/* * Copyright (c) 2013, 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. */ #define _LARGEFILE64_SOURCE /* enable lseek64() */ /****************************************************************************** * INCLUDE SECTION ******************************************************************************/ #include <stdio.h> #include <fcntl.h> #include <string.h> #include <errno.h> #include <sys/stat.h> #include <sys/ioctl.h> #include <scsi/ufs/ioctl.h> #include <scsi/ufs/ufs.h> #include <unistd.h> #include <linux/fs.h> #include <limits.h> #include <dirent.h> #include <inttypes.h> #include <linux/kernel.h> #include <asm/byteorder.h> #include <map> #include <vector> #include <string> #define LOG_TAG "gpt-utils" #include <cutils/log.h> #include <cutils/properties.h> #include "gpt-utils.h" #ifdef __cplusplus extern "C" { #endif #include "sparse_crc32.h" #ifdef __cplusplus } #endif #include <endian.h> /****************************************************************************** * DEFINE SECTION ******************************************************************************/ #define BLK_DEV_FILE "/dev/block/mmcblk0" /* list the names of the backed-up partitions to be swapped */ /* extension used for the backup partitions - tzbak, abootbak, etc. */ #define BAK_PTN_NAME_EXT "bak" #define XBL_PRIMARY "/dev/block/bootdevice/by-name/xbl" #define XBL_BACKUP "/dev/block/bootdevice/by-name/xblbak" #define XBL_AB_PRIMARY "/dev/block/bootdevice/by-name/xbl_a" #define XBL_AB_SECONDARY "/dev/block/bootdevice/by-name/xbl_b" /* GPT defines */ #define MAX_LUNS 26 //Size of the buffer that needs to be passed to the UFS ioctl #define UFS_ATTR_DATA_SIZE 32 //This will allow us to get the root lun path from the path to the partition. //i.e: from /dev/block/sdaXXX get /dev/block/sda. The assumption here is that //the boot critical luns lie between sda to sdz which is acceptable because //only user added external disks,etc would lie beyond that limit which do not //contain partitions that interest us here. #define PATH_TRUNCATE_LOC (sizeof("/dev/block/sda") - 1) //From /dev/block/sda get just sda #define LUN_NAME_START_LOC (sizeof("/dev/block/") - 1) #define BOOT_LUN_A_ID 1 #define BOOT_LUN_B_ID 2 /****************************************************************************** * MACROS ******************************************************************************/ #define GET_4_BYTES(ptr) ((uint32_t) *((uint8_t *)(ptr)) | \ ((uint32_t) *((uint8_t *)(ptr) + 1) << 8) | \ ((uint32_t) *((uint8_t *)(ptr) + 2) << 16) | \ ((uint32_t) *((uint8_t *)(ptr) + 3) << 24)) #define GET_8_BYTES(ptr) ((uint64_t) *((uint8_t *)(ptr)) | \ ((uint64_t) *((uint8_t *)(ptr) + 1) << 8) | \ ((uint64_t) *((uint8_t *)(ptr) + 2) << 16) | \ ((uint64_t) *((uint8_t *)(ptr) + 3) << 24) | \ ((uint64_t) *((uint8_t *)(ptr) + 4) << 32) | \ ((uint64_t) *((uint8_t *)(ptr) + 5) << 40) | \ ((uint64_t) *((uint8_t *)(ptr) + 6) << 48) | \ ((uint64_t) *((uint8_t *)(ptr) + 7) << 56)) #define PUT_4_BYTES(ptr, y) *((uint8_t *)(ptr)) = (y) & 0xff; \ *((uint8_t *)(ptr) + 1) = ((y) >> 8) & 0xff; \ *((uint8_t *)(ptr) + 2) = ((y) >> 16) & 0xff; \ *((uint8_t *)(ptr) + 3) = ((y) >> 24) & 0xff; /****************************************************************************** * TYPES ******************************************************************************/ using namespace std; enum gpt_state { GPT_OK = 0, GPT_BAD_SIGNATURE, GPT_BAD_CRC }; //List of LUN's containing boot critical images. //Required in the case of UFS devices struct update_data { char lun_list[MAX_LUNS][PATH_MAX]; uint32_t num_valid_entries; }; /****************************************************************************** * FUNCTIONS ******************************************************************************/ /** * ========================================================================== * * \brief Read/Write len bytes from/to block dev * * \param [in] fd block dev file descriptor (returned from open) * \param [in] rw RW flag: 0 - read, != 0 - write * \param [in] offset block dev offset [bytes] - RW start position * \param [in] buf Pointer to the buffer containing the data * \param [in] len RW size in bytes. Buf must be at least that big * * \return 0 on success * * ========================================================================== */ static int blk_rw(int fd, int rw, int64_t offset, uint8_t *buf, unsigned len) { int r; if (lseek64(fd, offset, SEEK_SET) < 0) { fprintf(stderr, "block dev lseek64 %" PRIi64 " failed: %s\n", offset, strerror(errno)); return -1; } if (rw) r = write(fd, buf, len); else r = read(fd, buf, len); if (r < 0) fprintf(stderr, "block dev %s failed: %s\n", rw ? "write" : "read", strerror(errno)); else r = 0; return r; } /** * ========================================================================== * * \brief Search within GPT for partition entry with the given name * or it's backup twin (name-bak). * * \param [in] ptn_name Partition name to seek * \param [in] pentries_start Partition entries