#include #include #define GDT_ENTRIES 6 // The contents of each entry is defined in gdt_init. /* One entry of the table */ typedef struct { uint16_t limit_low; uint16_t base_low; uint8_t base_middle; uint8_t access; uint8_t granularity; uint8_t base_high; } __attribute__((packed)) gdt_entry_t; /* Structure defining the whole table : address and size (in bytes). */ typedef struct { uint16_t limit; uint32_t base; } __attribute__((packed)) gdt_ptr_t; /* The TSS is used for hardware multitasking. We don't use that, but we still need a TSS so that user mode process exceptions can be handled correctly by the kernel. */ typedef struct { uint32_t prev_tss; // The previous TSS - if we used hardware task switching this would form a linked list. uint32_t esp0; // The stack pointer to load when we change to kernel mode. uint32_t ss0; // The stack segment to load when we change to kernel mode. uint32_t esp1; // Unused... uint32_t ss1; uint32_t esp2; uint32_t ss2; uint32_t cr3; uint32_t eip; uint32_t eflags; uint32_t eax; uint32_t ecx; uint32_t edx; uint32_t ebx; uint32_t esp; uint32_t ebp; uint32_t esi; uint32_t edi; uint32_t es; // The value to load into ES when we change to kernel mode. uint32_t cs; // The value to load into CS when we change to kernel mode. uint32_t ss; // The value to load into SS when we change to kernel mode. uint32_t ds; // The value to load into DS when we change to kernel mode. uint32_t fs; // The value to load into FS when we change to kernel mode. uint32_t gs; // The value to load into GS when we change to kernel mode. uint32_t ldt; // Unused... uint16_t trap; uint16_t iomap_base; } __attribute__((packed)) tss_entry_t; // ========================= // // Actual definitions static gdt_entry_t gdt_entries[GDT_ENTRIES]; static gdt_ptr_t gdt_ptr; static tss_entry_t tss_entry; /* For internal use only. Writes one entry of the GDT with given parameters. */ static void gdt_set_gate(int num, uint32_t base, uint32_t limit, uint8_t access, uint8_t gran) { gdt_entries[num].base_low = (base & 0xFFFF); gdt_entries[num].base_middle = (base >> 16) & 0xFF; gdt_entries[num].base_high = (base >> 24) & 0xFF; gdt_entries[num].limit_low = (limit & 0xFFFF); gdt_entries[num].granularity = (limit >> 16) & 0x0F; gdt_entries[num].granularity |= gran & 0xF0; gdt_entries[num].access = access; } /* Write data to the GDT and enable it. */ void gdt_init() { gdt_ptr.limit = (sizeof(gdt_entry_t) * GDT_ENTRIES) - 1; gdt_ptr.base = (uint32_t)&gdt_entries; gdt_set_gate(0, 0, 0, 0, 0); //Null segment gdt_set_gate(1, 0, 0xFFFFFFFF, 0x9A, 0xCF); //Kernel code segment 0x08 gdt_set_gate(2, 0, 0xFFFFFFFF, 0x92, 0xCF); //Kernel data segment 0x10 gdt_set_gate(3, 0, 0xFFFFFFFF, 0xFA, 0xCF); //User code segment 0x18 gdt_set_gate(4, 0, 0xFFFFFFFF, 0xF2, 0xCF); //User data segment 0x20 // Write TSS memset(&tss_entry, 0, sizeof(tss_entry_t)); tss_entry.ss0 = 0x10; tss_entry.esp0 = 0; tss_entry.iomap_base = sizeof(tss_entry_t); uint32_t tss_base = (uint32_t)&tss_entry; uint32_t tss_limit = tss_base + sizeof(tss_entry_t); gdt_set_gate(5, tss_base, tss_limit, 0xE9, 0x00); asm volatile("lgdt %0"::"m"(gdt_ptr):"memory"); asm volatile("movw $0x2b, %%ax; ltr %%ax":::"%eax"); } void set_kernel_stack(void* addr) { tss_entry.esp0 = (uint32_t)addr; } /* vim: set ts=4 sw=4 tw=0 noet :*/