coreboot-kgpe-d16/util/cbfstool/ifwitool.c

1938 lines
51 KiB
C

/*
* ifwitool, CLI utility for IFWI manipulation
*
* Copyright 2016 Google Inc.
*
* 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; version 2 of the License.
*
* 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.
*/
#include <commonlib/endian.h>
#include <getopt.h>
#include <stdlib.h>
#include <time.h>
#include "common.h"
/*
* BPDT is Boot Partition Descriptor Table. It is located at the start of a
* logical boot partition(LBP). It stores information about the critical
* sub-partitions present within the LBP.
*
* S-BPDT is Secondary Boot Partition Descriptor Table. It is located after the
* critical sub-partitions and contains information about the non-critical
* sub-partitions present within the LBP.
*
* Both tables are identified by BPDT_SIGNATURE stored at the start of the
* table.
*/
#define BPDT_SIGNATURE (0x000055AA)
/* Parameters passed in by caller. */
static struct param {
const char *file_name;
const char *subpart_name;
const char *image_name;
bool dir_ops;
const char *dentry_name;
} param;
struct bpdt_header {
/*
* This is used to identify start of BPDT. It should always be
* BPDT_SIGNATURE.
*/
uint32_t signature;
/* Count of BPDT entries present. */
uint16_t descriptor_count;
/* Version - Currently supported = 1. */
uint16_t bpdt_version;
/* Unused - Should be 0. */
uint32_t xor_redundant_block;
/* Version of IFWI build. */
uint32_t ifwi_version;
/* Version of FIT tool used to create IFWI. */
uint64_t fit_tool_version;
} __attribute__((packed));
#define BPDT_HEADER_SIZE (sizeof(struct bpdt_header))
struct bpdt_entry {
/* Type of sub-partition. */
uint16_t type;
/* Attributes of sub-partition. */
uint16_t flags;
/* Offset of sub-partition from beginning of LBP. */
uint32_t offset;
/* Size in bytes of sub-partition. */
uint32_t size;
} __attribute__((packed));
#define BPDT_ENTRY_SIZE (sizeof(struct bpdt_entry))
struct bpdt {
struct bpdt_header h;
/* In practice, this could be an array of 0 to n entries. */
struct bpdt_entry e[0];
} __attribute__((packed));
static inline size_t bpdt_size(struct bpdt_header *h)
{
return (sizeof(*h) + BPDT_ENTRY_SIZE * h->descriptor_count);
}
/* Minimum size in bytes allocated to BPDT in IFWI. */
#define BPDT_MIN_SIZE (512)
/* Header to define directory header for sub-partition. */
struct subpart_dir_header {
/* Should be SUBPART_DIR_MARKER. */
uint32_t marker;
/* Number of directory entries in the sub-partition. */
uint32_t num_entries;
/* Currenty supported - 1. */
uint8_t header_version;
/* Currenty supported - 1. */
uint8_t entry_version;
/* Length of directory header in bytes. */
uint8_t header_length;
/*
* TODO(furquan): Add checksum calculation once more details are
* available.
*/
uint8_t checksum;
/* ASCII short name of sub-partition. */
uint8_t name[4];
} __attribute__((packed));
#define SUBPART_DIR_HEADER_SIZE \
(sizeof(struct subpart_dir_header))
#define SUBPART_DIR_MARKER 0x44504324
#define SUBPART_DIR_HEADER_VERSION_SUPPORTED 1
#define SUBPART_DIR_ENTRY_VERSION_SUPPORTED 1
/* Structure for each directory entry for sub-partition. */
struct subpart_dir_entry {
/* Name of directory entry - Not guaranteed to be NULL-terminated. */
uint8_t name[12];
/* Offset of entry from beginning of sub-partition. */
uint32_t offset;
/* Length in bytes of sub-directory entry. */
uint32_t length;
/* Must be zero. */
uint32_t rsvd;
} __attribute__((packed));
#define SUBPART_DIR_ENTRY_SIZE \
(sizeof(struct subpart_dir_entry))
struct subpart_dir {
struct subpart_dir_header h;
/* In practice, this could be an array of 0 to n entries. */
struct subpart_dir_entry e[0];
} __attribute__((packed));
static inline size_t subpart_dir_size(struct subpart_dir_header *h)
{
return (sizeof(*h) + SUBPART_DIR_ENTRY_SIZE * h->num_entries);
}
struct manifest_header {
uint32_t header_type;
uint32_t header_length;
uint32_t header_version;
uint32_t flags;
uint32_t vendor;
uint32_t date;
uint32_t size;
uint32_t id;
uint32_t rsvd;
uint64_t version;
uint32_t svn;
uint64_t rsvd1;
uint8_t rsvd2[64];
uint32_t modulus_size;
uint32_t exponent_size;
uint8_t public_key[256];
uint32_t exponent;
uint8_t signature[256];
} __attribute__((packed));
#define DWORD_SIZE 4
#define MANIFEST_HDR_SIZE (sizeof(struct manifest_header))
#define MANIFEST_ID_MAGIC (0x324e4d24)
struct module {
uint8_t name[12];
uint8_t type;
uint8_t hash_alg;
uint16_t hash_size;
uint32_t metadata_size;
uint8_t metadata_hash[32];
} __attribute__((packed));
#define MODULE_SIZE (sizeof(struct module))
struct signed_pkg_info_ext {
uint32_t ext_type;
uint32_t ext_length;
uint8_t name[4];
uint32_t vcn;
uint8_t bitmap[16];
uint32_t svn;
uint8_t rsvd[16];
} __attribute__((packed));
#define SIGNED_PKG_INFO_EXT_TYPE 0x15
#define SIGNED_PKG_INFO_EXT_SIZE \
(sizeof(struct signed_pkg_info_ext))
/*
* Attributes for various IFWI sub-partitions.
* LIES_WITHIN_BPDT_4K = Sub-Partition should lie within the same 4K block as
* BPDT.
* NON_CRITICAL_SUBPART = Sub-Partition entry should be present in S-BPDT.
* CONTAINS_DIR = Sub-Partition contains directory.
* AUTO_GENERATED = Sub-Partition is generated by the tool.
* MANDATORY_BPDT_ENTRY = Even if sub-partition is deleted, BPDT should contain
* an entry for it with size 0 and offset 0.
*/
enum subpart_attributes {
LIES_WITHIN_BPDT_4K = (1 << 0),
NON_CRITICAL_SUBPART = (1 << 1),
CONTAINS_DIR = (1 << 2),
AUTO_GENERATED = (1 << 3),
MANDATORY_BPDT_ENTRY = (1 << 4),
};
/* Type value for various IFWI sub-partitions. */
enum bpdt_entry_type {
SMIP_TYPE = 0,
CSE_RBE_TYPE = 1,
CSE_BUP_TYPE = 2,
UCODE_TYPE = 3,
IBB_TYPE = 4,
S_BPDT_TYPE = 5,
OBB_TYPE = 6,
CSE_MAIN_TYPE = 7,
ISH_TYPE = 8,
CSE_IDLM_TYPE = 9,
IFP_OVERRIDE_TYPE = 10,
DEBUG_TOKENS_TYPE = 11,
UFS_PHY_TYPE = 12,
UFS_GPP_TYPE = 13,
PMC_TYPE = 14,
IUNIT_TYPE = 15,
NVM_CONFIG_TYPE = 16,
UEP_TYPE = 17,
UFS_RATE_B_TYPE = 18,
MAX_SUBPARTS = 19,
};
/*
* There are two order requirements for an IFWI image:
* 1. Order in which the sub-partitions lie within the BPDT entries.
* 2. Order in which the sub-partitions lie within the image.
*
* header_order defines #1 i.e. the order in which the sub-partitions should
* appear in the BPDT entries. pack_order defines #2 i.e. the order in which
* sub-partitions appear in the IFWI image. pack_order controls the offset and
* thus sub-partitions would have increasing offsets as we loop over pack_order.
