccessful attempts, indicated by * returning an error code. The ISHTP driver will stop attempting after three tries. * Recovery: A platform reset is required to retry firmware loading from the host. */ #define dev_fmt(fmt) "ISH loader: " fmt #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "hbm.h" #include "loader.h" /** * loader_write_message() - Write a message to the ISHTP device * @dev: The ISHTP device * @buf: The buffer containing the message * @len: The length of the message * * Return: 0 on success, negative error code on failure */ static int loader_write_message(struct ishtp_device *dev, void *buf, int len) { struct ishtp_msg_hdr ishtp_hdr = { .fw_addr = ISHTP_LOADER_CLIENT_ADDR, .length = len, .msg_complete = 1, }; dev->fw_loader_received = false; return ishtp_write_message(dev, &ishtp_hdr, buf); } /** * loader_xfer_cmd() - Transfer a command to the ISHTP device * @dev: The ISHTP device * @req: The request buffer * @req_len: The length of the request * @resp: The response buffer * @resp_len: The length of the response * * Return: 0 on success, negative error code on failure */ static int loader_xfer_cmd(struct ishtp_device *dev, void *req, int req_len, void *resp, int resp_len) { union loader_msg_header req_hdr; union loader_msg_header resp_hdr; struct device *devc = dev->devc; int rv; dev->fw_loader_rx_buf = resp; dev->fw_loader_rx_size = resp_len; rv = loader_write_message(dev, req, req_len); req_hdr.val32 = le32_to_cpup(req); if (rv < 0) { dev_err(devc, "write cmd %u failed:%d\n", req_hdr.command, rv); return rv; } /* Wait the ACK */ wait_event_interruptible_timeout(dev->wait_loader_recvd_msg, dev->fw_loader_received, ISHTP_LOADER_TIMEOUT); resp_hdr.val32 = le32_to_cpup(resp); dev->fw_loader_rx_size = 0; dev->fw_loader_rx_buf = NULL; if (!dev->fw_loader_received) { dev_err(devc, "wait response of cmd %u timeout\n", req_hdr.command); return -ETIMEDOUT; } if (!resp_hdr.is_response) { dev_err(devc, "not a response for %u\n", req_hdr.command); return -EBADMSG; } if (req_hdr.command != resp_hdr.command) { dev_err(devc, "unexpected cmd response %u:%u\n", req_hdr.command, resp_hdr.command); return -EBADMSG; } if (resp_hdr.status) { dev_err(devc, "cmd %u failed %u\n", req_hdr.command, resp_hdr.status); return -EIO; } return 0; } /** * release_dma_bufs() - Release the DMA buffer for transferring firmware fragments * @dev: The ISHTP device * @fragment: The ISHTP firmware fragment descriptor * @dma_bufs: The array of DMA fragment buffers * @fragment_size: The size of a single DMA fragment */ static void release_dma_bufs(struct ishtp_device *dev, struct loader_xfer_dma_fragment *fragment, void **dma_bufs, u32 fragment_size) { dma_addr_t dma_addr; int i; for (i = 0; i < FRAGMENT_MAX_NUM; i++) { if (dma_bufs[i]) { dma_addr = le64_to_cpu(fragment->fragment_tbl[i].ddr_adrs); dma_free_coherent(dev->devc, fragment_size, dma_bufs[i], dma_addr); dma_bufs[i] = NULL; } } } /** * prepare_dma_bufs() - Prepare the DMA buffer for transferring firmware fragments * @dev: The ISHTP device * @ish_fw: The ISH firmware * @fragment: The ISHTP firmware fragment descriptor * @dma_bufs: The array of DMA fragment buffers * @fragment_size: The size of a single DMA fragment * @fragment_count: Number of fragments * * Return: 0 on success, negative error code on failure */ static int prepare_dma_bufs(struct ishtp_device *dev, const struct firmware *ish_fw, struct loader_xfer_dma_fragment *fragment, void **dma_bufs, u32 fragment_size, u32 fragment_count) { dma_addr_t dma_addr; u32 offset = 0; u32 length; int i; for (i = 0; i < fragment_count && offset < ish_fw->size; i++) { dma_bufs[i] = dma_alloc_coherent(dev->devc, fragment_size, &dma_addr, GFP_KERNEL); if (!dma_bufs[i]) return -ENOMEM; fragment->fragment_tbl[i].ddr_adrs = cpu_to_le64(dma_addr); length = clamp(ish_fw->size - offset, 0, fragment_size); fragment->fragment_tbl[i].length = cpu_to_le32(length); fragment->fragment_tbl[i].fw_off = cpu_to_le32(offset); memcpy(dma_bufs[i], ish_fw->data + offset, length); clflush_cache_range(dma_bufs[i], fragment_size); offset += length; } return 