rulimine/stage23/protos/multiboot2.c

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#include <protos/multiboot2.h>
#include <stdint.h>
#include <stddef.h>
#include <lib/libc.h>
#include <lib/elf.h>
#include <lib/blib.h>
#include <lib/config.h>
#include <lib/print.h>
#include <lib/uri.h>
#include <lib/fb.h>
#include <lib/term.h>
#include <sys/pic.h>
#include <sys/cpu.h>
#include <sys/idt.h>
#include <fs/file.h>
#include <mm/vmm.h>
#include <lib/acpi.h>
#include <mm/pmm.h>
#include <lib/blib.h>
#include <drivers/vga_textmode.h>
/// Returns the size required to store the multiboot2 info.
static size_t get_multiboot2_info_size(
char *cmdline,
size_t modules_size,
uint32_t section_hdr_size,
uint32_t smbios_tag_size
) {
return ALIGN_UP(sizeof(struct multiboot2_start_tag), MULTIBOOT_TAG_ALIGN) + // start
ALIGN_UP(strlen(cmdline) + 1 + offsetof(struct multiboot_tag_string, string), MULTIBOOT_TAG_ALIGN) + // cmdline
ALIGN_UP(8 + offsetof(struct multiboot_tag_string, string), MULTIBOOT_TAG_ALIGN) + // bootloader brand
ALIGN_UP(sizeof(struct multiboot_tag_framebuffer), MULTIBOOT_TAG_ALIGN) + // framebuffer
ALIGN_UP(sizeof(struct multiboot_tag_new_acpi) + sizeof(struct rsdp), MULTIBOOT_TAG_ALIGN) + // new ACPI info
ALIGN_UP(sizeof(struct multiboot_tag_old_acpi) + 20, MULTIBOOT_TAG_ALIGN) + // old ACPI info
ALIGN_UP(sizeof(struct multiboot_tag_elf_sections) + section_hdr_size, MULTIBOOT_TAG_ALIGN) + // ELF info
ALIGN_UP(modules_size, MULTIBOOT_TAG_ALIGN) + // modules
ALIGN_UP(smbios_tag_size, MULTIBOOT_TAG_ALIGN) + // SMBIOS
ALIGN_UP(sizeof(struct multiboot_tag_basic_meminfo), MULTIBOOT_TAG_ALIGN) + // basic memory info
ALIGN_UP(sizeof(struct multiboot_tag_mmap) + sizeof(struct multiboot_mmap_entry) * 256, MULTIBOOT_TAG_ALIGN) + // MMAP
#if uefi == 1
ALIGN_UP(sizeof(struct multiboot_tag_efi_mmap) + (efi_desc_size * 256), MULTIBOOT_TAG_ALIGN) + // EFI MMAP
#if defined (__i386__)
ALIGN_UP(sizeof(struct multiboot_tag_efi32), MULTIBOOT_TAG_ALIGN) + // EFI system table 32
ALIGN_UP(sizeof(struct multiboot_tag_efi32_ih), MULTIBOOT_TAG_ALIGN) + // EFI image handle 32
#elif defined (__x86_64__)
ALIGN_UP(sizeof(struct multiboot_tag_efi64), MULTIBOOT_TAG_ALIGN) + // EFI system table 64
ALIGN_UP(sizeof(struct multiboot_tag_efi64_ih), MULTIBOOT_TAG_ALIGN) + // EFI image handle 64
#endif
#endif
ALIGN_UP(sizeof(struct multiboot_tag), MULTIBOOT_TAG_ALIGN); // end
}
#define append_tag(P, TAG) ({ (P) += ALIGN_UP((TAG)->size, MULTIBOOT_TAG_ALIGN); })
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bool multiboot2_load(char *config, char* cmdline) {
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struct file_handle *kernel_file;
char *kernel_path = config_get_value(config, 0, "KERNEL_PATH");
if (kernel_path == NULL)
panic("multiboot2: KERNEL_PATH not specified");
print("multiboot2: Loading kernel `%s`...\n", kernel_path);
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if ((kernel_file = uri_open(kernel_path)) == NULL)
panic("multiboot2: Failed to open kernel with path `%s`. Is the path correct?", kernel_path);
uint8_t *kernel = freadall(kernel_file, MEMMAP_KERNEL_AND_MODULES);
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size_t kernel_file_size = kernel_file->size;
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fclose(kernel_file);
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struct multiboot_header *header;
for (size_t header_offset = 0; header_offset < MULTIBOOT_SEARCH; header_offset += MULTIBOOT_HEADER_ALIGN) {
header = (void *)(kernel + header_offset);
if (header->magic == MULTIBOOT2_HEADER_MAGIC) {
break;
}
}
if (header->magic != MULTIBOOT2_HEADER_MAGIC) {
pmm_free(kernel_file, kernel_file_size);
return false;
}
if (header->magic + header->architecture + header->checksum + header->header_length) {
panic("multiboot2: Header checksum is invalid");
}
struct multiboot_header_tag_address *addresstag = NULL;
struct multiboot_header_tag_framebuffer *fbtag = NULL;
bool is_new_acpi_required = false;
bool is_old_acpi_required = false;
bool is_elf_info_requested = false;
uint32_t entry_point = 0xffffffff;
// Iterate through the entries...