array start pointer * \param [in] pentries_end Partition entries array end pointer * \param [in] pentry_size Single partition entry size [bytes] * * \return First partition entry pointer that matches the name or NULL * * ========================================================================== */ static uint8_t *gpt_pentry_seek(const char *ptn_name, const uint8_t *pentries_start, const uint8_t *pentries_end, uint32_t pentry_size) { char *pentry_name; unsigned len = strlen(ptn_name); for (pentry_name = (char *) (pentries_start + PARTITION_NAME_OFFSET); pentry_name < (char *) pentries_end; pentry_name += pentry_size) { char name8[MAX_GPT_NAME_SIZE / 2]; unsigned i; /* Partition names in GPT are UTF-16 - ignoring UTF-16 2nd byte */ for (i = 0; i < sizeof(name8); i++) name8[i] = pentry_name[i * 2]; if (!strncmp(ptn_name, name8, len)) if (name8[len] == 0 || !strcmp(&name8[len], BAK_PTN_NAME_EXT)) return (uint8_t *) (pentry_name - PARTITION_NAME_OFFSET); } return NULL; } /** * ========================================================================== * * \brief Swaps boot chain in GPT partition entries array * * \param [in] pentries_start Partition entries array start * \param [in] pentries_end Partition entries array end * \param [in] pentry_size Single partition entry size * * \return 0 on success, 1 if no backup partitions found * * ========================================================================== */ static int gpt_boot_chain_swap(const uint8_t *pentries_start, const uint8_t *pentries_end, uint32_t pentry_size) { const char ptn_swap_list[][MAX_GPT_NAME_SIZE] = { PTN_SWAP_LIST }; int backup_not_found = 1; unsigned i; for (i = 0; i < ARRAY_SIZE(ptn_swap_list); i++) { uint8_t *ptn_entry; uint8_t *ptn_bak_entry; uint8_t ptn_swap[PTN_ENTRY_SIZE]; //Skip the xbl partition on UFS devices. That is handled //seperately. if (gpt_utils_is_ufs_device() && !strncmp(ptn_swap_list[i], PTN_XBL, strlen(PTN_XBL))) continue; ptn_entry = gpt_pentry_seek(ptn_swap_list[i], pentries_start, pentries_end, pentry_size); if (ptn_entry == NULL) continue; ptn_bak_entry = gpt_pentry_seek(ptn_swap_list[i], ptn_entry + pentry_size, pentries_end, pentry_size); if (ptn_bak_entry == NULL) { fprintf(stderr, "'%s' partition not backup - skip safe update\n", ptn_swap_list[i]); continue; } /* swap primary <-> backup partition entries */ memcpy(ptn_swap, ptn_entry, PTN_ENTRY_SIZE); memcpy(ptn_entry, ptn_bak_entry, PTN_ENTRY_SIZE); memcpy(ptn_bak_entry, ptn_swap, PTN_ENTRY_SIZE); backup_not_found = 0; } return backup_not_found; } /** * ========================================================================== * * \brief Sets secondary GPT boot chain * * \param [in] fd block dev file descriptor * \param [in] boot Boot chain to switch to * * \return 0 on success * * ========================================================================== */ static int gpt2_set_boot_chain(int fd, enum boot_chain boot) { int64_t gpt2_header_offset; uint64_t pentries_start_offset; uint32_t gpt_header_size; uint32_t pentry_size; uint32_t pentries_array_size; uint8_t *gpt_header = NULL; uint8_t *pentries = NULL; uint32_t crc; uint32_t blk_size = 0; int r; if (ioctl(fd, BLKSSZGET, &blk_size) != 0) { fprintf(stderr, "Failed to get GPT device block size: %s\n", strerror(errno)); r = -1; goto EXIT; } gpt_header = (uint8_t*)malloc(blk_size); if (!gpt_header) { fprintf(stderr, "Failed to allocate memory to hold GPT block\n"); r = -1; goto EXIT; } gpt2_header_offset = lseek64(fd, 0, SEEK_END) - blk_size; if (gpt2_header_offset < 0) { fprintf(stderr, "Getting secondary GPT header offset failed: %s\n", strerror(errno)); r = -1; goto EXIT; } /* Read primary GPT header from block dev */ r = blk_rw(fd, 0, blk_size, gpt_header, blk_size); if (r) { fprintf(stderr, "Failed to read primary GPT header from blk dev\n"); goto EXIT; } pentries_start_offset = GET_8_BYTES(gpt_header + PENTRIES_OFFSET) * blk_size; pentry_size = GET_4_BYTES(gpt_header + PENTRY_SIZE_OFFSET); pentries_array_size = GET_4_BYTES(gpt_header + PARTITION_COUNT_OFFSET) * pentry_size; pentries = (uint8_t *) calloc(1, pentries_array_size); if (pentries == NULL) { fprintf(stderr, "Failed to alloc memory for GPT partition entries array\n"); r = -1; goto EXIT; } /* Read primary GPT partititon entries array from block dev */ r = blk_rw(fd, 0, pentries_start_offset, pentries, pentries_array_size); if (r) goto EXIT; crc = sparse_crc32(0, pentries, pentries_array_size); if (GET_4_BYTES(gpt_header + PARTITION_CRC_OFFSET) != crc) { fprintf(stderr, "Primary GPT partition entries array CRC invalid\n"); r = -1; goto EXIT; } /* Read secondary GPT header from block dev */ r = blk_rw(fd, 0, gpt2_header_offset, gpt_header, blk_size); if (r) goto EXIT; gpt_header_size = GET_4_BYTES(gpt_header + HEADER_SIZE_OFFSET); pentries_start_offset = GET_8_BYTES(gpt_header + PENTRIES_OFFSET) * blk_size; if (boot == BACKUP_BOOT) { r = gpt_boot_chain_swap(pentries, pentries + pentries_array_size, pentry_size); if (r) goto EXIT; } crc = sparse_crc32(0, pentries, pentries_array_size); PUT_4_BYTES(gpt_header + PARTITION_CRC_OFFSET, crc); /* header CRC is calculated with this field cleared */ PUT_4_BYTES(gpt_header + HEADER_CRC_OFFSET, 0); crc = sparse_crc32(0, gpt_header, gpt_header_size); PUT_4_BYTES(gpt_header + HEADER_CRC_OFFSET, crc); /* Write the modified GPT header back to block dev */ r = blk_rw(fd, 1, gpt2_header_offset, gpt_header, blk_size); if (!r) /* Write the modified GPT partititon entries array back to block dev */ r = blk_rw(fd, 1, pentries_start_offset, pentries, pentries_array_size); EXIT: if(gpt_header) free(gpt_header); if (pentries) free(pentries); return r; } /** * ========================================================================== * * \brief Checks GPT state (header signature and CRC) * * \param [in] fd block dev file descriptor * \param [in] gpt GPT header to be checked * \param [out] state GPT header state * * \return 0 on success * * ========================================================================== */ static int gpt_get_state(int fd, enum gpt_instance gpt, enum gpt_state *state) { int64_t gpt_header_offset; uint32_t gpt_header_size; uint8_t *gpt_header = NULL; uint32_t crc; uint32_t blk_size = 0; *state = GPT_OK; if (ioctl(fd, BLKSSZGET, &blk_size) != 0) { fprintf(stderr, "Failed to get GPT device block size: %s\n", strerror(errno)); goto error; } gpt_header = (uint8_t*)malloc(blk_size); if (!gpt_header) { fprintf(stderr, "gpt_get_state:Failed to alloc memory for header\n"); goto error; } if (gpt == PRIMARY_GPT) gpt_header_offset = blk_size; else { gpt_header_offset = lseek64(fd, 0, SEEK_END) - blk_size; if (gpt_header_offset < 0) { fprintf(stderr, "gpt_get_state:Seek to end of GPT part fail\n"); goto error; } } if (blk_rw(fd, 0, gpt_header_offset, gpt_header, blk_size)) { fprintf(stderr, "gpt_get_state: blk_rw failed\n"); goto error; } if (memcmp(gpt_header, GPT_SIGNATURE, sizeof(GPT_SIGNATURE))) *state = GPT_BAD_SIGNATURE; gpt_header_size = GET_4_BYTES(gpt_header + HEADER_SIZE_OFFSET); crc = GET_4_BYTES(gpt_header + HEADER_CRC_OFFSET); /* header CRC is calculated with this field cleared */ PUT_4_BYTES(gpt_header + HEADER_CRC_OFFSET, 0); if (sparse_crc32(0, gpt_header, gpt_header_size) != crc) *state = GPT_BAD_CRC; free(gpt_header); return 0; error: if (gpt_header) free(gpt_header); return -1; } /** * ========================================================================== * * \brief Sets GPT header state (used to corrupt and fix GPT signature) * * \param [in] fd block dev file descriptor * \param [in] gpt GPT header to be checked * \param [in] state GPT header state to set (GPT_OK or GPT_BAD_SIGNATURE) * * \return 0 on success * * ========================================================================== */ static int gpt_set_state(int fd, enum gpt_instance gpt, enum gpt_state state) { int64_t gpt_header_offset; uint32_t gpt_header_size; uint8_t *gpt_header = NULL; uint32_t crc; uint32_t blk_size = 0; if (ioctl(fd, BLKSSZGET, &blk_size) != 0) { fprintf(stderr, "Failed to get GPT device block size: %s\n", strerror(errno)); goto error; } gpt_header = (uint8_t*)malloc(blk_size); if (!gpt_header) { fprintf(stderr, "Failed to alloc memory for gpt header\n"); goto error; } if (gpt == PRIMARY_GPT) gpt_header_offset = blk_size; else { gpt_header_offset = lseek64(fd, 0, SEEK_END) - blk_size; if (gpt_header_offset < 0) { fprintf(stderr, "Failed to seek to end of GPT device\n"); goto error; } } if (blk_rw(fd, 0, gpt_header_offset, gpt_header, blk_size)) { fprintf(stderr, "Failed to r/w gpt header\n"); goto error; } if (state == GPT_OK) memcpy(gpt_header, GPT_SIGNATURE, sizeof(GPT_SIGNATURE)); else if (state == GPT_BAD_SIGNATURE) *gpt_header = 0; else { fprintf(stderr, "gpt_set_state: Invalid state\n"); goto error; } gpt_header_size = GET_4_BYTES(gpt_header + HEADER_SIZE_OFFSET); /* header CRC is calculated with this field cleared */ PUT_4_BYTES(gpt_header + HEADER_CRC_OFFSET, 0); crc = sparse_crc32(0, gpt_header, gpt_header_size); PUT_4_BYTES(gpt_header + HEADER_CRC_OFFSET, crc); if (blk_rw(fd, 1, gpt_header_offset, gpt_header, blk_size)) { fprintf(stderr, "gpt_set_state: blk write failed\n"); goto error; } return 0; error: if(gpt_header) free(gpt_header); return -1; } int get_scsi_node_from_bootdevice(const char *bootdev_path, char *sg_node_path, size_t buf_size) { char sg_dir_path[PATH_MAX] = {0}; char real_path[PATH_MAX] = {0}; DIR *scsi_dir = NULL; struct dirent *de; int node_found = 0; if (!bootdev_path || !sg_node_path) { fprintf(stderr, "%s : invalid argument\n", __func__); goto error; } if (readlink(bootdev_path, real_path, sizeof(real_path) - 1) < 0) { fprintf(stderr, "failed to resolve link for %s(%s)\n", bootdev_path, strerror(errno)); goto error; } if(strlen(real_path) < PATH_TRUNCATE_LOC + 1){ fprintf(stderr, "Unrecognized path :%s:\n", real_path); goto error; } //For the safe side in case there are additional partitions on //the XBL lun we truncate the name. real_path[PATH_TRUNCATE_LOC] = '\0'; if(strlen(real_path) < LUN_NAME_START_LOC + 1){ fprintf(stderr, "Unrecognized truncated path :%s:\n", real_path); goto error; } //This will give us /dev/block/sdb/device/scsi_generic //which contains a file sgY whose name gives us the path //to /dev/sgY which we return snprintf(sg_dir_path, sizeof(sg_dir_path) - 1, "/sys/block/%s/device/scsi_generic", &real_path[LUN_NAME_START_LOC]); scsi_dir = opendir(sg_dir_path); if (!scsi_dir) { fprintf(stderr, "%s : Failed to open %s(%s)\n", __func__, sg_dir_path, strerror(errno)); goto error; } while((de = readdir(scsi_dir))) { if (de->d_name[0] == '.') continue; else if (!strncmp(de->d_name, "sg", 2)) { snprintf(sg_node_path, buf_size -1, "/dev/%s", de->d_name); fprintf(stderr, "%s:scsi generic node is :%s:\n", __func__, sg_node_path); node_found = 1; break; } } if(!node_found) { fprintf(stderr,"%s: Unable to locate scsi generic node\n", __func__); goto error; } closedir(scsi_dir); return 0; error: if (scsi_dir) closedir(scsi_dir); return -1; } int set_boot_lun(char *sg_dev, uint8_t boot_lun_id) { int fd = -1; int rc; struct ufs_ioctl_query_data *data = NULL; size_t ioctl_data_size = sizeof(struct ufs_ioctl_query_data) + UFS_ATTR_DATA_SIZE; data = (struct ufs_ioctl_query_data*)malloc(ioctl_data_size); if (!data) { fprintf(stderr, "%s: Failed to alloc query data struct\n", __func__); goto error; } memset(data, 0, ioctl_data_size); data->opcode = UPIU_QUERY_OPCODE_WRITE_ATTR; data->idn = QUERY_ATTR_IDN_BOOT_LU_EN; data->buf_size = UFS_ATTR_DATA_SIZE; data->buffer[0] = boot_lun_id; fd = open(sg_dev, O_RDWR); if (fd < 0) { fprintf(stderr, "%s: Failed to open %s(%s)\n", __func__, sg_dev, strerror(errno)); goto error; } rc = ioctl(fd, UFS_IOCTL_QUERY, data); if (rc) { fprintf(stderr, "%s: UFS query ioctl failed(%s)\n", __func__, strerror(errno)); goto error; } close(fd); free(data); return 0; error: if (fd >= 0) close(fd); if (data) free(data); return -1; } //Swtich betwieen using either the primary or the backup //boot LUN for boot. This is required since UFS boot partitions //cannot have a backup GPT which is what we use for failsafe //updates of the other 'critical' partitions. This function will //not be invoked for emmc targets and on UFS targets is only required //to be invoked for XBL. // //The algorithm to do this is as follows: //- Find the real block device(eg: /dev/block/sdb) that corresponds // to the /dev/block/bootdevice/by-name/xbl(bak) symlink // //- Once we have the block device 'node' name(sdb in the above example) // use this node to to locate the scsi generic device that represents // it by checking the file /sys/block/sdb/device/scsi_generic/sgY // //- Once we locate sgY we call the query ioctl on /dev/sgy to switch //the boot lun to either LUNA or LUNB int gpt_utils_set_xbl_boot_partition(enum boot_chain chain) { struct stat st; ///sys/block/sdX/device/scsi_generic/ char sg_dev_node[PATH_MAX] = {0}; uint8_t boot_lun_id = 0; const char *boot_dev = NULL; if (chain == BACKUP_BOOT) { boot_lun_id = BOOT_LUN_B_ID; if (!stat(XBL_BACKUP, &st)) boot_dev = XBL_BACKUP; else if (!stat(XBL_AB_SECONDARY, &st)) boot_dev = XBL_AB_SECONDARY; else { fprintf(stderr, "%s: Failed to locate secondary xbl\n", __func__); goto error; } } else if (chain == NORMAL_BOOT) { boot_lun_id = BOOT_LUN_A_ID; if (!stat(XBL_PRIMARY, &st)) boot_dev = XBL_PRIMARY; else if (!stat(XBL_AB_PRIMARY, &st)) boot_dev = XBL_AB_PRIMARY; else { fprintf(stderr, "%s: Failed to locate primary xbl\n", __func__); goto error; } } else { fprintf(stderr, "%s: Invalid boot chain id\n", __func__); goto error; } //We need either both xbl and xblbak or both xbl_a and xbl_b to exist at //the same time. If not the current configuration is invalid. if((stat(XBL_PRIMARY, &st) || stat(XBL_BACKUP, &st)) && (stat(XBL_AB_PRIMARY, &st) || stat(XBL_AB_SECONDARY, &st))) { fprintf(stderr, "%s:primary/secondary XBL prt not found(%s)\n", __func__, strerror(errno)); goto error; } fprintf(stderr, "%s: setting %s lun as boot lun\n", __func__, boot_dev); if (get_scsi_node_from_bootdevice(boot_dev, sg_dev_node, sizeof(sg_dev_node))) { fprintf(stderr, "%s: Failed to get scsi node path for xblbak\n", __func__); goto error; } if (set_boot_lun(sg_dev_node, boot_lun_id)) { fprintf(stderr, "%s: Failed to set xblbak as boot partition\n", __func__); goto error; } return 0; error: return -1; } int gpt_utils_is_ufs_device() { char bootdevice[PROPERTY_VALUE_MAX] = {0}; property_get("ro.boot.bootdevice", bootdevice, "N/A"); if (strlen(bootdevice) < strlen(".ufshc") + 1) return 0; return (!strncmp(&bootdevice[strlen(bootdevice) - strlen(".ufshc")], ".ufshc", sizeof(".ufshc"))); } //dev_path is the path to the block device that contains the GPT image that //needs to be updated. This would be the device which holds one or more critical //boot partitions and their backups. In the case of EMMC this function would //be invoked only once on /dev/block/mmcblk1 since it holds the GPT image //containing all the partitions For UFS devices it could potentially be //invoked