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Kernel is now able to boot from mb2

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This commit is contained in:
Alex
2023-05-08 00:27:12 +03:00
parent c4798a69b1
commit 7811c21971
10 changed files with 558 additions and 400 deletions
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23
Architecture/amd64/Bootstrap/Header_Multiboot2.asm
View File

@@ -1,3 +1,4 @@
; https://www.gnu.org/software/grub/manual/multiboot2/multiboot.html
section .multiboot2
align 4096
HEADER_START:
@@ -33,6 +34,28 @@ MB2_INFO_REQUEST_TAG_START:
dd 21 ; Load Base Address
MB2_INFO_REQUEST_TAG_END:
align 8
MB2_FRAMEBUFFER_TAG_START:
dw 5
dw 1
dd MB2_FRAMEBUFFER_TAG_END - MB2_FRAMEBUFFER_TAG_START
dd 0
dd 0
dd 32
MB2_FRAMEBUFFER_TAG_END:
align 8
MB2_EGA_SUPPORT_TAG_START:
dw 4
dw 0
dd MB2_EGA_SUPPORT_TAG_END - MB2_EGA_SUPPORT_TAG_START
dd 1 ; https://www.gnu.org/software/grub/manual/multiboot2/html_node/Console-header-tags.html
MB2_EGA_SUPPORT_TAG_END:
align 8
MB2_MODULE_ALIGN_TAG_START:
dw 6
dw 0
dd MB2_MODULE_ALIGN_TAG_END - MB2_MODULE_ALIGN_TAG_START
MB2_MODULE_ALIGN_TAG_END:
align 8
MB2_TAG_START:
dw 0
dw 0

482
Architecture/amd64/Bootstrap/Multiboot.cpp
View File

@@ -22,266 +22,278 @@ EXTERNC void multiboot_main(uint64_t Magic, uint64_t Info)
CPU::Stop();
}
uint64_t div = 1193180 / 1000;
outb(0x43, 0xB6);
outb(0x42, (uint8_t)div);
outb(0x42, (uint8_t)(div >> 8));
uint8_t tmp = inb(0x61);
if (tmp != (tmp | 3))
outb(0x61, tmp | 3);
BootInfo mb2binfo{};
// Clear the BSS
// memset_unsafe(&_kernel_rodata_end, 0, &_kernel_end - &_kernel_rodata_end);
BootInfo mb2binfo;
int pos = 0;
auto InfoAddress = Info;
for (auto Tag = (struct multiboot_tag *)((uint8_t *)InfoAddress + 8);
;
Tag = (struct multiboot_tag *)((multiboot_uint8_t *)Tag + ((Tag->size + 7) & ~7)))
{
if (Tag->type == MULTIBOOT_TAG_TYPE_END)
{
debug("End of multiboot2 tags");
break;
}
uint64_t div = 1193180 / 1000;
outb(0x43, 0xB6);
outb(0x42, (uint8_t)div);
outb(0x42, (uint8_t)(div >> 8));
uint8_t tmp = inb(0x61);
if (tmp != (tmp | 3))
outb(0x61, tmp | 3);
switch (Tag->type)
int pos = 0;
auto InfoAddress = Info;
for (auto Tag = (struct multiboot_tag *)((uint8_t *)InfoAddress + 8);
;
Tag = (struct multiboot_tag *)((multiboot_uint8_t *)Tag + ((Tag->size + 7) & ~7)))
{
case MULTIBOOT_TAG_TYPE_CMDLINE:
{
strncpy(mb2binfo.Kernel.CommandLine,
((multiboot_tag_string *)Tag)->string,
strlen(((multiboot_tag_string *)Tag)->string));
debug("Kernel command line: %s", mb2binfo.Kernel.CommandLine);
break;
}
case MULTIBOOT_TAG_TYPE_BOOT_LOADER_NAME:
{
strncpy(mb2binfo.Bootloader.Name,
((multiboot_tag_string *)Tag)->string,
strlen(((multiboot_tag_string *)Tag)->string));