for (struct multiboot_header_tag *tag = (struct multiboot_header_tag*)(header + 1); // header + 1 to skip the header struct.
tag < (struct multiboot_header_tag *)((uintptr_t)header + header->header_length) && tag->type != MULTIBOOT_HEADER_TAG_END;
tag = (struct multiboot_header_tag *)((uintptr_t)tag + ALIGN_UP(tag->size, MULTIBOOT_TAG_ALIGN))) {
switch (tag->type) {
case MULTIBOOT_HEADER_TAG_INFORMATION_REQUEST: {
// Iterate the requests and check if they are supported by or not.
struct multiboot_header_tag_information_request *request = (void *)tag;
uint32_t size = (request->size - sizeof(struct multiboot_header_tag_information_request)) / sizeof(uint32_t);
bool is_required = !(request->flags & MULTIBOOT_HEADER_TAG_OPTIONAL);
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for (uint32_t i = 0; i < size; i++) {
uint32_t r = request->requests[i];
switch (r) {
// We already support the following requests:
case MULTIBOOT_TAG_TYPE_CMDLINE:
case MULTIBOOT_TAG_TYPE_BOOT_LOADER_NAME:
case MULTIBOOT_TAG_TYPE_MODULE:
case MULTIBOOT_TAG_TYPE_MMAP:
case MULTIBOOT_TAG_TYPE_SMBIOS:
case MULTIBOOT_TAG_TYPE_BASIC_MEMINFO:
#if uefi == 1
case MULTIBOOT_TAG_TYPE_EFI_MMAP:
#if defined (__i386__)
case MULTIBOOT_TAG_TYPE_EFI32:
case MULTIBOOT_TAG_TYPE_EFI32_IH:
#elif defined (__x86_64__)
case MULTIBOOT_TAG_TYPE_EFI64:
case MULTIBOOT_TAG_TYPE_EFI64_IH:
#endif
#endif
case MULTIBOOT_TAG_TYPE_FRAMEBUFFER:
break;
case MULTIBOOT_TAG_TYPE_ACPI_NEW:
is_new_acpi_required = is_required;
break;
case MULTIBOOT_TAG_TYPE_ACPI_OLD:
is_old_acpi_required = is_required;
break;
case MULTIBOOT_TAG_TYPE_ELF_SECTIONS:
is_elf_info_requested = is_required;
break;
default:
if (is_required)
panic("multiboot2: Requested tag `%d` which is not supported", r);
break;
}
}
break;
}
case MULTIBOOT_HEADER_TAG_FRAMEBUFFER: {
fbtag = (void *)tag;
break;
}
case MULTIBOOT_HEADER_TAG_ENTRY_ADDRESS: {
struct multiboot_header_tag_entry_address *entrytag = (void *)tag;
entry_point = entrytag->entry_addr;
break;
}
case MULTIBOOT_HEADER_TAG_ADDRESS: {
addresstag = (void *)tag;
break;
}
// We always align the modules ;^)
case MULTIBOOT_HEADER_TAG_MODULE_ALIGN:
case MULTIBOOT_HEADER_TAG_EFI_BS:
break;
default: panic("multiboot2: Unknown header tag type");
}
}
uint32_t kernel_top;
if (addresstag != NULL) {
if (addresstag->load_addr > addresstag->header_addr)
panic("multiboot2: Illegal load address");
size_t load_size = 0;
if (addresstag->load_end_addr)
load_size = addresstag->load_end_addr - addresstag->load_addr;
else
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load_size = kernel_file_size;
size_t header_offset = (size_t)header - (size_t)kernel;
memmap_alloc_range(addresstag->load_addr, load_size, MEMMAP_KERNEL_AND_MODULES, true, true, false, false);
memcpy((void *)(uintptr_t)addresstag->load_addr, kernel + (header_offset
- (addresstag->header_addr - addresstag->load_addr)), load_size);
kernel_top = addresstag->load_addr + load_size;
if (addresstag->bss_end_addr) {
uintptr_t bss_addr = addresstag->load_addr + load_size;
if (addresstag->bss_end_addr < bss_addr)
panic("multiboot2: Illegal bss end address");
uint32_t bss_size = addresstag->bss_end_addr - bss_addr;
