/* SPDX-License-Identifier: GPL-2.0-only */ /* * This is a ramstage driver for the Intel Management Engine found in the * 6-series chipset. It handles the required boot-time messages over the * MMIO-based Management Engine Interface to tell the ME that the BIOS is * finished with POST. Additional messages are defined for debug but are * not used unless the console loglevel is high enough. */ #include #include #include #include #include #include #include #include #include #include #include #include "chip.h" #include "me.h" #include "pch.h" #include /* Path that the BIOS should take based on ME state */ static const char *const me_bios_path_values[] = { [ME_NORMAL_BIOS_PATH] = "Normal", [ME_S3WAKE_BIOS_PATH] = "S3 Wake", [ME_ERROR_BIOS_PATH] = "Error", [ME_RECOVERY_BIOS_PATH] = "Recovery", [ME_DISABLE_BIOS_PATH] = "Disable", [ME_FIRMWARE_UPDATE_BIOS_PATH] = "Firmware Update", }; /* MMIO base address for MEI interface */ static u8 *mei_base_address; static void mei_dump(u32 dword, int offset, const char *type) { union mei_csr csr; if (!CONFIG(DEBUG_INTEL_ME)) return; printk(BIOS_SPEW, "%-9s[%02x] : ", type, offset); switch (offset) { case MEI_H_CSR: case MEI_ME_CSR_HA: csr.raw = dword; printk(BIOS_SPEW, "cbd=%u cbrp=%02u cbwp=%02u ready=%u " "reset=%u ig=%u is=%u ie=%u\n", csr.buffer_depth, csr.buffer_read_ptr, csr.buffer_write_ptr, csr.ready, csr.reset, csr.interrupt_generate, csr.interrupt_status, csr.interrupt_enable); break; case MEI_ME_CB_RW: case MEI_H_CB_WW: printk(BIOS_SPEW, "CB: 0x%08x\n", dword); break; default: printk(BIOS_SPEW, "0x%08x\n", offset); break; } } /* * ME/MEI access helpers using memcpy to avoid aliasing. */ static inline union mei_csr read_host_csr(void) { union mei_csr csr = { .raw = read32(mei_base_address + MEI_H_CSR) }; mei_dump(csr.raw, MEI_H_CSR, "READ"); return csr; } static inline void write_host_csr(union mei_csr csr) { write32(mei_base_address + MEI_H_CSR, csr.raw); mei_dump(csr.raw, MEI_H_CSR, "WRITE"); } static inline union mei_csr read_me_csr(void) { union mei_csr csr = { .raw = read32(mei_base_address + MEI_ME_CSR_HA) }; mei_dump(csr.raw, MEI_ME_CSR_HA, "READ"); return csr; } static inline void write_cb(u32 dword) { write32(mei_base_address + MEI_H_CB_WW, dword); mei_dump(dword, MEI_H_CB_WW, "WRITE"); } static inline u32 read_cb(void) { u32 dword = read32(mei_base_address + MEI_ME_CB_RW); mei_dump(dword, MEI_ME_CB_RW, "READ"); return dword; } /* Wait for ME ready bit to be asserted */ static int mei_wait_for_me_ready(void) { union mei_csr me; unsigned int try = ME_RETRY; while (try--) { me = read_me_csr(); if (me.ready) return 0; udelay(ME_DELAY); } printk(BIOS_ERR, "ME: failed to become ready\n"); return -1; } static void mei_reset(void) { union mei_csr host; if (mei_wait_for_me_ready() < 0) return; /* Reset host and ME circular buffers for next message */ host = read_host_csr(); host.reset = 1; host.interrupt_generate = 1; write_host_csr(host); if (mei_wait_for_me_ready() < 0) return; /* Re-init and indicate host is ready */ host = read_host_csr(); host.interrupt_generate = 1; host.ready = 1; host.reset = 0; write_host_csr(host); } static int mei_send_packet(union mei_header *mei, void *req_data) { union mei_csr host; unsigned int ndata, n; u32 *data; /* Number of dwords to write */ ndata = mei->length >> 2; /* Pad non-dword aligned request message length */ if (mei->length & 3) ndata++; if (!ndata) { printk(BIOS_DEBUG, "ME: request has no data\n"); return -1; } ndata++; /* Add MEI header */ /* * Make sure there is still room left in the circular buffer. * Reset the buffer pointers if the requested message will not fit. */ host = read_host_csr(); if ((host.buffer_depth - host.buffer_write_ptr) < ndata) { printk(BIOS_ERR, "ME: circular buffer full, resetting...\n"); mei_reset(); host = read_host_csr(); } /* Ensure the requested length will fit in the circular buffer. */ if ((host.buffer_depth - host.buffer_write_ptr) < ndata) { printk(BIOS_ERR, "ME: message (%u) too large for buffer (%u)\n", ndata + 2, host.buffer_depth); return -1; } /* Write MEI header */ write_cb(mei->raw); ndata--; /* Write message data */ data = req_data; for (n = 0; n < ndata; ++n) write_cb(*data++); /* Generate interrupt to the ME */ host = read_host_csr(); host.interrupt_generate = 1; write_host_csr(host); /* Make sure ME is ready after sending request data */ return mei_wait_for_me_ready(); } static int mei_send_data(u8 me_address, u8 host_address, void *req_data, int req_bytes) { union mei_header header = { .client_address = me_address, .host_address = host_address, }; union mei_csr host; int current = 0; u8 *req_ptr = req_data; while (!header.is_complete) { int remain = req_bytes - current; int buf_len; host = read_host_csr(); buf_len = host.buffer_depth - host.buffer_write_ptr; if (buf_len > remain) { /* Send all remaining data as final message */ header.length = req_bytes - current; header.is_complete = 1; } else { /* Send as much data as the buffer can hold */ header.length = buf_len; } mei_send_packet(&header, req_ptr); req_ptr += header.length; current += header.length; } return 0; } static int mei_send_header(u8 me_address, u8 host_address, void *header, int header_len, int complete) { union mei_header mei = { .client_address = me_address, .host_address = host_address, .length = header_len, .is_complete = complete, }; return mei_send_packet(&mei, header); } static int mei_recv_msg(void *header, int header_bytes, void *rsp_data, int rsp_bytes) { union mei_header mei_rsp; union mei_csr me, host; unsigned int ndata, n; unsigned int expected; u32 *data; /* Total number of dwords to read from circular buffer */ expected = (rsp_bytes + sizeof(mei_rsp) + header_bytes) >> 2; if (rsp_bytes & 3) expected++; if (mei_wait_for_me_ready() < 0) return -1; /* * The interrupt status bit does not appear to indicate that the * message has actually been received. Instead we wait until the * expected number of dwords are present in the circular buffer. */ for (n = ME_RETRY; n; --n) { me = read_me_csr(); if ((me.buffer_write_ptr - me.buffer_read_ptr) >= expected) break; udelay(ME_DELAY); } if (!n) { printk(BIOS_ERR, "ME: timeout waiting for data: expected " "%u, available %u\n", expected, me.buffer_write_ptr - me.buffer_read_ptr); return -1; } /* Read and verify MEI response header from the ME */ mei_rsp.raw = read_cb(); if (!mei_rsp.is_complete) { printk(BIOS_ERR, "ME: response is not complete\n"); return -1; } /* Handle non-dword responses and expect at least the header */ ndata = mei_rsp.length >> 2; if (mei_rsp.length & 3) ndata++; if (ndata != (expected - 1)) { printk(BIOS_ERR, "ME: response is missing data %d != %d\n", ndata, (expected - 1)); return -1; } /* Read response header from the ME */ data = header; for (n = 0; n < (header_bytes >> 2); ++n) *data++ = read_cb(); ndata -= header_bytes >> 2; /* Make sure caller passed a buffer with enough space */ if (ndata != (rsp_bytes >> 2)) { printk(BIOS_ERR, "ME: not enough room in response buffer: " "%u != %u\n", ndata, rsp_bytes >> 2); return -1; } /* Read response data from the circular buffer */ data = rsp_data; for (n = 0; n < ndata; ++n) *data++ = read_cb(); /* Tell the ME that we have consumed the response */ host = read_host_csr(); host.interrupt_status = 1; host.interrupt_generate = 1; write_host_csr(host); return mei_wait_for_me_ready(); } static inline int mei_sendrecv_mkhi(struct mkhi_header *mkhi, void *req_data, int req_bytes, void *rsp_data, int rsp_bytes) { struct mkhi_header mkhi_rsp; /* Send header */ if (mei_send_header(MEI_ADDRESS_MKHI, MEI_HOST_ADDRESS, mkhi, sizeof(*mkhi), req_bytes ? 0 : 1) < 0) return -1; /* Send data if available */ if (req_bytes && mei_send_data(MEI_ADDRESS_MKHI, MEI_HOST_ADDRESS, req_data, req_bytes) < 0) return -1; /* Return now if no response expected */ if (!rsp_bytes) return 0; /* Read header and data */ if (mei_recv_msg(&mkhi_rsp, sizeof(mkhi_rsp), rsp_data, rsp_bytes) < 0) return -1; if (!mkhi_rsp.is_response || mkhi->group_id != mkhi_rsp.group_id || mkhi->command != mkhi_rsp.command) { printk(BIOS_ERR, "ME: invalid response, group %u ?= %u," "command %u ?= %u, is_response %u\n", mkhi->group_id, mkhi_rsp.group_id, mkhi->command, mkhi_rsp.command, mkhi_rsp.is_response); return -1; } return 0; } static inline int mei_sendrecv_icc(struct icc_header *icc, void *req_data, int req_bytes, void *rsp_data, int rsp_bytes) { struct icc_header icc_rsp; /* Send header */ if (mei_send_header(MEI_ADDRESS_ICC, MEI_HOST_ADDRESS, icc, sizeof(*icc), req_bytes ? 0 : 1) < 0) return -1; /* Send data if available */ if (req_bytes && mei_send_data(MEI_ADDRESS_ICC, MEI_HOST_ADDRESS, req_data, req_bytes) < 0) return -1; /* Read header and data, if needed */ if (rsp_bytes && mei_recv_msg(&icc_rsp, sizeof(icc_rsp), rsp_data, rsp_bytes) < 0) return -1; return 0; } /* * mbp give up routine. This path is taken if hfs.mpb_rdy is 0 or the read * state machine on the BIOS end doesn't match the ME's state machine. */ static void intel_me_mbp_give_up(struct device *dev) { union mei_csr csr; pci_write_config32(dev, PCI_ME_H_GS2, PCI_ME_MBP_GIVE_UP); csr = read_host_csr(); csr.reset = 1; csr.interrupt_generate = 1; write_host_csr(csr); } /* * mbp clear routine. This will wait for the ME to indicate that * the MBP has been read and cleared. */ static void intel_me_mbp_clear(struct device *dev) { int count; union me_hfs2 hfs2; /* Wait for the mbp_cleared indicator */ for (count = ME_RETRY; count > 0; --count) { hfs2.raw = pci_read_config32(dev, PCI_ME_HFS2); if (hfs2.mbp_cleared) break; udelay(ME_DELAY); } if (count == 0) { printk(BIOS_WARNING, "ME: Timeout waiting for mbp_cleared\n"); intel_me_mbp_give_up(dev); } else { printk(BIOS_INFO, "ME: MBP cleared\n"); } } static void me_print_fw_version(struct mbp_fw_version_name *vers_name) { if (!vers_name) { printk(BIOS_ERR, "ME: mbp missing version report\n"); return; } printk(BIOS_DEBUG, "ME: found version %d.