/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #include #define CONTROL_INTERFACE_OFFSET 0x5 #define CRASHLOG_PUNIT_STORAGE_OFF_MASK BIT(24) #define CRASHLOG_RE_ARM_STATUS_MASK BIT(25) #define CRASHLOG_CONSUMED_MASK BIT(31) /* global crashLog info */ static bool m_pmc_crashLog_support; static bool m_pmc_crashLog_present; static bool m_cpu_crashLog_support; static bool m_cpu_crashLog_present; static u32 m_pmc_crashLog_size; static u32 m_cpu_crashLog_size; static u32 cpu_crash_version; static pmc_ipc_discovery_buf_t discovery_buf; static pmc_crashlog_desc_table_t descriptor_table; static tel_crashlog_devsc_cap_t cpu_cl_devsc_cap; static cpu_crashlog_discovery_table_t cpu_cl_disc_tab; static u32 disc_tab_addr; static u64 get_disc_tab_header(void) { return read64((void *)(uintptr_t)disc_tab_addr); } /* Get the SRAM BAR. */ static uintptr_t get_sram_bar(pci_devfn_t sram_devfn) { uintptr_t sram_bar; const struct device *dev; struct resource *res; dev = pcidev_path_on_root(sram_devfn); if (!dev) { printk(BIOS_ERR, "device: 0x%x not found!\n", sram_devfn); return 0; } res = probe_resource(dev, PCI_BASE_ADDRESS_0); if (!res) { printk(BIOS_ERR, "SOC SRAM device not found!\n"); return 0; } /* Get the base address of the resource */ sram_bar = res->base; return sram_bar; } static void configure_sram(const struct device *sram_dev, u32 base_addr) { pci_update_config16(sram_dev, PCI_COMMAND, ~(PCI_COMMAND_IO | PCI_COMMAND_MEMORY), 0); /* Program BAR 0 and enable command register memory space decoding */ pci_write_config32(sram_dev, PCI_BASE_ADDRESS_0, base_addr); pci_or_config16(sram_dev, PCI_COMMAND, PCI_COMMAND_MEMORY); } void cl_get_pmc_sram_data(cl_node_t *head) { u32 pmc_sram_base = cl_get_cpu_tmp_bar(); u32 ioe_sram_base = get_sram_bar(PCI_DEVFN_IOE_SRAM); u32 pmc_crashLog_size = cl_get_pmc_record_size(); cl_node_t *cl_cur = head; if (!pmc_crashLog_size) { printk(BIOS_ERR, "No PMC crashlog records\n"); return; } if (!pmc_sram_base) { printk(BIOS_ERR, "PMC SRAM base not valid\n"); return; } if (!ioe_sram_base) { printk(BIOS_ERR, "IOE SRAM base not valid\n"); return; } configure_sram(PCI_DEV_IOE_SRAM, ioe_sram_base); if (!cl_pmc_sram_has_mmio_access()) return; if (!cl_ioe_sram_has_mmio_access()) return; printk(BIOS_DEBUG, "PMC crashLog size : 0x%x\n", pmc_crashLog_size); /* goto tail node */ while (cl_cur && cl_cur->next) { cl_cur = cl_cur->next; } /* process crashlog records */ for (int i = 0; i < descriptor_table.numb_regions + 1; i++) { u32 sram_base = 0; bool pmc_sram = true; printk(BIOS_DEBUG, "Region[0x%x].Tag=0x%x offset=0x%x, size=0x%x\n", i, descriptor_table.regions[i].bits.assign_tag, descriptor_table.regions[i].bits.offset, descriptor_table.regions[i].bits.size); if (!descriptor_table.regions[i].bits.size) continue; /* * Region with metadata TAG contains information about BDF entry for