*/
const enum bpdt_entry_type bpdt_header_order[MAX_SUBPARTS] = {
/* Order of the following entries is mandatory. */
CSE_IDLM_TYPE,
IFP_OVERRIDE_TYPE,
S_BPDT_TYPE,
CSE_RBE_TYPE,
UFS_PHY_TYPE,
UFS_GPP_TYPE,
/* Order of the following entries is recommended. */
UEP_TYPE,
NVM_CONFIG_TYPE,
UFS_RATE_B_TYPE,
IBB_TYPE,
SMIP_TYPE,
PMC_TYPE,
CSE_BUP_TYPE,
UCODE_TYPE,
DEBUG_TOKENS_TYPE,
IUNIT_TYPE,
CSE_MAIN_TYPE,
ISH_TYPE,
OBB_TYPE,
};
const enum bpdt_entry_type bpdt_pack_order[MAX_SUBPARTS] = {
/* Order of the following entries is mandatory. */
UFS_GPP_TYPE,
UFS_PHY_TYPE,
IFP_OVERRIDE_TYPE,
UEP_TYPE,
NVM_CONFIG_TYPE,
UFS_RATE_B_TYPE,
/* Order of the following entries is recommended. */
IBB_TYPE,
SMIP_TYPE,
CSE_RBE_TYPE,
PMC_TYPE,
CSE_BUP_TYPE,
UCODE_TYPE,
CSE_IDLM_TYPE,
DEBUG_TOKENS_TYPE,
S_BPDT_TYPE,
IUNIT_TYPE,
CSE_MAIN_TYPE,
ISH_TYPE,
OBB_TYPE,
};
/* Utility functions. */
enum ifwi_ret {
COMMAND_ERR = -1,
NO_ACTION_REQUIRED = 0,
REPACK_REQUIRED = 1,
};
struct dir_ops {
enum ifwi_ret (*dir_add)(int);
};
static enum ifwi_ret ibbp_dir_add(int);
const struct subpart_info {
const char *name;
const char *readable_name;
uint32_t attr;
struct dir_ops dir_ops;
} subparts[MAX_SUBPARTS] = {
/* OEM SMIP */
[SMIP_TYPE] = {"SMIP", "SMIP", CONTAINS_DIR, {NULL} },
/* CSE RBE */
[CSE_RBE_TYPE] = {"RBEP", "CSE_RBE", CONTAINS_DIR |
MANDATORY_BPDT_ENTRY, {NULL} },
/* CSE BUP */
[CSE_BUP_TYPE] = {"FTPR", "CSE_BUP", CONTAINS_DIR |
MANDATORY_BPDT_ENTRY, {NULL} },
/* uCode */
[UCODE_TYPE] = {"UCOD", "Microcode", CONTAINS_DIR, {NULL} },
/* IBB */
[IBB_TYPE] = {"IBBP", "Bootblock", CONTAINS_DIR, {ibbp_dir_add} },
/* S-BPDT */
[S_BPDT_TYPE] = {"S_BPDT", "S-BPDT", AUTO_GENERATED |
MANDATORY_BPDT_ENTRY, {NULL} },
/* OBB */
[OBB_TYPE] = {"OBBP", "OEM boot block", CONTAINS_DIR |
NON_CRITICAL_SUBPART, {NULL} },
/* CSE Main */
[CSE_MAIN_TYPE] = {"NFTP", "CSE_MAIN", CONTAINS_DIR |
NON_CRITICAL_SUBPART, {NULL} },
/* ISH */
[ISH_TYPE] = {"ISHP", "ISH", NON_CRITICAL_SUBPART, {NULL} },
/* CSE IDLM */
[CSE_IDLM_TYPE] = {"DLMP", "CSE_IDLM", CONTAINS_DIR |
MANDATORY_BPDT_ENTRY, {NULL} },
/* IFP Override */
[IFP_OVERRIDE_TYPE] = {"IFP_OVERRIDE", "IFP_OVERRIDE",
LIES_WITHIN_BPDT_4K | MANDATORY_BPDT_ENTRY,
{NULL} },
/* Debug Tokens */
[DEBUG_TOKENS_TYPE] = {"DEBUG_TOKENS", "Debug Tokens", 0, {NULL} },
/* UFS Phy Configuration */
[UFS_PHY_TYPE] = {"UFS_PHY", "UFS Phy", LIES_WITHIN_BPDT_4K |
MANDATORY_BPDT_ENTRY, {NULL} },
/* UFS GPP LUN ID */
[UFS_GPP_TYPE] = {"UFS_GPP", "UFS GPP", LIES_WITHIN_BPDT_4K |
MANDATORY_BPDT_ENTRY, {NULL} },
/* PMC */
[PMC_TYPE] = {"PMCP", "PMC firmware", CONTAINS_DIR, {NULL} },
/* IUNIT */
[IUNIT_TYPE] = {"IUNP", "IUNIT", NON_CRITICAL_SUBPART, {NULL} },
/* NVM Config */
[NVM_CONFIG_TYPE] = {"NVM_CONFIG", "NVM Config", 0, {NULL} },
/* UEP */
[UEP_TYPE] = {"UEP", "UEP", LIES_WITHIN_BPDT_4K | MANDATORY_BPDT_ENTRY,
{NULL} },
/* UFS Rate B Config */
[UFS_RATE_B_TYPE] = {"UFS_RATE_B", "UFS Rate B Config", 0, {NULL} },
};
struct ifwi_image {
/* Data read from input file. */
struct buffer input_buff;
/* BPDT header and entries. */
struct buffer bpdt;
size_t input_ifwi_start_offset;
size_t input_ifwi_end_offset;
/* Subpartition content. */
struct buffer subpart_buf[MAX_SUBPARTS];
} ifwi_image;
static void alloc_buffer(struct buffer *b, size_t s, const char *n)
{
if (buffer_create(b, s, n) == 0)
return;
ERROR("Buffer allocation failure for %s (size = %zx).\n", n, s);
exit(-1);
}
/*
* Read header/entry members in little-endian format.
* Returns the offset upto which the read was performed.
*/
static size_t read_member(void *src, size_t offset, size_t size_bytes,
void *dst)
{
switch (size_bytes) {
case 1:
*(uint8_t *)dst = read_at_le8(src, offset);
break;
case 2:
*(uint16_t *)dst = read_at_le16(src, offset);
break;
case 4:
*(uint32_t *)dst = read_at_le32(src, offset);
break;
case 8:
*(uint64_t *)dst = read_at_le64(src, offset);
break;
default:
ERROR("Read size not supported %zd\n", size_bytes);
exit(-1);
}
return (offset + size_bytes);
}
/*
* Convert to little endian format.
* Returns the offset upto which the fixup was performed.