%d.%d.%d\n", vers_name->major_version, vers_name->minor_version, vers_name->hotfix_version, vers_name->build_version); } static inline void print_cap(const char *name, int state) { printk(BIOS_DEBUG, "ME Capability: %-41s : %sabled\n", name, state ? " en" : "dis"); } /* Get ME Firmware Capabilities */ static int mkhi_get_fwcaps(struct mbp_mefwcaps *cap) { u32 rule_id = 0; struct me_fwcaps cap_msg; struct mkhi_header mkhi = { .group_id = MKHI_GROUP_ID_FWCAPS, .command = MKHI_FWCAPS_GET_RULE, }; /* Send request and wait for response */ if (mei_sendrecv_mkhi(&mkhi, &rule_id, sizeof(u32), &cap_msg, sizeof(cap_msg)) < 0) { printk(BIOS_ERR, "ME: GET FWCAPS message failed\n"); return -1; } *cap = cap_msg.caps_sku; return 0; } /* Get ME Firmware Capabilities */ static void me_print_fwcaps(struct mbp_mefwcaps *cap) { struct mbp_mefwcaps local_caps; if (!cap) { cap = &local_caps; printk(BIOS_ERR, "ME: mbp missing fwcaps report\n"); if (mkhi_get_fwcaps(cap)) return; } print_cap("Full Network manageability", cap->full_net); print_cap("Regular Network manageability", cap->std_net); print_cap("Manageability", cap->manageability); print_cap("IntelR Anti-Theft (AT)", cap->intel_at); print_cap("IntelR Capability Licensing Service (CLS)", cap->intel_cls); print_cap("IntelR Power Sharing Technology (MPC)", cap->intel_mpc); print_cap("ICC Over Clocking", cap->icc_over_clocking); print_cap("Protected Audio Video Path (PAVP)", cap->pavp); print_cap("IPV6", cap->ipv6); print_cap("KVM Remote Control (KVM)", cap->kvm); print_cap("Outbreak Containment Heuristic (OCH)", cap->och); print_cap("Virtual LAN (VLAN)", cap->vlan); print_cap("TLS", cap->tls); print_cap("Wireless LAN (WLAN)", cap->wlan); } /* Send END OF POST message to the ME */ static int mkhi_end_of_post(void) { struct mkhi_header mkhi = { .group_id = MKHI_GROUP_ID_GEN, .command = MKHI_END_OF_POST, }; u32 eop_ack; /* Send request and wait for response */ printk(BIOS_NOTICE, "ME: %s\n", __func__); if (mei_sendrecv_mkhi(&mkhi, NULL, 0, &eop_ack, sizeof(eop_ack)) < 0) { printk(BIOS_ERR, "ME: END OF POST message failed\n"); return -1; } printk(BIOS_INFO, "ME: END OF POST message successful (%d)\n", eop_ack); return 0; } void intel_me_finalize(struct device *dev) { union me_hfs hfs; u32 reg32; reg32 = pci_read_config32(dev, PCI_BASE_ADDRESS_0); mei_base_address = (u8 *)(uintptr_t)(reg32 & ~PCI_BASE_ADDRESS_MEM_ATTR_MASK); /* S3 path will have hidden this device already */ if (!mei_base_address || mei_base_address == (u8 *)0xfffffff0) return; /* Wait for ME MBP Cleared indicator */ intel_me_mbp_clear(dev); /* Make sure ME is in a mode that expects EOP */ hfs.raw = pci_read_config32(dev, PCI_ME_HFS); /* Abort and leave device alone if not normal mode */ if (hfs.fpt_bad || hfs.working_state != ME_HFS_CWS_NORMAL || hfs.operation_mode != ME_HFS_MODE_NORMAL) return; /* Try