SOC PMC SRAM * and IOE SRAM. We don't need to parse this as we already define BDFs in * soc/pci_devs.h for these SRAMs. Also we need to skip this region as it does not * contain any crashlog data. */ if (descriptor_table.regions[i].bits.assign_tag == CRASHLOG_DESCRIPTOR_TABLE_TAG_META) { pmc_crashLog_size -= descriptor_table.regions[i].bits.size * sizeof(u32); printk(BIOS_DEBUG, "Found metadata tag. PMC crashlog size adjusted to: 0x%x\n", pmc_crashLog_size); continue; } else { if (descriptor_table.regions[i].bits.assign_tag == CRASHLOG_DESCRIPTOR_TABLE_TAG_SOC) sram_base = pmc_sram_base; else if (descriptor_table.regions[i].bits.assign_tag == CRASHLOG_DESCRIPTOR_TABLE_TAG_IOE) sram_base = ioe_sram_base; else continue; cl_node_t *cl_node = malloc_cl_node(descriptor_table.regions[i].bits.size); if (!cl_node) { printk(BIOS_DEBUG, "failed to allocate cl_node [region = %d]\n", i); goto pmc_send_re_arm_after_reset; } if (cl_copy_data_from_sram(sram_base, descriptor_table.regions[i].bits.offset, descriptor_table.regions[i].bits.size, cl_node->data, i, pmc_sram)) { cl_cur->next = cl_node; cl_cur = cl_cur->next; } else { /* coping data from sram failed */ pmc_crashLog_size -= descriptor_table.regions[i].bits.size * sizeof(u32); printk(BIOS_DEBUG, "PMC crashlog size adjusted to: 0x%x\n", pmc_crashLog_size); /* free cl_node */ free_cl_node(cl_node); } } } update_new_pmc_crashlog_size(&pmc_crashLog_size); pmc_send_re_arm_after_reset: /* when bit 7 of discov cmd resp is set -> bit 2 of size field */ cl_pmc_re_arm_after_reset(); /* Clear the SSRAM region after copying the error log */ cl_pmc_clear(); } bool pmc_cl_discovery(void) { u32 bar_addr = 0, desc_table_addr = 0; const struct pmc_ipc_buffer req = { 0 }; struct pmc_ipc_buffer res; uint32_t cmd_reg; int r; cmd_reg = pmc_make_ipc_cmd(PMC_IPC_CMD_CRASHLOG, PMC_IPC_CMD_ID_CRASHLOG_DISCOVERY, PMC_IPC_CMD_SIZE_SHIFT); printk(BIOS_DEBUG, "cmd_reg from pmc_make_ipc_cmd %d in %s\n", cmd_reg, __func__); r = pmc_send_ipc_cmd(cmd_reg, &req, &res); if (r < 0) { printk(BIOS_ERR, "pmc_send_ipc_cmd failed in %s\n", __func__); return false; } discovery_buf.conv_val_64_bits = ((u64)res.buf[1] << 32) | res.buf[0]; if ((discovery_buf.conv_bits64.supported != 1) || (discovery_buf.conv_bits64.discov_mechanism == 0) || (discovery_buf.conv_bits64.crash_dis_sts == 1)) { printk(BIOS_INFO, "PCH crashlog feature not supported.\n"); m_pmc_crashLog_support = false; m_pmc_crashLog_size = 0; printk(BIOS_DEBUG, "discovery_buf supported: %d, mechanism: %d, CrashDisSts: %d\n", discovery_buf.conv_bits64.supported, discovery_buf.conv_bits64.discov_mechanism, discovery_buf.conv_bits64.crash_dis_sts); return false; } printk(BIOS_INFO, "PMC crashlog feature is supported.