debug("Bootloader name: %s", mb2binfo.Bootloader.Name);
break;
}
case MULTIBOOT_TAG_TYPE_MODULE:
{
multiboot_tag_module *module = (multiboot_tag_module *)Tag;
static int module_count = 0;
mb2binfo.Modules[module_count++].Address = (void *)(uint64_t)module->mod_start;
mb2binfo.Modules[module_count++].Size = module->size;
strncpy(mb2binfo.Modules[module_count++].Path, "(null)", 6);
strncpy(mb2binfo.Modules[module_count++].CommandLine, module->cmdline,
strlen(module->cmdline));
debug("Module: %s", mb2binfo.Modules[module_count++].Path);
break;
}
case MULTIBOOT_TAG_TYPE_BASIC_MEMINFO:
{
multiboot_tag_basic_meminfo *meminfo = (multiboot_tag_basic_meminfo *)Tag;
fixme("basic_meminfo->[mem_lower: %#x, mem_upper: %#x]",
meminfo->mem_lower, meminfo->mem_upper);
break;
}
case MULTIBOOT_TAG_TYPE_BOOTDEV:
{
multiboot_tag_bootdev *bootdev = (multiboot_tag_bootdev *)Tag;
fixme("bootdev->[biosdev: %#x, slice: %#x, part: %#x]",
bootdev->biosdev, bootdev->slice, bootdev->part);
break;
}
case MULTIBOOT_TAG_TYPE_MMAP:
{
multiboot_tag_mmap *mmap = (multiboot_tag_mmap *)Tag;
uint32_t EntryCount = mmap->size / sizeof(multiboot_mmap_entry);
mb2binfo.Memory.Entries = EntryCount;
for (uint32_t i = 0; i < EntryCount; i++)
if (Tag->type == MULTIBOOT_TAG_TYPE_END)
{
if (EntryCount > MAX_MEMORY_ENTRIES)
debug("End of multiboot2 tags");
break;
}
switch (Tag->type)
{
case MULTIBOOT_TAG_TYPE_CMDLINE:
{
strncpy(mb2binfo.Kernel.CommandLine,
((multiboot_tag_string *)Tag)->string,
strlen(((multiboot_tag_string *)Tag)->string));
debug("Kernel command line: %s", mb2binfo.Kernel.CommandLine);
break;
}
case MULTIBOOT_TAG_TYPE_BOOT_LOADER_NAME:
{
strncpy(mb2binfo.Bootloader.Name,
((multiboot_tag_string *)Tag)->string,
strlen(((multiboot_tag_string *)Tag)->string));
debug("Bootloader name: %s", mb2binfo.Bootloader.Name);
break;
}
case MULTIBOOT_TAG_TYPE_MODULE:
{
multiboot_tag_module *module = (multiboot_tag_module *)Tag;
static int module_count = 0;
mb2binfo.Modules[module_count].Address = (void *)(uint64_t)module->mod_start;
mb2binfo.Modules[module_count].Size = module->size;
strncpy(mb2binfo.Modules[module_count].Path, "(null)", 6);
strncpy(mb2binfo.Modules[module_count].CommandLine, module->cmdline,
strlen(module->cmdline));
debug("Module: %s", mb2binfo.Modules[module_count].Path);
module_count++;
break;
}
case MULTIBOOT_TAG_TYPE_BASIC_MEMINFO:
{
multiboot_tag_basic_meminfo *meminfo = (multiboot_tag_basic_meminfo *)Tag;
fixme("basic_meminfo->[mem_lower: %#x, mem_upper: %#x]",
meminfo->mem_lower, meminfo->mem_upper);
break;
}
case MULTIBOOT_TAG_TYPE_BOOTDEV:
{
multiboot_tag_bootdev *bootdev = (multiboot_tag_bootdev *)Tag;
fixme("bootdev->[biosdev: %#x, slice: %#x, part: %#x]",