to send EOP command so ME stops accepting other commands */ mkhi_end_of_post(); if (!CONFIG(DISABLE_ME_PCI)) return; /* Make sure IO is disabled */ pci_and_config16(dev, PCI_COMMAND, ~(PCI_COMMAND_MASTER | PCI_COMMAND_MEMORY | PCI_COMMAND_IO)); /* Hide the PCI device */ RCBA32_OR(FD2, PCH_DISABLE_MEI1); } static int me_icc_set_clock_enables(u32 mask) { struct icc_clock_enables_msg clk = { .clock_enables = 0, /* Turn off specified clocks */ .clock_mask = mask, .no_response = 1, /* Do not expect response */ }; struct icc_header icc = { .api_version = ICC_API_VERSION_LYNXPOINT, .icc_command = ICC_SET_CLOCK_ENABLES, .length = sizeof(clk), }; /* Send request and wait for response */ if (mei_sendrecv_icc(&icc, &clk, sizeof(clk), NULL, 0) < 0) { printk(BIOS_ERR, "ME: ICC SET CLOCK ENABLES message failed\n"); return -1; } printk(BIOS_INFO, "ME: ICC SET CLOCK ENABLES 0x%08x\n", mask); return 0; } /* Determine the path that we should take based on ME status */ static enum me_bios_path intel_me_path(struct device *dev) { enum me_bios_path path = ME_DISABLE_BIOS_PATH; union me_hfs hfs = { .raw = pci_read_config32(dev, PCI_ME_HFS) }; union me_hfs2 hfs2 = { .raw = pci_read_config32(dev, PCI_ME_HFS2) }; /* Check and dump status */ intel_me_status(hfs, hfs2); /* Check Current Working State */ switch (hfs.working_state) { case ME_HFS_CWS_NORMAL: path = ME_NORMAL_BIOS_PATH; break; case ME_HFS_CWS_REC: path = ME_RECOVERY_BIOS_PATH; break; default: path = ME_DISABLE_BIOS_PATH; break; } /* Check Current Operation Mode */ switch (hfs.operation_mode) { case ME_HFS_MODE_NORMAL: break; case ME_HFS_MODE_DEBUG: case ME_HFS_MODE_DIS: case ME_HFS_MODE_OVER_JMPR: case ME_HFS_MODE_OVER_MEI: default: path = ME_DISABLE_BIOS_PATH; break; } /* Check for any error code and valid firmware and MBP */ if (hfs.error_code || hfs.fpt_bad) path = ME_ERROR_BIOS_PATH; /* Check if the MBP is ready */ if (!hfs2.mbp_rdy) { printk(BIOS_CRIT, "%s: mbp is not ready!\n", __func__); path = ME_ERROR_BIOS_PATH; } if (CONFIG(ELOG) && path != ME_NORMAL_BIOS_PATH) { struct elog_event_data_me_extended data = { .current_working_state = hfs.working_state, .operation_state = hfs.operation_state, .operation_mode = hfs.operation_mode, .error_code = hfs.error_code, .progress_code = hfs2.progress_code, .current_pmevent = hfs2.current_pmevent, .current_state = hfs2.current_state, }; elog_add_event_byte(ELOG_TYPE_MANAGEMENT_ENGINE, path); elog_add_event_raw(ELOG_TYPE_MANAGEMENT_ENGINE_EXT, &data, sizeof(data)); } return path; } /* Prepare ME for MEI messages */ static int intel_mei_setup(struct device *dev) { struct resource *res; union mei_csr host; /* Find the MMIO base for the ME interface */ res = probe_resource(dev, PCI_BASE_ADDRESS_0); if (!res || res->base == 0 || res->size == 0) { printk(BIOS_DEBUG, "ME: MEI resource not present!