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mod ext {
extern "C" {
pub fn mmap_read8(addr: u32) -> i32;
pub fn mmap_read16(addr: u32) -> i32;
pub fn mmap_read32(addr: u32) -> i32;
pub fn mmap_write8(addr: u32, value: i32);
pub fn mmap_write16(addr: u32, value: i32);
pub fn mmap_write32(addr: u32, value: i32);
pub fn mmap_write64(addr: u32, v0: i32, v1: i32);
pub fn mmap_write128(addr: u32, v0: i32, v1: i32, v2: i32, v3: i32);
}
}
use crate::cpu::apic;
use crate::cpu::cpu::{
handle_irqs, reg128, APIC_MEM_ADDRESS, APIC_MEM_SIZE, IOAPIC_MEM_ADDRESS, IOAPIC_MEM_SIZE,
};
use crate::cpu::global_pointers::memory_size;
use crate::cpu::ioapic;
use crate::cpu::vga;
use crate::jit;
use crate::page::Page;
use std::alloc;
use std::ptr;
#[allow(non_upper_case_globals)]
pub static mut mem8: *mut u8 = ptr::null_mut();
#[no_mangle]
pub fn allocate_memory(size: u32) -> u32 {
unsafe {
dbg_assert!(mem8.is_null());
};
dbg_log!("Allocate memory size={}m", size >> 20);
let layout = alloc::Layout::from_size_align(size as usize, 0x1000).unwrap();
let ptr = unsafe { alloc::alloc(layout) as u32 };
unsafe {
mem8 = ptr as *mut u8;
};
ptr
}
#[no_mangle]
pub unsafe fn zero_memory(addr: u32, size: u32) {
ptr::write_bytes(mem8.offset(addr as isize), 0, size as usize);
}
#[allow(non_upper_case_globals)]
pub static mut vga_mem8: *mut u8 = ptr::null_mut();
#[allow(non_upper_case_globals)]
pub static mut vga_memory_size: u32 = 0;
#[no_mangle]
pub fn svga_allocate_memory(size: u32) -> u32 {
unsafe {
dbg_assert!(vga_mem8.is_null());
};
let layout = alloc::Layout::from_size_align(size as usize, 0x1000).unwrap();
let ptr = unsafe { alloc::alloc(layout) };
dbg_assert!(
size & (1 << 12 << 6) == 0,
"size not aligned to dirty_bitmap"
);
unsafe {
vga_mem8 = ptr;
vga_memory_size = size;
vga::set_dirty_bitmap_size(size >> 12 >> 6);
};
ptr as u32
}
#[no_mangle]
pub fn in_mapped_range(addr: u32) -> bool {
return addr >= 0xA0000 && addr < 0xC0000 || addr >= unsafe { *memory_size };
}
pub const VGA_LFB_ADDRESS: u32 = 0xE0000000;
pub fn in_svga_lfb(addr: u32) -> bool {
addr >= VGA_LFB_ADDRESS && addr <= unsafe { VGA_LFB_ADDRESS + (vga_memory_size - 1) }
}
#[no_mangle]
pub fn read8(addr: u32) -> i32 {
if in_mapped_range(addr) {
if in_svga_lfb(addr) {
unsafe { *vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as i32 }
}
else {
unsafe { ext::mmap_read8(addr) }
}
}
else {
read8_no_mmap_check(addr)
}
}
pub fn read8_no_mmap_check(addr: u32) -> i32 { unsafe { *mem8.offset(addr as isize) as i32 } }
#[no_mangle]
pub fn read16(addr: u32) -> i32 {
if in_mapped_range(addr) {
if in_svga_lfb(addr) {
unsafe {
ptr::read_unaligned(vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as *const u16)
as i32
}
}
else {
unsafe { ext::mmap_read16(addr) }
}
}
else {
read16_no_mmap_check(addr)
}
}
pub fn read16_no_mmap_check(addr: u32) -> i32 {
unsafe { ptr::read_unaligned(mem8.offset(addr as isize) as *const u16) as i32 }
}
#[no_mangle]
pub fn read32s(addr: u32) -> i32 {
if in_mapped_range(addr) {
if in_svga_lfb(addr) {
unsafe {
ptr::read_unaligned(vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as *const i32)
} // XXX
}
else if addr >= APIC_MEM_ADDRESS && addr < APIC_MEM_ADDRESS + APIC_MEM_SIZE {
apic::read32(addr - APIC_MEM_ADDRESS) as i32
}
else if addr >= IOAPIC_MEM_ADDRESS && addr < IOAPIC_MEM_ADDRESS + IOAPIC_MEM_SIZE {
ioapic::read32(addr - IOAPIC_MEM_ADDRESS) as i32
}
else {
unsafe { ext::mmap_read32(addr) }
}
}
else {
read32_no_mmap_check(addr)
}
}
pub fn read32_no_mmap_check(addr: u32) -> i32 {
unsafe { ptr::read_unaligned(mem8.offset(addr as isize) as *const i32) }
}
pub unsafe fn read64s(addr: u32) -> i64 {
if in_mapped_range(addr) {
if in_svga_lfb(addr) {
ptr::read_unaligned(vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as *const i64)
}
else {
ext::mmap_read32(addr) as i64 | (ext::mmap_read32(addr + 4) as i64) << 32
}
}
else {
ptr::read_unaligned(mem8.offset(addr as isize) as *const i64)
}
}
pub unsafe fn read128(addr: u32) -> reg128 {
if in_mapped_range(addr) {
if in_svga_lfb(addr) {
ptr::read_unaligned(vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as *const reg128)
}
else {
reg128 {
i32: [
ext::mmap_read32(addr + 0),
ext::mmap_read32(addr + 4),
ext::mmap_read32(addr + 8),