\n"); m_pmc_crashLog_support = true; /* Program BAR 0 and enable command register memory space decoding */ bar_addr = get_sram_bar(PCI_DEVFN_SRAM); if (bar_addr == 0) { printk(BIOS_ERR, "PCH SRAM not available, crashlog feature can't be enabled.\n"); return false; } configure_sram(PCI_DEV_SRAM, bar_addr); desc_table_addr = bar_addr + discovery_buf.conv_bits64.desc_tabl_offset; m_pmc_crashLog_size = pmc_cl_gen_descriptor_table(desc_table_addr, &descriptor_table); printk(BIOS_DEBUG, "PMC CrashLog size in discovery mode: 0x%X\n", m_pmc_crashLog_size); m_pmc_crashLog_present = m_pmc_crashLog_size > 0; return true; } u32 cl_get_cpu_bar_addr(void) { u32 base_addr = 0; if (cpu_cl_devsc_cap.discovery_data.fields.t_bir_q == TEL_DVSEC_TBIR_BAR0) { base_addr = pci_read_config32(PCI_DEV_TELEMETRY, PCI_BASE_ADDRESS_0) & ~PCI_BASE_ADDRESS_MEM_ATTR_MASK; } else if (cpu_cl_devsc_cap.discovery_data.fields.t_bir_q == TEL_DVSEC_TBIR_BAR1) { base_addr = pci_read_config32(PCI_DEV_TELEMETRY, PCI_BASE_ADDRESS_1) & ~PCI_BASE_ADDRESS_MEM_ATTR_MASK; } else { printk(BIOS_ERR, "Invalid TEL_CFG_BAR value %d, discovery failure expected.\n", cpu_cl_devsc_cap.discovery_data.fields.t_bir_q); } return base_addr; } u32 cl_get_cpu_tmp_bar(void) { return get_sram_bar(PCI_DEVFN_SRAM); } bool cl_pmc_sram_has_mmio_access(void) { if (pci_read_config16(PCI_DEV_SRAM, PCI_VENDOR_ID) == 0xFFFF) { printk(BIOS_ERR, "PMC SSRAM PCI device disabled. Can be enabled in device tree.\n"); return false; } return true; } bool cl_ioe_sram_has_mmio_access(void) { if (pci_read_config16(PCI_DEV_IOE_SRAM, PCI_VENDOR_ID) == 0xFFFF) { printk(BIOS_ERR, "IOE SSRAM PCI device disabled. Can be enabled in device tree.\n"); return false; } return true; } static bool cpu_cl_get_capability(tel_crashlog_devsc_cap_t *cl_devsc_cap) { cl_devsc_cap->cap_data.data = pci_read_config32(PCI_DEV_TELEMETRY, TEL_DVSEC_OFFSET + TEL_DVSEC_PCIE_CAP_ID); if (cl_devsc_cap->cap_data.fields.pcie_cap_id != TELEMETRY_EXTENDED_CAP_ID) { printk(BIOS_DEBUG, "Read ID for Telemetry: 0x%x differs from expected: 0x%x\n", cl_devsc_cap->cap_data.fields.pcie_cap_id, TELEMETRY_EXTENDED_CAP_ID); return false; } /* walk through the entries until crashLog entry */ cl_devsc_cap->devsc_data.data_32[1] = pci_read_config32(PCI_DEV_TELEMETRY, TEL_DVSEV_ID); int new_offset = 0; while (cl_devsc_cap->devsc_data.fields.devsc_id != CRASHLOG_DVSEC_ID) { if (cl_devsc_cap->cap_data.fields.next_cap_offset == 0 || cl_devsc_cap->cap_data.fields.next_cap_offset == 0xFFFF) { printk(BIOS_DEBUG, "Read invalid pcie_cap_id value: 0x%x\n", cl_devsc_cap->cap_data.fields.pcie_cap_id); return false; } new_offset = cl_devsc_cap->cap_data.fields.next_cap_offset; cl_devsc_cap->cap_data.data = pci_read_config32(PCI_DEV_TELEMETRY, new_offset + TEL_DVSEC_PCIE_CAP_ID); cl_devsc_cap->devsc_data.data_32[1] = pci_read_config32(PCI_DEV_TELEMETRY, new_offset + TEL_DVSEV_ID); } cpu_crash_version = cl_devsc_cap->devsc_data.fields.devsc_ver; cl_devsc_cap->discovery_data.data = pci_read_config32(PCI_DEV_TELEMETRY, new_offset + TEL_DVSEV_DISCOVERY_TABLE_OFFSET); return true; } static u32 get_disc_table_offset(void) { u32 offset = cpu_cl_devsc_cap.discovery_data.fields.discovery_table_offset; if (cpu_get_cpuid() >= CPUID_METEORLAKE_B0) { offset <<= 3; printk(BIOS_DEBUG, "adjusted cpu discovery table offset: 0x%x\n", offset); } return offset; } static bool is_crashlog_data_valid(u32 dw0) { return (dw0 != 0x0 && dw0 != INVALID_CRASHLOG_RECORD); } static bool cpu_cl_gen_discovery_table(void) { u32 bar_addr = cl_get_cpu_bar_addr(); if (!bar_addr) return false; disc_tab_addr = bar_addr + get_disc_table_offset(); u32 dw0 = read32((u32 *)(uintptr_t)disc_tab_addr); if (!is_crashlog_data_valid(dw0)) return false; memset(&cpu_cl_disc_tab, 0, sizeof(cpu_crashlog_discovery_table_t)); cpu_cl_disc_tab.header.data = get_disc_tab_header(); printk(BIOS_DEBUG, "cpu_crashlog_discovery_table buffer count: 0x%x\n", cpu_cl_disc_tab.header.fields.count); int cur_offset = 0; for (int i = 0; i < cpu_cl_disc_tab.header.fields.count; i++) { cur_offset = 8 + 24 * i; dw0 = read32((u32 *)(uintptr_t)disc_tab_addr + cur_offset); if (!is_crashlog_data_valid(dw0)) continue; if (dw0 & CRASHLOG_CONSUMED_MASK) { printk(BIOS_DEBUG, "cpu crashlog records already consumed." "id: 0x%x dw0: 0x%x\n", i, dw0); break; } cpu_cl_disc_tab.buffers[i].data = read64((void *)(uintptr_t)(disc_tab_addr + cur_offset)); printk(BIOS_DEBUG, "cpu_crashlog_discovery_table buffer: 0x%x size: " "0x%x offset: 0x%x\n", i, cpu_cl_disc_tab.buffers[i].fields.size, cpu_cl_disc_tab.buffers[i].fields.offset); m_cpu_crashLog_size += cpu_cl_disc_tab.buffers[i].fields.size * sizeof(u32); } if (m_cpu_crashLog_size > 0) m_cpu_crashLog_present = true; else m_cpu_crashLog_present = false; return true; } bool cpu_cl_discovery(void) { memset(&cpu_cl_devsc_cap, 0, sizeof(tel_crashlog_devsc_cap_t)); if (!cpu_cl_get_capability(&cpu_cl_devsc_cap)) { printk(BIOS_ERR, "CPU crashlog capability not found.\n"); m_cpu_crashLog_support = false; return false; } m_cpu_crashLog_support = true; if (!cpu_cl_gen_discovery_table()) { printk(BIOS_ERR, "CPU crashlog discovery table not valid.\n"); m_cpu_crashLog_present = false; return false; } return true; } void reset_discovery_buffers(void) { memset(&discovery_buf, 0, sizeof(pmc_ipc_discovery_buf_t)); memset(&descriptor_table, 0, sizeof(pmc_crashlog_desc_table_t)); memset(&cpu_cl_devsc_cap, 0, sizeof(tel_crashlog_devsc_cap_t)); } int cl_get_total_data_size(void) { printk(BIOS_DEBUG, "crashlog size:pmc-0x%x, cpu-0x%x\n", m_pmc_crashLog_size, m_cpu_crashLog_size); return m_pmc_crashLog_size + m_cpu_crashLog_size; } static u32 get_control_status_interface(void) { if (disc_tab_addr) return (disc_tab_addr + CONTROL_INTERFACE_OFFSET * sizeof(u32)); return 0; } int cpu_cl_clear_data(void) { return 