//! Global descriptor table
use core::mem;
use x86::dtables::{self, DescriptorTablePointer};
use x86::segmentation::{self, SegmentSelector};
use x86::task::{self, TaskStateSegment};
pub const GDT_NULL: usize = 0;
pub const GDT_KERNEL_CODE: usize = 1;
pub const GDT_KERNEL_DATA: usize = 2;
pub const GDT_KERNEL_TLS: usize = 3;
pub const GDT_USER_CODE: usize = 4;
pub const GDT_USER_DATA: usize = 5;
pub const GDT_USER_TLS: usize = 6;
pub const GDT_TSS: usize = 7;
pub const GDT_TSS_HIGH: usize = 8;
pub const GDT_A_PRESENT: u8 = 1 << 7;
pub const GDT_A_RING_0: u8 = 0 << 5;
pub const GDT_A_RING_1: u8 = 1 << 5;
pub const GDT_A_RING_2: u8 = 2 << 5;
pub const GDT_A_RING_3: u8 = 3 << 5;
pub const GDT_A_SYSTEM: u8 = 1 << 4;
pub const GDT_A_EXECUTABLE: u8 = 1 << 3;
pub const GDT_A_CONFORMING: u8 = 1 << 2;
pub const GDT_A_PRIVILEGE: u8 = 1 << 1;
pub const GDT_A_DIRTY: u8 = 1;
pub const GDT_A_TSS_AVAIL: u8 = 0x9;
pub const GDT_A_TSS_BUSY: u8 = 0xB;
pub const GDT_F_PAGE_SIZE: u8 = 1 << 7;
pub const GDT_F_PROTECTED_MODE: u8 = 1 << 6;
pub const GDT_F_LONG_MODE: u8 = 1 << 5;
static mut INIT_GDTR: DescriptorTablePointer = DescriptorTablePointer {
limit: 0,
base: 0
};
static mut INIT_GDT: [GdtEntry; 4] = [
// Null
GdtEntry::new(0, 0, 0, 0),
// Kernel code
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_0 | GDT_A_SYSTEM | GDT_A_EXECUTABLE | GDT_A_PRIVILEGE, GDT_F_LONG_MODE),
// Kernel data
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_0 | GDT_A_SYSTEM | GDT_A_PRIVILEGE, GDT_F_LONG_MODE),
// Kernel TLS
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_3 | GDT_A_SYSTEM | GDT_A_PRIVILEGE, GDT_F_LONG_MODE)
];
#[thread_local]
pub static mut GDTR: DescriptorTablePointer = DescriptorTablePointer {
limit: 0,
base: 0
};
#[thread_local]
pub static mut GDT: [GdtEntry; 9] = [
// Null
GdtEntry::new(0, 0, 0, 0),
// Kernel code
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_0 | GDT_A_SYSTEM | GDT_A_EXECUTABLE | GDT_A_PRIVILEGE, GDT_F_LONG_MODE),
// Kernel data
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_0 | GDT_A_SYSTEM | GDT_A_PRIVILEGE, GDT_F_LONG_MODE),
// Kernel TLS
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_0 | GDT_A_SYSTEM | GDT_A_PRIVILEGE, GDT_F_LONG_MODE),
// User code
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_3 | GDT_A_SYSTEM | GDT_A_EXECUTABLE | GDT_A_PRIVILEGE, GDT_F_LONG_MODE),
// User data
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_3 | GDT_A_SYSTEM | GDT_A_PRIVILEGE, GDT_F_LONG_MODE),
// User TLS
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_3 | GDT_A_SYSTEM | GDT_A_PRIVILEGE, GDT_F_LONG_MODE),
// TSS
GdtEntry::new(0, 0, GDT_A_PRESENT | GDT_A_RING_3 | GDT_A_TSS_AVAIL, 0),
// TSS must be 16 bytes long, twice the normal size
GdtEntry::new(0, 0, 0, 0),
];
#[thread_local]
pub static mut TSS: TaskStateSegment = TaskStateSegment {
reserved: 0,
rsp: [0; 3],
reserved2: 0,
ist: [0; 7],
reserved3: 0,
reserved4: 0,
iomap_base: 0xFFFF
};
/// Initialize GDT
pub unsafe fn init(tcb_offset: usize, stack_offset: usize) {
