*/
addr_t map_data(const void *data, size_t len, size_t align, int flags)
{
- addr_t start = (flags & MAP_HIGH) ? mboot_high_water_mark : 0x2000;
- addr_t pad = (flags & MAP_NOPAD) ? 0 : -len & (align-1);
- addr_t xlen = len+pad;
-
- if (syslinux_memmap_find(amap, SMT_FREE, &start, &xlen, align) ||
- syslinux_add_memmap(&amap, start, len+pad, SMT_ALLOC) ||
- syslinux_add_movelist(&ml, start, (addr_t)data, len) ||
- (pad && syslinux_add_memmap(&mmap, start+len, pad, SMT_ZERO))) {
- printf("Cannot map %zu bytes\n", len+pad);
- return 0;
- }
+ addr_t start = (flags & MAP_HIGH) ? mboot_high_water_mark : 0x2000;
+ addr_t pad = (flags & MAP_NOPAD) ? 0 : -len & (align - 1);
+ addr_t xlen = len + pad;
+
+ if (syslinux_memmap_find(amap, SMT_FREE, &start, &xlen, align) ||
+ syslinux_add_memmap(&amap, start, len + pad, SMT_ALLOC) ||
+ syslinux_add_movelist(&ml, start, (addr_t) data, len) ||
+ (pad && syslinux_add_memmap(&mmap, start + len, pad, SMT_ZERO))) {
+ printf("Cannot map %zu bytes\n", len + pad);
+ return 0;
+ }
- dprintf("Mapping 0x%08x bytes (%#x pad) at 0x%08x\n", len, pad, start);
+ dprintf("Mapping 0x%08x bytes (%#x pad) at 0x%08x\n", len, pad, start);
- if (start+len+pad > mboot_high_water_mark)
- mboot_high_water_mark = start+len+pad;
+ if (start + len + pad > mboot_high_water_mark)
+ mboot_high_water_mark = start + len + pad;
- return start;
+ return start;
}
addr_t map_string(const char *string)
{
- if (!string)
- return 0;
- else
- return map_data(string, strlen(string)+1, 1, 0);
+ if (!string)
+ return 0;
+ else
+ return map_data(string, strlen(string) + 1, 1, 0);
}
int init_map(void)
{
- /*
- * Note: mmap is the memory map (containing free and zeroed regions)
- * needed by syslinux_shuffle_boot_pm(); amap is a map where we keep
- * track ourselves which target memory ranges have already been
- * allocated.
- */
- mmap = syslinux_memory_map();
- amap = syslinux_dup_memmap(mmap);
- if (!mmap || !amap) {
- error("Failed to allocate initial memory map!\n");
- return -1;
- }
-
+ /*
+ * Note: mmap is the memory map (containing free and zeroed regions)
+ * needed by syslinux_shuffle_boot_pm(); amap is a map where we keep
+ * track ourselves which target memory ranges have already been
+ * allocated.
+ */
+ mmap = syslinux_memory_map();
+ amap = syslinux_dup_memmap(mmap);
+ if (!mmap || !amap) {
+ error("Failed to allocate initial memory map!\n");
+ return -1;
+ }
#if DEBUG
- dprintf("Initial memory map:\n");
- syslinux_dump_memmap(stdout, mmap);
+ dprintf("Initial memory map:\n");
+ syslinux_dump_memmap(stdout, mmap);
#endif
- return 0;
+ return 0;
}
int map_image(void *ptr, size_t len)
{
- int mbh_len;
- char *cptr = ptr;
- Elf32_Ehdr *eh = ptr;
- Elf32_Phdr *ph;
- Elf32_Shdr *sh;
- unsigned int i;
- uint32_t bad_flags;
-
- /*
- * Search for the multiboot header...