bootdev->biosdev, bootdev->slice, bootdev->part);
break;
}
case MULTIBOOT_TAG_TYPE_MMAP:
{
multiboot_tag_mmap *mmap = (multiboot_tag_mmap *)Tag;
size_t EntryCount = mmap->size / sizeof(multiboot_mmap_entry);
mb2binfo.Memory.Entries = EntryCount;
for (uint32_t i = 0; i < EntryCount; i++)
{
warn("Too many memory entries, skipping the rest...");
if (EntryCount > MAX_MEMORY_ENTRIES)
{
warn("Too many memory entries, skipping the rest...");
break;
}
multiboot_mmap_entry entry = mmap->entries[i];
mb2binfo.Memory.Size += entry.len;
switch (entry.type)
{
case MULTIBOOT_MEMORY_AVAILABLE:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = Usable;
break;
case MULTIBOOT_MEMORY_RESERVED:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = Reserved;
break;
case MULTIBOOT_MEMORY_ACPI_RECLAIMABLE:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = ACPIReclaimable;
break;
case MULTIBOOT_MEMORY_NVS:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = ACPINVS;
break;
case MULTIBOOT_MEMORY_BADRAM:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = BadMemory;
break;
default:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = Unknown;
break;
}
debug("Memory entry: [BaseAddress: %#x, Length: %#x, Type: %d]",
mb2binfo.Memory.Entry[i].BaseAddress,
mb2binfo.Memory.Entry[i].Length,
mb2binfo.Memory.Entry[i].Type);
}
break;
}
case MULTIBOOT_TAG_TYPE_VBE:
{
multiboot_tag_vbe *vbe = (multiboot_tag_vbe *)Tag;
fixme("vbe->[vbe_mode: %#x, vbe_interface_seg: %#x, vbe_interface_off: %#x, vbe_interface_len: %#x]",
vbe->vbe_mode, vbe->vbe_interface_seg, vbe->vbe_interface_off, vbe->vbe_interface_len);
break;
}
case MULTIBOOT_TAG_TYPE_FRAMEBUFFER:
{
multiboot_tag_framebuffer *fb = (multiboot_tag_framebuffer *)Tag;
static int fb_count = 0;
mb2binfo.Framebuffer[fb_count].BaseAddress = (void *)fb->common.framebuffer_addr;
mb2binfo.Framebuffer[fb_count].Width = fb->common.framebuffer_width;
mb2binfo.Framebuffer[fb_count].Height = fb->common.framebuffer_height;
mb2binfo.Framebuffer[fb_count].Pitch = fb->common.framebuffer_pitch;
mb2binfo.Framebuffer[fb_count].BitsPerPixel = fb->common.framebuffer_bpp;
switch (fb->common.framebuffer_type)
{
case MULTIBOOT_FRAMEBUFFER_TYPE_INDEXED:
{
mb2binfo.Framebuffer[fb_count].Type = Indexed;
break;
}
multiboot_mmap_entry entry = mmap->entries[i];
mb2binfo.Memory.Size += entry.len;
switch (entry.type)
case MULTIBOOT_FRAMEBUFFER_TYPE_RGB:
{
case MULTIBOOT_MEMORY_AVAILABLE:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = Usable;
mb2binfo.Framebuffer[fb_count].Type = RGB;
mb2binfo.Framebuffer[fb_count].RedMaskSize = fb->framebuffer_red_mask_size;
mb2binfo.Framebuffer[fb_count].RedMaskShift = fb->framebuffer_red_field_position;