*/
static size_t fix_member(void *data, size_t offset, size_t size_bytes)
{
uint8_t *src = (uint8_t *)data + offset;
switch (size_bytes) {
case 1:
write_at_le8(data, *(uint8_t *)src, offset);
break;
case 2:
write_at_le16(data, *(uint16_t *)src, offset);
break;
case 4:
write_at_le32(data, *(uint32_t *)src, offset);
break;
case 8:
write_at_le64(data, *(uint64_t *)src, offset);
break;
default:
ERROR("Write size not supported %zd\n", size_bytes);
exit(-1);
}
return (offset + size_bytes);
}
static void print_subpart_dir(struct subpart_dir *s)
{
if (verbose == 0)
return;
size_t i;
printf("%-25s 0x%-23.8x\n", "Marker", s->h.marker);
printf("%-25s %-25d\n", "Num entries", s->h.num_entries);
printf("%-25s %-25d\n", "Header Version", s->h.header_version);
printf("%-25s %-25d\n", "Entry Version", s->h.entry_version);
printf("%-25s 0x%-23x\n", "Header Length", s->h.header_length);
printf("%-25s 0x%-23x\n", "Checksum", s->h.checksum);
printf("%-25s ", "Name");
for (i = 0; i < sizeof(s->h.name); i++)
printf("%c", s->h.name[i]);
printf("\n");
printf("%-25s%-25s%-25s%-25s%-25s\n", "Entry #", "Name", "Offset",
"Length", "Rsvd");
printf("=============================================================="
"===========================================================\n");
for (i = 0; i < s->h.num_entries; i++) {
printf("%-25zd%-25.12s0x%-23x0x%-23x0x%-23x\n", i+1,
s->e[i].name, s->e[i].offset, s->e[i].length,
s->e[i].rsvd);
}
printf("=============================================================="
"===========================================================\n");
}
static void bpdt_print_header(struct bpdt_header *h, const char *name)
{
if (verbose == 0)
return;
printf("%-25s %-25s\n", "Header", name);
printf("%-25s 0x%-23.8x\n", "Signature", h->signature);
printf("%-25s %-25d\n", "Descriptor count", h->descriptor_count);
printf("%-25s %-25d\n", "BPDT Version", h->bpdt_version);
printf("%-25s 0x%-23x\n", "XOR checksum", h->xor_redundant_block);
printf("%-25s 0x%-23x\n", "IFWI Version", h->ifwi_version);
printf("%-25s 0x%-23llx\n", "FIT Tool Version",
(long long)h->fit_tool_version);
}
static void bpdt_print_entries(struct bpdt_entry *e, size_t count,
const char *name)
{
if (verbose == 0)
return;
printf("%s entries\n", name);
printf("%-25s%-25s%-25s%-25s%-25s%-25s%-25s%-25s\n", "Entry #",
"Sub-Partition", "Name", "Type", "Flags", "Offset", "Size",
"File Offset");
printf("=============================================================="
"=============================================================="
"=============================================================="
"===============\n");
size_t i;
for (i = 0; i < count; i++) {
printf("%-25zd%-25s%-25s%-25d0x%-23.08x0x%-23x0x%-23x0x%-23zx"
"\n", i+1, subparts[e[i].type].name,
subparts[e[i].type].readable_name, e[i].type, e[i].flags,
e[i].offset, e[i].size,
e[i].offset + ifwi_image.input_ifwi_start_offset);
}
printf("=============================================================="
"=============================================================="
"=============================================================="
"===============\n");
}
static void bpdt_validate_header(struct bpdt_header *h, const char *name)
{
assert(h->signature == BPDT_SIGNATURE);
if (h->bpdt_version != 1) {
ERROR("Invalid header : %s\n", name);
exit(-1);
}
DEBUG("Validated header : %s\n", name);
}
static void bpdt_read_header(void *data, struct bpdt_header *h,
const char *name)
{
size_t offset = 0;
offset = read_member(data, offset, sizeof(h->signature), &h->signature);
offset = read_member(data, offset, sizeof(h->descriptor_count),
&h->descriptor_count);
offset = read_member(data, offset, sizeof(h->bpdt_version),
&h->bpdt_version);
offset = read_member(data, offset, sizeof(h->xor_redundant_block),
&h->xor_redundant_block);
offset = read_member(data, offset, sizeof(h->ifwi_version),
&h->ifwi_version);
offset = read_member(data, offset, sizeof(h->fit_tool_version),
&h->fit_tool_version);
bpdt_validate_header(h, name);
bpdt_print_header(h, name);
}
static void bpdt_read_entries(void *data, struct bpdt *bpdt, const char *name)
{
size_t i, offset = 0;
struct bpdt_entry *e = &bpdt->e[0];
size_t count = bpdt->h.descriptor_count;
for (i = 0; i < count; i++) {
offset = read_member(data, offset, sizeof(e[i].type),
&e[i].type);
offset = read_member(data, offset, sizeof(e[i].flags),
&e[i].flags);
offset = read_member(data, offset, sizeof(e[i].offset),
&e[i].offset);
offset = read_member(data, offset, sizeof(e[i].size),
&e[i].size);
}
bpdt_print_entries(e, count, name);
}
/*
* Given type of sub-partition, identify BPDT entry for it.
* Sub-Partition could lie either within BPDT or S-BPDT.
*/
static struct bpdt_entry *__find_entry_by_type(struct bpdt_entry *e,
size_t count, int type)
{
size_t i;
for (i = 0; i < count; i++) {
if (e[i].type == type)
break;
}
if (i == count)
return NULL;
return &e[i];
}
static struct bpdt_entry *find_entry_by_type(int type)
{
struct bpdt *b = buffer_get(&ifwi_image.bpdt);
if (b == NULL)
return NULL;
struct bpdt_entry *curr = __find_entry_by_type(&b->e[0],
b->h.descriptor_count,
type);
if (curr)
return curr;
b = buffer_get(&ifwi_image.subpart_buf[S_BPDT_TYPE]);
if (b == NULL)
return NULL;
return __find_entry_by_type(&b->e[0], b->h.descriptor_count, type);
}
/*
* Find sub-partition type given its name. If the name does not exist, returns
* -1.
*/
static int find_type_by_name(const char *name)
{
int i;
for (i = 0; i < MAX_SUBPARTS; i++) {
if ((strlen(subparts[i].name) == strlen(name)) &&
(!strcmp(subparts[i].name, name)))
break;
}
if (i == MAX_SUBPARTS) {
ERROR("Invalid sub-partition name %s.\n", name);
return -1;
}
return i;
}
/*
* Read the content of a sub-partition from input file and store it in
* ifwi_image.subpart_buf[SUB-PARTITION_TYPE].
*
* Returns the maximum offset occupied by the sub-partitions.
*/
static size_t read_subpart_buf(void *data, size_t size, struct bpdt_entry *e,
size_t count)
{
size_t i, type;
struct buffer *buf;
size_t max_offset = 0;
for (i = 0; i < count; i++) {
type = e[i].type;
if (type >= MAX_SUBPARTS) {
ERROR("Invalid sub-partition type %zd.\n", type);
exit(-1);
}
if (buffer_size(&ifwi_image.subpart_buf[type])) {
ERROR("Multiple sub-partitions of type %zd(%s).\n",
type, subparts[type].name);
exit(-1);
}
if (e[i].size == 0) {
INFO("Dummy sub-partition %zd(%s). Skipping.\n", type,
subparts[type].name);
continue;
}
assert((e[i].offset + e[i].size) <= size);
/*
* Sub-partitions in IFWI image are not in the same order as
* in BPDT entries. BPDT entires are in header_order whereas
* sub-partition offsets in the image are in pack_order.
*/
if ((e[i].offset + e[i].size) > max_offset)
max_offset = e[i].offset + e[i].size;
/*
* S-BPDT sub-partition contains information about all the
* non-critical sub-partitions. Thus, size of S-BPDT
* sub-partition equals size of S-BPDT plus size of all the
* non-critical sub-partitions. Thus, reading whole of S-BPDT
* here would be redundant as the non-critical partitions are
* read and allocated buffers separately. Also, S-BPDT requires
* special handling for reading header and entries.
*/
if (type == S_BPDT_TYPE)
continue;
buf = &ifwi_image.subpart_buf[type];
alloc_buffer(buf, e[i].size, subparts[type].name);
memcpy(buffer_get(buf), (uint8_t *)data + e[i].offset,
e[i].size);
}
assert(max_offset);
return max_offset;
}
/*
* Allocate buffer for bpdt header, entries and all sub-partition content.
* Returns offset in data where BPDT ends.
*/
static size_t alloc_bpdt_buffer(void *data, size_t size, size_t offset,
struct buffer *b, const char *name)
{
struct bpdt_header bpdt_header;
assert((offset + BPDT_HEADER_SIZE) < size);
bpdt_read_header((uint8_t *)data + offset, &bpdt_header, name);
/* Buffer to read BPDT header and entries. */
alloc_buffer(b, bpdt_size(&bpdt_header), name);
struct bpdt *bpdt = buffer_get(b);
memcpy(&bpdt->h, &bpdt_header, BPDT_HEADER_SIZE);
/*
* If no entries are present, maximum offset occupied is (offset +
* BPDT_HEADER_SIZE).
