Magisk/jni/magiskboot/parseimg.c
2017-03-29 04:35:35 +08:00

254 lines
5.6 KiB
C

#include "bootimg.h"
#include "elf.h"
#include "magiskboot.h"
unsigned char *kernel, *ramdisk, *second, *dtb, *extra;
boot_img_hdr hdr;
int mtk_kernel = 0, mtk_ramdisk = 0;
file_t boot_type, ramdisk_type, dtb_type;
static void check_headers() {
// Check ramdisk compression type
ramdisk_type = check_type(ramdisk);
// Check MTK
if (check_type(kernel) == MTK) {
printf("MTK header found in kernel\n");
mtk_kernel = 1;
}
if (ramdisk_type == MTK) {
printf("MTK header found in ramdisk\n");
mtk_ramdisk = 1;
ramdisk_type = check_type(ramdisk + 512);
}
// Check dtb if ELF boot
if (boot_type == ELF && hdr.dt_size) {
dtb_type = check_type(dtb);
}
// Print info
print_info();
}
static void elf_header_check(void *elf, int is64) {
size_t e_size, mach, ver, p_size, p_num, s_size, s_num;
size_t r_e_size, r_p_size, r_s_size;
if (is64) {
e_size = ((elf64_ehdr *) elf)->e_ehsize;
mach = ((elf64_ehdr *) elf)->e_machine;
ver = ((elf64_ehdr *) elf)->e_version;
p_size = ((elf64_ehdr *) elf)->e_phentsize;
p_num = ((elf64_ehdr *) elf)->e_phnum;
s_size = ((elf64_ehdr *) elf)->e_shentsize;
s_num = ((elf64_ehdr *) elf)->e_shnum;
r_e_size = sizeof(elf64_ehdr);
r_p_size = sizeof(elf64_phdr);
r_s_size = sizeof(elf64_shdr);
} else {
e_size = ((elf32_ehdr *) elf)->e_ehsize;
mach = ((elf32_ehdr *) elf)->e_machine;
ver = ((elf32_ehdr *) elf)->e_version;
p_size = ((elf32_ehdr *) elf)->e_phentsize;
p_num = ((elf32_ehdr *) elf)->e_phnum;
s_size = ((elf32_ehdr *) elf)->e_shentsize;
s_num = ((elf32_ehdr *) elf)->e_shnum;
r_e_size = sizeof(elf32_ehdr);
r_p_size = sizeof(elf32_phdr);
r_s_size = sizeof(elf32_shdr);
}
if (e_size != r_e_size)
error(1, "Header size not %d", r_e_size);
if (mach != EM_ARM)
error(1, "ELF machine is not ARM");
if (ver != 1)
error(1, "Unknown ELF version");
if (p_size != r_p_size)
error(1, "Program header size not %d", r_p_size);
if (p_num < 2 || p_num > 4)
error(1, "Unexpected number of elements: %d", p_num);
if (s_num && s_size != r_s_size)
error(1, "Section header size not %d", r_s_size);
if (s_num > 1)
error(1, "More than one section header");
}
static void elf_set(int i, unsigned char *base, size_t size, size_t offset, size_t addr) {
if (size <= 4096) {
// Possible cmdline
memset(hdr.cmdline, 0, BOOT_ARGS_SIZE);
strncpy((char *) hdr.cmdline, (char *) (base + offset), BOOT_ARGS_SIZE);
hdr.cmdline[strcspn((char*) hdr.cmdline, "\n")] = '\0';
return;
}
switch(i) {
case 0:
// kernel
kernel = base + offset;
hdr.kernel_size = size;
hdr.kernel_addr = addr;
break;
case 1:
// ramdisk
ramdisk = base + offset;
hdr.ramdisk_size = size;
hdr.ramdisk_addr = addr;
break;
case 2:
// dtb
dtb = base + offset;
hdr.dt_size = size;
hdr.tags_addr = addr;
break;
}
}
static void parse_elf(unsigned char *base) {
// Reset boot image header
memset(&hdr, 0, sizeof(hdr));
// Hardcode header magic and pagesize
memcpy(hdr.magic, BOOT_MAGIC, BOOT_MAGIC_SIZE);
hdr.page_size = 4096;
switch(base[EI_CLASS]) {
case ELFCLASS32: {
elf32_ehdr *elf32;
elf32_phdr *ph32;
elf32_shdr *sh32;
printf("IMAGE [ELF32]\n");
elf32 = (elf32_ehdr *) base;
elf_header_check(elf32, 0);
ph32 = (elf32_phdr *) (base + elf32->e_phoff);
sh32 = (elf32_shdr *) (base + elf32->e_shoff);
for (int i = 0; i < elf32->e_phnum; ++i) {
elf_set(i, base, ph32[i].p_filesz, ph32[i].p_offset, ph32[i].p_paddr);
}
if (elf32->e_shnum) {
// cmdline
memset(hdr.cmdline, 0, BOOT_ARGS_SIZE);
strncpy((char *) hdr.cmdline, (char *) (base + sh32->s_offset + 8), BOOT_ARGS_SIZE);
hdr.cmdline[strcspn((char*) hdr.cmdline, "\n")] = '\0';
}
break;
}
case ELFCLASS64: {
elf64_ehdr *elf64;
elf64_phdr *ph64;
elf64_shdr *sh64;
printf("IMAGE [ELF64]\n");
elf64 = (elf64_ehdr *) base;
elf_header_check(elf64, 1);
ph64 = (elf64_phdr *) (base + elf64->e_phoff);
sh64 = (elf64_shdr *) (base + elf64->e_shoff);
for (int i = 0; i < elf64->e_phnum; ++i) {
elf_set(i, base, ph64[i].p_filesz, ph64[i].p_offset, ph64[i].p_paddr);
}
if (elf64->e_shnum) {
// cmdline
memset(hdr.cmdline, 0, BOOT_ARGS_SIZE);
strncpy((char *) hdr.cmdline, (char *) (base + sh64->s_offset + 8), BOOT_ARGS_SIZE);
hdr.cmdline[strcspn((char*) hdr.cmdline, "\n")] = '\0';
}
break;
}
default:
error(1, "ELF format error!");
}
check_headers();
}
static void parse_aosp(unsigned char *base, size_t size) {
printf("IMG [AOSP]\n");
size_t pos = 0;
// Read the header
memcpy(&hdr, base, sizeof(hdr));
pos += hdr.page_size;
// Kernel position
kernel = base + pos;
pos += hdr.kernel_size;
mem_align(&pos, hdr.page_size);
// Ramdisk position
ramdisk = base + pos;
pos += hdr.ramdisk_size;
mem_align(&pos, hdr.page_size);
if (hdr.second_size) {
// Second position
second = base + pos;
pos += hdr.second_size;
mem_align(&pos, hdr.page_size);
}
if (hdr.dt_size) {
// dtb position
dtb = base + pos;
pos += hdr.dt_size;
mem_align(&pos, hdr.page_size);
}
if (pos < size) {
extra = base + pos;
}
check_headers();
}
void parse_img(unsigned char *orig, size_t size) {
unsigned char *base, *end;
for(base = orig, end = orig + size; base < end; base += 256, size -= 256) {
switch (check_type(base)) {
case CHROMEOS:
boot_type = CHROMEOS;
continue;
case AOSP:
// Don't override CHROMEOS
if (boot_type != CHROMEOS)
boot_type = AOSP;
parse_aosp(base, size);
return;
case ELF:
boot_type = ELF;
parse_elf(base);
return;
default:
continue;
}
}
error(1, "No boot image magic found!");
}