mb2binfo.Framebuffer[fb_count].GreenMaskSize = fb->framebuffer_green_mask_size;
mb2binfo.Framebuffer[fb_count].GreenMaskShift = fb->framebuffer_green_field_position;
mb2binfo.Framebuffer[fb_count].BlueMaskSize = fb->framebuffer_blue_mask_size;
mb2binfo.Framebuffer[fb_count].BlueMaskShift = fb->framebuffer_blue_field_position;
break;
case MULTIBOOT_MEMORY_RESERVED:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = Reserved;
break;
case MULTIBOOT_MEMORY_ACPI_RECLAIMABLE:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = ACPIReclaimable;
break;
case MULTIBOOT_MEMORY_NVS:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = ACPINVS;
break;
case MULTIBOOT_MEMORY_BADRAM:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = BadMemory;
}
case MULTIBOOT_FRAMEBUFFER_TYPE_EGA_TEXT:
{
mb2binfo.Framebuffer[fb_count].Type = EGA;
break;
}
default:
mb2binfo.Memory.Entry[i].BaseAddress = (void *)entry.addr;
mb2binfo.Memory.Entry[i].Length = entry.len;
mb2binfo.Memory.Entry[i].Type = Unknown;
{
mb2binfo.Framebuffer[fb_count].Type = Unknown_Framebuffer_Type;
break;
}
debug("Memory entry: [BaseAddress: %#x, Length: %#x, Type: %d]",
mb2binfo.Memory.Entry[i].BaseAddress,
mb2binfo.Memory.Entry[i].Length,
mb2binfo.Memory.Entry[i].Type);
}
break;
}
case MULTIBOOT_TAG_TYPE_VBE:
{
multiboot_tag_vbe *vbe = (multiboot_tag_vbe *)Tag;
fixme("vbe->[vbe_mode: %#x, vbe_interface_seg: %#x, vbe_interface_off: %#x, vbe_interface_len: %#x]",
vbe->vbe_mode, vbe->vbe_interface_seg, vbe->vbe_interface_off, vbe->vbe_interface_len);
break;
}
case MULTIBOOT_TAG_TYPE_FRAMEBUFFER:
{
multiboot_tag_framebuffer *fb = (multiboot_tag_framebuffer *)Tag;
static int fb_count = 0;
mb2binfo.Framebuffer[fb_count].BaseAddress = (void *)fb->common.framebuffer_addr;
mb2binfo.Framebuffer[fb_count].Width = fb->common.framebuffer_width;
mb2binfo.Framebuffer[fb_count].Height = fb->common.framebuffer_height;
mb2binfo.Framebuffer[fb_count].Pitch = fb->common.framebuffer_pitch;
mb2binfo.Framebuffer[fb_count].BitsPerPixel = fb->common.framebuffer_bpp;
switch (fb->common.framebuffer_type)
{
case MULTIBOOT_FRAMEBUFFER_TYPE_INDEXED:
{
mb2binfo.Framebuffer[fb_count].Type = Indexed;
}
debug("Framebuffer %d: %dx%d %d bpp", fb_count, fb->common.framebuffer_width, fb->common.framebuffer_height, fb->common.framebuffer_bpp);
debug("More info:\nAddress: %p\nPitch: %lld\nMemoryModel: %d\nRedMaskSize: %d\nRedMaskShift: %d\nGreenMaskSize: %d\nGreenMaskShift: %d\nBlueMaskSize: %d\nBlueMaskShift: %d",
fb->common.framebuffer_addr, fb->common.framebuffer_pitch, fb->common.framebuffer_type,
fb->framebuffer_red_mask_size, fb->framebuffer_red_field_position, fb->framebuffer_green_mask_size,