memmap_alloc_range(bss_addr, bss_size, MEMMAP_KERNEL_AND_MODULES, true, true, false, false);
memset((void *)bss_addr, 0, bss_size);
kernel_top = bss_addr + bss_size;
}
} else {
int bits = elf_bits(kernel);
uint64_t e = 0, t = 0;
switch (bits) {
case 32:
if (elf32_load(kernel, (uint32_t *)&e, (uint32_t *)&t, MEMMAP_KERNEL_AND_MODULES))
panic("multiboot2: ELF32 load failure");
break;
case 64: {
if (elf64_load(kernel, &e, &t, NULL, MEMMAP_KERNEL_AND_MODULES, false, true, NULL, NULL, false, NULL, NULL))
panic("multiboot2: ELF64 load failure");
break;
}
default:
panic("multiboot2: Invalid ELF file bitness");
}
if (entry_point == 0xffffffff) {
entry_point = e;
}
kernel_top = t;
}
struct elf_section_hdr_info *section_hdr_info = NULL;
int bits = elf_bits(kernel);
switch (bits) {
case 32:
section_hdr_info = elf32_section_hdr_info(kernel);
break;
case 64: {
section_hdr_info = elf64_section_hdr_info(kernel);
break;
}
}
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size_t modules_size = 0;
size_t n_modules;
for (n_modules = 0;; n_modules++) {
if (config_get_value(config, modules_size, "MODULE_PATH") == NULL)
break;
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char *module_cmdline = config_get_value(config, modules_size, "MODULE_STRING");
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if (module_cmdline == NULL) {
module_cmdline = "";
}
modules_size += sizeof(struct multiboot_tag_module) + strlen(module_cmdline) + 1;
}
struct smbios_entry_point_32* smbios_entry_32 = NULL;
struct smbios_entry_point_64* smbios_entry_64 = NULL;
acpi_get_smbios((void **)&smbios_entry_32, (void **)&smbios_entry_64);
uint32_t smbios_tag_size = 0;
if (smbios_entry_32 != NULL)
smbios_tag_size += sizeof(struct multiboot_tag_smbios) + smbios_entry_32->length;
if (smbios_entry_64 != NULL)
smbios_tag_size += sizeof(struct multiboot_tag_smbios) + smbios_entry_64->length;
size_t mb2_info_size = get_multiboot2_info_size(
cmdline,
modules_size,
section_hdr_info ? section_hdr_info->section_hdr_size : 0,
smbios_tag_size
);
size_t info_idx = 0;
uint8_t *mb2_info = conv_mem_alloc(mb2_info_size);
struct multiboot2_start_tag* mbi_start = (struct multiboot2_start_tag *)mb2_info;
info_idx += sizeof(struct multiboot2_start_tag);
mbi_start->size = mb2_info_size;
mbi_start->reserved = 0x00;
//////////////////////////////////////////////
// Create modules tag
//////////////////////////////////////////////
for (size_t i = 0; i < n_modules; i++) {
char *module_path = config_get_value(config, i, "MODULE_PATH");
if (module_path == NULL)
panic("multiboot2: Module disappeared unexpectedly");
print("multiboot2: Loading module `%s`...\n", module_path);
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struct file_handle *f;
if ((f = uri_open(module_path)) == NULL)
panic("multiboot2: Failed to open module with path `%s`. Is the path correct?", module_path);
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char *module_cmdline = config_get_value(config, i, "MODULE_STRING");
void *module_addr = (void *)(uintptr_t)ALIGN_UP(kernel_top, 4096);
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// Module commandline can be null, so we guard against that and make the
// string "".