- */
- mbh_len = 0;
- for (i = 0 ; i < MULTIBOOT_SEARCH ; i += 4) {
- mbh = (struct multiboot_header *)((char *)ptr + i);
- if (mbh->magic != MULTIBOOT_MAGIC)
- continue;
- if (mbh->magic + mbh->flags + mbh->checksum)
- continue;
- if (mbh->flags & MULTIBOOT_VIDEO_MODE)
- mbh_len = 48;
- else if (mbh->flags & MULTIBOOT_AOUT_KLUDGE)
- mbh_len = 32;
- else
- mbh_len = 12;
+ int mbh_len;
+ char *cptr = ptr;
+ Elf32_Ehdr *eh = ptr;
+ Elf32_Phdr *ph;
+ Elf32_Shdr *sh;
+ unsigned int i;
+ uint32_t bad_flags;
- if (i + mbh_len < len)
- mbh_len = 0; /* Invalid... */
- else
- break; /* Found something... */
- }
-
- if (mbh_len) {
- bad_flags = mbh->flags & (MULTIBOOT_UNSUPPORTED|MULTIBOOT_VIDEO_MODE);
- if (bad_flags) {
- printf("Unsupported Multiboot flags set: %#x\n", bad_flags);
- return -1;
+ /*
+ * Search for the multiboot header...
+ */
+ mbh_len = 0;
+ for (i = 0; i < MULTIBOOT_SEARCH; i += 4) {
+ mbh = (struct multiboot_header *)((char *)ptr + i);
+ if (mbh->magic != MULTIBOOT_MAGIC)
+ continue;
+ if (mbh->magic + mbh->flags + mbh->checksum)
+ continue;
+ if (mbh->flags & MULTIBOOT_VIDEO_MODE)
+ mbh_len = 48;
+ else if (mbh->flags & MULTIBOOT_AOUT_KLUDGE)
+ mbh_len = 32;
+ else
+ mbh_len = 12;
+
+ if (i + mbh_len < len)
+ mbh_len = 0; /* Invalid... */
+ else
+ break; /* Found something... */
}
- }
-
- if ( len < sizeof(Elf32_Ehdr) ||
- memcmp(eh->e_ident, "\x7f""ELF\1\1\1", 6) ||
- (eh->e_machine != EM_386 && eh->e_machine != EM_486 &&
- eh->e_machine != EM_X86_64) ||
- eh->e_version != EV_CURRENT ||
- eh->e_ehsize < sizeof(Elf32_Ehdr) || eh->e_ehsize >= len ||
- eh->e_phentsize < sizeof(Elf32_Phdr) ||
- !eh->e_phnum ||
- eh->e_phoff+eh->e_phentsize*eh->e_phnum > len )
- eh = NULL; /* No valid ELF header found */
-
- /*
- * Note: the Multiboot Specification implies that AOUT_KLUDGE should
- * have precedence over the ELF header. However, Grub disagrees, and
- * Grub is "the reference bootloader" for the Multiboot Specification.
- * This is insane, since it makes the AOUT_KLUDGE bit functionally
- * useless, but at least Solaris apparently depends on this behavior.
- */
- if (eh && !(opt.aout && mbh_len && (mbh->flags & MULTIBOOT_AOUT_KLUDGE))) {
- regs.eip = eh->e_entry; /* Can be overridden further down... */
-
- ph = (Elf32_Phdr *)(cptr+eh->e_phoff);
-
- for (i = 0; i < eh->e_phnum; i++) {
- if (ph->p_type == PT_LOAD || ph->p_type == PT_PHDR) {
- /*
- * This loads at p_paddr, which matches Grub. However, if
- * e_entry falls within the p_vaddr range of this PHDR, then
- * adjust it to match the p_paddr range... this is how Grub
- * behaves, so it's by definition correct (it doesn't have to
- * make sense...)
