/* * Copyright (c) 2016, The Linux Foundation. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above * copyright notice, this list of conditions and the following * disclaimer in the documentation and/or other materials provided * with the distribution. * * Neither the name of The Linux Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * Copyright (C) 2021-2023 Caleb Connolly * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include #include #include #include #include #include #include #include #include #include #include #include #include "gpt-utils.h" #include "ufs-bsg.h" #include "utils.h" #include "bootctrl.h" #define BOOTDEV_DIR "/dev/disk/by-partlabel" #define BOOT_IMG_PTN_NAME "boot_" #define LUN_NAME_END_LOC 14 #define BOOT_SLOT_PROP "slot_suffix" #define MAX_CMDLINE_SIZE 4096 #define SLOT_ACTIVE 1 #define SLOT_INACTIVE 2 #define UPDATE_SLOT(pentry, guid, slot_state) \ ({ \ memcpy(pentry, guid, TYPE_GUID_SIZE); \ if (slot_state == SLOT_ACTIVE) \ *(pentry + AB_FLAG_OFFSET) = AB_SLOT_ACTIVE_VAL; \ else if (slot_state == SLOT_INACTIVE) \ *(pentry + AB_FLAG_OFFSET) = \ (*(pentry + AB_FLAG_OFFSET) & ~AB_PARTITION_ATTR_SLOT_ACTIVE); \ }) const char *slot_suffix_arr[] = { AB_SLOT_A_SUFFIX, AB_SLOT_B_SUFFIX, NULL }; enum part_attr_type { ATTR_SLOT_ACTIVE = 0, ATTR_BOOT_SUCCESSFUL, ATTR_UNBOOTABLE, ATTR_BOOTABLE, }; void get_kernel_cmdline_arg(const char *arg, char *buf, const char *def) { int fd; char pcmd[MAX_CMDLINE_SIZE]; char *val, *found, *ptr = buf; fd = open("/proc/cmdline", O_RDONLY); int rc = read(fd, pcmd, MAX_CMDLINE_SIZE); if (rc < 0) { fprintf(stderr, "Couldn't open /proc/cmdline: %d (%s)\n", rc, strerror(errno)); goto error; } close(fd); found = strstr(pcmd, arg); if (!found || !(val = strstr(found, "="))) { fprintf(stderr, "Couldn't find cmdline arg: '%s'\n", arg); goto error; } val++; // no this doesn't handle quotes lol while (*val != ' ') { *ptr++ = *val++; } return; error: strcpy(buf, def); } // Get the value of one of the attribute fields for a partition. static int get_partition_attribute(struct gpt_disk *disk, const char *partname, enum part_attr_type part_attr) { uint8_t *pentry = NULL; int retval = -1; uint8_t *attr = NULL; if (!partname) return -1; // Will initialise the disk if null, or reinitialise it if // it's for a partition on a different disk if (gpt_disk_get_disk_info(partname, disk) < 0) { fprintf(stderr, "%s: gpt_disk_get_disk_info failed\n", __func__); return -1; } pentry = gpt_disk_get_pentry(disk, partname, PRIMARY_GPT); if (!pentry) { fprintf(stderr, "%s: pentry does not exist in disk struct\n", __func__); return -1; } attr = pentry + AB_FLAG_OFFSET; LOGD("%s() partname = %s, attr = 0x%x\n", __func__, partname, *attr); switch (part_attr) { case ATTR_SLOT_ACTIVE: retval = !!(*attr & AB_PARTITION_ATTR_SLOT_ACTIVE); LOGD("ATTR_SLOT_ACTIVE, retval = %d\n", retval); break; case ATTR_BOOT_SUCCESSFUL: retval = !!(*attr & AB_PARTITION_ATTR_BOOT_SUCCESSFUL); LOGD("AB_PARTITION_ATTR_BOOT_SUCCESSFUL, retval = %d\n", retval); break; case ATTR_UNBOOTABLE: retval = !!