*/
if (bpdt->h.descriptor_count == 0)
return (offset + BPDT_HEADER_SIZE);
/* Read all entries. */
assert((offset + bpdt_size(&bpdt->h)) < size);
bpdt_read_entries((uint8_t *)data + offset + BPDT_HEADER_SIZE, bpdt,
name);
/* Read all sub-partition content in subpart_buf. */
return read_subpart_buf(data, size, &bpdt->e[0],
bpdt->h.descriptor_count);
}
static void parse_sbpdt(void *data, size_t size)
{
struct bpdt_entry *s;
s = find_entry_by_type(S_BPDT_TYPE);
if (!s)
return;
assert(size > s->offset);
alloc_bpdt_buffer(data, size, s->offset,
&ifwi_image.subpart_buf[S_BPDT_TYPE],
"S-BPDT");
}
static void validate_subpart_dir(struct subpart_dir *s, const char *name)
{
if ((s->h.marker != SUBPART_DIR_MARKER) ||
(s->h.header_version != SUBPART_DIR_HEADER_VERSION_SUPPORTED) ||
(s->h.entry_version != SUBPART_DIR_ENTRY_VERSION_SUPPORTED) ||
(s->h.header_length != SUBPART_DIR_HEADER_SIZE)) {
ERROR("Invalid subpart_dir for %s.\n", name);
exit(-1);
}
}
static void parse_subpart_dir(struct buffer *subpart_dir_buf,
struct buffer *input_buf, const char *name)
{
struct subpart_dir_header hdr;
size_t offset = 0;
uint8_t *data = buffer_get(input_buf);
size_t size = buffer_size(input_buf);
/* Read Subpart_Dir header. */
assert(size >= SUBPART_DIR_HEADER_SIZE);
offset = read_member(data, offset, sizeof(hdr.marker), &hdr.marker);
offset = read_member(data, offset, sizeof(hdr.num_entries),
&hdr.num_entries);
offset = read_member(data, offset, sizeof(hdr.header_version),
&hdr.header_version);
offset = read_member(data, offset, sizeof(hdr.entry_version),
&hdr.entry_version);
offset = read_member(data, offset, sizeof(hdr.header_length),
&hdr.header_length);
offset = read_member(data, offset, sizeof(hdr.checksum), &hdr.checksum);
memcpy(hdr.name, data + offset, sizeof(hdr.name));
offset += sizeof(hdr.name);
validate_subpart_dir((struct subpart_dir *)&hdr, name);
assert(size > subpart_dir_size(&hdr));
alloc_buffer(subpart_dir_buf, subpart_dir_size(&hdr), "Subpart Dir");
memcpy(buffer_get(subpart_dir_buf), &hdr, SUBPART_DIR_HEADER_SIZE);
/* Read Subpart Dir entries. */
struct subpart_dir *subpart_dir = buffer_get(subpart_dir_buf);
struct subpart_dir_entry *e = &subpart_dir->e[0];
uint32_t i;
for (i = 0; i < hdr.num_entries; i++) {
memcpy(e[i].name, data + offset, sizeof(e[i].name));
offset += sizeof(e[i].name);
offset = read_member(data, offset, sizeof(e[i].offset),
&e[i].offset);
offset = read_member(data, offset, sizeof(e[i].length),
&e[i].length);
offset = read_member(data, offset, sizeof(e[i].rsvd),
&e[i].rsvd);
}
print_subpart_dir(subpart_dir);
}
/* Parse input image file to identify different sub-partitions. */
static int ifwi_parse(void)
{
DEBUG("Parsing IFWI image...\n");
const char *image_name = param.image_name;
/* Read input file. */
struct buffer *buff = &ifwi_image.input_buff;
if (buffer_from_file(buff, image_name)) {
ERROR("Failed to read input file %s.\n", image_name);
return -1;
}
INFO("Buffer %p size 0x%zx\n", buff->data, buff->size);
/* Look for BPDT signature at 4K intervals. */
size_t offset = 0;
void *data = buffer_get(buff);
while (offset < buffer_size(buff)) {
if (read_at_le32(data, offset) == BPDT_SIGNATURE)
break;
offset += 4 * KiB;
}
if (offset >= buffer_size(buff)) {
ERROR("Image does not contain BPDT!!\n");
return -1;
}
ifwi_image.input_ifwi_start_offset = offset;
INFO("BPDT starts at offset 0x%zx.\n", offset);
data = (uint8_t *)data + offset;
size_t ifwi_size = buffer_size(buff) - offset;
/* Read BPDT and sub-partitions. */
uintptr_t end_offset;
end_offset = ifwi_image.input_ifwi_start_offset +
alloc_bpdt_buffer(data, ifwi_size, 0, &ifwi_image.bpdt, "BPDT");
/* Parse S-BPDT, if any. */
parse_sbpdt(data, ifwi_size);
/*
* Store end offset of IFWI. Required for copying any trailing non-IFWI
* part of the image.
* ASSUMPTION: IFWI image always ends on a 4K boundary.
*/
ifwi_image.input_ifwi_end_offset = ALIGN(end_offset, 4 * KiB);
DEBUG("Parsing done.\n");
return 0;
}
/*
* This function is used by repack to count the number of BPDT and S-BPDT
* entries that are present. It frees the current buffers used by the entries
* and allocates fresh buffers that can be used for repacking. Returns BPDT
* entries which are empty and need to be filled in.
*/
static void __bpdt_reset(struct buffer *b, size_t count, size_t size)
{
size_t bpdt_size = BPDT_HEADER_SIZE + count * BPDT_ENTRY_SIZE;
assert(size >= bpdt_size);
/*
* If buffer does not have the required size, allocate a fresh buffer.
*/
if (buffer_size(b) != size) {
struct buffer temp;
alloc_buffer(&temp, size, b->name);
memcpy(buffer_get(&temp), buffer_get(b), buffer_size(b));
buffer_delete(b);
*b = temp;
}
struct bpdt *bpdt = buffer_get(b);
uint8_t *ptr = (uint8_t *)&bpdt->e[0];
size_t entries_size = BPDT_ENTRY_SIZE * count;
/* Zero out BPDT entries. */
memset(ptr, 0, entries_size);
/* Fill any pad-space with FF. */
memset(ptr + entries_size, 0xFF, size - bpdt_size);
bpdt->h.descriptor_count = count;
}
static void bpdt_reset(void)
{
size_t i;
size_t bpdt_count = 0, sbpdt_count = 0, dummy_bpdt_count = 0;
/* Count number of BPDT and S-BPDT entries. */
for (i = 0; i < MAX_SUBPARTS; i++) {
if (buffer_size(&ifwi_image.subpart_buf[i]) == 0) {
if (subparts[i].attr & MANDATORY_BPDT_ENTRY) {
bpdt_count++;
dummy_bpdt_count++;
}
continue;
}
if (subparts[i].attr & NON_CRITICAL_SUBPART)
sbpdt_count++;
else
bpdt_count++;
}
DEBUG("Count: BPDT = %zd, Dummy BPDT = %zd, S-BPDT = %zd\n", bpdt_count,
dummy_bpdt_count, sbpdt_count);
/* Update BPDT if required. */
size_t bpdt_size = MAX(BPDT_MIN_SIZE,
BPDT_HEADER_SIZE + bpdt_count * BPDT_ENTRY_SIZE);
__bpdt_reset(&ifwi_image.bpdt, bpdt_count, bpdt_size);
/* Update S-BPDT if required. */
bpdt_size = ALIGN(BPDT_HEADER_SIZE + sbpdt_count * BPDT_ENTRY_SIZE,
4 * KiB);
__bpdt_reset(&ifwi_image.subpart_buf[S_BPDT_TYPE], sbpdt_count,
bpdt_size);
}
/* Initialize BPDT entries in header order. */
static void bpdt_entries_init_header_order(void)
{
int i, type;
size_t size;
struct bpdt *bpdt, *sbpdt, *curr;
size_t bpdt_curr = 0, sbpdt_curr = 0, *count_ptr;
bpdt = buffer_get(&ifwi_image.bpdt);
sbpdt = buffer_get(&ifwi_image.subpart_buf[S_BPDT_TYPE]);
for (i = 0; i < MAX_SUBPARTS; i++) {
type = bpdt_header_order[i];
size = buffer_size(&ifwi_image.subpart_buf[type]);
if ((size == 0) && !(subparts[type].attr &
MANDATORY_BPDT_ENTRY))
continue;
if (subparts[type].attr & NON_CRITICAL_SUBPART) {
curr = sbpdt;
count_ptr = &sbpdt_curr;
} else {
curr = bpdt;
count_ptr = &bpdt_curr;
}
assert(*count_ptr < curr->h.descriptor_count);
curr->e[*count_ptr].type = type;
curr->e[*count_ptr].flags = 0;
curr->e[*count_ptr].offset = 0;
curr->e[*count_ptr].size = size;
(*count_ptr)++;
}
}
static void pad_buffer(struct buffer *b, size_t size)
{
size_t buff_size = buffer_size(b);
assert(buff_size <= size);
if (buff_size == size)
return;
struct buffer temp;
alloc_buffer(&temp, size, b->name);
uint8_t *data = buffer_get(&temp);
memcpy(data, buffer_get(b), buff_size);
memset(data + buff_size, 0xFF, size - buff_size);
*b = temp;
}
/* Initialize offsets of entries using pack order. */
static void bpdt_entries_init_pack_order(void)
{
int i, type;
struct bpdt_entry *curr;
size_t curr_offset, curr_end;
curr_offset = MAX(BPDT_MIN_SIZE, buffer_size(&ifwi_image.bpdt));
/*
* There are two types of sub-partitions that need to be handled here:
* 1. Sub-partitions that lie within the same 4K as BPDT
* 2. Sub-partitions that lie outside the 4K of BPDT
*
* For sub-partitions of type # 1, there is no requirement on the start
* or end of the sub-partition. They need to be packed in without any
* holes left in between. If there is any empty space left after the end
* of the last sub-partition in 4K of BPDT, then that space needs to be
* padded with FF bytes, but the size of the last sub-partition remains
* unchanged.
