// SPDX-License-Identifier: GPL-2.0-or-later /* * Firmware Assisted dump: A robust mechanism to get reliable kernel crash * dump with assistance from firmware. This approach does not use kexec, * instead firmware assists in booting the kdump kernel while preserving * memory contents. The most of the code implementation has been adapted * from phyp assisted dump implementation written by Linas Vepstas and * Manish Ahuja * * Copyright 2011 IBM Corporation * Author: Mahesh Salgaonkar */ #undef DEBUG #define pr_fmt(fmt) "fadump: " fmt #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * The CPU who acquired the lock to trigger the fadump crash should * wait for other CPUs to enter. * * The timeout is in milliseconds. */ #define CRASH_TIMEOUT 500 static struct fw_dump fw_dump; static void __init fadump_reserve_crash_area(u64 base); #ifndef CONFIG_PRESERVE_FA_DUMP static struct kobject *fadump_kobj; static atomic_t cpus_in_fadump; static DEFINE_MUTEX(fadump_mutex); #define RESERVED_RNGS_SZ 16384 /* 16K - 128 entries */ #define RESERVED_RNGS_CNT (RESERVED_RNGS_SZ / \ sizeof(struct fadump_memory_range)) static struct fadump_memory_range rngs[RESERVED_RNGS_CNT]; static struct fadump_mrange_info reserved_mrange_info = { "reserved", rngs, RESERVED_RNGS_SZ, 0, RESERVED_RNGS_CNT, true }; static void __init early_init_dt_scan_reserved_ranges(unsigned long node); #ifdef CONFIG_CMA static struct cma *fadump_cma; /* * fadump_cma_init() - Initialize CMA area from a fadump reserved memory * * This function initializes CMA area from fadump reserved memory. * The total size of fadump reserved memory covers for boot memory size * + cpu data size + hpte size and metadata. * Initialize only the area equivalent to boot memory size for CMA use. * The remaining portion of fadump reserved memory will be not given * to CMA and pages for those will stay reserved. boot memory size is * aligned per CMA requirement to satisy cma_init_reserved_mem() call. * But for some reason even if it fails we still have the memory reservation * with us and we can still continue doing fadump. */ void __init fadump_cma_init(void) { unsigned long long base, size, end; int rc; if (!fw_dump.fadump_supported || !fw_dump.fadump_enabled || fw_dump.dump_active) return; /* * Do not use CMA if user has provided fadump=nocma kernel parameter. */ if (fw_dump.nocma || !fw_dump.boot_memory_size) return; /* * [base, end) should be reserved during early init in * fadump_reserve_mem(). No need to check this here as * cma_init_reserved_mem() already checks for overlap. * Here we give the aligned chunk of this reserved memory to CMA. */ base = fw_dump.reserve_dump_area_start; size = fw_dump.boot_memory_size; end = base + size; base = ALIGN(base, CMA_MIN_ALIGNMENT_BYTES); end = ALIGN_DOWN(end, CMA_MIN_ALIGNMENT_BYTES); size = end - base; if (end <= base) { pr_warn("%s: Too less memory to give to CMA\n", __func__); return; } rc = cma_init_reserved_mem(base, size, 0, "fadump_cma", &fadump_cma); if (rc) { pr_err("Failed to init cma area for firmware-assisted dump,%d\n", rc); /* * Though the CMA init has failed we still have memory * reservation with us. The reserved memory will be * blocked from production system usage. Hence return 1, * so that we can continue with fadump. */ return; } /* * If CMA activation fails, keep the pages reserved, instead of * exposing them to buddy allocator. Same as 'fadump=nocma' case. */ cma_reserve_pages_on_error(fadump_cma); /* * So we now have successfully initialized cma area for fadump. */ pr_info("Initialized [0x%llx, %luMB] cma area from [0x%lx, %luMB] " "bytes of memory reserved for firmware-assisted dump\n", cma_get_base(fadump_cma), cma_get_size(fadump_cma) >> 20, fw_dump.reserve_dump_area_start, fw_dump.boot_memory_size >> 20); return; } #endif /* CONFIG_CMA */ /* * Additional parameters meant for capture kernel are placed in a dedicated area. * If this is capture kernel boot, append these parameters to bootargs. */ void __init fadump_append_bootargs(void) { char *append_args; size_t len; if (!fw_dump.dump_active || !fw_dump.param_area_supported || !fw_dump.param_area) return; if (fw_dump.param_area < fw_dump.boot_mem_top) { if (memblock_reserve(fw_dump.param_area, COMMAND_LINE_SIZE)) { pr_warn("WARNING: Can't use additional parameters area!\n"); fw_dump.param_area = 0; return; } } append_args = (char *)fw_dump.param_area; len = strlen(boot_command_line); /* * Too late to fail even if cmdline size exceeds. Truncate additional parameters * to cmdline size and proceed anyway. */ if (len + strlen(append_args) >= COMMAND_LINE_SIZE - 1) pr_warn("WARNING: Appending parameters exceeds cmdline size. Truncating!\n"); pr_debug("Cmdline: %s\n", boot_command_line); snprintf(boot_command_line + len, COMMAND_LINE_SIZE - len, " %s", append_args); pr_info("Updated cmdline: %s\n", boot_command_line); } /* Scan the Firmware Assisted dump configuration details. */ int __init early_init_dt_scan_fw_dump(unsigned long node, const char *uname, int depth, void *data) { if (depth == 0) { early_init_dt_scan_reserved_ranges(node); return 0; } if (depth != 1) return 0; if (strcmp(uname, "rtas") == 0) { rtas_fadump_dt_scan(&fw_dump, node); return 1; } if (strcmp(uname, "ibm,opal") == 0) { opal_fadump_dt_scan(&fw_dump, node); return 1; } return 0; } /* * If fadump is registered, check if the memory provided * falls within boot memory area and reserved memory area. */ int is_fadump_memory_area(u64 addr, unsigned long size) { u64 d_start, d_end; if (!fw_dump.dump_registered) return 0; if (!size) return 0; d_start = fw_dump.reserve_dump_area_start; d_end = d_start + fw_dump.reserve_dump_area_size; if (((addr + size) > d_start) && (addr <= d_end)) return 1; return (addr <= fw_dump.boot_mem_top); } int should_fadump_crash(void) { if (!fw_dump.dump_registered || !fw_dump.fadumphdr_addr) return 