multiple times, once for each LUN containing critical image(s) and //their backups int prepare_partitions(enum boot_update_stage stage, const char *dev_path) { int r = 0; int fd = -1; int is_ufs = gpt_utils_is_ufs_device(); enum gpt_state gpt_prim, gpt_second; enum boot_update_stage internal_stage; struct stat xbl_partition_stat; struct stat ufs_dir_stat; if (!dev_path) { fprintf(stderr, "%s: Invalid dev_path\n", __func__); r = -1; goto EXIT; } fd = open(dev_path, O_RDWR); if (fd < 0) { fprintf(stderr, "%s: Opening '%s' failed: %s\n", __func__, BLK_DEV_FILE, strerror(errno)); r = -1; goto EXIT; } r = gpt_get_state(fd, PRIMARY_GPT, &gpt_prim) || gpt_get_state(fd, SECONDARY_GPT, &gpt_second); if (r) { fprintf(stderr, "%s: Getting GPT headers state failed\n", __func__); goto EXIT; } /* These 2 combinations are unexpected and unacceptable */ if (gpt_prim == GPT_BAD_CRC || gpt_second == GPT_BAD_CRC) { fprintf(stderr, "%s: GPT headers CRC corruption detected, aborting\n", __func__); r = -1; goto EXIT; } if (gpt_prim == GPT_BAD_SIGNATURE && gpt_second == GPT_BAD_SIGNATURE) { fprintf(stderr, "%s: Both GPT headers corrupted, aborting\n", __func__); r = -1; goto EXIT; } /* Check internal update stage according GPT headers' state */ if (gpt_prim == GPT_OK && gpt_second == GPT_OK) internal_stage = UPDATE_MAIN; else if (gpt_prim == GPT_BAD_SIGNATURE) internal_stage = UPDATE_BACKUP; else if (gpt_second == GPT_BAD_SIGNATURE) internal_stage = UPDATE_FINALIZE; else { fprintf(stderr, "%s: Abnormal GPTs state: primary (%d), secondary (%d), " "aborting\n", __func__, gpt_prim, gpt_second); r = -1; goto EXIT; } /* Stage already set - ready for update, exitting */ if ((int) stage == (int) internal_stage - 1) goto EXIT; /* Unexpected stage given */ if (stage != internal_stage) { r = -1; goto EXIT; } switch (stage) { case UPDATE_MAIN: if (is_ufs) { if(stat(XBL_PRIMARY, &xbl_partition_stat)|| stat(XBL_BACKUP, &xbl_partition_stat)){ //Non fatal error. Just means this target does not //use XBL but relies on sbl whose update is handled //by the normal methods. fprintf(stderr, "%s: xbl part not found(%s).Assuming sbl in use\n", __func__, strerror(errno)); } else { //Switch the boot lun so that backup boot LUN is used r = gpt_utils_set_xbl_boot_partition(BACKUP_BOOT); if(r){ fprintf(stderr, "%s: Failed to set xbl backup partition as boot\n", __func__); goto EXIT; } } } //Fix up the backup GPT table so that it actually points to //the backup copy of the boot critical images fprintf(stderr, "%s: Preparing for primary partition update\n", __func__); r = gpt2_set_boot_chain(fd, BACKUP_BOOT); if (r) { if (r < 0) fprintf(stderr, "%s: Setting secondary GPT to backup boot failed\n", __func__); /* No backup partitions - do not corrupt GPT, do not flag error */ else r = 0; goto EXIT; } //corrupt the primary GPT so that the backup(which now points to //the backup boot partitions is used) r = gpt_set_state(fd, PRIMARY_GPT, GPT_BAD_SIGNATURE); if (r) { fprintf(stderr, "%s: Corrupting primary GPT header failed\n", __func__); goto EXIT; } break; case UPDATE_BACKUP: if (is_ufs) { if(stat(XBL_PRIMARY, &xbl_partition_stat)|| stat(XBL_BACKUP, &xbl_partition_stat)){ //Non fatal error. Just means this target does not //use XBL but relies on sbl whose update is handled //by the normal methods. fprintf(stderr, "%s: xbl part not found(%s).Assuming sbl in use\n", __func__, strerror(errno)); } else { //Switch the boot lun so that backup boot LUN is used r = gpt_utils_set_xbl_boot_partition(NORMAL_BOOT); if(r) { fprintf(stderr, "%s: Failed to set xbl backup partition as boot\n", __func__); goto EXIT; } } } //Fix the primary GPT header so that is used fprintf(stderr, "%s: Preparing for backup partition update\n", __func__); r = gpt_set_state(fd, PRIMARY_GPT, GPT_OK); if (r) { fprintf(stderr, "%s: Fixing primary GPT header failed\n", __func__); goto EXIT; } //Corrupt the scondary GPT header r = gpt_set_state(fd, SECONDARY_GPT, GPT_BAD_SIGNATURE); if (r) { fprintf(stderr, "%s: Corrupting secondary GPT header failed\n", __func__); goto EXIT; } break; case UPDATE_FINALIZE: //Undo the changes we had made in the UPDATE_MAIN stage so that the //primary/backup GPT headers once again point to the same set of //partitions fprintf(stderr, "%s: Finalizing partitions\n", __func__); r = gpt2_set_boot_chain(fd, NORMAL_BOOT); if (r < 0) { fprintf(stderr, "%s: Setting secondary GPT to normal boot failed\n", __func__); goto EXIT; } r = gpt_set_state(fd, SECONDARY_GPT, GPT_OK); if (r) { fprintf(stderr, "%s: Fixing secondary GPT header failed\n", __func__); goto EXIT; } break; default:; } EXIT: if (fd >= 0) { fsync(fd); close(fd); } return r; } int add_lun_to_update_list(char *lun_path, struct update_data *dat) { uint32_t i = 0; struct stat st; if (!lun_path || !dat){ fprintf(stderr, "%s: Invalid data", __func__); return -1; } if (stat(lun_path, &st)) { fprintf(stderr, "%s: Unable to access %s. Skipping adding to list", __func__, lun_path); return -1; } if (dat->num_valid_entries == 