- */
- addr_t addr = ph->p_paddr;
- addr_t msize = ph->p_memsz;
- addr_t dsize = min(msize, ph->p_filesz);
- if (eh->e_entry >= ph->p_vaddr && eh->e_entry < ph->p_vaddr + msize)
- regs.eip = eh->e_entry + (ph->p_paddr - ph->p_vaddr);
+ if (mbh_len) {
+ bad_flags = mbh->flags & (MULTIBOOT_UNSUPPORTED | MULTIBOOT_VIDEO_MODE);
+ if (bad_flags) {
+ printf("Unsupported Multiboot flags set: %#x\n", bad_flags);
+ return -1;
+ }
+ }
- dprintf("Segment at 0x%08x data 0x%08x len 0x%08x\n",
- addr, dsize, msize);
+ if (len < sizeof(Elf32_Ehdr) ||
+ memcmp(eh->e_ident, "\x7f" "ELF\1\1\1", 6) ||
+ (eh->e_machine != EM_386 && eh->e_machine != EM_486 &&
+ eh->e_machine != EM_X86_64) ||
+ eh->e_version != EV_CURRENT ||
+ eh->e_ehsize < sizeof(Elf32_Ehdr) || eh->e_ehsize >= len ||
+ eh->e_phentsize < sizeof(Elf32_Phdr) ||
+ !eh->e_phnum || eh->e_phoff + eh->e_phentsize * eh->e_phnum > len)
+ eh = NULL; /* No valid ELF header found */
- if (syslinux_memmap_type(amap, addr, msize) != SMT_FREE) {
- printf("Memory segment at 0x%08x (len 0x%08x) is unavailable\n",
- addr, msize);
- return -1; /* Memory region unavailable */
+ /*
+ * Note: the Multiboot Specification implies that AOUT_KLUDGE should
+ * have precedence over the ELF header. However, Grub disagrees, and
+ * Grub is "the reference bootloader" for the Multiboot Specification.
+ * This is insane, since it makes the AOUT_KLUDGE bit functionally
+ * useless, but at least Solaris apparently depends on this behavior.
+ */
+ if (eh && !(opt.aout && mbh_len && (mbh->flags & MULTIBOOT_AOUT_KLUDGE))) {
+ regs.eip = eh->e_entry; /* Can be overridden further down... */
+
+ ph = (Elf32_Phdr *) (cptr + eh->e_phoff);
+
+ for (i = 0; i < eh->e_phnum; i++) {
+ if (ph->p_type == PT_LOAD || ph->p_type == PT_PHDR) {
+ /*
+ * This loads at p_paddr, which matches Grub. However, if
+ * e_entry falls within the p_vaddr range of this PHDR, then
+ * adjust it to match the p_paddr range... this is how Grub
+ * behaves, so it's by definition correct (it doesn't have to
+ * make sense...)
+ */
+ addr_t addr = ph->p_paddr;
+ addr_t msize = ph->p_memsz;
+ addr_t dsize = min(msize, ph->p_filesz);
+
+ if (eh->e_entry >= ph->p_vaddr
+ && eh->e_entry < ph->p_vaddr + msize)
+ regs.eip = eh->e_entry + (ph->p_paddr - ph->p_vaddr);
+
+ dprintf("Segment at 0x%08x data 0x%08x len 0x%08x\n",
+ addr, dsize, msize);
+
+ if (syslinux_memmap_type(amap, addr, msize) != SMT_FREE) {
+ printf
+ ("Memory segment at 0x%08x (len 0x%08x) is unavailable\n",
+ addr, msize);
+ return -1; /* Memory region unavailable */
+ }
+
+ /* Mark this region as allocated in the available map */
+ if (syslinux_add_memmap(&amap, addr, msize, SMT_ALLOC)) {
+ error("Overlapping segments found in ELF header\n");
+ return -1;
+ }
+
+ if (ph->p_filesz) {
+ /* Data present region. Create a move entry for it. */
+ if (syslinux_add_movelist
+ (&ml, addr, (addr_t) cptr + ph->p_offset, dsize)) {
+ error("Failed to map PHDR data\n");
+ return -1;
+ }
+ }
+ if (msize > dsize) {
+ /* Zero-filled region. Mark as a zero region in the memory map. */
+ if (syslinux_add_memmap
+ (&mmap, addr + dsize, msize - dsize, SMT_ZERO)) {
+ error("Failed to map PHDR zero region\n");
+ return -1;
+ }
+ }
+ if (addr + msize > mboot_high_water_mark)
+ mboot_high_water_mark = addr + msize;
+ } else {
+ /* Ignore this program header */
+ }
+
+ ph = (Elf32_Phdr *) ((char *)ph + eh->e_phentsize);
}
- /* Mark this region as allocated in the available map */
- if (syslinux_add_memmap(&amap, addr, msize, SMT_ALLOC)) {
- error("Overlapping segments found in ELF header\n");
- return -1;
+ /* Load the ELF symbol table */
+ if (eh->e_shoff) {
+ addr_t addr, len;
+
+ sh = (Elf32_Shdr *) ((char *)eh + eh->e_shoff);
+
+ len = eh->e_shentsize * eh->e_shnum;
+ /*
+ * Align this, but don't pad -- in general this means a bunch of
+ * smaller sections gets packed into a single page.