0; return 1; } int is_fadump_active(void) { return fw_dump.dump_active; } /* * Returns true, if there are no holes in memory area between d_start to d_end, * false otherwise. */ static bool is_fadump_mem_area_contiguous(u64 d_start, u64 d_end) { phys_addr_t reg_start, reg_end; bool ret = false; u64 i, start, end; for_each_mem_range(i, ®_start, ®_end) { start = max_t(u64, d_start, reg_start); end = min_t(u64, d_end, reg_end); if (d_start < end) { /* Memory hole from d_start to start */ if (start > d_start) break; if (end == d_end) { ret = true; break; } d_start = end + 1; } } return ret; } /* * Returns true, if there are no holes in reserved memory area, * false otherwise. */ bool is_fadump_reserved_mem_contiguous(void) { u64 d_start, d_end; d_start = fw_dump.reserve_dump_area_start; d_end = d_start + fw_dump.reserve_dump_area_size; return is_fadump_mem_area_contiguous(d_start, d_end); } /* Print firmware assisted dump configurations for debugging purpose. */ static void __init fadump_show_config(void) { int i; pr_debug("Support for firmware-assisted dump (fadump): %s\n", (fw_dump.fadump_supported ? "present" : "no support")); if (!fw_dump.fadump_supported) return; pr_debug("Fadump enabled : %s\n", (fw_dump.fadump_enabled ? "yes" : "no")); pr_debug("Dump Active : %s\n", (fw_dump.dump_active ? "yes" : "no")); pr_debug("Dump section sizes:\n"); pr_debug(" CPU state data size: %lx\n", fw_dump.cpu_state_data_size); pr_debug(" HPTE region size : %lx\n", fw_dump.hpte_region_size); pr_debug(" Boot memory size : %lx\n", fw_dump.boot_memory_size); pr_debug(" Boot memory top : %llx\n", fw_dump.boot_mem_top); pr_debug("Boot memory regions cnt: %llx\n", fw_dump.boot_mem_regs_cnt); for (i = 0; i < fw_dump.boot_mem_regs_cnt; i++) { pr_debug("[%03d] base = %llx, size = %llx\n", i, fw_dump.boot_mem_addr[i], fw_dump.boot_mem_sz[i]); } } /** * fadump_calculate_reserve_size(): reserve variable boot area 5% of System RAM * * Function to find the largest memory size we need to reserve during early * boot process. This will be the size of the memory that is required for a * kernel to boot successfully. * * This function has been taken from phyp-assisted dump feature implementation. * * returns larger of 256MB or 5% rounded down to multiples of 256MB. * * TODO: Come up with better approach to find out more accurate memory size * that is required for a kernel to boot successfully. * */ static __init u64 fadump_calculate_reserve_size(void) { u64 base, size, bootmem_min; int ret; if (fw_dump.reserve_bootvar) pr_warn("'fadump_reserve_mem=' parameter is deprecated in favor of 'crashkernel=' parameter.\n"); /* * Check if the size is specified through crashkernel= cmdline * option. If yes, then use that but ignore base as fadump reserves * memory at a predefined offset. */ ret = parse_crashkernel(boot_command_line, memblock_phys_mem_size(), &size, &base, NULL, NULL); if (ret == 0 && size > 0) { unsigned long max_size; if (fw_dump.reserve_bootvar) pr_info("Using 'crashkernel=' parameter for memory reservation.\n"); fw_dump.reserve_bootvar = (unsigned long)size; /* * Adjust if the boot memory size specified is above * the upper limit. */ max_size = memblock_phys_mem_size() / MAX_BOOT_MEM_RATIO; if (fw_dump.reserve_bootvar > max_size) { fw_dump.reserve_bootvar = max_size; pr_info("Adjusted boot memory size to %luMB\n", (fw_dump.reserve_bootvar >> 20)); } return fw_dump.reserve_bootvar; } else if (fw_dump.reserve_bootvar) { /* * 'fadump_reserve_mem=' is being used to reserve memory * for firmware-assisted dump. */ return fw_dump.reserve_bootvar; } /* divide by 20 to get 5% of value */ size = memblock_phys_mem_size() / 20; /* round it down in multiples of 256 */ size = size & ~0x0FFFFFFFUL; /* Truncate to memory_limit. We don't want to over reserve the memory.*/ if (memory_limit && size > memory_limit) size = memory_limit; bootmem_min = fw_dump.ops->fadump_get_bootmem_min(); return (size > bootmem_min ? size : bootmem_min); } /* * Calculate the total memory size required to be reserved for * firmware-assisted dump registration. */ static unsigned long __init get_fadump_area_size(void) { unsigned long size = 0; size += fw_dump.cpu_state_data_size; size += fw_dump.hpte_region_size; /* * Account for pagesize alignment of boot memory area destination address. * This faciliates in mmap reading of first kernel's memory. */ size = PAGE_ALIGN(size); size += fw_dump.boot_memory_size; size += sizeof(struct fadump_crash_info_header); /* This is to hold kernel metadata on platforms that support it */ size += (fw_dump.ops->fadump_get_metadata_size ? fw_dump.ops->fadump_get_metadata_size() : 0); return size; } static int __init add_boot_mem_region(unsigned long rstart, unsigned long rsize) { int max_boot_mem_rgns = fw_dump.ops->fadump_max_boot_mem_rgns(); int i = fw_dump.boot_mem_regs_cnt++; if (fw_dump.boot_mem_regs_cnt > max_boot_mem_rgns) { fw_dump.boot_mem_regs_cnt = max_boot_mem_rgns; return 0; } pr_debug("Added boot memory range[%d] [%#016lx-%#016lx)\n", i, rstart, (rstart + rsize)); fw_dump.boot_mem_addr[i] = rstart; fw_dump.boot_mem_sz[i] = rsize; return 1; } /* * Firmware usually has a hard limit on the data it can copy per region. * Honour that by splitting a memory range into multiple regions. */ static int __init add_boot_mem_regions(unsigned long mstart, unsigned long msize) { unsigned long rstart, rsize, max_size; int ret = 1; rstart = mstart; max_size = fw_dump.max_copy_size ? fw_dump.max_copy_size : msize; while (msize) { if (msize > max_size) rsize = max_size; else rsize = msize; ret = add_boot_mem_region(rstart, rsize); if (!ret) break; msize -= rsize; rstart += rsize; } return ret; } static int __init fadump_get_boot_mem_regions(void) { unsigned long size, cur_size, hole_size, last_end; unsigned long mem_size = fw_dump.boot_memory_size; phys_addr_t