*
* For sub-partitions of type # 2, both the start and end should be a
* multiple of 4K. If not, then it needs to be padded with FF bytes and
* size adjusted such that the sub-partition ends on 4K boundary.
*/
/* #1 Sub-partitions that lie within same 4K as BPDT. */
struct buffer *last_bpdt_buff = &ifwi_image.bpdt;
for (i = 0; i < MAX_SUBPARTS; i++) {
type = bpdt_pack_order[i];
curr = find_entry_by_type(type);
if ((curr == NULL) || (curr->size == 0))
continue;
if (!(subparts[type].attr & LIES_WITHIN_BPDT_4K))
continue;
curr->offset = curr_offset;
curr_offset = curr->offset + curr->size;
last_bpdt_buff = &ifwi_image.subpart_buf[type];
DEBUG("type=%d, curr_offset=0x%zx, curr->offset=0x%x, "
"curr->size=0x%x, buff_size=0x%zx\n", type, curr_offset,
curr->offset, curr->size,
buffer_size(&ifwi_image.subpart_buf[type]));
}
/* Pad ff bytes if there is any empty space left in BPDT 4K. */
curr_end = ALIGN(curr_offset, 4 * KiB);
pad_buffer(last_bpdt_buff,
buffer_size(last_bpdt_buff) + (curr_end - curr_offset));
curr_offset = curr_end;
/* #2 Sub-partitions that lie outside of BPDT 4K. */
for (i = 0; i < MAX_SUBPARTS; i++) {
type = bpdt_pack_order[i];
curr = find_entry_by_type(type);
if ((curr == NULL) || (curr->size == 0))
continue;
if (subparts[type].attr & LIES_WITHIN_BPDT_4K)
continue;
assert(curr_offset == ALIGN(curr_offset, 4 * KiB));
curr->offset = curr_offset;
curr_end = ALIGN(curr->offset + curr->size, 4 * KiB);
curr->size = curr_end - curr->offset;
pad_buffer(&ifwi_image.subpart_buf[type], curr->size);
curr_offset = curr_end;
DEBUG("type=%d, curr_offset=0x%zx, curr->offset=0x%x, "
"curr->size=0x%x, buff_size=0x%zx\n", type, curr_offset,
curr->offset, curr->size,
buffer_size(&ifwi_image.subpart_buf[type]));
}
/*
* Update size of S-BPDT to include size of all non-critical
* sub-partitions.
*
* Assumption: S-BPDT always lies at the end of IFWI image.
*/
curr = find_entry_by_type(S_BPDT_TYPE);
assert(curr);
assert(curr_offset == ALIGN(curr_offset, 4 * KiB));
curr->size = curr_offset - curr->offset;
}
/* Convert all members of BPDT to little-endian format. */
static void bpdt_fixup_write_buffer(struct buffer *buf)
{
struct bpdt *s = buffer_get(buf);
struct bpdt_header *h = &s->h;
struct bpdt_entry *e = &s->e[0];
size_t count = h->descriptor_count;
size_t offset = 0;
offset = fix_member(&h->signature, offset, sizeof(h->signature));
offset = fix_member(&h->descriptor_count, offset,
sizeof(h->descriptor_count));
offset = fix_member(&h->bpdt_version, offset, sizeof(h->bpdt_version));
offset = fix_member(&h->xor_redundant_block, offset,
sizeof(h->xor_redundant_block));
offset = fix_member(&h->ifwi_version, offset, sizeof(h->ifwi_version));
offset = fix_member(&h->fit_tool_version, offset,
sizeof(h->fit_tool_version));
uint32_t i;
for (i = 0; i < count; i++) {
offset = fix_member(&e[i].type, offset, sizeof(e[i].type));
offset = fix_member(&e[i].flags, offset, sizeof(e[i].flags));
offset = fix_member(&e[i].offset, offset, sizeof(e[i].offset));
offset = fix_member(&e[i].size, offset, sizeof(e[i].size));
}
}
/* Write BPDT to output buffer after fixup. */
static void bpdt_write(struct buffer *dst, size_t offset, struct buffer *src)
{
bpdt_fixup_write_buffer(src);
memcpy(buffer_get(dst) + offset, buffer_get(src), buffer_size(src));
}
/*
* Follows these steps to re-create image:
* 1. Write any non-IFWI prefix.
* 2. Write out BPDT header and entries.
* 3. Write sub-partition buffers to respective offsets.
* 4. Write any non-IFWI suffix.
*
* While performing the above steps, make sure that any empty holes are filled
* with FF.