// Setup the initial GDT with TLS, so we can setup the TLS GDT (a little confusing)
// This means that each CPU will have its own GDT, but we only need to define it once as a thread local
INIT_GDTR.limit = (INIT_GDT.len() * mem::size_of::<GdtEntry>() - 1) as u16;
INIT_GDTR.base = INIT_GDT.as_ptr() as u64;
// Set the TLS segment to the offset of the Thread Control Block
INIT_GDT[GDT_KERNEL_TLS].set_offset(tcb_offset as u32);
// Load the initial GDT, before we have access to thread locals
dtables::lgdt(&INIT_GDTR);
// Load the segment descriptors
segmentation::load_cs(SegmentSelector::new(GDT_KERNEL_CODE as u16));
segmentation::load_ds(SegmentSelector::new(GDT_KERNEL_DATA as u16));
segmentation::load_es(SegmentSelector::new(GDT_KERNEL_DATA as u16));
segmentation::load_fs(SegmentSelector::new(GDT_KERNEL_TLS as u16));
segmentation::load_gs(SegmentSelector::new(GDT_KERNEL_DATA as u16));
segmentation::load_ss(SegmentSelector::new(GDT_KERNEL_DATA as u16));
// Now that we have access to thread locals, setup the AP's individual GDT
GDTR.limit = (GDT.len() * mem::size_of::<GdtEntry>() - 1) as u16;
GDTR.base = GDT.as_ptr() as u64;
// Set the TLS segment to the offset of the Thread Control Block
GDT[GDT_KERNEL_TLS].set_offset(tcb_offset as u32);
// Set the User TLS segment to the offset of the user TCB
GDT[GDT_USER_TLS].set_offset(::USER_TCB_OFFSET as u32);
// We can now access our TSS, which is a thread local
GDT[GDT_TSS].set_offset(&TSS as *const _ as u32);
GDT[GDT_TSS].set_limit(mem::size_of::<TaskStateSegment>() as u32);
// Set the stack pointer when coming back from userspace
TSS.rsp[0] = stack_offset as u64;
// Load the new GDT, which is correctly located in thread local storage
dtables::lgdt(&GDTR);
// Reload the segment descriptors
segmentation::load_cs(SegmentSelector::new(GDT_KERNEL_CODE as u16));
segmentation::load_ds(SegmentSelector::new(GDT_KERNEL_DATA as u16));
segmentation::load_es(SegmentSelector::new(GDT_KERNEL_DATA as u16));
segmentation::load_fs(SegmentSelector::new(GDT_KERNEL_TLS as u16));
segmentation::load_gs(SegmentSelector::new(GDT_KERNEL_DATA as u16));
segmentation::load_ss(SegmentSelector::new(GDT_KERNEL_DATA as u16));
// Load the task register
task::load_ltr(SegmentSelector::new(GDT_TSS as u16));
}
#[derive(Copy, Clone, Debug)]
#[repr(packed)]
pub struct GdtEntry {
pub limitl: u16,
pub offsetl: u16,
pub offsetm: u8,
pub access: u8,
pub flags_limith: u8,
pub offseth: u8
}
impl GdtEntry {
pub const fn new(offset: u32, limit: u32, access: u8, flags: u8) -> Self {
GdtEntry {
limitl: limit as u16,
offsetl: offset as u16,
offsetm: (offset >> 16) as u8,
access: access,
flags_limith: flags & 0xF0 | ((limit >> 16) as u8) & 0x0F,
offseth: (offset >> 24) as u8
}
}
pub fn set_offset(&mut self, offset: u32) {
self.offsetl = offset as u16;
self.offsetm = (offset >> 16) as u8;
self.offseth = (offset >> 24) as u8;
}
pub fn set_limit(&mut self, limit: u32) {
self.limitl = limit as u16;
self.flags_limith = self.flags_limith & 0xF0 | ((limit >> 16) as u8) & 0x0F;
}
}