reg_start, reg_end; int ret = 1; u64 i; fw_dump.boot_mem_regs_cnt = 0; last_end = 0; hole_size = 0; cur_size = 0; for_each_mem_range(i, ®_start, ®_end) { size = reg_end - reg_start; hole_size += (reg_start - last_end); if ((cur_size + size) >= mem_size) { size = (mem_size - cur_size); ret = add_boot_mem_regions(reg_start, size); break; } mem_size -= size; cur_size += size; ret = add_boot_mem_regions(reg_start, size); if (!ret) break; last_end = reg_end; } fw_dump.boot_mem_top = PAGE_ALIGN(fw_dump.boot_memory_size + hole_size); return ret; } /* * Returns true, if the given range overlaps with reserved memory ranges * starting at idx. Also, updates idx to index of overlapping memory range * with the given memory range. * False, otherwise. */ static bool __init overlaps_reserved_ranges(u64 base, u64 end, int *idx) { bool ret = false; int i; for (i = *idx; i < reserved_mrange_info.mem_range_cnt; i++) { u64 rbase = reserved_mrange_info.mem_ranges[i].base; u64 rend = rbase + reserved_mrange_info.mem_ranges[i].size; if (end <= rbase) break; if ((end > rbase) && (base < rend)) { *idx = i; ret = true; break; } } return ret; } /* * Locate a suitable memory area to reserve memory for FADump. While at it, * lookup reserved-ranges & avoid overlap with them, as they are used by F/W. */ static u64 __init fadump_locate_reserve_mem(u64 base, u64 size) { struct fadump_memory_range *mrngs; phys_addr_t mstart, mend; int idx = 0; u64 i, ret = 0; mrngs = reserved_mrange_info.mem_ranges; for_each_free_mem_range(i, NUMA_NO_NODE, MEMBLOCK_NONE, &mstart, &mend, NULL) { pr_debug("%llu) mstart: %llx, mend: %llx, base: %llx\n", i, mstart, mend, base); if (mstart > base) base = PAGE_ALIGN(mstart); while ((mend > base) && ((mend - base) >= size)) { if (!overlaps_reserved_ranges(base, base+size, &idx)) { ret = base; goto out; } base = mrngs[idx].base + mrngs[idx].size; base = PAGE_ALIGN(base); } } out: return ret; } int __init fadump_reserve_mem(void) { u64 base, size, mem_boundary, bootmem_min; int ret = 1; if (!fw_dump.fadump_enabled) return 0; if (!fw_dump.fadump_supported) { pr_info("Firmware-Assisted Dump is not supported on this hardware\n"); goto error_out; } /* * Initialize boot memory size * If dump is active then we have already calculated the size during * first kernel. */ if (!fw_dump.dump_active) { fw_dump.boot_memory_size = PAGE_ALIGN(fadump_calculate_reserve_size()); bootmem_min = fw_dump.ops->fadump_get_bootmem_min(); if (fw_dump.boot_memory_size < bootmem_min) { pr_err("Can't enable fadump with boot memory size (0x%lx) less than 0x%llx\n", fw_dump.boot_memory_size, bootmem_min); goto error_out; } if (!fadump_get_boot_mem_regions()) { pr_err("Too many holes in boot memory area to enable fadump\n"); goto error_out; } } if (memory_limit) mem_boundary = memory_limit; else mem_boundary = memblock_end_of_DRAM(); base = fw_dump.boot_mem_top; size = get_fadump_area_size(); fw_dump.reserve_dump_area_size = size; if (fw_dump.dump_active) { pr_info("Firmware-assisted dump is active.\n"); #ifdef CONFIG_HUGETLB_PAGE /* * FADump capture kernel doesn't care much about hugepages. * In fact, handling hugepages in capture kernel is asking for * trouble. So, disable HugeTLB support when fadump is active. */ hugetlb_disabled = true; #endif /* * If last boot has crashed then reserve all the memory * above boot memory size so that we don't touch it until * dump is written to disk by userspace tool. This memory * can be released for general use by invalidating fadump. */ fadump_reserve_crash_area(base); pr_debug("fadumphdr_addr = %#016lx\n", fw_dump.fadumphdr_addr); pr_debug("Reserve dump area start address: 0x%lx\n", fw_dump.reserve_dump_area_start); } else { /* * Reserve memory at an offset closer to bottom of the RAM to * minimize the impact of memory hot-remove operation. */ base = fadump_locate_reserve_mem(base, size); if (!base || (base + size > mem_boundary)) { pr_err("Failed to find memory chunk for reservation!\n"); goto error_out; } fw_dump.reserve_dump_area_start = base; /* * Calculate the kernel metadata address and register it with * f/w if the platform supports. */ if (fw_dump.ops->fadump_setup_metadata && (fw_dump.ops->fadump_setup_metadata(&fw_dump) < 0)) goto error_out; if (memblock_reserve(base, size)) { pr_err("Failed to reserve memory!\n"); goto error_out; } pr_info("Reserved %lldMB of memory at %#016llx (System RAM: %lldMB)\n", (size >> 20), base, (memblock_phys_mem_size() >> 20)); } return ret; error_out: fw_dump.fadump_enabled = 0; fw_dump.reserve_dump_area_size = 0; return 0; } /* Look for fadump= cmdline option. */ static int __init early_fadump_param(char *p) { if (!p) return 1; if (strncmp(p, "on", 2) == 0) fw_dump.fadump_enabled = 1; else if (strncmp(p, "off", 3) == 0) fw_dump.fadump_enabled = 0; else if (strncmp(p, "nocma", 5) == 0) { fw_dump.fadump_enabled = 1; fw_dump.nocma = 1; } return 0; } early_param("fadump", early_fadump_param); /* * Look for fadump_reserve_mem= cmdline option * TODO: Remove references to 'fadump_reserve_mem=' parameter, * the sooner 'crashkernel=' parameter is accustomed to. */ static int __init early_fadump_reserve_mem(char *p) { if (p) fw_dump.reserve_bootvar = memparse(p, &p); return 0; } early_param("fadump_reserve_mem", early_fadump_reserve_mem); void crash_fadump(struct pt_regs *regs, const char *str) { unsigned int msecs; struct fadump_crash_info_header *fdh = NULL; int old_cpu, this_cpu; /* Do not include first CPU */ unsigned int ncpus = num_online_cpus() - 1; if (!should_fadump_crash()) return; /* * old_cpu == -1 means this is the first CPU which has come here, * go ahead and trigger fadump. * * old_cpu != -1 means some other CPU has already on its way * to trigger fadump, just keep looping here. */ this_cpu = smp_processor_id(); old_cpu = cmpxchg(&crashing_cpu, -1, this_cpu); if (old_cpu != -1) { atomic_inc(&cpus_in_fadump); /* * We can't loop here indefinitely. Wait as long as fadump * is in force. If we race with fadump un-registration this * loop will break and then we go down to normal panic path * and reboot. If fadump is in force the first crashing * cpu will definitely trigger fadump. */ while (fw_dump.dump_registered) cpu_relax(); return; } fdh = __va(fw_dump.fadumphdr_addr); fdh->crashing_cpu = crashing_cpu; crash_save_vmcoreinfo(); if (regs) fdh->regs = *regs; else ppc_save_regs(&fdh->regs); fdh->cpu_mask = *cpu_online_mask; /* * If we came in via system reset, wait a while for the secondary * CPUs to enter. */ if (TRAP(&(fdh->regs)) == INTERRUPT_SYSTEM_RESET) { msecs = CRASH_TIMEOUT; while ((atomic_read(&cpus_in_fadump) < ncpus) && (--msecs > 0)) mdelay(1); } fw_dump.ops->fadump_trigger(fdh, str); } u32 *__init fadump_regs_to_elf_notes(u32 *buf, struct pt_regs *regs) { struct elf_prstatus prstatus; memset(&prstatus, 0, sizeof(prstatus)); /* * FIXME: How do i get PID? Do I really need it? * prstatus.pr_pid = ???? */ elf_core_copy_regs(&prstatus.pr_reg, regs); buf = append_elf_note(buf, CRASH_CORE_NOTE_NAME, NT_PRSTATUS, &prstatus, sizeof(prstatus)); return buf; } void __init fadump_update_elfcore_header(char *bufp) { struct elf_phdr *phdr; bufp += sizeof(struct elfhdr); /* First note is a place holder for cpu notes info. */ phdr = (struct elf_phdr *)bufp; if (phdr->p_type == PT_NOTE) { phdr->p_paddr = __pa(fw_dump.cpu_notes_buf_vaddr); phdr->p_offset = phdr->p_paddr; phdr->p_filesz = fw_dump.cpu_notes_buf_size; phdr->p_memsz = fw_dump.cpu_notes_buf_size; } return; } static void *__init fadump_alloc_buffer(unsigned long size) { unsigned long count, i; struct page *page; void *vaddr; vaddr = alloc_pages_exact(size, GFP_KERNEL | __GFP_ZERO); if (!vaddr) return NULL; count = PAGE_ALIGN(size) / PAGE_SIZE; page = virt_to_page(vaddr); for (i = 0; i < count; i++) mark_page_reserved(page + i); return vaddr; } static void fadump_free_buffer(unsigned long vaddr, unsigned long size) { free_reserved_area((void *)vaddr, (void *)(vaddr + size), -1, NULL); } s32 __init fadump_setup_cpu_notes_buf(u32 num_cpus) { /* Allocate buffer to hold cpu crash notes. */ fw_dump.cpu_notes_buf_size = num_cpus * sizeof(note_buf_t); fw_dump.cpu_notes_buf_size = PAGE_ALIGN(fw_dump.cpu_notes_buf_size); fw_dump.cpu_notes_buf_vaddr = (unsigned long)fadump_alloc_buffer(fw_dump.cpu_notes_buf_size); if (!fw_dump.cpu_notes_buf_vaddr) { pr_err("Failed to allocate %ld bytes for CPU notes buffer\n", fw_dump.cpu_notes_buf_size); return -ENOMEM; } pr_debug("Allocated buffer for cpu notes of size %ld at 0x%lx\n", fw_dump.cpu_notes_buf_size, fw_dump.cpu_notes_buf_vaddr); return 0; } void fadump_free_cpu_notes_buf(void) { if (!fw_dump.cpu_notes_buf_vaddr) return; fadump_free_buffer(fw_dump.cpu_notes_buf_vaddr, fw_dump.cpu_notes_buf_size); fw_dump.cpu_notes_buf_vaddr = 0; fw_dump.cpu_notes_buf_size = 0; } static void fadump_free_mem_ranges(struct fadump_mrange_info *mrange_info) { if (mrange_info->is_static) { mrange_info->mem_range_cnt = 0; return; } kfree(mrange_info->mem_ranges); memset((void *)((u64)mrange_info + RNG_NAME_SZ), 0, (sizeof(struct fadump_mrange_info) - RNG_NAME_SZ)); } /* * Allocate or reallocate mem_ranges array in incremental units * of PAGE_SIZE. */ static int fadump_alloc_mem_ranges(struct fadump_mrange_info *mrange_info) { struct fadump_memory_range *new_array; u64 new_size; new_size = mrange_info->mem_ranges_sz + PAGE_SIZE; pr_debug("Allocating %llu bytes of memory for %s memory ranges\n", new_size, mrange_info->name); new_array = krealloc(mrange_info->mem_ranges, new_size, GFP_KERNEL); if (new_array == NULL) { pr_err("Insufficient memory for setting up %s memory ranges\n", mrange_info->name); fadump_free_mem_ranges(mrange_info); return -ENOMEM; } mrange_info->mem_ranges = new_array; mrange_info->mem_ranges_sz = new_size; mrange_info->max_mem_ranges = (new_size / sizeof(struct fadump_memory_range)); return 0; } static inline int fadump_add_mem_range(struct fadump_mrange_info *mrange_info, u64 base, u64 end) { struct fadump_memory_range *mem_ranges = mrange_info->mem_ranges; bool is_adjacent = false; u64 start, size; if (base == end) return 0; /* * Fold adjacent memory ranges to bring down the memory ranges/ * PT_LOAD segments count. */ if (mrange_info->mem_range_cnt) { start = mem_ranges[mrange_info->mem_range_cnt - 1].base; size = mem_ranges[mrange_info->mem_range_cnt - 1].size; /* * Boot memory area needs separate PT_LOAD segment(s) as it * is moved to a different location at the time of crash. * So, fold only if the region is not boot memory area. */ if ((start + size) == base && start >= fw_dump.boot_mem_top) is_adjacent = true; } if (!is_adjacent) { /* resize the array on reaching the limit */ if (mrange_info->mem_range_cnt == mrange_info->max_mem_ranges) { int ret; if (mrange_info->is_static) { pr_err("Reached array size limit for %s memory ranges\n", mrange_info->name); return -ENOSPC; } ret = fadump_alloc_mem_ranges(mrange_info); if (ret) return ret; /* Update to the new resized array */ mem_ranges = mrange_info->mem_ranges; } start = base; mem_ranges[mrange_info->mem_range_cnt].base = start; mrange_info->mem_range_cnt++; } mem_ranges[mrange_info->mem_range_cnt - 1].size = (end - start); pr_debug("%s_memory_range[%d] [%#016llx-%#016llx], %#llx bytes\n", mrange_info->name, (mrange_info->mem_range_cnt - 1), start, end - 1, (end - start)); return 0; } static int fadump_init_elfcore_header(char *bufp) { struct elfhdr *elf; elf = (struct elfhdr *) bufp; bufp += sizeof(struct elfhdr); memcpy(elf->e_ident, ELFMAG, SELFMAG); elf->e_ident[EI_CLASS] = ELF_CLASS; elf->e_ident[EI_DATA] = ELF_DATA; elf->e_ident[EI_VERSION] = EV_CURRENT; elf->e_ident[EI_OSABI] = ELF_OSABI; memset(elf->e_ident+EI_PAD, 0, EI_NIDENT-EI_PAD); elf->e_type = ET_CORE; elf->e_machine = ELF_ARCH; elf->e_version = EV_CURRENT; elf->e_entry = 0; elf->e_phoff = sizeof(struct elfhdr); elf->e_shoff = 0; if (IS_ENABLED(CONFIG_PPC64_ELF_ABI_V2)) elf->e_flags = 2; else if (IS_ENABLED(CONFIG_PPC64_ELF_ABI_V1)) elf->e_flags = 1; else elf->e_flags = 0; elf->e_ehsize = sizeof(struct elfhdr); elf->e_phentsize = sizeof(struct elf_phdr); elf->e_phnum = 0; elf->e_shentsize = 0; elf->e_shnum = 0; elf->e_shstrndx = 0; return 0; } /* * If the given physical address falls within the boot memory region then * return the relocated address that points to the dump region reserved * for saving initial boot memory contents. */ static inline unsigned long fadump_relocate(unsigned long paddr) { unsigned long raddr, rstart, rend, rlast, hole_size; int i; hole_size = 0; rlast = 0; raddr = paddr; for (i = 0; i < fw_dump.boot_mem_regs_cnt; i++) { rstart = fw_dump.boot_mem_addr[i]; rend = rstart + fw_dump.boot_mem_sz[i]; hole_size += (rstart - rlast); if (paddr >= rstart && paddr < rend) { raddr += fw_dump.boot_mem_dest_addr - hole_size; break; } rlast = rend; } pr_debug("vmcoreinfo: paddr = 0x%lx, raddr = 0x%lx\n", paddr, raddr); return raddr; } static void __init populate_elf_pt_load(struct elf_phdr *phdr, u64 start, u64 size, unsigned long long offset) { phdr->p_align = 0; phdr->p_memsz = size; phdr->p_filesz = size; phdr->p_paddr = start; phdr->p_offset = offset; phdr->p_type = PT_LOAD; phdr->p_flags = PF_R|PF_W|PF_X; phdr->p_vaddr = (unsigned long)__va(start); } static void __init fadump_populate_elfcorehdr(struct fadump_crash_info_header *fdh) { char *bufp; struct elfhdr *elf; struct elf_phdr *phdr; u64 boot_mem_dest_offset; unsigned long long i, ra_start, ra_end, ra_size, mstart, mend; bufp = (char *) fw_dump.elfcorehdr_addr; fadump_init_elfcore_header(bufp); elf = (struct elfhdr *)bufp; bufp += sizeof(struct elfhdr); /* * Set up ELF PT_NOTE, a placeholder for CPU notes information. * The notes info will be populated later by platform-specific code. * Hence, this PT_NOTE will always be the first ELF note. * * NOTE: Any new ELF note addition should be placed after this note. */ phdr = (struct elf_phdr *)bufp; bufp += sizeof(struct elf_phdr); phdr->p_type = PT_NOTE; phdr->p_flags = 0; phdr->p_vaddr = 0; phdr->p_align = 0; phdr->p_offset = 0; phdr->p_paddr = 0; phdr->p_filesz = 0; phdr->p_memsz = 0; /* Increment number of program headers. */ (elf->e_phnum)++; /* setup ELF PT_NOTE for vmcoreinfo */ phdr = (struct elf_phdr *)bufp; bufp += sizeof(struct elf_phdr); phdr->p_type = PT_NOTE; phdr->p_flags = 0; phdr->p_vaddr = 0; phdr->p_align = 0; phdr->p_paddr = phdr->p_offset = fdh->vmcoreinfo_raddr; phdr->p_memsz = phdr->p_filesz = fdh->vmcoreinfo_size; /* Increment number of program headers. */ (elf->e_phnum)++; /* * Setup PT_LOAD sections. first include boot memory regions * and then add rest of the memory regions. */ boot_mem_dest_offset = fw_dump.boot_mem_dest_addr; for (i = 0; i < fw_dump.boot_mem_regs_cnt; i++) { phdr = (struct elf_phdr *)bufp; bufp += sizeof(struct elf_phdr); populate_elf_pt_load(phdr, fw_dump.boot_mem_addr[i], fw_dump.boot_mem_sz[i], boot_mem_dest_offset); /* Increment number of program headers. */ (elf->e_phnum)++; boot_mem_dest_offset += fw_dump.boot_mem_sz[i]; } /* Memory reserved for fadump in first kernel */ ra_start = fw_dump.reserve_dump_area_start; ra_size = get_fadump_area_size(); ra_end = ra_start + ra_size; phdr = (struct elf_phdr *)bufp; for_each_mem_range(i, &mstart, &mend) { /* Boot memory regions already added, skip them now */ if (mstart < fw_dump.boot_mem_top) { if (mend > fw_dump.boot_mem_top) mstart = fw_dump.boot_mem_top; else continue; } /* Handle memblock regions overlaps with fadump reserved area */ if ((ra_start < mend) && (ra_end > mstart)) { if ((mstart < ra_start) && (mend > ra_end)) { populate_elf_pt_load(phdr, mstart, ra_start - mstart, mstart); /* Increment number of program headers. */ (elf->e_phnum)++; bufp += sizeof(struct elf_phdr); phdr = (struct elf_phdr *)bufp; populate_elf_pt_load(phdr, ra_end, mend - ra_end, ra_end); } else if (mstart < ra_start) { populate_elf_pt_load(phdr, mstart, ra_start - mstart, mstart); } else if (ra_end < mend) { populate_elf_pt_load(phdr, ra_end, mend - ra_end, ra_end); } } else { /* No overlap with fadump reserved memory region */ populate_elf_pt_load(phdr, mstart, mend - mstart, mstart); } /* Increment number of program headers. */ (elf->e_phnum)++; bufp += sizeof(struct elf_phdr); phdr = (struct elf_phdr *) bufp; } } static unsigned long init_fadump_header(unsigned long addr) { struct fadump_crash_info_header *fdh; if (!addr) return 0; fdh = __va(addr); addr += sizeof(struct fadump_crash_info_header); memset(fdh, 0, sizeof(struct fadump_crash_info_header)); fdh->magic_number = FADUMP_CRASH_INFO_MAGIC; fdh->version = FADUMP_HEADER_VERSION; /* We will set the crashing cpu id in crash_fadump() during crash. */ fdh->crashing_cpu = FADUMP_CPU_UNKNOWN; /* * The physical address and size of vmcoreinfo are required in the * second kernel to prepare elfcorehdr. */ fdh->vmcoreinfo_raddr = fadump_relocate(paddr_vmcoreinfo_note()); fdh->vmcoreinfo_size = VMCOREINFO_NOTE_SIZE; fdh->pt_regs_sz = sizeof(struct pt_regs); /* * When LPAR is terminated by PYHP, ensure all possible CPUs' * register data is processed while exporting the vmcore. */ fdh->cpu_mask = *cpu_possible_mask; fdh->cpu_mask_sz = sizeof(struct cpumask); return addr; } static int register_fadump(void) { unsigned long addr; /* * If no memory is reserved then we can not register for firmware- * assisted dump. */ if (!fw_dump.reserve_dump_area_size) return -ENODEV; addr = fw_dump.fadumphdr_addr; /* Initialize fadump crash info header. */ addr = init_fadump_header(addr); /* register the future kernel dump with firmware. */ pr_debug("Registering for firmware-assisted kernel dump...