0; } #define ISH_FW_FILE_VENDOR_NAME_SKU_FMT "intel/ish/ish_%s_%08x_%08x_%08x.bin" #define ISH_FW_FILE_VENDOR_SKU_FMT "intel/ish/ish_%s_%08x_%08x.bin" #define ISH_FW_FILE_VENDOR_NAME_FMT "intel/ish/ish_%s_%08x_%08x.bin" #define ISH_FW_FILE_VENDOR_FMT "intel/ish/ish_%s_%08x.bin" #define ISH_FW_FILE_DEFAULT_FMT "intel/ish/ish_%s.bin" #define ISH_FW_FILENAME_LEN_MAX 56 #define ISH_CRC_INIT (~0u) #define ISH_CRC_XOROUT (~0u) static int _request_ish_firmware(const struct firmware **firmware_p, const char *name, struct device *dev) { int ret; dev_dbg(dev, "Try to load firmware: %s\n", name); ret = firmware_request_nowarn(firmware_p, name, dev); if (!ret) dev_info(dev, "load firmware: %s\n", name); return ret; } /** * request_ish_firmware() - Request and load the ISH firmware. * @firmware_p: Pointer to the firmware image. * @dev: Device for which firmware is being requested. * * This function attempts to load the Integrated Sensor Hub (ISH) firmware * for the given device in the following order, prioritizing custom firmware * with more precise matching patterns: * * ish_${fw_generation}_${SYS_VENDOR_CRC32}_$(PRODUCT_NAME_CRC32)_${PRODUCT_SKU_CRC32}.bin * ish_${fw_generation}_${SYS_VENDOR_CRC32}_${PRODUCT_SKU_CRC32}.bin * ish_${fw_generation}_${SYS_VENDOR_CRC32}_$(PRODUCT_NAME_CRC32).bin * ish_${fw_generation}_${SYS_VENDOR_CRC32}.bin * ish_${fw_generation}.bin * * The driver will load the first matching firmware and skip the rest. If no * matching firmware is found, it will proceed to the next pattern in the * specified order. If all searches fail, the default Intel firmware, listed * last in the order above, will be loaded. * * The firmware file name is constructed using CRC32 checksums of strings. * This is done to create a valid file name that does not contain spaces * or special characters which may be present in the original strings. * * The CRC-32 algorithm uses the following parameters: * Poly: 0x04C11DB7 * Init: 0xFFFFFFFF * RefIn: true * RefOut: true * XorOut: 0xFFFFFFFF * * Return: 0 on success, negative error code on failure. */ static int request_ish_firmware(const struct firmware **firmware_p, struct device *dev) { const char *gen, *sys_vendor, *product_name, *product_sku; struct ishtp_device *ishtp = dev_get_drvdata(dev); u32 vendor_crc, name_crc, sku_crc; char filename[ISH_FW_FILENAME_LEN_MAX]; int ret; gen = ishtp->driver_data->fw_generation; sys_vendor = dmi_get_system_info(DMI_SYS_VENDOR); product_name = dmi_get_system_info(DMI_PRODUCT_NAME); product_sku = dmi_get_system_info(DMI_PRODUCT_SKU); if (sys_vendor) vendor_crc = crc32(ISH_CRC_INIT, sys_vendor, strlen(sys_vendor)) ^ ISH_CRC_XOROUT; if (product_name) name_crc = crc32(ISH_CRC_INIT, product_name, strlen(product_name)) ^ ISH_CRC_XOROUT; if (product_sku) sku_crc = crc32(ISH_CRC_INIT, product_sku, strlen(product_sku)) ^ ISH_CRC_XOROUT; if (sys_vendor && product_name && product_sku) { snprintf(filename, sizeof(filename), ISH_FW_FILE_VENDOR_NAME_SKU_FMT, gen, vendor_crc, name_crc, sku_crc); ret = _request_ish_firmware(firmware_p, filename, dev); if (!ret) return 0; } if (sys_vendor && product_sku) { snprintf(filename, sizeof(filename), ISH_FW_FILE_VENDOR_SKU_FMT, gen, vendor_crc, sku_crc); ret = _request_ish_firmware(firmware_p, filename, dev); if (!ret) return 0; } if (sys_vendor && product_name) { snprintf(filename, sizeof(filename), ISH_FW_FILE_VENDOR_NAME_FMT, gen, vendor_crc, name_crc); ret = _request_ish_firmware(firmware_p, filename, dev); if (!ret) return 0; } if (sys_vendor) { snprintf(filename, sizeof(filename), ISH_FW_FILE_VENDOR_FMT, gen, vendor_crc); ret = _request_ish_firmware(firmware_p, filename, dev); if (!ret) return 0; } snprintf(filename, sizeof(filename), ISH_FW_FILE_DEFAULT_FMT, gen); return _request_ish_firmware(firmware_p, filename, dev); } static int copy_manifest(const struct firmware *fw, struct ish_global_manifest *manifest) { u32 offset; for (offset = 0; offset + sizeof(*manifest) < fw->size; offset += ISH_MANIFEST_ALIGNMENT) { memcpy(manifest, fw->data + offset, sizeof(*manifest)); if (le32_to_cpu(manifest->sig_fourcc) == ISH_GLOBAL_SIG) return 