+ */
+ addr = map_data(sh, len, 4096, MAP_HIGH | MAP_NOPAD);
+ if (!addr) {
+ error("Failed to map symbol table\n");
+ return -1;
+ }
+
+ mbinfo.flags |= MB_INFO_ELF_SHDR;
+ mbinfo.syms.e.addr = addr;
+ mbinfo.syms.e.num = eh->e_shnum;
+ mbinfo.syms.e.size = eh->e_shentsize;
+ mbinfo.syms.e.shndx = eh->e_shstrndx;
+
+ for (i = 0; i < eh->e_shnum; i++) {
+ addr_t align;
+
+ if (!sh[i].sh_size)
+ continue; /* Empty section */
+ if (sh[i].sh_flags & SHF_ALLOC)
+ continue; /* SHF_ALLOC sections should have PHDRs */
+
+ align = sh[i].sh_addralign ? sh[i].sh_addralign : 0;
+ addr = map_data((char *)ptr + sh[i].sh_offset, sh[i].sh_size,
+ align, MAP_HIGH);
+ if (!addr) {
+ error("Failed to map symbol section\n");
+ return -1;
+ }
+ sh[i].sh_addr = addr;
+ }
}
+ } else if (mbh_len && (mbh->flags & MULTIBOOT_AOUT_KLUDGE)) {
+ /*
+ * a.out kludge thing...
+ */
+ char *data_ptr;
+ addr_t data_len, bss_len;
- if (ph->p_filesz) {
- /* Data present region. Create a move entry for it. */
- if (syslinux_add_movelist(&ml, addr, (addr_t)cptr+ph->p_offset,
- dsize)) {
- error("Failed to map PHDR data\n");
- return -1;
- }
+ regs.eip = mbh->entry_addr;
+
+ data_ptr = (char *)mbh - (mbh->header_addr - mbh->load_addr);
+ data_len = mbh->load_end_addr - mbh->load_addr;
+ bss_len = mbh->bss_end_addr - mbh->load_end_addr;
+
+ if (syslinux_memmap_type(amap, mbh->load_addr, data_len + bss_len)
+ != SMT_FREE) {
+ printf("Memory segment at 0x%08x (len 0x%08x) is unavailable\n",
+ mbh->load_addr, data_len + bss_len);
+ return -1; /* Memory region unavailable */
}
- if (msize > dsize) {
- /* Zero-filled region. Mark as a zero region in the memory map. */
- if (syslinux_add_memmap(&mmap, addr+dsize, msize-dsize, SMT_ZERO)) {
- error("Failed to map PHDR zero region\n");
+ if (syslinux_add_memmap(&amap, mbh->load_addr,
+ data_len + bss_len, SMT_ALLOC)) {
+ error("Failed to claim a.out address space!\n");
return -1;
- }
}
- if (addr+msize > mboot_high_water_mark)
- mboot_high_water_mark = addr+msize;
- } else {
- /* Ignore this program header */
- }
-
- ph = (Elf32_Phdr *)((char *)ph + eh->e_phentsize);
- }
-
- /* Load the ELF symbol table */
- if (eh->e_shoff) {
- addr_t addr, len;
-
- sh = (Elf32_Shdr *)((char *)eh + eh->e_shoff);
-
- len = eh->e_shentsize * eh->e_shnum;
- /*
- * Align this, but don't pad -- in general this means a bunch of
- * smaller sections gets packed into a single page.