(*attr & AB_PARTITION_ATTR_UNBOOTABLE); LOGD("AB_PARTITION_ATTR_UNBOOTABLE, retval = %d\n", retval); break; default: retval = -1; } return retval; } // Set a particular attribute for all the partitions in a // slot static int update_slot_attribute(struct gpt_disk *disk, unsigned slot, enum part_attr_type ab_attr) { unsigned int i = 0; char buf[GPT_PTN_PATH_MAX]; struct stat st; uint8_t *pentry = NULL; uint8_t *pentry_bak = NULL; int rc = -1; uint8_t *attr = NULL; uint8_t *attr_bak = NULL; const char *partName; char devpath[GPT_PTN_PATH_MAX] = { 0 }; for (i = 0; i < ARRAY_SIZE(g_all_ptns); i++) { memset(buf, '\0', sizeof(buf)); // Check if A/B versions of this ptn exist rc = snprintf(buf, sizeof(buf) - 1, "%s/%.72s", BOOT_DEV_DIR, g_all_ptns[i]); if (stat(buf, &st) < 0) { // partition does not have _a version continue; } buf[strlen(buf) - 1] = 'b'; if (stat(buf, &st) < 0) { // partition does not have _b version continue; } if (slot == 0) partName = g_all_ptns[i]; else partName = buf + strlen(BOOT_DEV_DIR) + 1; LOGD("%s: partName = '%s'\n", __func__, partName); // If the current partition is for a different disk (e.g. /dev/sde when the current disk is /dev/sda) // Then commit the current disk if (!partition_is_for_disk(disk, partName, devpath, sizeof(devpath))) { if (gpt_disk_commit(disk)) { fprintf(stderr, "%s: Failed to commit disk\n", __func__); return -1; } } rc = gpt_disk_get_disk_info(partName, disk); if (rc != 0) { fprintf(stderr, "%s: Failed to get disk info for %s\n", __func__, partName); return -1; } pentry = gpt_disk_get_pentry(disk, partName, PRIMARY_GPT); pentry_bak = gpt_disk_get_pentry(disk, partName, SECONDARY_GPT); if (!pentry || !pentry_bak) { fprintf(stderr, "%s: Failed to get pentry/pentry_bak for %s\n", __func__, partName); return -1; } attr = pentry + AB_FLAG_OFFSET; // LOGD("%s: got pentry for part '%s': 0x%lx (at flags: 0x%x)\n", __func__, partName, // *(uint64_t *)pentry, *attr); attr_bak = pentry_bak + AB_FLAG_OFFSET; switch (ab_attr) { case ATTR_BOOT_SUCCESSFUL: *attr = (*attr) | AB_PARTITION_ATTR_BOOT_SUCCESSFUL; *attr_bak = (*attr_bak) | AB_PARTITION_ATTR_BOOT_SUCCESSFUL; break; case ATTR_UNBOOTABLE: *attr = (*attr) | AB_PARTITION_ATTR_UNBOOTABLE; *attr_bak = (*attr_bak) | AB_PARTITION_ATTR_UNBOOTABLE; break; case ATTR_BOOTABLE: *attr = (*attr) ^ AB_PARTITION_ATTR_UNBOOTABLE; *attr_bak = (*attr_bak) ^ AB_PARTITION_ATTR_UNBOOTABLE; break; case ATTR_SLOT_ACTIVE: *attr = (*attr) | AB_PARTITION_ATTR_SLOT_ACTIVE; *attr_bak = (*attr) | AB_PARTITION_ATTR_SLOT_ACTIVE; break; default: fprintf(stderr, "%s: Unrecognized attr\n", __func__); return -1; } } if (gpt_disk_commit(disk)) { fprintf(stderr, "%s: Failed to commit disk %s\n", __func__, disk->devpath); return -1; } return 0; } /* * Returns 0 for no slots, or the number of slots found. * Fun semantic note: Having "1" slot (ie just a "boot" partition) * is the same as having "no slots". * * This function will never return 1. */ unsigned get_number_slots() { struct dirent *de = NULL; DIR *dir_bootdev = NULL; static int slot_count = 0; // If we've already counted the slots, return the cached value. // If there are no slots then we'll always rerun the search... if (slot_count > 0) return slot_count; assert(AB_SLOT_A_SUFFIX[0] == '_'); assert(AB_SLOT_B_SUFFIX[0] == '_'); dir_bootdev = opendir(BOOTDEV_DIR); // Shouldn't this be an assert? if (!dir_bootdev) { fprintf(stderr, "%s: Failed to open bootdev dir (%s)\n", __func__, strerror(errno)); return 0; } while ((de = readdir(dir_bootdev))) { if (de->d_name[0] == '.') continue; if (!strncmp(de->d_name, BOOT_IMG_PTN_NAME, strlen(BOOT_IMG_PTN_NAME)) && !!strncmp(de->d_name, "boot_aging\n", strlen("boot_aging"))) { slot_count++; } } if (slot_count < 0) slot_count = 0; closedir(dir_bootdev); return slot_count; } static int boot_control_check_slot_sanity(unsigned slot) { uint32_t num_slots = get_number_slots(); if ((num_slots < 1) || (slot > num_slots - 1)) { fprintf(stderr, "Invalid slot number %u\n", slot); return -1; } return 0; } int get_boot_attr(struct gpt_disk *disk, unsigned slot, enum part_attr_type attr) { char bootPartition[MAX_GPT_NAME_SIZE + 1] = { 0 }; if (boot_control_check_slot_sanity(slot) != 0) { fprintf(stderr, "%s: Argument check failed\n", __func__); return -1; } snprintf(bootPartition, sizeof(bootPartition) - 1, "boot%s", slot_suffix_arr[slot]); return get_partition_attribute(disk, bootPartition, attr); } static unsigned int get_current_slot_from_kernel_cmdline() { uint32_t num_slots = 0; char bootSlotProp[MAX_CMDLINE_SIZE] = { '\0' }; unsigned i = 0; num_slots = get_number_slots(); if (num_slots <= 1) { // Slot 0 is the only slot around. return 0; } get_kernel_cmdline_arg(BOOT_SLOT_PROP, bootSlotProp, "_a"); if (!strncmp(bootSlotProp, "N/A\n", strlen("N/A"))) { fprintf(stderr, "%s: Unable to read boot slot property\n", __func__); return 0; } // Iterate through a list of partitons named as boot+suffix // and see which one is currently active. for (i = 0; slot_suffix_arr[i] != NULL; i++) { if (!strncmp(bootSlotProp, slot_suffix_arr[i], strlen(slot_suffix_arr[i]))) { // printf("%s current_slot = %d\n", __func__, i); return i; } } // The HAL spec requires that we return a number between // 0 to num_slots - 1. Since something went wrong here we // are just going to return the default slot. return 0; } int is_slot_bootable(unsigned slot) { int attr = 0; struct gpt_disk disk = { 0 }; attr = get_boot_attr(&disk, slot, ATTR_UNBOOTABLE); if (attr >= 0) return !attr; return -1; } int mark_boot_successful(unsigned slot) { struct gpt_disk disk = { 0 }; int successful = get_boot_attr(&disk, slot, ATTR_BOOT_SUCCESSFUL); int unbootable = get_boot_attr(&disk, slot, ATTR_UNBOOTABLE); int ret = 0; if (successful < 0 || unbootable < 0) { fprintf(stderr, "SLOT %s: Failed to read attributes\n", slot_suffix_arr[slot]); ret = -1; goto out; } if (unbootable) { printf("SLOT %s: was marked unbootable, fixing this" " (I hope you know what you're doing...)\n", slot_suffix_arr[slot]); update_slot_attribute(&disk, slot, ATTR_BOOTABLE); } if (successful) { fprintf(stderr, "SLOT %s: already marked successful\n", slot_suffix_arr[slot]); goto out; } if (update_slot_attribute(&disk, slot, ATTR_BOOT_SUCCESSFUL)) { fprintf(stderr, "SLOT %s: Failed to mark boot successful\n", slot_suffix_arr[slot]); ret = -1; goto out; } out: gpt_disk_free(&disk); return ret; } const char *get_suffix(unsigned slot) { if (boot_control_check_slot_sanity(slot) != 0) return ""; else return