fb->framebuffer_green_field_position, fb->framebuffer_blue_mask_size, fb->framebuffer_blue_field_position);
fb_count++;
break;
}
case MULTIBOOT_FRAMEBUFFER_TYPE_RGB:
case MULTIBOOT_TAG_TYPE_ELF_SECTIONS:
{
mb2binfo.Framebuffer[fb_count].Type = RGB;
mb2binfo.Framebuffer[fb_count].RedMaskSize = fb->framebuffer_red_mask_size;
mb2binfo.Framebuffer[fb_count].RedMaskShift = fb->framebuffer_red_field_position;
mb2binfo.Framebuffer[fb_count].GreenMaskSize = fb->framebuffer_green_mask_size;
mb2binfo.Framebuffer[fb_count].GreenMaskShift = fb->framebuffer_green_field_position;
mb2binfo.Framebuffer[fb_count].BlueMaskSize = fb->framebuffer_blue_mask_size;
mb2binfo.Framebuffer[fb_count].BlueMaskShift = fb->framebuffer_blue_field_position;
multiboot_tag_elf_sections *elf = (multiboot_tag_elf_sections *)Tag;
fixme("elf_sections->[num=%d, size=%d, entsize=%d, shndx=%d]",
elf->num, elf->size, elf->entsize, elf->shndx);
break;
}
case MULTIBOOT_FRAMEBUFFER_TYPE_EGA_TEXT:
case MULTIBOOT_TAG_TYPE_APM:
{
mb2binfo.Framebuffer[fb_count].Type = EGA;
multiboot_tag_apm *apm = (multiboot_tag_apm *)Tag;
fixme("apm->[version: %d, cseg: %d, offset: %d, cseg_16: %d, dseg: %d, flags: %d, cseg_len: %d, cseg_16_len: %d, dseg_len: %d]",
apm->version, apm->cseg, apm->offset, apm->cseg_16, apm->dseg, apm->flags, apm->cseg_len, apm->cseg_16_len, apm->dseg_len);
break;
}
case MULTIBOOT_TAG_TYPE_EFI32:
{
multiboot_tag_efi32 *efi32 = (multiboot_tag_efi32 *)Tag;
fixme("efi32->[pointer: %p, size: %d]", efi32->pointer, efi32->size);
break;
}
case MULTIBOOT_TAG_TYPE_EFI64:
{
multiboot_tag_efi64 *efi64 = (multiboot_tag_efi64 *)Tag;
fixme("efi64->[pointer: %p, size: %d]", efi64->pointer, efi64->size);
break;
}
case MULTIBOOT_TAG_TYPE_SMBIOS:
{
multiboot_tag_smbios *smbios = (multiboot_tag_smbios *)Tag;
fixme("smbios->[major: %d, minor: %d]", smbios->major, smbios->minor);
break;
}
case MULTIBOOT_TAG_TYPE_ACPI_OLD:
{
mb2binfo.RSDP = (BootInfo::RSDPInfo *)((multiboot_tag_old_acpi *)Tag)->rsdp;
debug("OLD ACPI RSDP: %p", mb2binfo.RSDP);
break;
}
case MULTIBOOT_TAG_TYPE_ACPI_NEW:
{
mb2binfo.RSDP = (BootInfo::RSDPInfo *)((multiboot_tag_new_acpi *)Tag)->rsdp;
debug("NEW ACPI RSDP: %p", mb2binfo.RSDP);
break;
}
case MULTIBOOT_TAG_TYPE_NETWORK:
{
multiboot_tag_network *net = (multiboot_tag_network *)Tag;
fixme("network->[dhcpack: %p]", net->dhcpack);
break;
}
case MULTIBOOT_TAG_TYPE_EFI_MMAP:
{
multiboot_tag_efi_mmap *efi_mmap = (multiboot_tag_efi_mmap *)Tag;
fixme("efi_mmap->[descr_size: %d, descr_vers: %d, efi_mmap: %p]",
efi_mmap->descr_size, efi_mmap->descr_vers, efi_mmap->efi_mmap);
break;
}
case MULTIBOOT_TAG_TYPE_EFI_BS:
{
fixme("efi_bs->[%p] (unknown structure)", Tag);
break;
}
case MULTIBOOT_TAG_TYPE_EFI32_IH:
{
multiboot_tag_efi32_ih *efi32_ih = (multiboot_tag_efi32_ih *)Tag;
fixme("efi32_ih->[pointer: %p]", efi32_ih->pointer);
break;
}
case MULTIBOOT_TAG_TYPE_EFI64_IH:
{
multiboot_tag_efi64_ih *efi64_ih = (multiboot_tag_efi64_ih *)Tag;
fixme("efi64_ih->[pointer: %p]", efi64_ih->pointer);
break;
}
case MULTIBOOT_TAG_TYPE_LOAD_BASE_ADDR:
{
multiboot_tag_load_base_addr *load_base_addr = (multiboot_tag_load_base_addr *)Tag;
mb2binfo.Kernel.PhysicalBase = (void *)(uint64_t)load_base_addr->load_base_addr;
mb2binfo.Kernel.VirtualBase = (void *)(uint64_t)(load_base_addr->load_base_addr + 0xFFFFFFFF80000000);
mb2binfo.Kernel.Size = ((uint64_t)&_kernel_end - (uint64_t)&_kernel_start) + ((uint64_t)&_bootstrap_end - (uint64_t)&_bootstrap_start);
debug("Kernel base: %p (physical) %p (virtual)", mb2binfo.Kernel.PhysicalBase, mb2binfo.Kernel.VirtualBase);
break;
}
default:
{
error("Unknown multiboot2 tag type: %d", Tag->type);
break;
}
}
debug("Framebuffer %d: %dx%d %d bpp", fb_count, fb->common.framebuffer_width, fb->common.framebuffer_height, fb->common.framebuffer_bpp);
debug("More info:\nAddress: %p\nPitch: %lld\nMemoryModel: %d\nRedMaskSize: %d\nRedMaskShift: %d\nGreenMaskSize: %d\nGreenMaskShift: %d\nBlueMaskSize: %d\nBlueMaskShift: %d",
fb->common.framebuffer_addr, fb->common.framebuffer_pitch, fb->common.framebuffer_type,
fb->framebuffer_red_mask_size, fb->framebuffer_red_field_position, fb->framebuffer_green_mask_size,
fb->framebuffer_green_field_position, fb->framebuffer_blue_mask_size, fb->framebuffer_blue_field_position);
fb_count++;
break;
}
case MULTIBOOT_TAG_TYPE_ELF_SECTIONS:
{
multiboot_tag_elf_sections *elf = (multiboot_tag_elf_sections *)Tag;
fixme("elf_sections->[num=%d, size=%d, entsize=%d, shndx=%d]",
elf->num, elf->size, elf->entsize, elf->shndx);
break;
}
case MULTIBOOT_TAG_TYPE_APM:
{
multiboot_tag_apm *apm = (multiboot_tag_apm *)Tag;
fixme("apm->[version: %d, cseg: %d, offset: %d, cseg_16: %d, dseg: %d, flags: %d, cseg_len: %d, cseg_16_len: %d, dseg_len: %d]",
apm->version, apm->cseg, apm->offset, apm->cseg_16, apm->dseg, apm->flags, apm->cseg_len, apm->cseg_16_len, apm->dseg_len);
break;
}
case MULTIBOOT_TAG_TYPE_EFI32:
{
multiboot_tag_efi32 *efi32 = (multiboot_tag_efi32 *)Tag;
fixme("efi32->[pointer: %p, size: %d]", efi32->pointer, efi32->size);
break;
}
case MULTIBOOT_TAG_TYPE_EFI64:
{
multiboot_tag_efi64 *efi64 = (multiboot_tag_efi64 *)Tag;
fixme("efi64->[pointer: %p, size: %d]", efi64->pointer, efi64->size);
break;
}
case MULTIBOOT_TAG_TYPE_SMBIOS:
{
multiboot_tag_smbios *smbios = (multiboot_tag_smbios *)Tag;
fixme("smbios->[major: %d, minor: %d]", smbios->major, smbios->minor);
break;
}
case MULTIBOOT_TAG_TYPE_ACPI_OLD:
{
mb2binfo.RSDP = (BootInfo::RSDPInfo *)((multiboot_tag_old_acpi *)Tag)->rsdp;
debug("OLD ACPI RSDP: %p", mb2binfo.RSDP);
break;
}
case MULTIBOOT_TAG_TYPE_ACPI_NEW:
{
mb2binfo.RSDP = (BootInfo::RSDPInfo *)((multiboot_tag_new_acpi *)Tag)->rsdp;
debug("NEW ACPI RSDP: %p", mb2binfo.RSDP);
break;
}
case MULTIBOOT_TAG_TYPE_NETWORK:
{
multiboot_tag_network *net = (multiboot_tag_network *)Tag;
fixme("network->[dhcpack: %p]", net->dhcpack);
break;
}
case MULTIBOOT_TAG_TYPE_EFI_MMAP:
{
multiboot_tag_efi_mmap *efi_mmap = (multiboot_tag_efi_mmap *)Tag;
fixme("efi_mmap->[descr_size: %d, descr_vers: %d, efi_mmap: %p]",
efi_mmap->descr_size, efi_mmap->descr_vers, efi_mmap->efi_mmap);
break;
}
case MULTIBOOT_TAG_TYPE_EFI_BS:
{
fixme("efi_bs->[%p] (unknown structure)", Tag);
break;
}
case MULTIBOOT_TAG_TYPE_EFI32_IH:
{
multiboot_tag_efi32_ih *efi32_ih = (multiboot_tag_efi32_ih *)Tag;
fixme("efi32_ih->[pointer: %p]", efi32_ih->pointer);
break;
}
case MULTIBOOT_TAG_TYPE_EFI64_IH:
{
multiboot_tag_efi64_ih *efi64_ih = (multiboot_tag_efi64_ih *)Tag;
fixme("efi64_ih->[pointer: %p]", efi64_ih->pointer);
break;
}
case MULTIBOOT_TAG_TYPE_LOAD_BASE_ADDR:
{
multiboot_tag_load_base_addr *load_base_addr = (multiboot_tag_load_base_addr *)Tag;
mb2binfo.Kernel.PhysicalBase = (void *)(uint64_t)load_base_addr->load_base_addr;
mb2binfo.Kernel.VirtualBase = (void *)(uint64_t)(load_base_addr->load_base_addr + 0xFFFFFFFF80000000);
mb2binfo.Kernel.Size = &_kernel_end - &_kernel_start;
debug("Kernel base: %p (physical) %p (virtual)", mb2binfo.Kernel.PhysicalBase, mb2binfo.Kernel.VirtualBase);
break;
}
default:
{
error("Unknown multiboot2 tag type: %d", Tag->type);
break;
}
}
}
tmp = inb(0x61) & 0xFC;
outb(0x61, tmp);
tmp = inb(0x61) & 0xFC;
outb(0x61, tmp);
}
Entry(&mb2binfo);
}

26
Architecture/amd64/Bootstrap/Multiboot64bitMap.cpp
View File

@@ -33,7 +33,7 @@ union __attribute__((packed)) PageTableEntry
struct __attribute__((packed)) PageTableEntryPtr
{
PageTableEntry Entries[511];
PageTableEntry Entries[512];
};
union __attribute__((packed)) PageDirectoryEntry
@@ -67,7 +67,7 @@ union __attribute__((packed)) PageDirectoryEntry
struct __attribute__((packed)) PageDirectoryEntryPtr
{
PageDirectoryEntry Entries[511];
PageDirectoryEntry Entries[512];
};
union __attribute__((packed)) PageDirectoryPointerTableEntry
@@ -101,7 +101,7 @@ union __attribute__((packed)) PageDirectoryPointerTableEntry
struct __attribute__((packed)) PageDirectoryPointerTableEntryPtr
{
PageDirectoryPointerTableEntry Entries[511];
PageDirectoryPointerTableEntry Entries[512];
};
union __attribute__((packed)) PageMapLevel4
@@ -135,7 +135,7 @@ union __attribute__((packed)) PageMapLevel4
struct PageTable4