0; } static bool wait_and_check(u32 bit_mask) { u32 stall_cnt = 0; do { cpu_cl_disc_tab.header.data = get_disc_tab_header(); udelay(CPU_CRASHLOG_WAIT_STALL); stall_cnt++; } while (((cpu_cl_disc_tab.header.data & bit_mask) == 0) && ((stall_cnt * CPU_CRASHLOG_WAIT_STALL) < CPU_CRASHLOG_WAIT_TIMEOUT)); return (cpu_cl_disc_tab.header.data & bit_mask); } void cpu_cl_rearm(void) { u32 ctrl_sts_intfc_addr = get_control_status_interface(); if (!ctrl_sts_intfc_addr) { printk(BIOS_ERR, "CPU crashlog control and status interface address not valid\n"); return; } /* Rearm the CPU crashlog. Crashlog does not get collected if rearming fails */ cl_punit_control_interface_t punit_ctrl_intfc; memset(&punit_ctrl_intfc, 0, sizeof(cl_punit_control_interface_t)); punit_ctrl_intfc.fields.set_re_arm = 1; write32((u32 *)(uintptr_t)(ctrl_sts_intfc_addr), punit_ctrl_intfc.data); if (!wait_and_check(CRASHLOG_RE_ARM_STATUS_MASK)) printk(BIOS_ERR, "CPU crashlog re_arm not asserted\n"); else printk(BIOS_DEBUG, "CPU crashlog re_arm asserted\n"); } void cpu_cl_cleanup(void) { /* Perform any SOC specific cleanup after reading the crashlog data from SRAM */ u32 ctrl_sts_intfc_addr = get_control_status_interface(); if (!ctrl_sts_intfc_addr) { printk(BIOS_ERR, "CPU crashlog control and status interface address not valid\n"); return; } /* If storage-off is supported, turn off the PUNIT SRAM * stroage to save power. This clears crashlog records also. */ if (!cpu_cl_disc_tab.header.fields.storage_off_support) { printk(BIOS_INFO, "CPU crashlog storage_off not supported\n"); return; } cl_punit_control_interface_t punit_ctrl_intfc; memset(&punit_ctrl_intfc, 0, sizeof(cl_punit_control_interface_t)); punit_ctrl_intfc.fields.set_storage_off = 1; write32((u32 *)(uintptr_t)(ctrl_sts_intfc_addr), punit_ctrl_intfc.data); if (!wait_and_check(CRASHLOG_PUNIT_STORAGE_OFF_MASK)) printk(BIOS_ERR, "CPU crashlog storage_off not asserted\n"); else printk(BIOS_DEBUG, "CPU crashlog storage_off asserted\n"); } pmc_ipc_discovery_buf_t cl_get_pmc_discovery_buf(void) { return discovery_buf; } pmc_crashlog_desc_table_t cl_get_pmc_descriptor_table(void) { return descriptor_table; } int cl_get_pmc_record_size(void) { return m_pmc_crashLog_size; } int cl_get_cpu_record_size(void) { return m_cpu_crashLog_size; } bool cl_cpu_data_present(void) { return m_cpu_crashLog_present; } bool cl_pmc_data_present(void) { return m_pmc_crashLog_present; } bool cpu_crashlog_support(void) { return m_cpu_crashLog_support; } bool pmc_crashlog_support(void) { return m_pmc_crashLog_support; } void update_new_pmc_crashlog_size(u32 *pmc_crash_size) { m_pmc_crashLog_size = *pmc_crash_size; } cpu_crashlog_discovery_table_t cl_get_cpu_discovery_table(void) { return cpu_cl_disc_tab; } void update_new_cpu_crashlog_size(u32 *cpu_crash_size) { m_cpu_crashLog_size = *cpu_crash_size; }