slot_suffix_arr[slot]; } // The argument here is a vector of partition names(including the slot suffix) // that lie on a single disk static int boot_ctl_set_active_slot_for_partitions(struct gpt_disk *disk, unsigned slot) { char buf[GPT_PTN_PATH_MAX] = { 0 }; const char *slotA; char slotB[MAX_GPT_NAME_SIZE] = { 0 }; char active_guid[TYPE_GUID_SIZE + 1] = { 0 }; char inactive_guid[TYPE_GUID_SIZE + 1] = { 0 }; int rc, i; // Pointer to the partition entry of current 'A' partition uint8_t *pentryA = NULL; uint8_t *pentryA_bak = NULL; // Pointer to partition entry of current 'B' partition uint8_t *pentryB = NULL; uint8_t *pentryB_bak = NULL; struct stat st; LOGD("Marking slot %s as active:\n", slot_suffix_arr[slot]); for (i = 0, slotA = g_all_ptns[0]; i < ARRAY_SIZE(g_all_ptns); slotA = g_all_ptns[++i]) { // Chop off the slot suffix from the partition name to // make the string easier to work with. LOGD("Part: %s\n", slotA); int n = strlen(slotA) - strlen(AB_SLOT_A_SUFFIX); if (n + 1 < 3 || n + 1 > MAX_GPT_NAME_SIZE) { fprintf(stderr, "Invalid partition name: %s\n", slotA); return -1; } memset(slotB, 0, sizeof(slotB)); strncat(slotB, slotA, MAX_GPT_NAME_SIZE - 1); slotB[strlen(slotB) - 1] = 'b'; rc = snprintf(buf, sizeof(buf) - 1, "%s", BOOT_DEV_DIR); snprintf(buf + rc, GPT_PTN_PATH_MAX - rc, "/%s", slotA); LOGD("Checking for partition %s\n", buf); if (stat(buf, &st)) { if (!strcmp(slotA, "boot_a") || !strcmp(slotA, "dtbo_a")) { fprintf(stderr, "Couldn't find required partition %s\n", slotA); return -1; } // Not every device has every partition continue; } buf[strlen(buf) - 1] = 'b'; if (stat(buf, &st)) { fprintf(stderr, "Partition %s does not exist\n", buf); return -1; } // Get the disk containing this partition. This only // actually re-initialises disk if this partition refers // to a different block device than the last one. if (gpt_disk_get_disk_info(slotA, disk) < 0) return -1; // Get partition entry for slot A & B from the primary // and backup tables. pentryA = gpt_disk_get_pentry(disk, slotA, PRIMARY_GPT); pentryA_bak = gpt_disk_get_pentry(disk, slotA, SECONDARY_GPT); pentryB = gpt_disk_get_pentry(disk, slotB, PRIMARY_GPT); pentryB_bak = gpt_disk_get_pentry(disk, slotB, SECONDARY_GPT); if (!pentryA || !pentryA_bak || !pentryB || !pentryB_bak) { // None of these should be NULL since we have already // checked for A & B versions earlier. fprintf(stderr, "Slot pentries for %s not found.\n", slotA); return -1; } LOGD("\tAB attr (A): 0x%x (backup: 0x%x)\n", *(uint16_t *)(pentryA + AB_FLAG_OFFSET), *(uint16_t *)(pentryA_bak + AB_FLAG_OFFSET)); LOGD("\tAB attr (B): 0x%x (backup: 0x%x)\n", *(uint16_t *)(pentryB + AB_FLAG_OFFSET), *(uint16_t *)(pentryB_bak + AB_FLAG_OFFSET)); memset(active_guid, '\0', sizeof(active_guid)); memset(inactive_guid, '\0', sizeof(inactive_guid)); if (get_partition_attribute(disk, slotA, ATTR_SLOT_ACTIVE) == 1) { // A is the current active slot memcpy((void *)active_guid, (const void *)pentryA, TYPE_GUID_SIZE); memcpy((void *)inactive_guid, (const void *)pentryB, TYPE_GUID_SIZE); } else if (get_partition_attribute(disk, slotB, ATTR_SLOT_ACTIVE) == 1) { // B is the current active slot memcpy((void *)active_guid, (const void *)pentryB, TYPE_GUID_SIZE); memcpy((void *)inactive_guid, (const void *)pentryA, TYPE_GUID_SIZE); } else { fprintf(stderr, "Both A & B are inactive..Aborting"); return -1; } int a_state = slot == 0 ? SLOT_ACTIVE : SLOT_INACTIVE; int b_state = slot == 1 ? SLOT_ACTIVE : SLOT_INACTIVE; // This check *Really* shouldn't be here... But I don't know this codebase // well enough to remove it. if (slot > 1) { fprintf(stderr, "%s: Unknown slot %d!