- */
- addr = map_data(sh, len, 4096, MAP_HIGH|MAP_NOPAD);
- if (!addr) {
- error("Failed to map symbol table\n");
+ if (data_len)
+ if (syslinux_add_movelist(&ml, mbh->load_addr, (addr_t) data_ptr,
+ data_len)) {
+ error("Failed to map a.out data\n");
+ return -1;
+ }
+ if (bss_len)
+ if (syslinux_add_memmap
+ (&mmap, mbh->load_end_addr, bss_len, SMT_ZERO)) {
+ error("Failed to map a.out bss\n");
+ return -1;
+ }
+ if (mbh->bss_end_addr > mboot_high_water_mark)
+ mboot_high_water_mark = mbh->bss_end_addr;
+ } else {
+ error
+ ("Invalid Multiboot image: neither ELF header nor a.out kludge found\n");
return -1;
- }
-
- mbinfo.flags |= MB_INFO_ELF_SHDR;
- mbinfo.syms.e.addr = addr;
- mbinfo.syms.e.num = eh->e_shnum;
- mbinfo.syms.e.size = eh->e_shentsize;
- mbinfo.syms.e.shndx = eh->e_shstrndx;
-
- for (i = 0; i < eh->e_shnum; i++) {
- addr_t align;
-
- if (!sh[i].sh_size)
- continue; /* Empty section */
- if (sh[i].sh_flags & SHF_ALLOC)
- continue; /* SHF_ALLOC sections should have PHDRs */
-
- align = sh[i].sh_addralign ? sh[i].sh_addralign : 0;
- addr = map_data((char *)ptr + sh[i].sh_offset, sh[i].sh_size,
- align, MAP_HIGH);
- if (!addr) {
- error("Failed to map symbol section\n");
- return -1;
- }
- sh[i].sh_addr = addr;
- }
}
- } else if (mbh_len && (mbh->flags & MULTIBOOT_AOUT_KLUDGE)) {
- /*
- * a.out kludge thing...
- */
- char *data_ptr;
- addr_t data_len, bss_len;
-
- regs.eip = mbh->entry_addr;
- data_ptr = (char *)mbh - (mbh->header_addr - mbh->load_addr);
- data_len = mbh->load_end_addr - mbh->load_addr;
- bss_len = mbh->bss_end_addr - mbh->load_end_addr;
-
- if (syslinux_memmap_type(amap, mbh->load_addr, data_len+bss_len)
- != SMT_FREE) {
- printf("Memory segment at 0x%08x (len 0x%08x) is unavailable\n",
- mbh->load_addr, data_len+bss_len);
- return -1; /* Memory region unavailable */
- }
- if (syslinux_add_memmap(&amap, mbh->load_addr,
- data_len+bss_len, SMT_ALLOC)) {
- error("Failed to claim a.out address space!\n");
- return -1;
- }
- if (data_len)
- if (syslinux_add_movelist(&ml, mbh->load_addr, (addr_t)data_ptr,
- data_len)) {
- error("Failed to map a.out data\n");
- return -1;
- }
- if (bss_len)
- if (syslinux_add_memmap(&mmap, mbh->load_end_addr, bss_len, SMT_ZERO)) {
- error("Failed to map a.out bss\n");
- return -1;
- }
- if (mbh->bss_end_addr > mboot_high_water_mark)
- mboot_high_water_mark = mbh->bss_end_addr;
- } else {
- error("Invalid Multiboot image: neither ELF header nor a.out kludge found\n");
- return -1;
- }
-
- return 0;
+ return 0;
}
/*
*/
static void mboot_map_stack(void)
{
- addr_t start, len;
+ addr_t start, len;
- if (syslinux_memmap_largest(amap, SMT_FREE, &start, &len) || len < 64)
- return; /* Not much we can do, here... */
+ if (syslinux_memmap_largest(amap, SMT_FREE, &start, &len) || len < 64)
+ return; /* Not much we can do, here... */
- regs.esp = (start+len-32) & ~15;
- dprintf("Mapping stack at 0x%08x\n", regs.esp);
- syslinux_add_memmap(&mmap, regs.esp, 32, SMT_ZERO);
+ regs.esp = (start + len - 32) & ~15;
+ dprintf("Mapping stack at 0x%08x\n", regs.esp);
+ syslinux_add_memmap(&mmap, regs.esp, 32, SMT_ZERO);
}
void mboot_run(int bootflags)
{
- mboot_map_stack();
-
- dprintf("Running, eip = 0x%08x, ebx = 0x%08x\n", regs.eip, regs.ebx);
+ mboot_map_stack();
+
+ dprintf("Running, eip = 0x%08x, ebx = 0x%08x\n", regs.eip, regs.ebx);
- regs.eax = MULTIBOOT_VALID;
- syslinux_shuffle_boot_pm(ml, mmap, bootflags, ®s);
+ regs.eax = MULTIBOOT_VALID;
+ syslinux_shuffle_boot_pm(ml, mmap, bootflags, ®s);
}