\n"); return fw_dump.ops->fadump_register(&fw_dump); } void fadump_cleanup(void) { if (!fw_dump.fadump_supported) return; /* Invalidate the registration only if dump is active. */ if (fw_dump.dump_active) { pr_debug("Invalidating firmware-assisted dump registration\n"); fw_dump.ops->fadump_invalidate(&fw_dump); } else if (fw_dump.dump_registered) { /* Un-register Firmware-assisted dump if it was registered. */ fw_dump.ops->fadump_unregister(&fw_dump); } if (fw_dump.ops->fadump_cleanup) fw_dump.ops->fadump_cleanup(&fw_dump); } static void fadump_free_reserved_memory(unsigned long start_pfn, unsigned long end_pfn) { unsigned long pfn; unsigned long time_limit = jiffies + HZ; pr_info("freeing reserved memory (0x%llx - 0x%llx)\n", PFN_PHYS(start_pfn), PFN_PHYS(end_pfn)); for (pfn = start_pfn; pfn < end_pfn; pfn++) { free_reserved_page(pfn_to_page(pfn)); if (time_after(jiffies, time_limit)) { cond_resched(); time_limit = jiffies + HZ; } } } /* * Skip memory holes and free memory that was actually reserved. */ static void fadump_release_reserved_area(u64 start, u64 end) { unsigned long reg_spfn, reg_epfn; u64 tstart, tend, spfn, epfn; int i; spfn = PHYS_PFN(start); epfn = PHYS_PFN(end); for_each_mem_pfn_range(i, MAX_NUMNODES, ®_spfn, ®_epfn, NULL) { tstart = max_t(u64, spfn, reg_spfn); tend = min_t(u64, epfn, reg_epfn); if (tstart < tend) { fadump_free_reserved_memory(tstart, tend); if (tend == epfn) break; spfn = tend; } } } /* * Sort the mem ranges in-place and merge adjacent ranges * to minimize the memory ranges count. */ static void sort_and_merge_mem_ranges(struct fadump_mrange_info *mrange_info) { struct fadump_memory_range *mem_ranges; u64 base, size; int i, j, idx; if (!reserved_mrange_info.mem_range_cnt) return; /* Sort the memory ranges */ mem_ranges = mrange_info->mem_ranges; for (i = 0; i < mrange_info->mem_range_cnt; i++) { idx = i; for (j = (i + 1); j < mrange_info->mem_range_cnt; j++) { if (mem_ranges[idx].base > mem_ranges[j].base) idx = j; } if (idx != i) swap(mem_ranges[idx], mem_ranges[i]); } /* Merge adjacent reserved ranges */ idx = 0; for (i = 1; i < mrange_info->mem_range_cnt; i++) { base = mem_ranges[i-1].base; size = mem_ranges[i-1].size; if (mem_ranges[i].base == (base + size)) mem_ranges[idx].size += mem_ranges[i].size; else { idx++; if (i == idx) continue; mem_ranges[idx] = mem_ranges[i]; } } mrange_info->mem_range_cnt = idx + 1; } /* * Scan reserved-ranges to consider them while reserving/releasing * memory for FADump. */ static void __init early_init_dt_scan_reserved_ranges(unsigned long node) { const __be32 *prop; int len, ret = -1; unsigned long i; /* reserved-ranges already scanned */ if (reserved_mrange_info.mem_range_cnt != 0) return; prop = of_get_flat_dt_prop(node, "reserved-ranges", &len); if (!prop) return; /* * Each reserved range is an (address,size) pair, 2 cells each, * totalling 4 cells per range. */ for (i = 0; i < len / (sizeof(*prop) * 4); i++) { u64 base, size; base = of_read_number(prop + (i * 4) + 0, 2); size = of_read_number(prop + (i * 4) + 2, 2); if (size) { ret = fadump_add_mem_range(&reserved_mrange_info, base, base + size); if (ret < 0) { pr_warn("some reserved ranges are ignored!\n"); break; } } } /* Compact reserved ranges */ sort_and_merge_mem_ranges(&reserved_mrange_info); } /* * Release the memory that was reserved during early boot to preserve the * crash'ed kernel's memory contents except reserved dump area (permanent * reservation) and reserved ranges used by F/W. The released memory will * be available for general use. */ static void fadump_release_memory(u64 begin, u64 end) { u64 ra_start, ra_end, tstart; int i, ret; ra_start = fw_dump.reserve_dump_area_start; ra_end = ra_start + fw_dump.reserve_dump_area_size; /* * If reserved ranges array limit is hit, overwrite the last reserved * memory range with reserved dump area to ensure it is excluded from * the memory being released (reused for next FADump registration). */ if (reserved_mrange_info.mem_range_cnt == reserved_mrange_info.max_mem_ranges) reserved_mrange_info.mem_range_cnt--; ret = fadump_add_mem_range(&reserved_mrange_info, ra_start, ra_end); if (ret != 0) return; /* Get the reserved ranges list in order first. */ sort_and_merge_mem_ranges(&reserved_mrange_info); /* Exclude reserved ranges and release remaining memory */ tstart = begin; for (i = 0; i < reserved_mrange_info.mem_range_cnt; i++) { ra_start = reserved_mrange_info.mem_ranges[i].base; ra_end = ra_start + reserved_mrange_info.mem_ranges[i].size; if (tstart >= ra_end) continue; if (tstart < ra_start) fadump_release_reserved_area(tstart, ra_start); tstart = ra_end; } if (tstart < end) fadump_release_reserved_area(tstart, end); } static void fadump_free_elfcorehdr_buf(void) { if (fw_dump.elfcorehdr_addr == 0 || fw_dump.elfcorehdr_size == 0) return; /* * Before freeing the memory of `elfcorehdr`, reset the global * `elfcorehdr_addr` to prevent modules like `vmcore` from accessing * invalid memory. */ elfcorehdr_addr = ELFCORE_ADDR_ERR; fadump_free_buffer(fw_dump.elfcorehdr_addr, fw_dump.elfcorehdr_size); fw_dump.elfcorehdr_addr = 0; fw_dump.elfcorehdr_size = 0; } static void fadump_invalidate_release_mem(void) { mutex_lock(&fadump_mutex); if (!fw_dump.dump_active) { mutex_unlock(&fadump_mutex); return; } fadump_cleanup(); mutex_unlock(&fadump_mutex); fadump_free_elfcorehdr_buf(); fadump_release_memory(fw_dump.boot_mem_top, memblock_end_of_DRAM()); fadump_free_cpu_notes_buf(); /* * Setup kernel metadata and initialize the kernel dump * memory structure for FADump re-registration. */ if (fw_dump.ops->fadump_setup_metadata && (fw_dump.ops->fadump_setup_metadata(&fw_dump) < 0)) pr_warn("Failed to setup kernel metadata!