*/
static void ifwi_write(const char *image_name)
{
struct bpdt_entry *s = find_entry_by_type(S_BPDT_TYPE);
assert(s);
size_t ifwi_start, ifwi_end, file_end;
ifwi_start = ifwi_image.input_ifwi_start_offset;
ifwi_end = ifwi_start + ALIGN(s->offset + s->size, 4 * KiB);
file_end = ifwi_end + (buffer_size(&ifwi_image.input_buff) -
ifwi_image.input_ifwi_end_offset);
struct buffer b;
alloc_buffer(&b, file_end, "Final-IFWI");
uint8_t *input_data = buffer_get(&ifwi_image.input_buff);
uint8_t *output_data = buffer_get(&b);
DEBUG("ifwi_start:0x%zx, ifwi_end:0x%zx, file_end:0x%zx\n", ifwi_start,
ifwi_end, file_end);
/* Copy non-IFWI prefix, if any. */
memcpy(output_data, input_data, ifwi_start);
DEBUG("Copied non-IFWI prefix (offset=0x0, size=0x%zx).\n", ifwi_start);
struct buffer ifwi;
buffer_splice(&ifwi, &b, ifwi_start, ifwi_end - ifwi_start);
uint8_t *ifwi_data = buffer_get(&ifwi);
/* Copy sub-partitions using pack_order. */
struct bpdt_entry *curr;
struct buffer *subpart_buf;
int i, type;
for (i = 0; i < MAX_SUBPARTS; i++) {
type = bpdt_pack_order[i];
if (type == S_BPDT_TYPE)
continue;
curr = find_entry_by_type(type);
if ((curr == NULL) || (curr->size == 0))
continue;
subpart_buf = &ifwi_image.subpart_buf[type];
DEBUG("curr->offset=0x%x, curr->size=0x%x, type=%d, "
"write_size=0x%zx\n", curr->offset, curr->size, type,
buffer_size(subpart_buf));
assert((curr->offset + buffer_size(subpart_buf)) <=
buffer_size(&ifwi));
memcpy(ifwi_data + curr->offset, buffer_get(subpart_buf),
buffer_size(subpart_buf));
}
/* Copy non-IFWI suffix, if any. */
if (ifwi_end != file_end) {
memcpy(output_data + ifwi_end,
input_data + ifwi_image.input_ifwi_end_offset,
file_end - ifwi_end);
DEBUG("Copied non-IFWI suffix (offset=0x%zx,size=0x%zx).\n",
ifwi_end, file_end - ifwi_end);
}
/*
* Convert BPDT to little-endian format and write it to output buffer.
* S-BPDT is written first and then BPDT.
*/
bpdt_write(&ifwi, s->offset, &ifwi_image.subpart_buf[S_BPDT_TYPE]);
bpdt_write(&ifwi, 0, &ifwi_image.bpdt);
if (buffer_write_file(&b, image_name)) {
ERROR("File write error\n");
exit(-1);
}
buffer_delete(&b);
printf("Image written successfully to %s.\n", image_name);
}
/*
* Calculate size and offset of each sub-partition again since it might have
* changed because of add/delete operation. Also, re-create BPDT and S-BPDT
* entries and write back the new IFWI image to file.
*/
static void ifwi_repack(void)
{
bpdt_reset();
bpdt_entries_init_header_order();
bpdt_entries_init_pack_order();
struct bpdt *b = buffer_get(&ifwi_image.bpdt);
bpdt_print_entries(&b->e[0], b->h.descriptor_count, "BPDT");
b = buffer_get(&ifwi_image.subpart_buf[S_BPDT_TYPE]);
bpdt_print_entries(&b->e[0], b->h.descriptor_count, "S-BPDT");
DEBUG("Repack done.. writing image.\n");
ifwi_write(param.image_name);
}
static void init_subpart_dir_header(struct subpart_dir_header *hdr,
size_t count, const char *name)
{
memset(hdr, 0, sizeof(*hdr));
hdr->marker = SUBPART_DIR_MARKER;
hdr->num_entries = count;
hdr->header_version = SUBPART_DIR_HEADER_VERSION_SUPPORTED;
hdr->entry_version = SUBPART_DIR_ENTRY_VERSION_SUPPORTED;
hdr->header_length = SUBPART_DIR_HEADER_SIZE;
memcpy(hdr->name, name, sizeof(hdr->name));
}
static size_t init_subpart_dir_entry(struct subpart_dir_entry *e,
struct buffer *b, size_t offset)
{
memset(e, 0, sizeof(*e));
assert(strlen(b->name) <= sizeof(e->name));
strncpy((char *)e->name, (char *)b->name, sizeof(e->name));
e->offset = offset;
e->length = buffer_size(b);
return (offset + buffer_size(b));
}
static void init_manifest_header(struct manifest_header *hdr, size_t size)
{
memset(hdr, 0, sizeof(*hdr));
hdr->header_type = 0x4;
assert((MANIFEST_HDR_SIZE % DWORD_SIZE) == 0);
hdr->header_length = MANIFEST_HDR_SIZE / DWORD_SIZE;
hdr->header_version = 0x10000;
hdr->vendor = 0x8086;
struct tm *local_time;
time_t curr_time;
char buffer[11];
curr_time = time(NULL);
local_time = localtime(&curr_time);
strftime(buffer, sizeof(buffer), "0x%Y%m%d", local_time);
hdr->date = strtoul(buffer, NULL, 16);
assert((size % DWORD_SIZE) == 0);
hdr->size = size / DWORD_SIZE;
hdr->id = MANIFEST_ID_MAGIC;
}
static void init_signed_pkg_info_ext(struct signed_pkg_info_ext *ext,
size_t count, const char *name)
{
memset(ext, 0, sizeof(*ext));
ext->ext_type = SIGNED_PKG_INFO_EXT_TYPE;
ext->ext_length = SIGNED_PKG_INFO_EXT_SIZE + count * MODULE_SIZE;
memcpy(ext->name, name, sizeof(ext->name));
}
static void subpart_dir_fixup_write_buffer(struct buffer *buf)
{
struct subpart_dir *s = buffer_get(buf);
struct subpart_dir_header *h = &s->h;
struct subpart_dir_entry *e = &s->e[0];
size_t count = h->num_entries;
size_t offset = 0;
offset = fix_member(&h->marker, offset, sizeof(h->marker));
offset = fix_member(&h->num_entries, offset, sizeof(h->num_entries));
offset = fix_member(&h->header_version, offset,
sizeof(h->header_version));
offset = fix_member(&h->entry_version, offset,
sizeof(h->entry_version));
offset = fix_member(&h->header_length, offset,
sizeof(h->header_length));
offset = fix_member(&h->checksum, offset, sizeof(h->checksum));
offset += sizeof(h->name);
uint32_t i;
for (i = 0; i < count; i++) {
offset += sizeof(e[i].name);
offset = fix_member(&e[i].offset, offset, sizeof(e[i].offset));
offset = fix_member(&e[i].length, offset, sizeof(e[i].length));
offset = fix_member(&e[i].rsvd, offset, sizeof(e[i].rsvd));
}
}
static void create_subpart(struct buffer *dst, struct buffer *info[],
size_t count, const char *name)
{
struct buffer subpart_dir_buff;
size_t size = SUBPART_DIR_HEADER_SIZE + count * SUBPART_DIR_ENTRY_SIZE;
alloc_buffer(&subpart_dir_buff, size, "subpart-dir");
struct subpart_dir_header *h = buffer_get(&subpart_dir_buff);
struct subpart_dir_entry *e = (struct subpart_dir_entry *)(h + 1);
init_subpart_dir_header(h, count, name);
size_t curr_offset = size;
size_t i;
for (i = 0; i < count; i++) {
curr_offset = init_subpart_dir_entry(&e[i], info[i],
curr_offset);
}
alloc_buffer(dst, curr_offset, name);
uint8_t *data = buffer_get(dst);
for (i = 0; i < count; i++) {
memcpy(data + e[i].offset, buffer_get(info[i]),
buffer_size(info[i]));
}
h->checksum = 0;
struct subpart_dir *dir = buffer_get(&subpart_dir_buff);
print_subpart_dir(dir);
subpart_dir_fixup_write_buffer(&subpart_dir_buff);
memcpy(data, dir, buffer_size(&subpart_dir_buff));
buffer_delete(&subpart_dir_buff);
}
static enum ifwi_ret ibbp_dir_add(int type)
{
#define DUMMY_IBB_SIZE (4 * KiB)
assert(type == IBB_TYPE);
/*
* Entry # 1 - IBBP.man
* Contains manifest header and signed pkg info extension.