{
PageMapLevel4 Entries[511];
PageMapLevel4 Entries[512];
} __attribute__((aligned(0x1000)));
extern "C" char BootPageTable[];
@@ -177,7 +177,7 @@ public:
}
};
__always_inline inline SafeFunction NIF void Map(void *VirtualAddress, void *PhysicalAddress, uint64_t Flags)
__attribute__((section(".bootstrap.text"))) SafeFunction NIF void MB2_64_Map(void *VirtualAddress, void *PhysicalAddress, uint64_t Flags)
{
PageMapIndexer Index = PageMapIndexer((uintptr_t)VirtualAddress);
// Clear any flags that are not 1 << 0 (Present) - 1 << 5 (Accessed) because rest are for page table entries only
@@ -188,9 +188,11 @@ __always_inline inline SafeFunction NIF void Map(void *VirtualAddress, void *Phy
if (!PML4.Present)
{
PDPTEPtr = (PageDirectoryPointerTableEntryPtr *)RequestPage();
if (PDPTEPtr == nullptr)
return;
{
void *ptr = PDPTEPtr;
int value = 0;
uint8_t value = 0;
size_t num = 0x1000;
uint8_t *p = (uint8_t *)ptr;
for (size_t i = 0; i < num; i++)
@@ -209,9 +211,11 @@ __always_inline inline SafeFunction NIF void Map(void *VirtualAddress, void *Phy
if (!PDPTE.Present)
{
PDEPtr = (PageDirectoryEntryPtr *)RequestPage();
if (PDEPtr == nullptr)
return;
{
void *ptr = PDEPtr;
int value = 0;
uint8_t value = 0;
size_t num = 0x1000;
uint8_t *p = (uint8_t *)ptr;
for (size_t i = 0; i < num; i++)
@@ -230,9 +234,11 @@ __always_inline inline SafeFunction NIF void Map(void *VirtualAddress, void *Phy
if (!PDE.Present)
{
PTEPtr = (PageTableEntryPtr *)RequestPage();
if (PTEPtr == nullptr)
return;
{
void *ptr = PTEPtr;
int value = 0;
uint8_t value = 0;
size_t num = 0x1000;
uint8_t *p = (uint8_t *)ptr;
for (size_t i = 0; i < num; i++)
@@ -262,14 +268,14 @@ EXTERNC __attribute__((section(".bootstrap.text"))) SafeFunction NIF __attribute
BPTable = (PageTable4 *)BootPageTable;
// for (size_t i = 0; i < 0x10000000; i += 0x1000)
// Map((void *)i, (void *)i, 0x3);
// MB2_64_Map((void *)i, (void *)i, 0x3);
uintptr_t KernelStart = (uintptr_t)&_kernel_start;
uintptr_t KernelEnd = (uintptr_t)&_kernel_end;
uintptr_t PhysicalStart = KernelStart - 0xFFFFFFFF80000000;
for (uintptr_t i = KernelStart; i < KernelEnd; i += 0x1000)
{
Map((void *)i, (void *)PhysicalStart, 0x3);
MB2_64_Map((void *)i, (void *)PhysicalStart, 0x3);
PhysicalStart += 0x1000;
}

3
Architecture/amd64/linker.ld
View File

@@ -57,8 +57,6 @@ SECTIONS
{
*(.rodata .rodata.*)
}
_kernel_rodata_end = ALIGN(CONSTANT(MAXPAGESIZE));
. += CONSTANT(MAXPAGESIZE);
.init_array : AT(ADDR(.init_array) - KERNEL_VMA)
{
@@ -75,6 +73,7 @@ SECTIONS
KEEP(*(.fini_array .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
}
_kernel_rodata_end = ALIGN(CONSTANT(MAXPAGESIZE));
. += CONSTANT(MAXPAGESIZE);
.bss : AT(ADDR(.bss) - KERNEL_VMA)