\n"); fw_dump.ops->fadump_init_mem_struct(&fw_dump); } static ssize_t release_mem_store(struct kobject *kobj, struct kobj_attribute *attr, const char *buf, size_t count) { int input = -1; if (!fw_dump.dump_active) return -EPERM; if (kstrtoint(buf, 0, &input)) return -EINVAL; if (input == 1) { /* * Take away the '/proc/vmcore'. We are releasing the dump * memory, hence it will not be valid anymore. */ #ifdef CONFIG_PROC_VMCORE vmcore_cleanup(); #endif fadump_invalidate_release_mem(); } else return -EINVAL; return count; } /* Release the reserved memory and disable the FADump */ static void __init unregister_fadump(void) { fadump_cleanup(); fadump_release_memory(fw_dump.reserve_dump_area_start, fw_dump.reserve_dump_area_size); fw_dump.fadump_enabled = 0; kobject_put(fadump_kobj); } static ssize_t enabled_show(struct kobject *kobj, struct kobj_attribute *attr, char *buf) { return sprintf(buf, "%d\n", fw_dump.fadump_enabled); } /* * /sys/kernel/fadump/hotplug_ready sysfs node returns 1, which inidcates * to usersapce that fadump re-registration is not required on memory * hotplug events. */ static ssize_t hotplug_ready_show(struct kobject *kobj, struct kobj_attribute *attr, char *buf) { return sprintf(buf, "%d\n", 1); } static ssize_t mem_reserved_show(struct kobject *kobj, struct kobj_attribute *attr, char *buf) { return sprintf(buf, "%ld\n", fw_dump.reserve_dump_area_size); } static ssize_t registered_show(struct kobject *kobj, struct kobj_attribute *attr, char *buf) { return sprintf(buf, "%d\n", fw_dump.dump_registered); } static ssize_t bootargs_append_show(struct kobject *kobj, struct kobj_attribute *attr, char *buf) { return sprintf(buf, "%s\n", (char *)__va(fw_dump.param_area)); } static ssize_t bootargs_append_store(struct kobject *kobj, struct kobj_attribute *attr, const char *buf, size_t count) { char *params; if (!fw_dump.fadump_enabled || fw_dump.dump_active) return -EPERM; if (count >= COMMAND_LINE_SIZE) return -EINVAL; /* * Fail here instead of handling this scenario with * some silly workaround in capture kernel. */ if (saved_command_line_len + count >= COMMAND_LINE_SIZE) { pr_err("Appending parameters exceeds cmdline size!\n"); return -ENOSPC; } params = __va(fw_dump.param_area); strscpy_pad(params, buf, COMMAND_LINE_SIZE); /* Remove newline character at the end. */ if (params[count-1] == '\n') params[count-1] = '\0'; return count; } static ssize_t registered_store(struct kobject *kobj, struct kobj_attribute *attr, const char *buf, size_t count) { int ret = 0; int input = -1; if (!fw_dump.fadump_enabled || fw_dump.dump_active) return -EPERM; if (kstrtoint(buf, 0, &input)) return -EINVAL; mutex_lock(&fadump_mutex); switch (input) { case 0: if (fw_dump.dump_registered == 0) { goto unlock_out; } /* Un-register Firmware-assisted dump */ pr_debug("Un-register firmware-assisted dump\n"); fw_dump.ops->fadump_unregister(&fw_dump); break; case 1: if (fw_dump.dump_registered == 1) { /* Un-register Firmware-assisted dump */ fw_dump.ops->fadump_unregister(&fw_dump); } /* Register Firmware-assisted dump */ ret = register_fadump(); break; default: ret = -EINVAL; break; } unlock_out: mutex_unlock(&fadump_mutex); return ret < 0 ? ret : count; } static int fadump_region_show(struct seq_file *m, void *private) { if (!fw_dump.fadump_enabled) return 0; mutex_lock(&fadump_mutex); fw_dump.ops->fadump_region_show(&fw_dump, m); mutex_unlock(&fadump_mutex); return 0; } static struct kobj_attribute release_attr = __ATTR_WO(release_mem); static struct kobj_attribute enable_attr = __ATTR_RO(enabled); static struct kobj_attribute register_attr = __ATTR_RW(registered); static struct kobj_attribute mem_reserved_attr = __ATTR_RO(mem_reserved); static struct kobj_attribute hotplug_ready_attr = __ATTR_RO(hotplug_ready); static struct kobj_attribute bootargs_append_attr = __ATTR_RW(bootargs_append); static struct attribute *fadump_attrs[] = { &enable_attr.attr, ®ister_attr.attr, &mem_reserved_attr.attr, &hotplug_ready_attr.attr, NULL, }; ATTRIBUTE_GROUPS(fadump); DEFINE_SHOW_ATTRIBUTE(fadump_region); static void __init fadump_init_files(void) { int rc = 0; fadump_kobj = kobject_create_and_add("fadump", kernel_kobj); if (!fadump_kobj) { pr_err("failed to create fadump kobject\n"); return; } if (fw_dump.param_area) { rc = sysfs_create_file(fadump_kobj, &bootargs_append_attr.attr); if (rc) pr_err("unable to create bootargs_append sysfs file (%d)\n", rc); } debugfs_create_file("fadump_region", 0444, arch_debugfs_dir, NULL, &fadump_region_fops); if (fw_dump.dump_active) { rc = sysfs_create_file(fadump_kobj, &release_attr.attr); if (rc) pr_err("unable to create release_mem sysfs file (%d)\n", rc); } rc = sysfs_create_groups(fadump_kobj, fadump_groups); if (rc) { pr_err("sysfs group creation failed (%d), unregistering FADump", rc); unregister_fadump(); return; } /* * The FADump sysfs are moved from kernel_kobj to fadump_kobj need to * create symlink at old location to maintain backward compatibility. * * - fadump_enabled -> fadump/enabled * - fadump_registered -> fadump/registered * - fadump_release_mem -> fadump/release_mem */ rc = compat_only_sysfs_link_entry_to_kobj(kernel_kobj, fadump_kobj, "enabled", "fadump_enabled"); if (rc) { pr_err("unable to create fadump_enabled symlink (%d)", rc); return; } rc = compat_only_sysfs_link_entry_to_kobj(kernel_kobj, fadump_kobj, "registered", "fadump_registered"); if (rc) { pr_err("unable to create fadump_registered symlink (%d)", rc); sysfs_remove_link(kernel_kobj, "fadump_enabled"); return; } if (fw_dump.dump_active) { rc = compat_only_sysfs_link_entry_to_kobj(kernel_kobj, fadump_kobj, "release_mem", "fadump_release_mem"); if (rc) pr_err("unable to create fadump_release_mem symlink (%d)", rc); } return; } static int __init fadump_setup_elfcorehdr_buf(void) { int elf_phdr_cnt; unsigned long elfcorehdr_size; /* * Program header for CPU notes comes first, followed by one for * vmcoreinfo, and the remaining program headers correspond to * memory regions. */ elf_phdr_cnt = 2 + fw_dump.boot_mem_regs_cnt + memblock_num_regions(memory); elfcorehdr_size = sizeof(struct elfhdr) + (elf_phdr_cnt * sizeof(struct elf_phdr)); elfcorehdr_size = PAGE_ALIGN(elfcorehdr_size); fw_dump.elfcorehdr_addr = (u64)fadump_alloc_buffer(elfcorehdr_size); if (!fw_dump.elfcorehdr_addr) { pr_err("Failed to allocate %lu bytes for elfcorehdr\n", elfcorehdr_size); return -ENOMEM; } fw_dump.elfcorehdr_size = elfcorehdr_size; return 0; } /* * Check if the fadump header of crashed kernel is compatible with fadump kernel. * * It checks the magic number, endianness, and size of non-primitive type * members of fadump header to ensure safe dump collection. */ static bool __init is_fadump_header_compatible(struct fadump_crash_info_header *fdh) { if (fdh->magic_number == FADUMP_CRASH_INFO_MAGIC_OLD) { pr_err("Old magic number, can't process the dump.