*/
struct buffer manifest;
size_t size = MANIFEST_HDR_SIZE + SIGNED_PKG_INFO_EXT_SIZE;
alloc_buffer(&manifest, size, "IBBP.man");
struct manifest_header *man_hdr = buffer_get(&manifest);
init_manifest_header(man_hdr, size);
struct signed_pkg_info_ext *ext;
ext = (struct signed_pkg_info_ext *)(man_hdr + 1);
init_signed_pkg_info_ext(ext, 0, subparts[type].name);
/* Entry # 2 - IBBL */
struct buffer ibbl;
if (buffer_from_file(&ibbl, param.file_name))
return COMMAND_ERR;
/* Entry # 3 - IBB */
struct buffer ibb;
alloc_buffer(&ibb, DUMMY_IBB_SIZE, "IBB");
memset(buffer_get(&ibb), 0xFF, DUMMY_IBB_SIZE);
/* Create subpartition. */
struct buffer *info[] = {
&manifest, &ibbl, &ibb,
};
create_subpart(&ifwi_image.subpart_buf[type], &info[0],
ARRAY_SIZE(info), subparts[type].name);
return REPACK_REQUIRED;
}
static enum ifwi_ret ifwi_raw_add(int type)
{
if (buffer_from_file(&ifwi_image.subpart_buf[type], param.file_name))
return COMMAND_ERR;
printf("Sub-partition %s(%d) added from file %s.\n", param.subpart_name,
type, param.file_name);
return REPACK_REQUIRED;
}
static enum ifwi_ret ifwi_dir_add(int type)
{
if (!(subparts[type].attr & CONTAINS_DIR) ||
(subparts[type].dir_ops.dir_add == NULL)) {
ERROR("Sub-Partition %s(%d) does not support dir ops.\n",
subparts[type].name, type);
return COMMAND_ERR;
}
if (!param.dentry_name) {
ERROR("%s: -e option required\n", __func__);
return COMMAND_ERR;
}
enum ifwi_ret ret = subparts[type].dir_ops.dir_add(type);
if (ret != COMMAND_ERR)
printf("Sub-partition %s(%d) entry %s added from file %s.\n",
param.subpart_name, type, param.dentry_name,
param.file_name);
else
ERROR("Sub-partition dir operation failed.\n");
return ret;
}
static enum ifwi_ret ifwi_add(void)
{
if (!param.file_name) {
ERROR("%s: -f option required\n", __func__);
return COMMAND_ERR;
}
if (!param.subpart_name) {
ERROR("%s: -n option required\n", __func__);
return COMMAND_ERR;
}
int type = find_type_by_name(param.subpart_name);
if (type == -1)
return COMMAND_ERR;
const struct subpart_info *curr_subpart = &subparts[type];
if (curr_subpart->attr & AUTO_GENERATED) {
ERROR("Cannot add auto-generated sub-partitions.\n");
return COMMAND_ERR;
}
if (buffer_size(&ifwi_image.subpart_buf[type])) {
ERROR("Image already contains sub-partition %s(%d).\n",
param.subpart_name, type);
return COMMAND_ERR;
}
if (param.dir_ops)
return ifwi_dir_add(type);
return ifwi_raw_add(type);
}
static enum ifwi_ret ifwi_delete(void)
{
if (!param.subpart_name) {
ERROR("%s: -n option required\n", __func__);
return COMMAND_ERR;
}
int type = find_type_by_name(param.subpart_name);
if (type == -1)
return COMMAND_ERR;
const struct subpart_info *curr_subpart = &subparts[type];
if (curr_subpart->attr & AUTO_GENERATED) {
ERROR("Cannot delete auto-generated sub-partitions.\n");
return COMMAND_ERR;
}
if (buffer_size(&ifwi_image.subpart_buf[type]) == 0) {
printf("Image does not contain sub-partition %s(%d).\n",
param.subpart_name, type);
return NO_ACTION_REQUIRED;
}
buffer_delete(&ifwi_image.subpart_buf[type]);
printf("Sub-Partition %s(%d) deleted.\n", subparts[type].name, type);
return REPACK_REQUIRED;
}
static enum ifwi_ret ifwi_dir_extract(int type)
{
if (!(subparts[type].attr & CONTAINS_DIR)) {
ERROR("Sub-Partition %s(%d) does not support dir ops.\n",
subparts[type].name, type);
return COMMAND_ERR;
}
if (!param.dentry_name) {
ERROR("%s: -e option required.\n", __func__);
return COMMAND_ERR;
}
struct buffer subpart_dir_buff;
parse_subpart_dir(&subpart_dir_buff, &ifwi_image.subpart_buf[type],
subparts[type].name);
uint32_t i;
struct subpart_dir *s = buffer_get(&subpart_dir_buff);
for (i = 0; i < s->h.num_entries; i++) {
if (!strncmp((char *)s->e[i].name, param.dentry_name,
sizeof(s->e[i].name)))
break;
}
if (i == s->h.num_entries) {
ERROR("Entry %s not found in subpartition for %s.\n",
param.dentry_name, param.subpart_name);
exit(-1);
}
struct buffer dst;
DEBUG("Splicing buffer at 0x%x size 0x%x\n", s->e[i].offset,
s->e[i].length);
buffer_splice(&dst, &ifwi_image.subpart_buf[type], s->e[i].offset,
s->e[i].length);
if (buffer_write_file(&dst, param.file_name))
return COMMAND_ERR;
printf("Sub-Partition %s(%d), entry(%s) stored in %s.\n",
param.subpart_name, type, param.dentry_name, param.file_name);
return NO_ACTION_REQUIRED;
}
static enum ifwi_ret ifwi_raw_extract(int type)
{
if (buffer_write_file(&ifwi_image.subpart_buf[type], param.file_name))
return COMMAND_ERR;
printf("Sub-Partition %s(%d) stored in %s.\n", param.subpart_name, type,
param.file_name);
return NO_ACTION_REQUIRED;
}
static enum ifwi_ret ifwi_extract(void)
{
if (!param.file_name) {
ERROR("%s: -f option required\n", __func__);
return COMMAND_ERR;
}
if (!param.subpart_name) {
ERROR("%s: -n option required\n", __func__);
return COMMAND_ERR;
}
int type = find_type_by_name(param.subpart_name);
if (type == -1)
return COMMAND_ERR;
if (type == S_BPDT_TYPE) {
INFO("Tool does not support raw extract for %s\n",
param.subpart_name);
return NO_ACTION_REQUIRED;
}
if (buffer_size(&ifwi_image.subpart_buf[type]) == 0) {
ERROR("Image does not contain sub-partition %s(%d).\n",
param.subpart_name, type);
return COMMAND_ERR;
}
INFO("Extracting sub-partition %s(%d).\n", param.subpart_name, type);
if (param.dir_ops)
return ifwi_dir_extract(type);
return ifwi_raw_extract(type);
}
static enum ifwi_ret ifwi_print(void)
{
verbose += 2;
struct bpdt *b = buffer_get(&ifwi_image.bpdt);
bpdt_print_header(&b->h, "BPDT");
bpdt_print_entries(&b->e[0], b->h.descriptor_count, "BPDT");
b = buffer_get(&ifwi_image.subpart_buf[S_BPDT_TYPE]);
bpdt_print_header(&b->h, "S-BPDT");
bpdt_print_entries(&b->e[0], b->h.descriptor_count, "S-BPDT");
if (param.dir_ops == 0) {
verbose -= 2;
return NO_ACTION_REQUIRED;
}
int i;
struct buffer subpart_dir_buf;
for (i = 0; i < MAX_SUBPARTS ; i++) {
if (!(subparts[i].attr & CONTAINS_DIR) ||
(buffer_size(&ifwi_image.subpart_buf[i]) == 0))
continue;
parse_subpart_dir(&subpart_dir_buf, &ifwi_image.subpart_buf[i],
subparts[i].name);
buffer_delete(&subpart_dir_buf);
}
verbose -= 2;
return NO_ACTION_REQUIRED;
}
static enum ifwi_ret ifwi_raw_replace(int type)
{
buffer_delete(&ifwi_image.subpart_buf[type]);
return ifwi_raw_add(type);
}
static enum ifwi_ret ifwi_dir_replace(int type)
{
if (!(subparts[type].attr & CONTAINS_DIR)) {
ERROR("Sub-Partition %s(%d) does not support dir ops.\n",