if (module_cmdline == NULL) {
module_cmdline = "";
}
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memmap_alloc_range((uintptr_t)module_addr, f->size, MEMMAP_KERNEL_AND_MODULES,
true, true, false, false);
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kernel_top = (uintptr_t)module_addr + f->size;
fread(f, module_addr, 0, f->size);
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struct multiboot_tag_module *module_tag = (struct multiboot_tag_module *)(mb2_info + info_idx);
module_tag->type = MULTIBOOT_TAG_TYPE_MODULE;
module_tag->size = sizeof(struct multiboot_tag_module) + strlen(module_cmdline) + 1;
module_tag->mod_start = (uint32_t)(size_t)module_addr;
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module_tag->mod_end = module_tag->mod_start + f->size;
strcpy(module_tag->cmdline, module_cmdline); // Copy over the command line
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fclose(f);
if (verbose) {
print("multiboot2: Requested module %u:\n", i);
print(" Path: %s\n", module_path);
print(" String: \"%s\"\n", module_cmdline ?: "");
print(" Begin: %x\n", module_tag->mod_start);
print(" End: %x\n", module_tag->mod_end);
}
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append_tag(info_idx, module_tag);
}
//////////////////////////////////////////////
// Create command line tag
//////////////////////////////////////////////
{
uint32_t size = strlen(cmdline) + 1 + offsetof(struct multiboot_tag_string, string);
struct multiboot_tag_string *tag = (struct multiboot_tag_string *)(mb2_info + info_idx);
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tag->type = MULTIBOOT_TAG_TYPE_CMDLINE;
tag->size = size;
strcpy(tag->string, cmdline);
append_tag(info_idx, tag);
}
//////////////////////////////////////////////
// Create bootloader name tag
//////////////////////////////////////////////
{
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char brand[] = "Limine";
uint32_t size = sizeof(brand) + offsetof(struct multiboot_tag_string, string);
struct multiboot_tag_string *tag = (struct multiboot_tag_string *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_BOOT_LOADER_NAME;
tag->size = size;
strcpy(tag->string, brand);
append_tag(info_idx, tag);
}
//////////////////////////////////////////////
// Create EFI image handle tag
//////////////////////////////////////////////
#if uefi == 1
{
#if defined (__i386__)
struct multiboot_tag_efi64_ih *tag = (struct multiboot_tag_efi64_ih *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_EFI64_IH;
tag->size = sizeof(struct multiboot_tag_efi64_ih);
#elif defined (__x86_64__)
struct multiboot_tag_efi32_ih *tag = (struct multiboot_tag_efi32_ih *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_EFI32_IH;
tag->size = sizeof(struct multiboot_tag_efi32_ih);
#endif
tag->pointer = (uintptr_t)efi_image_handle;
append_tag(info_idx, tag);
}
#endif
//////////////////////////////////////////////
// Create framebuffer tag
//////////////////////////////////////////////
{
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term_deinit();
if (fbtag) {
size_t req_width = fbtag->width;
size_t req_height = fbtag->height;
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size_t req_bpp = fbtag->depth;
char *resolution = config_get_value(config, 0, "RESOLUTION");
if (resolution != NULL)
parse_resolution(&req_width, &req_height, &req_bpp, resolution);
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struct multiboot_tag_framebuffer *tag = (struct multiboot_tag_framebuffer *)(mb2_info + info_idx);
struct fb_info fbinfo;
if (!fb_init(&fbinfo, req_width, req_height, req_bpp)) {
#if bios == 1
size_t rows, cols;
init_vga_textmode(&rows, &cols, false);
tag->common.framebuffer_addr = 0xb8000;
tag->common.framebuffer_pitch = 2 * cols;
tag->common.framebuffer_width = cols;
tag->common.framebuffer_height = rows;
tag->common.framebuffer_bpp = 16;
tag->common.framebuffer_type = MULTIBOOT_FRAMEBUFFER_TYPE_EGA_TEXT;
#elif uefi == 1
panic("multiboot2: Cannot use text mode with UEFI");
#endif
} else {
tag->common.type = MULTIBOOT_TAG_TYPE_FRAMEBUFFER;
tag->common.size = sizeof(struct multiboot_tag_framebuffer);
tag->common.framebuffer_addr = fbinfo.framebuffer_addr;
tag->common.framebuffer_pitch = fbinfo.framebuffer_pitch;
tag->common.framebuffer_width = fbinfo.framebuffer_width;
tag->common.framebuffer_height = fbinfo.framebuffer_height;
tag->common.framebuffer_bpp = fbinfo.framebuffer_bpp;
tag->common.framebuffer_type = MULTIBOOT_FRAMEBUFFER_TYPE_RGB; // We only support RGB for VBE
tag->framebuffer_red_field_position = fbinfo.red_mask_shift;
tag->framebuffer_red_mask_size = fbinfo.red_mask_size;