0; } return -1; } static void copy_ish_version(struct version_in_manifest *src, struct ish_version *dst) { dst->major = le16_to_cpu(src->major); dst->minor = le16_to_cpu(src->minor); dst->hotfix = le16_to_cpu(src->hotfix); dst->build = le16_to_cpu(src->build); } /** * ishtp_loader_work() - Load the ISHTP firmware * @work: The work structure * * The ISH Loader attempts to load firmware by sending a series of commands * to the ISH device. If a command fails to be acknowledged by the ISH device, * the loader will retry sending the command, up to a maximum of * ISHTP_LOADER_RETRY_TIMES. * * After the maximum number of retries has been reached without success, the * ISH bootloader will return an error status code and will no longer respond * to the driver's commands. This behavior indicates that the ISH Loader has * encountered a critical error during the firmware loading process. * * In such a case, where the ISH bootloader is unresponsive after all retries * have been exhausted, a platform reset is required to restore communication * with the ISH device and to recover from this error state. */ void ishtp_loader_work(struct work_struct *work) { DEFINE_RAW_FLEX(struct loader_xfer_dma_fragment, fragment, fragment_tbl, FRAGMENT_MAX_NUM); struct ishtp_device *dev = container_of(work, struct ishtp_device, work_fw_loader); union loader_msg_header query_hdr = { .command = LOADER_CMD_XFER_QUERY, }; union loader_msg_header start_hdr = { .command = LOADER_CMD_START, }; union loader_msg_header fragment_hdr = { .command = LOADER_CMD_XFER_FRAGMENT, }; struct loader_xfer_query query = { .header = cpu_to_le32(query_hdr.val32), }; struct loader_start start = { .header = cpu_to_le32(start_hdr.val32), }; union loader_recv_message recv_msg; struct ish_global_manifest manifest; const struct firmware *ish_fw; void *dma_bufs[FRAGMENT_MAX_NUM] = {}; u32 fragment_size; u32 fragment_count; int retry = ISHTP_LOADER_RETRY_TIMES; int rv; rv = request_ish_firmware(&ish_fw, dev->devc); if (rv < 0) { dev_err(dev->devc, "request ISH firmware failed:%d\n", rv); return; } fragment->fragment.header = cpu_to_le32(fragment_hdr.val32); fragment->fragment.xfer_mode = cpu_to_le32(LOADER_XFER_MODE_DMA); fragment->fragment.is_last = cpu_to_le32(1); fragment->fragment.size = cpu_to_le32(ish_fw->size); /* Calculate the size of a single DMA fragment */ fragment_size = PFN_ALIGN(DIV_ROUND_UP(ish_fw->size, FRAGMENT_MAX_NUM)); /* Calculate the count of DMA fragments */ fragment_count = DIV_ROUND_UP(ish_fw->size, fragment_size); fragment->fragment_cnt = cpu_to_le32(fragment_count); rv = prepare_dma_bufs(dev, ish_fw, fragment, dma_bufs, fragment_size, fragment_count); if (rv) { dev_err(dev->devc, "prepare DMA buffer failed.\n"); goto out; } do { query.image_size = cpu_to_le32(ish_fw->size); rv = loader_xfer_cmd(dev, &query, sizeof(query), recv_msg.raw_data, sizeof(struct loader_xfer_query_ack)); if (rv) continue; /* try again if failed */ dev_dbg(dev->devc, "ISH Bootloader Version %u.%u.%u.%u\n", recv_msg.query_ack.version_major, recv_msg.query_ack.version_minor, recv_msg.query_ack.version_hotfix, recv_msg.query_ack.version_build); rv = loader_xfer_cmd(dev, fragment, struct_size(fragment, fragment_tbl, fragment_count), recv_msg.raw_data, sizeof(struct loader_xfer_fragment_ack)); if (rv) continue; /* try again if failed */ rv = loader_xfer_cmd(dev, &start, sizeof(start), recv_msg.raw_data, sizeof(struct loader_start_ack)); if (rv) continue; /* try again if failed */ dev_info(dev->devc, "firmware loaded. size:%zu\n", ish_fw->size); if (!copy_manifest(ish_fw, &manifest)) { copy_ish_version(&manifest.base_ver, &dev->base_ver); copy_ish_version(&manifest.prj_ver, &dev->prj_ver); dev_info(dev->devc, "FW base version: %u.%u.%u.%u\n", dev->base_ver.major, dev->base_ver.minor, dev->base_ver.hotfix, dev->base_ver.build); dev_info(dev->devc, "FW project version: %u.%u.%u.%u\n", dev->prj_ver.major, dev->prj_ver.minor, dev->prj_ver.hotfix, dev->prj_ver.build); } break; } while (--retry); out: release_dma_bufs(dev, fragment, dma_bufs, fragment_size); release_firmware(ish_fw); }