\n"); return -1; } mei_base_address = res2mmio(res, 0, 0); /* Ensure Memory and Bus Master bits are set */ pci_or_config16(dev, PCI_COMMAND, PCI_COMMAND_MASTER | PCI_COMMAND_MEMORY); /* Clean up status for next message */ host = read_host_csr(); host.interrupt_generate = 1; host.ready = 1; host.reset = 0; write_host_csr(host); return 0; } /* Read the Extend register hash of ME firmware */ static int intel_me_extend_valid(struct device *dev) { union me_heres status = { .raw = pci_read_config32(dev, PCI_ME_HERES) }; u32 extend[8] = {0}; int i, count = 0; if (!status.extend_feature_present) { printk(BIOS_ERR, "ME: Extend Feature not present\n"); return -1; } if (!status.extend_reg_valid) { printk(BIOS_ERR, "ME: Extend Register not valid\n"); return -1; } switch (status.extend_reg_algorithm) { case PCI_ME_EXT_SHA1: count = 5; printk(BIOS_DEBUG, "ME: Extend SHA-1: "); break; case PCI_ME_EXT_SHA256: count = 8; printk(BIOS_DEBUG, "ME: Extend SHA-256: "); break; default: printk(BIOS_ERR, "ME: Extend Algorithm %d unknown\n", status.extend_reg_algorithm); return -1; } for (i = 0; i < count; ++i) { extend[i] = pci_read_config32(dev, PCI_ME_HER(i)); printk(BIOS_DEBUG, "%08x", extend[i]); } printk(BIOS_DEBUG, "\n"); /* Save hash in NVS for the OS to verify */ if (CONFIG(CHROMEOS_NVS)) chromeos_set_me_hash(extend, count); return 0; } static u32 me_to_host_words_pending(void) { union mei_csr me = read_me_csr(); if (!me.ready) return 0; return (me.buffer_write_ptr - me.buffer_read_ptr) & (me.buffer_depth - 1); } struct mbp_payload { union mbp_header header; u32 data[0]; }; /* * Read and print ME MBP data * * Return -1 to indicate a problem (give up) * Return 0 to indicate success (send LOCK+EOP) */ static int intel_me_read_mbp(struct me_bios_payload *mbp_data, struct device *dev) { union mbp_header mbp_hdr; u32 me2host_pending; union mei_csr host; union me_hfs2 hfs2 = { .raw = pci_read_config32(dev, PCI_ME_HFS2) }; struct mbp_payload *mbp; int i; if (!hfs2.mbp_rdy) { printk(BIOS_ERR, "ME: MBP not ready\n"); goto mbp_failure; } me2host_pending = me_to_host_words_pending(); if (!me2host_pending) { printk(BIOS_ERR, "ME: no mbp data!\n"); goto mbp_failure; } /* we know for sure that at least the header is there */ mbp_hdr.raw = read_cb(); if ((mbp_hdr.num_entries > (mbp_hdr.mbp_size / 2)) || (me2host_pending < mbp_hdr.mbp_size)) { printk(BIOS_ERR, "ME: mbp of %d entries, total size %d words" " buffer contains %d words\n", mbp_hdr.num_entries, mbp_hdr.mbp_size, me2host_pending); goto mbp_failure; } mbp = malloc(mbp_hdr.mbp_size * sizeof(u32)); if (!mbp) goto mbp_failure; mbp->header = mbp_hdr; me2host_pending--; i = 0; while (i != me2host_pending) { mbp->data[i] = read_cb(); i++; } /* Signal to the ME that the host has finished reading the MBP. */ host = read_host_csr(); host.interrupt_generate = 1; write_host_csr(host); /* Dump out the MBP contents. */ if (CONFIG_DEFAULT_CONSOLE_LOGLEVEL >= BIOS_DEBUG) { printk(BIOS_INFO, "ME MBP: Header: items: %d, size dw: %d\n", mbp->header.num_entries, mbp->header.mbp_size); if (CONFIG(DEBUG_INTEL_ME)) { for (i = 0; i < mbp->header.mbp_size - 1; i++) { printk(BIOS_INFO, "ME MBP: %04x: 0x%08x\n", i, mbp->data[i]); } } } #define ASSIGN_FIELD_PTR(field_,val_) \ { \ mbp_data->field_ = (typeof(mbp_data->field_))(void *)val_; \ break; \ } /* Setup the pointers in the me_bios_payload structure. */ for (i = 0; i < mbp->header.mbp_size - 1;) { struct mbp_item_header *item = (void *)&mbp->data[i]; switch (MBP_MAKE_IDENT(item->app_id, item->item_id)) { case