tag->framebuffer_green_field_position = fbinfo.green_mask_shift;
tag->framebuffer_green_mask_size = fbinfo.green_mask_size;
tag->framebuffer_blue_field_position = fbinfo.blue_mask_shift;
tag->framebuffer_blue_mask_size = fbinfo.blue_mask_size;
}
append_tag(info_idx, &tag->common);
} else {
#if uefi == 1
panic("multiboot2: Cannot use text mode with UEFI");
#elif bios == 1
size_t rows, cols;
init_vga_textmode(&rows, &cols, false);
#endif
}
}
//////////////////////////////////////////////
// Create new ACPI info tag
//////////////////////////////////////////////
{
void *new_rsdp = acpi_get_rsdp_v2();
if (new_rsdp != NULL) {
uint32_t size = sizeof(struct multiboot_tag_new_acpi) + sizeof(struct rsdp); // XSDP is 36 bytes wide
struct multiboot_tag_new_acpi *tag = (struct multiboot_tag_new_acpi *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_ACPI_NEW;
tag->size = size;
memcpy(tag->rsdp, new_rsdp, sizeof(struct rsdp));
append_tag(info_idx, tag);
} else if (is_new_acpi_required) {
panic("multiboot2: XSDP requested but not found");
}
}
//////////////////////////////////////////////
// Create old ACPI info tag
//////////////////////////////////////////////
{
void *old_rsdp = acpi_get_rsdp_v1();
if (old_rsdp != NULL) {
uint32_t size = sizeof(struct multiboot_tag_old_acpi) + 20; // RSDP is 20 bytes wide
struct multiboot_tag_old_acpi *tag = (struct multiboot_tag_old_acpi *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_ACPI_OLD;
tag->size = size;
memcpy(tag->rsdp, old_rsdp, 20);
append_tag(info_idx, tag);
} else if (is_old_acpi_required) {
panic("multiboot2: RSDP requested but not found");
}
}
//////////////////////////////////////////////
// Create SMBIOS tag
//////////////////////////////////////////////
{
// NOTE: The multiboot2 specification does not say anything about if both
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// smbios 32 and 64 bit entry points are present, then we pass both of them + smbios
// support for grub2 is unimplemented. So, we are going to assume they expect us to
// pass both of them if avaliable. Oh well...
if (smbios_entry_32 != NULL) {
struct multiboot_tag_smbios *tag = (struct multiboot_tag_smbios *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_SMBIOS;
tag->size = sizeof(struct multiboot_tag_smbios);
tag->major = smbios_entry_32->major_version;
tag->minor = smbios_entry_32->minor_version;
memset(tag->reserved, 0, 6);
memcpy(tag->tables, smbios_entry_32, smbios_entry_32->length);
append_tag(info_idx, tag);
}
if (smbios_entry_64 != NULL) {
struct multiboot_tag_smbios *tag = (struct multiboot_tag_smbios *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_SMBIOS;
tag->size = sizeof(struct multiboot_tag_smbios);
tag->major = smbios_entry_64->major_version;
tag->minor = smbios_entry_64->minor_version;
memset(tag->reserved, 0, 6);
memcpy(tag->tables, smbios_entry_64, smbios_entry_64->length);
append_tag(info_idx, tag);
}
}
//////////////////////////////////////////////
// Create EFI system table info tag
//////////////////////////////////////////////
#if uefi == 1
{
#if defined (__i386__)
uint32_t size = sizeof(struct multiboot_tag_efi32);
struct multiboot_tag_efi32 *tag = (void *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_EFI32;
#elif defined (__x86_64__)
uint32_t size = sizeof(struct multiboot_tag_efi64);
struct multiboot_tag_efi64 *tag = (void *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_EFI64;
#endif
tag->size = size;
tag->pointer = (uintptr_t)gST;
append_tag(info_idx, tag);
}
#endif
//////////////////////////////////////////////
// Create ELF info tag
//////////////////////////////////////////////
{
if (section_hdr_info == NULL) {
if (is_elf_info_requested) {
panic("multiboot2: Cannot return ELF file information");
}
} else {
uint32_t size = sizeof(struct multiboot_tag_elf_sections) + section_hdr_info->section_hdr_size;
struct multiboot_tag_elf_sections *tag = (struct multiboot_tag_elf_sections*)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_ELF_SECTIONS;
tag->size = size;
tag->num = section_hdr_info->num;
tag->entsize = section_hdr_info->section_entry_size;
tag->shndx = section_hdr_info->str_section_idx;
memcpy(tag->sections, section_hdr_info->section_hdrs, section_hdr_info->section_hdr_size);
append_tag(info_idx, tag);
}
}
#if uefi == 1
efi_exit_boot_services();
#endif
size_t mb_mmap_count;
struct e820_entry_t *raw_memmap = get_raw_memmap(&mb_mmap_count);
//////////////////////////////////////////////
// Create memory map tag
//////////////////////////////////////////////
{
if (mb_mmap_count > 256) {
panic("multiboot2: too many memory map entries");
}
// Create the normal memory map tag.