\n"); return false; } if (fdh->magic_number != FADUMP_CRASH_INFO_MAGIC) { if (fdh->magic_number == swab64(FADUMP_CRASH_INFO_MAGIC)) pr_err("Endianness mismatch between the crashed and fadump kernels.\n"); else pr_err("Fadump header is corrupted.\n"); return false; } /* * Dump collection is not safe if the size of non-primitive type members * of the fadump header do not match between crashed and fadump kernel. */ if (fdh->pt_regs_sz != sizeof(struct pt_regs) || fdh->cpu_mask_sz != sizeof(struct cpumask)) { pr_err("Fadump header size mismatch.\n"); return false; } return true; } static void __init fadump_process(void) { struct fadump_crash_info_header *fdh; fdh = (struct fadump_crash_info_header *) __va(fw_dump.fadumphdr_addr); if (!fdh) { pr_err("Crash info header is empty.\n"); goto err_out; } /* Avoid processing the dump if fadump header isn't compatible */ if (!is_fadump_header_compatible(fdh)) goto err_out; /* Allocate buffer for elfcorehdr */ if (fadump_setup_elfcorehdr_buf()) goto err_out; fadump_populate_elfcorehdr(fdh); /* Let platform update the CPU notes in elfcorehdr */ if (fw_dump.ops->fadump_process(&fw_dump) < 0) goto err_out; /* * elfcorehdr is now ready to be exported. * * set elfcorehdr_addr so that vmcore module will export the * elfcorehdr through '/proc/vmcore'. */ elfcorehdr_addr = virt_to_phys((void *)fw_dump.elfcorehdr_addr); return; err_out: fadump_invalidate_release_mem(); } /* * Reserve memory to store additional parameters to be passed * for fadump/capture kernel. */ void __init fadump_setup_param_area(void) { phys_addr_t range_start, range_end; if (!fw_dump.param_area_supported || fw_dump.dump_active) return; /* This memory can't be used by PFW or bootloader as it is shared across kernels */ if (early_radix_enabled()) { /* * Anywhere in the upper half should be good enough as all memory * is accessible in real mode. */ range_start = memblock_end_of_DRAM() / 2; range_end = memblock_end_of_DRAM(); } else { /* * Passing additional parameters is supported for hash MMU only * if the first memory block size is 768MB or higher. */ if (ppc64_rma_size < 0x30000000) return; /* * 640 MB to 768 MB is not used by PFW/bootloader. So, try reserving * memory for passing additional parameters in this range to avoid * being stomped on by PFW/bootloader. */ range_start = 0x2A000000; range_end = range_start + 0x4000000; } fw_dump.param_area = memblock_phys_alloc_range(COMMAND_LINE_SIZE, COMMAND_LINE_SIZE, range_start, range_end); if (!fw_dump.param_area) { pr_warn("WARNING: Could not setup area to pass additional parameters!\n"); return; } memset((void *)fw_dump.param_area, 0, COMMAND_LINE_SIZE); } /* * Prepare for firmware-assisted dump. */ int __init setup_fadump(void) { if (!fw_dump.fadump_supported) return 0; fadump_init_files(); fadump_show_config(); if (!fw_dump.fadump_enabled) return 1; /* * If dump data is available then see if it is valid and prepare for * saving it to the disk. */ if (fw_dump.dump_active) { fadump_process(); } /* Initialize the kernel dump memory structure and register with f/w */ else if (fw_dump.reserve_dump_area_size) { fw_dump.ops->fadump_init_mem_struct(&fw_dump); register_fadump(); } /* * In case of panic, fadump is triggered via ppc_panic_event() * panic notifier. Setting crash_kexec_post_notifiers to 'true' * lets panic() function take crash friendly path before panic * notifiers are invoked. */ crash_kexec_post_notifiers = true; return 1; } /* * Use subsys_initcall_sync() here because there is dependency with * crash_save_vmcoreinfo_init(), which must run first to ensure vmcoreinfo initialization * is done before registering with f/w. */ subsys_initcall_sync(setup_fadump); #else /* !CONFIG_PRESERVE_FA_DUMP */ /* Scan the Firmware Assisted dump configuration details. */ int __init early_init_dt_scan_fw_dump(unsigned long node, const char *uname, int depth, void *data) { if ((depth != 1) || (strcmp(uname, "ibm,opal") != 0)) return 0; opal_fadump_dt_scan(&fw_dump, node); return 1; } /* * When dump is active but PRESERVE_FA_DUMP is enabled on the kernel, * preserve crash data. The subsequent memory preserving kernel boot * is likely to process this crash data. */ int __init fadump_reserve_mem(void) { if (fw_dump.dump_active) { /* * If last boot has crashed then reserve all the memory * above boot memory to preserve crash data. */ pr_info("Preserving crash data for processing in next boot.\n"); fadump_reserve_crash_area(fw_dump.boot_mem_top); } else pr_debug("FADump-aware kernel..\n"); return 1; } #endif /* CONFIG_PRESERVE_FA_DUMP */ /* Preserve everything above the base address */ static void __init fadump_reserve_crash_area(u64 base) { u64 i, mstart, mend, msize; for_each_mem_range(i, &mstart, &mend) { msize = mend - mstart; if ((mstart + msize) < base) continue; if (mstart < base) { msize -= (base - mstart); mstart = base; } pr_info("Reserving %lluMB of memory at %#016llx for preserving crash data", (msize >> 20), mstart); memblock_reserve(mstart, msize); } }