MBP_IDENT(KERNEL, FW_VER): ASSIGN_FIELD_PTR(fw_version_name, &mbp->data[i+1]); case MBP_IDENT(ICC, PROFILE): ASSIGN_FIELD_PTR(icc_profile, &mbp->data[i+1]); case MBP_IDENT(INTEL_AT, STATE): ASSIGN_FIELD_PTR(at_state, &mbp->data[i+1]); case MBP_IDENT(KERNEL, FW_CAP): ASSIGN_FIELD_PTR(fw_capabilities, &mbp->data[i+1]); case MBP_IDENT(KERNEL, ROM_BIST): ASSIGN_FIELD_PTR(rom_bist_data, &mbp->data[i+1]); case MBP_IDENT(KERNEL, PLAT_KEY): ASSIGN_FIELD_PTR(platform_key, &mbp->data[i+1]); case MBP_IDENT(KERNEL, FW_TYPE): ASSIGN_FIELD_PTR(fw_plat_type, &mbp->data[i+1]); case MBP_IDENT(KERNEL, MFS_FAILURE): ASSIGN_FIELD_PTR(mfsintegrity, &mbp->data[i+1]); case MBP_IDENT(KERNEL, PLAT_TIME): ASSIGN_FIELD_PTR(plat_time, &mbp->data[i+1]); case MBP_IDENT(NFC, SUPPORT_DATA): ASSIGN_FIELD_PTR(nfc_data, &mbp->data[i+1]); default: printk(BIOS_ERR, "ME MBP: unknown item 0x%x @ " "dw offset 0x%x\n", mbp->data[i], i); break; } i += item->length; } #undef ASSIGN_FIELD_PTR return 0; mbp_failure: intel_me_mbp_give_up(dev); return -1; } /* Check whether ME is present and do basic init */ static void intel_me_init(struct device *dev) { struct southbridge_intel_lynxpoint_config *config = dev->chip_info; enum me_bios_path path = intel_me_path(dev); struct me_bios_payload mbp_data; /* Do initial setup and determine the BIOS path */ printk(BIOS_NOTICE, "ME: BIOS path: %s\n", me_bios_path_values[path]); if (path == ME_NORMAL_BIOS_PATH) { /* Validate the extend register */ intel_me_extend_valid(dev); } memset(&mbp_data, 0, sizeof(mbp_data)); /* * According to the ME9 BWG, BIOS is required to fetch MBP data in * all boot flows except S3 Resume. */ /* Prepare MEI MMIO interface */ if (intel_mei_setup(dev) < 0) return; if (intel_me_read_mbp(&mbp_data, dev)) return; if (CONFIG_DEFAULT_CONSOLE_LOGLEVEL >= BIOS_DEBUG) { me_print_fw_version(mbp_data.fw_version_name); if (CONFIG(DEBUG_INTEL_ME)) me_print_fwcaps(mbp_data.fw_capabilities); if (mbp_data.plat_time) { printk(BIOS_DEBUG, "ME: Wake Event to ME Reset: %u ms\n", mbp_data.plat_time->wake_event_mrst_time_ms); printk(BIOS_DEBUG, "ME: ME Reset to Platform Reset: %u ms\n", mbp_data.plat_time->mrst_pltrst_time_ms); printk(BIOS_DEBUG, "ME: Platform Reset to CPU Reset: %u ms\n", mbp_data.plat_time->pltrst_cpurst_time_ms); } } /* Set clock enables according to devicetree */ if (config && config->icc_clock_disable) me_icc_set_clock_enables(config->icc_clock_disable); /* * Leave the ME unlocked. It will be locked later. */ } static void intel_me_enable(struct device *dev) { /* Avoid talking to the device in S3 path */ if (acpi_is_wakeup_s3() && CONFIG(DISABLE_ME_PCI)) { dev->enabled = 0; pch_disable_devfn(dev); } } static struct device_operations device_ops = { .read_resources = pci_dev_read_resources, .set_resources = pci_dev_set_resources, .enable_resources = pci_dev_enable_resources, .enable = intel_me_enable, .init = intel_me_init, .final = intel_me_finalize, .ops_pci = &pci_dev_ops_pci, }; static const unsigned short pci_device_ids[] = { PCI_DID_INTEL_LPT_H_MEI, PCI_DID_INTEL_LPT_LP_MEI, 0 }; static const struct pci_driver intel_me __pci_driver = { .ops = &device_ops, .vendor = PCI_VID_INTEL, .devices = pci_device_ids, };