0) { fprintf(stderr, "%s: Copying %s into lun_list[%d]\n", __func__, lun_path, i); strlcpy(dat->lun_list[0], lun_path, PATH_MAX * sizeof(char)); dat->num_valid_entries = 1; } else { for (i = 0; (i < dat->num_valid_entries) && (dat->num_valid_entries < MAX_LUNS - 1); i++) { //Check if the current LUN is not already part //of the lun list if (!strncmp(lun_path,dat->lun_list[i], strlen(dat->lun_list[i]))) { //LUN already in list..Return return 0; } } fprintf(stderr, "%s: Copying %s into lun_list[%d]\n", __func__, lun_path, dat->num_valid_entries); //Add LUN path lun list strlcpy(dat->lun_list[dat->num_valid_entries], lun_path, PATH_MAX * sizeof(char)); dat->num_valid_entries++; } return 0; } int prepare_boot_update(enum boot_update_stage stage) { int r, fd; int is_ufs = gpt_utils_is_ufs_device(); struct stat ufs_dir_stat; struct update_data data; int rcode = 0; uint32_t i = 0; int is_error = 0; const char ptn_swap_list[][MAX_GPT_NAME_SIZE] = { PTN_SWAP_LIST }; //Holds /dev/block/bootdevice/by-name/*bak entry char buf[PATH_MAX] = {0}; //Holds the resolved path of the symlink stored in buf char real_path[PATH_MAX] = {0}; if (!is_ufs) { //emmc device. Just pass in path to mmcblk0 return prepare_partitions(stage, BLK_DEV_FILE); } else { //Now we need to find the list of LUNs over //which the boot critical images are spread //and set them up for failsafe updates.To do //this we find out where the symlinks for the //each of the paths under ///dev/block/bootdevice/by-name/PTN_SWAP_LIST //actually point to. fprintf(stderr, "%s: Running on a UFS device\n", __func__); memset(&data, '\0', sizeof(struct update_data)); for (i=0; i < ARRAY_SIZE(ptn_swap_list); i++) { //XBL on UFS does not follow the convention //of being loaded based on well known GUID'S. //We take care of switching the UFS boot LUN //explicitly later on. if (!strncmp(ptn_swap_list[i], PTN_XBL, strlen(PTN_XBL))) continue; snprintf(buf, sizeof(buf), "%s/%sbak", BOOT_DEV_DIR, ptn_swap_list[i]); if (stat(buf, &ufs_dir_stat)) { continue; } if (readlink(buf, real_path, sizeof(real_path) - 1) < 0) { fprintf(stderr, "%s: readlink error. Skipping %s", __func__, strerror(errno)); } else { if(strlen(real_path) < PATH_TRUNCATE_LOC + 1){ fprintf(stderr, "Unknown path.Skipping :%s:\n", real_path); } else { real_path[PATH_TRUNCATE_LOC] = '\0'; add_lun_to_update_list(real_path, &data); } } memset(buf, '\0', sizeof(buf)); memset(real_path, '\0', sizeof(real_path)); } for (i=0; i < data.num_valid_entries; i++) { fprintf(stderr, "%s: Preparing %s for update stage %d\n", __func__, data.lun_list[i], stage); rcode = prepare_partitions(stage, data.lun_list[i]); if (rcode != 0) { fprintf(stderr, "%s: Failed to prepare %s.Continuing..\n", __func__, data.lun_list[i]); is_error = 1; } } } if (is_error) return -1; return 0; } //Given a parttion name(eg: rpm) get the path to the block device that //represents the GPT disk the partition resides on. In the case of emmc it //would be the default emmc dev(/dev/mmcblk0). In the case of UFS we look //through the /dev/block/bootdevice/by-name/ tree for partname, and resolve //the path to the LUN from there. static int get_dev_path_from_partition_name(const char *partname, char *buf, size_t buflen) { struct stat st; char path[PATH_MAX] = {0}; if (!partname || !buf || buflen < ((PATH_TRUNCATE_LOC) + 1)) { ALOGE("%s: Invalid argument", __func__); goto error; } if (gpt_utils_is_ufs_device()) { //Need to find the lun that holds partition partname snprintf(path, sizeof(path), "%s/%s", BOOT_DEV_DIR, partname); if (stat(path, &st)) { goto error; } if (readlink(path, buf, buflen) < 0) { goto error; } else { buf[PATH_TRUNCATE_LOC] = '\0'; } } else { snprintf(buf, buflen, "/dev/mmcblk0"); } return 0; error: return -1; } int gpt_utils_get_partition_map(vector<string>& ptn_list, map<string, vector<string>>& partition_map) { char devpath[PATH_MAX] = {'\0'}; map<string, vector<string>>::iterator it; if (ptn_list.size() < 1) { fprintf(stderr, "%s: Invalid ptn list\n", __func__); return -1; } //Go through the passed in list for (uint32_t i = 0; i < ptn_list.size(); i++) { //Key in the map is the path to the device that holds the //partition if (get_dev_path_from_partition_name(ptn_list[i].c_str(), devpath, sizeof(devpath))) { //Not necessarily an error. The partition may just //not be present. continue; } string path = devpath; it = partition_map.find(path); if (it != partition_map.end()) { it->second.push_back(ptn_list[i]); } else { vector<string> str_vec; str_vec.push_back( ptn_list[i]); partition_map.insert(pair<string, vector<string>> (path, str_vec)); } memset(devpath, '\0', sizeof(devpath)); } return 0; } //Get the block size of the disk represented by decsriptor fd static uint32_t gpt_get_block_size(int fd) { uint32_t block_size = 0; if (fd < 0) { ALOGE("%s: invalid descriptor", __func__); goto error; } if (ioctl(fd, BLKSSZGET, &block_size) != 0) { ALOGE("%s: Failed to get GPT dev block size : %s", __func__, strerror(errno)); goto error; } return block_size; error: return 0; } //Write the GPT header present in the passed in buffer back to the //disk represented by fd static int gpt_set_header(uint8_t *gpt_header, int fd, enum gpt_instance instance) { uint32_t block_size = 0; off_t gpt_header_offset = 0; if (!gpt_header || fd < 0) { ALOGE("%s: Invalid arguments", __func__); goto error; } block_size = gpt_get_block_size(fd); ALOGI("%s: Block size is : %d", __func__, block_size); if (block_size == 0) { ALOGE("%s: Failed to get block size", __func__); goto error; } if (instance == PRIMARY_GPT) gpt_header_offset = block_size; else gpt_header_offset = lseek64(fd, 0, SEEK_END) - block_size; if (gpt_header_offset <= 0) { ALOGE("%s: Failed to get gpt header offset",__func__); goto error; } ALOGI("%s: Writing back header to offset %ld", __func__, gpt_header_offset); if (blk_rw(fd, 1, gpt_header_offset, gpt_header, block_size)) { ALOGE("%s: Failed to write back GPT header", __func__); goto error; } return 0; error: return -1; } //Read out the GPT header for the disk that contains the partition partname static uint8_t* gpt_get_header(const char *partname, enum gpt_instance instance) { uint8_t* hdr = NULL; char devpath[PATH_MAX] = {0}; int64_t hdr_offset = 0; uint32_t block_size = 0; int fd = -1; if (!partname) { ALOGE("%s: Invalid partition name", __func__); goto error; } if (get_dev_path_from_partition_name(partname, devpath, sizeof(devpath)) != 0) { ALOGE("%s: Failed to resolve path for %s", __func__, partname); goto error; } fd = open(devpath, O_RDWR); if (fd < 0) { ALOGE("%s: Failed to open %s : %s", __func__, devpath, strerror(errno)); goto error; } block_size = gpt_get_block_size(fd); if (block_size == 0) { ALOGE("%s: Failed to get gpt block size for %s", __func__, partname); goto error; } hdr = (uint8_t*)malloc(block_size); if (!hdr) { ALOGE("%s: Failed to allocate memory for gpt header", __func__); } if (instance == PRIMARY_GPT) hdr_offset = block_size; else { hdr_offset = lseek64(fd, 0, SEEK_END) - block_size; } if (hdr_offset < 0) { ALOGE("%s: Failed to get gpt header offset", __func__); goto error; } if (blk_rw(fd, 0, hdr_offset, hdr, block_size)) { ALOGE("%s: Failed to read GPT header from device", __func__); goto error; } close(fd); return hdr; error: if (fd >= 0) close(fd); if (hdr) free(hdr); return NULL; } //Returns the partition entry array based on the //passed in buffer which contains the gpt header. //The fd here is the descriptor for the 'disk' which //holds the partition static uint8_t* gpt_get_pentry_arr(uint8_t *hdr, int fd) { uint64_t pentries_start = 0; uint32_t pentry_size = 0; uint32_t block_size = 0; uint32_t pentries_arr_size = 0; uint8_t *pentry_arr = NULL; int rc = 0; if (!hdr) { ALOGE("%s: Invalid header", __func__); goto error; } if (fd < 0) { ALOGE("%s: Invalid fd", __func__); goto error; } block_size = gpt_get_block_size(fd); if (!block_size) { ALOGE("%s: Failed to get gpt block size for", __func__); goto error; } pentries_start = GET_8_BYTES(hdr + PENTRIES_OFFSET) * block_size; pentry_size = GET_4_BYTES(hdr + PENTRY_SIZE_OFFSET); pentries_arr_size = GET_4_BYTES(hdr + PARTITION_COUNT_OFFSET) * pentry_size; pentry_arr = (uint8_t*)calloc(1, pentries_arr_size); if (!pentry_arr) { ALOGE("%s: Failed to allocate memory for partition array", __func__); goto error; } rc = blk_rw(fd, 0, pentries_start, pentry_arr, pentries_arr_size); if (rc) { ALOGE("%s: Failed to read partition entry array", __func__); goto error; } return pentry_arr; error: if (pentry_arr) free(pentry_arr); return NULL; } static int gpt_set_pentry_arr(uint8_t *hdr, int fd, uint8_t* arr) { uint32_t block_size = 0; uint64_t pentries_start = 0; uint32_t pentry_size = 0; uint32_t pentries_arr_size = 0; int rc = 0; if (!hdr || fd < 0 || !arr) { ALOGE("%s: Invalid argument", __func__); goto error; } block_size = gpt_get_block_size(fd); if (!block_size) { ALOGE("%s: Failed to get gpt block size for", __func__); goto error; } ALOGI("%s : Block size is %d", __func__, block_size); pentries_start = GET_8_BYTES(hdr + PENTRIES_OFFSET) * block_size; pentry_size = GET_4_BYTES(hdr + PENTRY_SIZE_OFFSET); pentries_arr_size = GET_4_BYTES(hdr + PARTITION_COUNT_OFFSET) * pentry_size; ALOGI("%s: Writing partition entry array of size %d to offset %" PRIu64, __func__, pentries_arr_size, pentries_start); rc = blk_rw(fd, 1, pentries_start, arr, pentries_arr_size); if (rc) { ALOGE("%s: Failed to read partition entry array", __func__); goto error; } return 0; error: return -1; } //Allocate a handle used by calls to the "gpt_disk" api's struct gpt_disk * gpt_disk_alloc() { struct gpt_disk *disk; disk = (struct gpt_disk *)malloc(sizeof(struct gpt_disk)); if (!disk) { ALOGE("%s: Failed to allocate memory", __func__); goto end; } memset(disk, 0, sizeof(struct gpt_disk)); end: return disk; } //Free previously allocated/initialized handle void gpt_disk_free(struct gpt_disk *disk) { if (!disk) return; if (disk->hdr) free(disk->hdr); if (disk->hdr_bak) free(disk->hdr_bak); if (disk->pentry_arr) free(disk->pentry_arr); if (disk->pentry_arr_bak) free(disk->pentry_arr_bak); free(disk); return; } //fills up the passed in gpt_disk struct with information about the //disk represented by path dev. Returns 0 on success and -1 on error. int gpt_disk_get_disk_info(const char *dev, struct gpt_disk *dsk) { struct gpt_disk *disk = NULL; int fd = -1; uint32_t gpt_header_size = 0; if (!dsk || !dev) { ALOGE("%s: Invalid arguments", __func__); goto error; } disk = dsk; disk->hdr = gpt_get_header(dev, PRIMARY_GPT); if (!disk->hdr) { ALOGE("%s: Failed to get primary header", __func__); goto error; } gpt_header_size = GET_4_BYTES(disk->hdr + HEADER_SIZE_OFFSET); disk->hdr_crc = sparse_crc32(0, disk->hdr, gpt_header_size); disk->hdr_bak = gpt_get_header(dev, PRIMARY_GPT); if (!disk->hdr_bak) { ALOGE("%s: Failed to get backup header", __func__); goto error; } disk->hdr_bak_crc = sparse_crc32(0, disk->hdr_bak, gpt_header_size); //Descriptor for the block device. We will use this for further //modifications to the partition table if (get_dev_path_from_partition_name(dev, disk->devpath, sizeof(disk->devpath)) != 0) { ALOGE("%s: Failed to resolve path for %s", __func__, dev); goto error; } fd = open(disk->devpath, O_RDWR); if (fd < 0) { ALOGE("%s: Failed to open %s: %s", __func__, disk->devpath, strerror(errno)); goto error; } disk->pentry_arr = gpt_get_pentry_arr(disk->hdr, fd); if (!disk->pentry_arr) { ALOGE("%s: Failed to obtain partition entry array", __func__); goto error; } disk->pentry_arr_bak = gpt_get_pentry_arr(disk->hdr_bak, fd); if (!disk->pentry_arr_bak) { ALOGE("%s: Failed to obtain backup partition entry array", __func__); goto error; } disk->pentry_size = GET_4_BYTES(disk->hdr + PENTRY_SIZE_OFFSET); disk->pentry_arr_size = GET_4_BYTES(disk->hdr + PARTITION_COUNT_OFFSET) * disk->pentry_size; disk->pentry_arr_crc = GET_4_BYTES(disk->hdr + PARTITION_CRC_OFFSET); disk->pentry_arr_bak_crc = GET_4_BYTES(disk->hdr_bak + PARTITION_CRC_OFFSET); disk->block_size = gpt_get_block_size(fd); close(fd); disk->is_initialized = GPT_DISK_INIT_MAGIC; return 0; error: if (fd >= 0) close(fd); return -1; } //Get pointer to partition entry from a allocated gpt_disk structure uint8_t* gpt_disk_get_pentry(struct gpt_disk *disk, const char *partname, enum gpt_instance instance) { uint8_t *ptn_arr = NULL; if (!disk || !partname || disk->is_initialized != GPT_DISK_INIT_MAGIC) { ALOGE("%s: Invalid argument",__func__); goto error; } ptn_arr = (instance == PRIMARY_GPT) ? disk->pentry_arr : disk->pentry_arr_bak; return (gpt_pentry_seek(partname, ptn_arr, ptn_arr + disk->pentry_arr_size , disk->pentry_size)); error: return NULL; } //Update CRC values for the various components of the gpt_disk //structure. This function should be called after any of the fields //have been updated before the structure contents are written back to //disk. int gpt_disk_update_crc(struct gpt_disk *disk) { uint32_t gpt_header_size = 0; if (!disk || (disk->is_initialized != GPT_DISK_INIT_MAGIC)) { ALOGE("%s: invalid argument", __func__); goto error; } //Recalculate the CRC of the primary partiton array disk->pentry_arr_crc = sparse_crc32(0, disk->pentry_arr, disk->pentry_arr_size); //Recalculate the CRC of the backup partition array disk->pentry_arr_bak_crc = sparse_crc32(0, disk->pentry_arr_bak, disk->pentry_arr_size); //Update the partition CRC value in the primary GPT header PUT_4_BYTES(disk->hdr + PARTITION_CRC_OFFSET, disk->pentry_arr_crc); //Update the partition CRC value in the backup GPT header PUT_4_BYTES(disk->hdr_bak + PARTITION_CRC_OFFSET, disk->pentry_arr_bak_crc); //Update the CRC value of the primary header gpt_header_size = GET_4_BYTES(disk->hdr + HEADER_SIZE_OFFSET); //Header CRC is calculated with its own CRC field set to 0 PUT_4_BYTES(disk->hdr + HEADER_CRC_OFFSET, 0); PUT_4_BYTES(disk->hdr_bak + HEADER_CRC_OFFSET, 0); disk->hdr_crc = sparse_crc32(0, disk->hdr, gpt_header_size); disk->hdr_bak_crc = sparse_crc32(0, disk->hdr_bak, gpt_header_size); PUT_4_BYTES(disk->hdr + HEADER_CRC_OFFSET, disk->hdr_crc); PUT_4_BYTES(disk->hdr_bak + HEADER_CRC_OFFSET, disk->hdr_bak_crc); return 0; error: return -1; } //Write the contents of struct gpt_disk back to the actual disk int gpt_disk_commit(struct gpt_disk *disk) { int fd = -1; if (!disk || (disk->is_initialized != GPT_DISK_INIT_MAGIC)){ ALOGE("%s: Invalid args", __func__); goto error; } fd = open(disk->devpath, O_RDWR); if (fd < 0) { ALOGE("%s: Failed to open %s: %s", __func__, disk->devpath, strerror(errno)); goto error; } ALOGI("%s: Writing back primary GPT header", __func__); //Write the primary header if(gpt_set_header(disk->hdr, fd, PRIMARY_GPT) != 0) { ALOGE("%s: Failed to update primary GPT header", __func__); goto error; } ALOGI("%s: Writing back primary partition array", __func__); //Write back the primary partition array if (gpt_set_pentry_arr(disk->hdr, fd, disk->pentry_arr)) { ALOGE("%s: Failed to write primary GPT partition arr", __func__); goto error; } close(fd); return 0; error: if (fd >= 0) close(fd); return -1; }