subparts[type].name, type);
return COMMAND_ERR;
}
if (!param.dentry_name) {
ERROR("%s: -e option required.\n", __func__);
return COMMAND_ERR;
}
struct buffer subpart_dir_buf;
parse_subpart_dir(&subpart_dir_buf, &ifwi_image.subpart_buf[type],
subparts[type].name);
uint32_t i;
struct subpart_dir *s = buffer_get(&subpart_dir_buf);
for (i = 0; i < s->h.num_entries; i++) {
if (!strcmp((char *)s->e[i].name, param.dentry_name))
break;
}
if (i == s->h.num_entries) {
ERROR("Entry %s not found in subpartition for %s.\n",
param.dentry_name, param.subpart_name);
exit(-1);
}
struct buffer b;
if (buffer_from_file(&b, param.file_name)) {
ERROR("Failed to read %s\n", param.file_name);
exit(-1);
}
struct buffer dst;
size_t dst_size = buffer_size(&ifwi_image.subpart_buf[type]) +
buffer_size(&b) - s->e[i].length;
size_t subpart_start = s->e[i].offset;
size_t subpart_end = s->e[i].offset + s->e[i].length;
alloc_buffer(&dst, dst_size, ifwi_image.subpart_buf[type].name);
uint8_t *src_data = buffer_get(&ifwi_image.subpart_buf[type]);
uint8_t *dst_data = buffer_get(&dst);
size_t curr_offset = 0;
/* Copy data before the sub-partition entry. */
memcpy(dst_data + curr_offset, src_data, subpart_start);
curr_offset += subpart_start;
/* Copy sub-partition entry. */
memcpy(dst_data + curr_offset, buffer_get(&b), buffer_size(&b));
curr_offset += buffer_size(&b);
/* Copy remaining data. */
memcpy(dst_data + curr_offset, src_data + subpart_end,
buffer_size(&ifwi_image.subpart_buf[type]) - subpart_end);
/* Update sub-partition buffer. */
int offset = s->e[i].offset;
buffer_delete(&ifwi_image.subpart_buf[type]);
ifwi_image.subpart_buf[type] = dst;
/* Update length of entry in the subpartition. */
s->e[i].length = buffer_size(&b);
buffer_delete(&b);
/* Adjust offsets of affected entries in subpartition. */
offset = s->e[i].offset - offset;
for (; i < s->h.num_entries; i++) {
s->e[i].offset += offset;
}
s->h.checksum = 0;
/* Convert members to litte-endian. */
subpart_dir_fixup_write_buffer(&subpart_dir_buf);
memcpy(dst_data, buffer_get(&subpart_dir_buf),
buffer_size(&subpart_dir_buf));
buffer_delete(&subpart_dir_buf);
printf("Sub-partition %s(%d) entry %s replaced from file %s.\n",
param.subpart_name, type, param.dentry_name, param.file_name);
return REPACK_REQUIRED;
}
static enum ifwi_ret ifwi_replace(void)
{
if (!param.file_name) {
ERROR("%s: -f option required\n", __func__);
return COMMAND_ERR;
}
if (!param.subpart_name) {
ERROR("%s: -n option required\n", __func__);
return COMMAND_ERR;
}
int type = find_type_by_name(param.subpart_name);
if (type == -1)
return COMMAND_ERR;
const struct subpart_info *curr_subpart = &subparts[type];
if (curr_subpart->attr & AUTO_GENERATED) {
ERROR("Cannot replace auto-generated sub-partitions.\n");
return COMMAND_ERR;
}
if (buffer_size(&ifwi_image.subpart_buf[type]) == 0) {
ERROR("Image does not contain sub-partition %s(%d).\n",
param.subpart_name, type);
return COMMAND_ERR;
}
if (param.dir_ops)
return ifwi_dir_replace(type);
return ifwi_raw_replace(type);
}
static enum ifwi_ret ifwi_create(void)
{
/*
* Create peels off any non-IFWI content present in the input buffer and
* creates output file with only the IFWI present.
*/
if (!param.file_name) {
ERROR("%s: -f option required\n", __func__);
return COMMAND_ERR;
}
/* Peel off any non-IFWI prefix. */
buffer_seek(&ifwi_image.input_buff,
ifwi_image.input_ifwi_start_offset);
/* Peel off any non-IFWI suffix. */
buffer_set_size(&ifwi_image.input_buff,
ifwi_image.input_ifwi_end_offset -
ifwi_image.input_ifwi_start_offset);
/*
* Adjust start and end offset of IFWI now that non-IFWI prefix is gone.
*/
ifwi_image.input_ifwi_end_offset -= ifwi_image.input_ifwi_start_offset;
ifwi_image.input_ifwi_start_offset = 0;
param.image_name = param.file_name;
return REPACK_REQUIRED;
}
struct command {
const char *name;
const char *optstring;
enum ifwi_ret (*function)(void);
};
static const struct command commands[] = {
{"add", "f:n:e:dvh?", ifwi_add},
{"create", "f:vh?", ifwi_create},
{"delete", "f:n:vh?", ifwi_delete},
{"extract", "f:n:e:dvh?", ifwi_extract},
{"print", "dh?", ifwi_print},
{"replace", "f:n:e:dvh?", ifwi_replace},
};
static struct option long_options[] = {
{"subpart_dentry", required_argument, 0, 'e'},
{"file", required_argument, 0, 'f'},
{"help", required_argument, 0, 'h'},
{"name", required_argument, 0, 'n'},
{"dir_ops", no_argument, 0, 'd'},
{"verbose", no_argument, 0, 'v'},
{NULL, 0, 0, 0 }
};
static void usage(const char *name)
{
printf("ifwitool: Utility for IFWI manipulation\n\n"
"USAGE:\n"
" %s [-h]\n"
" %s FILE COMMAND [PARAMETERS]\n\n"
"COMMANDs:\n"
" add -f FILE -n NAME [-d -e ENTRY]\n"
" create -f FILE\n"
" delete -n NAME\n"
" extract -f FILE -n NAME [-d -e ENTRY]\n"
" print [-d]\n"
" replace -f FILE -n NAME [-d -e ENTRY]\n"
"OPTIONs:\n"
" -f FILE : File to read/write/create/extract\n"
" -d : Perform directory operation\n"
" -e ENTRY: Name of directory entry to operate on\n"
" -v : Verbose level\n"
" -h : Help message\n"
" -n NAME : Name of sub-partition to operate on\n",
name, name
);
printf("\nNAME should be one of:\n");
int i;
for (i = 0; i < MAX_SUBPARTS; i++)
printf("%s(%s)\n", subparts[i].name, subparts[i].readable_name);
printf("\n");
}
int main(int argc, char **argv)
{
if (argc < 3) {
usage(argv[0]);
return 1;
}
param.image_name = argv[1];
char *cmd = argv[2];
optind += 2;
uint32_t i;
for (i = 0; i < ARRAY_SIZE(commands); i++) {
if (strcmp(cmd, commands[i].name) != 0)
continue;
int c;
while (1) {
int option_index;
c = getopt_long(argc, argv, commands[i].optstring,
long_options, &option_index);
if (c == -1)
break;
/* Filter out illegal long options. */
if (strchr(commands[i].optstring, c) == NULL) {
ERROR("%s: invalid option -- '%c'\n", argv[0],
c);
c = '?';
}
switch (c) {
case 'n':
param.subpart_name = optarg;
break;
case 'f':
param.file_name = optarg;
break;
case 'd':
param.dir_ops = 1;
break;
case 'e':
param.dentry_name = optarg;
break;
case 'v':
verbose++;
break;
case 'h':
case '?':
usage(argv[0]);
return 1;
default:
break;
}
}
if (ifwi_parse()) {
ERROR("%s: ifwi parsing failed\n", argv[0]);
return 1;
}
enum ifwi_ret ret = commands[i].function();
if (ret == COMMAND_ERR) {
ERROR("%s: failed execution\n", argv[0]);
return 1;
}
if (ret == REPACK_REQUIRED)
ifwi_repack();
return 0;
}
ERROR("%s: invalid command\n", argv[0]);
return 1;
}