\n", __func__, slot); return -1; } // Mark A as active in primary table UPDATE_SLOT(pentryA, active_guid, a_state); // Mark A as active in backup table UPDATE_SLOT(pentryA_bak, active_guid, a_state); // Mark B as inactive in primary table UPDATE_SLOT(pentryB, inactive_guid, b_state); // Mark B as inactive in backup table UPDATE_SLOT(pentryB_bak, inactive_guid, b_state); } // write updated content to disk if (gpt_disk_commit(disk)) { fprintf(stderr, "Failed to commit disk entry"); return -1; } return 0; } unsigned get_active_boot_slot() { struct gpt_disk disk = { 0 }; uint32_t num_slots = get_number_slots(); if (num_slots <= 1) { // Slot 0 is the only slot around. return 0; } for (uint32_t i = 0; i < num_slots; i++) { if (get_boot_attr(&disk, i, ATTR_SLOT_ACTIVE)) { gpt_disk_free(&disk); return i; } } fprintf(stderr, "%s: Failed to find the active boot slot\n", __func__); gpt_disk_free(&disk); return 0; } int set_active_boot_slot(unsigned slot) { enum boot_chain chain = (enum boot_chain)slot; struct gpt_disk disk = { 0 }; int rc; bool ismmc; if (boot_control_check_slot_sanity(slot)) { fprintf(stderr, "%s: Bad arguments\n", __func__); return -1; } ismmc = gpt_utils_is_partition_backed_by_emmc(PTN_XBL AB_SLOT_A_SUFFIX); // Do this *before* updating all the slot attributes // to make sure we can if (!ismmc && ufs_bsg_dev_open() < 0) { return -1; } rc = boot_ctl_set_active_slot_for_partitions(&disk, slot); if (rc) { fprintf(stderr, "%s: Failed to set active slot for partitions \n", __func__); goto out; } // EMMC doesn't need attributes to be set. if (ismmc) goto out; if (chain > BACKUP_BOOT) { fprintf(stderr, "%s: Unknown slot %d!\n", __func__, slot); rc = -1; goto out; } rc = gpt_utils_set_xbl_boot_partition(chain); if (rc) { fprintf(stderr, "%s: Failed to switch xbl boot partition\n", __func__); goto out; } out: gpt_disk_free(&disk); return rc; } int set_slot_as_unbootable(unsigned slot) { struct gpt_disk disk = { 0 }; int ret; if (boot_control_check_slot_sanity(slot) != 0) return -1; ret = update_slot_attribute(&disk, slot, ATTR_UNBOOTABLE); gpt_disk_free(&disk); return ret; } int is_slot_marked_successful(unsigned slot) { int ret; struct gpt_disk disk = { 0 }; if (boot_control_check_slot_sanity(slot) != 0) return -1; ret = get_boot_attr(&disk, slot, ATTR_BOOT_SUCCESSFUL); gpt_disk_free(&disk); return ret; } const struct boot_control_module bootctl = { .getCurrentSlot = get_current_slot_from_kernel_cmdline, .markBootSuccessful = mark_boot_successful, .setActiveBootSlot = set_active_boot_slot, .setSlotAsUnbootable = set_slot_as_unbootable, .isSlotBootable = is_slot_bootable, .getSuffix = get_suffix, .isSlotMarkedSuccessful = is_slot_marked_successful, .getActiveBootSlot = get_active_boot_slot, };