uint32_t mmap_size = sizeof(struct multiboot_tag_mmap) + sizeof(struct multiboot_mmap_entry) * mb_mmap_count;
struct multiboot_tag_mmap *mmap_tag = (struct multiboot_tag_mmap *)(mb2_info + info_idx);
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mmap_tag->type = MULTIBOOT_TAG_TYPE_MMAP;
mmap_tag->entry_size = sizeof(struct multiboot_mmap_entry);
mmap_tag->entry_version = 0;
mmap_tag->size = mmap_size;
for (size_t i = 0; i < mb_mmap_count; i++) {
struct multiboot_mmap_entry *entry = &mmap_tag->entries[i];
entry->addr = raw_memmap[i].base;
entry->len = raw_memmap[i].length;
entry->type = raw_memmap[i].type;
entry->zero = 0;
}
append_tag(info_idx, mmap_tag);
}
//////////////////////////////////////////////
// Create basic memory info tag
//////////////////////////////////////////////
{
struct meminfo meminfo = mmap_get_info(mb_mmap_count, raw_memmap);
struct multiboot_tag_basic_meminfo *tag = (struct multiboot_tag_basic_meminfo *)(mb2_info + info_idx);
tag->type = MULTIBOOT_TAG_TYPE_BASIC_MEMINFO;
tag->size = sizeof(struct multiboot_tag_basic_meminfo);
// Convert the uppermem and lowermem fields from bytes to
// KiB.
tag->mem_upper = (uint32_t)(meminfo.uppermem / 1024);
tag->mem_lower = (uint32_t)(meminfo.lowermem / 1024);
append_tag(info_idx, tag);
}
//////////////////////////////////////////////
// Create EFI memory map tag
//////////////////////////////////////////////
#if uefi == 1
{
if ((efi_mmap_size / efi_desc_size) > 256) {
panic("multiboot2: too many EFI memory map entries");
}
// Create the EFI memory map tag.
uint32_t size = sizeof(struct multiboot_tag_efi_mmap) * efi_mmap_size;
struct multiboot_tag_efi_mmap *mmap_tag = (struct multiboot_tag_efi_mmap *)(mb2_info + info_idx);
mmap_tag->type = MULTIBOOT_TAG_TYPE_EFI_MMAP;
mmap_tag->descr_vers = efi_desc_ver;
mmap_tag->descr_size = efi_desc_size;
mmap_tag->size = size;
// Copy over the EFI memory map.
memcpy(mmap_tag->efi_mmap, efi_mmap, efi_mmap_size);
append_tag(info_idx, mmap_tag);
}
#endif
//////////////////////////////////////////////
// Create end tag
//////////////////////////////////////////////
{
struct multiboot_tag *end_tag = (struct multiboot_tag *)(mb2_info + info_idx);
end_tag->type = MULTIBOOT_TAG_TYPE_END;
end_tag->size = sizeof(struct multiboot_tag);
append_tag(info_idx, end_tag);
}
irq_flush_type = IRQ_PIC_ONLY_FLUSH;
common_spinup(multiboot2_spinup_32, 2,
entry_point, (uint32_t)(uintptr_t)mbi_start);
}