ext::mmap_read32(addr + 12),
],
}
}
}
else {
ptr::read_unaligned(mem8.offset(addr as isize) as *const reg128)
}
}
#[no_mangle]
pub unsafe fn write8(addr: u32, value: i32) {
if in_mapped_range(addr) {
mmap_write8(addr, value & 0xFF);
}
else {
jit::jit_dirty_page(Page::page_of(addr));
write8_no_mmap_or_dirty_check(addr, value);
};
}
pub unsafe fn write8_no_mmap_or_dirty_check(addr: u32, value: i32) {
*mem8.offset(addr as isize) = value as u8
}
#[no_mangle]
pub unsafe fn write16(addr: u32, value: i32) {
if in_mapped_range(addr) {
mmap_write16(addr, value & 0xFFFF);
}
else {
jit::jit_dirty_cache_small(addr, addr + 2);
write16_no_mmap_or_dirty_check(addr, value);
};
}
pub unsafe fn write16_no_mmap_or_dirty_check(addr: u32, value: i32) {
ptr::write_unaligned(mem8.offset(addr as isize) as *mut u16, value as u16)
}
#[no_mangle]
pub unsafe fn write32(addr: u32, value: i32) {
if in_mapped_range(addr) {
mmap_write32(addr, value);
}
else {
jit::jit_dirty_cache_small(addr, addr + 4);
write32_no_mmap_or_dirty_check(addr, value);
}
}
pub unsafe fn write32_no_mmap_or_dirty_check(addr: u32, value: i32) {
ptr::write_unaligned(mem8.offset(addr as isize) as *mut i32, value)
}
pub unsafe fn write64_no_mmap_or_dirty_check(addr: u32, value: u64) {
ptr::write_unaligned(mem8.offset(addr as isize) as *mut u64, value)
}
pub unsafe fn write128_no_mmap_or_dirty_check(addr: u32, value: reg128) {
ptr::write_unaligned(mem8.offset(addr as isize) as *mut reg128, value)
}
pub unsafe fn memset_no_mmap_or_dirty_check(addr: u32, value: u8, count: u32) {
ptr::write_bytes(mem8.offset(addr as isize), value, count as usize);
}
pub unsafe fn memcpy_no_mmap_or_dirty_check(src_addr: u32, dst_addr: u32, count: u32) {
dbg_assert!(src_addr < *memory_size);
dbg_assert!(dst_addr < *memory_size);
ptr::copy(
mem8.offset(src_addr as isize),
mem8.offset(dst_addr as isize),
count as usize,
)
}
pub unsafe fn memcpy_into_svga_lfb(src_addr: u32, dst_addr: u32, count: u32) {
dbg_assert!(src_addr < *memory_size);
dbg_assert!(in_svga_lfb(dst_addr));
dbg_assert!(Page::page_of(dst_addr) == Page::page_of(dst_addr + count - 1));
vga::mark_dirty(dst_addr);
ptr::copy_nonoverlapping(
mem8.offset(src_addr as isize),
vga_mem8.offset((dst_addr - VGA_LFB_ADDRESS) as isize),
count as usize,
)
}
pub unsafe fn mmap_write8(addr: u32, value: i32) {
if in_svga_lfb(addr) {
vga::mark_dirty(addr);
*vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) = value as u8
}
else {
ext::mmap_write8(addr, value)
}
}
pub unsafe fn mmap_write16(addr: u32, value: i32) {
if in_svga_lfb(addr) {
vga::mark_dirty(addr);
ptr::write_unaligned(
vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as *mut u16,
value as u16,
)
}
else {
ext::mmap_write16(addr, value)
}
}
pub unsafe fn mmap_write32(addr: u32, value: i32) {
if in_svga_lfb(addr) {
vga::mark_dirty(addr);
ptr::write_unaligned(
vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as *mut i32,
value,
)
}
else if addr >= APIC_MEM_ADDRESS && addr < APIC_MEM_ADDRESS + APIC_MEM_SIZE {
apic::write32(addr - APIC_MEM_ADDRESS, value as u32);
handle_irqs();
}
else if addr >= IOAPIC_MEM_ADDRESS && addr < IOAPIC_MEM_ADDRESS + IOAPIC_MEM_SIZE {
ioapic::write32(addr - IOAPIC_MEM_ADDRESS, value as u32);
handle_irqs();
}
else {
ext::mmap_write32(addr, value)
}
}
pub unsafe fn mmap_write64(addr: u32, value: u64) {
if in_svga_lfb(addr) {
vga::mark_dirty(addr);
ptr::write_unaligned(
vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as *mut u64,
value,
)
}
else {
ext::mmap_write64(addr, value as i32, (value >> 32) as i32)
}
}
pub unsafe fn mmap_write128(addr: u32, v0: u64, v1: u64) {
if in_svga_lfb(addr) {
vga::mark_dirty(addr);
ptr::write_unaligned(
vga_mem8.offset((addr - VGA_LFB_ADDRESS) as isize) as *mut u64,
v0,
);
ptr::write_unaligned(
vga_mem8.offset((addr - VGA_LFB_ADDRESS + 8) as isize) as *mut u64,
v1,
)
}
else {
ext::mmap_write128(
addr,
v0 as i32,
(v0 >> 32) as i32,
v1 as i32,
(v1 >> 32) as i32,
)
}
}
#[no_mangle]
pub unsafe fn is_memory_zeroed(addr: u32, length: u32) -> bool {
dbg_assert!(addr % 8 == 0);
dbg_assert!(length % 8 == 0);
for i in (addr..addr + length).step_by(8) {
if *(mem8.offset(i as isize) as *const i64) != 0 {
return false;
}
}
return true;
}
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