int main(multiboot_t * mbp)
{
cpu_state_t *cpu;
// first is to save critical info from bootloader
// and get symbol tables so we can print back traces
mbootp = mbp;
init_debug(mbp);
// reset text-mode
c80_clear();
printk_color(rc_black, rc_red, "\t\t\t\tRed Magic\n");
// init processors
init_bootstrap_processor();
cpu = get_boot_processor();
ASSERT(cpu != NULL);
// initialize descriptors
init_global_descriptor_table(cpu);
init_interrupt_descriptor_table();
init_io_apic();
// interrupt on
local_irq_enable();
// memory management
show_kernel_pos();
show_ARDS_from_multiboot(mbp);
init_paging();
init_kheap();
// initialize devices and rootfs
init_dev();
//init_root_fs();
// start all APs
if (mpinfo.ismp)
start_smp();
// start system clock
if (!mpinfo.ismp)
init_pit_timer(CLOCK_INT_HZ);
else
init_apic_timer(CLOCK_INT_HZ);
// initialize kernel task and scheduling
setup_init_task();
init_sched();
// All our initialisation calls will go in here.
return 0xDEADBABA;
}
int start_kernel(unsigned long magic, unsigned long addr)
{
multiboot_info_t *mbi;
int i=0;
/* Initialize GDT */
initialize_gdt();
screen_init_early();
screen_reset(0);
printf("Welcome to StarxOS!\n");
/* Am I booted by a Multiboot-compliant boot loader? */
if (magic != MULTIBOOT_BOOTLOADER_MAGIC) {
printf("Invalid magic number: %x\n", (unsigned) magic);
return -1;
}
/* Set MBI to the address of the Multiboot information structure. */
mbi = (multiboot_info_t *) addr;
/* Print out the flags. */
printf_bochs("Welcome to StarxOS!\n");
printf_bochs("flags = 0x%x\n", (unsigned) mbi->flags);
/* Are mem_* valid? */
if ( mbi->flags != 0)
printf_bochs ("mem_lower = %x Byte, mem_upper = %x Byte\n",
(unsigned) mbi->mem_lower * 0x400, (unsigned) mbi->mem_upper * 0x400);
printf_bochs("kernel code: %p\n", &code);
printf_bochs("kernel data: %p\n", &data);
printf_bochs("kernel bss : %p\n", &bss);
printf_bochs("kernel end : %p\n", &end);
/* Initialize IDT */
initialize_idt();
/* Initialize Timer */
init_timer(50);
/* Enable Interrupt */
asm volatile("sti");
mem_lower = mbi->mem_lower * 0x400;
mem_upper = mbi->mem_upper * 0x400;
/* Setup memory, and init frame_bitmap */
setup_memory(mem_lower, mem_upper);
/* Enable Paging */
init_paging();
/* Init heap */
init_kheap();
u32int *ptr = (u32int*)kmalloc(0x1000+2);
*ptr = 0x1234;
printf_bochs("ptr:%x *ptr:%x\n", ptr, *ptr);
u32int *ptr2 = (u32int*)kmalloc(0x1000+2);
*ptr2 = 0x4567;
printf_bochs("ptr2:%x *ptr2:%x\n", ptr2, *ptr2);
bochs_enter_debugger();
bochs_shutdown();
return 0xBAD;
}
int kmain(UInt32 initial_stack, MultibootHeader* mboot, UInt32 mboot_magic) {
initial_esp = initial_stack;
CLI_Init();
Cls();
UInt32 initrd_end = *(UInt32*)(mboot->mods_addr+4);
placement_address = (Pointer) initrd_end;
// Set up our new stack here.
//UInt32 stack = (UInt32) kmalloc_a(8192, TRUE);
MultibootHeader* mboot_hdr = mboot; //kmalloc(sizeof(MultibootHeader));
//memcpy(mboot_hdr, mboot, sizeof(MultibootHeader));
kprintf("Starting init...\n");
//new_start(stack, mboot_hdr);
GDT_Init();
IDT_Init();
ISR_Init();
asm volatile("sti");
kprintf("Basics\t\t\t[OK]\n");
PIT_Init(PIT_MSTIME);
kprintf("PIT\t\t\t[OK]\n");
init_kheap();
InitPaging((mboot_hdr->mem_lower+mboot_hdr->mem_upper)&~3);
InitKernelHeap();
kprintf("Heap\t\t\t[OK]\n");
VFS_Init();
DevFS_Init();
kprintf("VFS\t\t\t[OK]\n");
DriversInit();
kprintf("Drivers\t\t\t[OK]\n");
Screen_Init();
FloppyInit();
checkAllBuses();
DumpPCIDeviceData();
kprintf("PCI\t\t\t[OK]\n");
/*kprintf("Keyboard Init... ");
KB_Init(0);
kprintf("[ok]\n");*/
FAT12_Init(FAT12_GetContext(FloppyGetDevice()), "/", "sys");
InitTasking();
KernelSymbolsLoad();
//Cls();
kprintf("kOS v0.6.13\n");
VFS_Node* rd = GetNodeFromFile(GetFileFromPath("/sys"));
kprintf("rd = %x\n", rd);
ArrayList* list = ListFiles(rd);
ALIterator* itr = ALGetItr(list);
while(ALItrHasNext(itr)) {
VFS_Node* node = ALItrNext(itr);
kprintf("file: %s\n", node->name);
}
ALFreeItr(itr);
ALFreeList(list);
//kprintf("kprintf symbol = %x\n", getKernelSymbol("kprintf"));
File* initScript = GetFileFromPath("/sys/init.script");
FileSeek(0, initScript); // Due to these being global objects, we have to do such ugly things as this.
#ifdef INIT_DEBUG
kprintf("initScript=%x\n", initScript);
#endif
char* lineBuf = kalloc(256);
int doBreak = 0;
while(!doBreak) {
if(fgetline(initScript, lineBuf, 256, '\n')==-1) {
if(strlen(lineBuf) > 0) {
doBreak = 1;
} else {
break; // We've processed everything that needs to be processed.
}
}
// Now parse it.
char* tok = strtok(lineBuf, " ");
kprintf("%s, %x\n", tok,tok);
if(!strcmp(tok, "load_driver")) {
#ifdef INIT_DEBUG
kprintf("load_driver ");
#endif
tok = strtok(NULL, " ");
// Load the driver specified.
File* drv = GetFileFromPath(tok);
if(drv != NULL) {
int drvLength = FileSeek(SEEK_EOF, drv);
FileSeek(0, drv);
void* drvBuf = kalloc(drvLength);
#ifdef INIT_DEBUG
kprintf("%s\n", GetNodeFromFile(drv)->name);
#endif
ReadFile(drvBuf, drvLength, drv);
ELF* elf = LoadKernelDriver(drvBuf);
#ifdef INIT_DEBUG
kprintf("elf->start=%x\n", elf->start);
#endif
if(elf->error == 0) {
void (*driverInit)() = (void (*)()) elf->start;
driverInit();
}
kfree(drvBuf);
drvBuf = NULL;
CloseFile(drv);
}
}
}
CloseFile(initScript);
kfree(lineBuf);
kprintf("Kernel init done...\n");
File* elf = GetFileFromPath("/sys/helloworld");
FileSeek(SEEK_EOF, elf);
int length = FileTell(elf);
FileSeek(0, elf);
UInt8* elfBuf = kalloc(length);
ReadFile(elfBuf, length, elf);
ELF* elfExe = Parse_ELF(elfBuf);
CreateTaskFromELF(elfExe);
// Kernel main logic loop
while(1) {
asm volatile("hlt");
}
return 0;
}
