#include #include #include #include #include #include #include #include #include #include extern char k_end_addr; // defined in linker script : 0xC0000000 plus kernel stuff void breakpoint_handler(registers_t *regs) { dbg_printf("Breakpoint! (int3)\n"); BOCHS_BREAKPOINT; } void test_pf_handler(pagedir_t *pd, region_info_t *i, void* addr) { dbg_printf(" {0x%p", addr); uint32_t f = frame_alloc(1); if (f == 0) PANIC("Out Of Memory"); dbg_printf(" -> %i} ", f); int error = pd_map_page(addr, f, 1); if (error) PANIC("Could not map frame (OOM)"); } void* page_alloc_fun_for_kmalloc(size_t bytes) { void* addr = region_alloc(bytes, REGION_T_CORE_HEAP, test_pf_handler); dbg_printf("Alloc %p bytes for kmalloc at: %p\n", bytes, addr); return addr; } void page_free_fun_for_kmalloc(void* ptr) { region_info_t *i = find_region(ptr); ASSERT(i != 0 && i->type == REGION_T_CORE_HEAP); for (void* x = i->addr; x < i->addr + i->size; x += PAGE_SIZE) { uint32_t f = pd_get_frame(x); if (f != 0) { pd_unmap_page(x); frame_free(f, 1); } } region_free(ptr); } slab_type_t slab_sizes[] = { { "8B obj", 8, 1 }, { "16B obj", 16, 2 }, { "32B obj", 32, 2 }, { "64B obj", 64, 2 }, { "128B obj", 128, 2 }, { "256B obj", 256, 4 }, { "512B obj", 512, 4 }, { "1KB obj", 1024, 8 }, { "2KB obj", 2048, 8 }, { "4KB obj", 4096, 16 }, { 0, 0, 0 } }; void kmain(struct multiboot_info_t *mbd, int32_t mb_magic) { dbglog_setup(); dbg_printf("Hello, kernel World!\n"); dbg_printf("This is %s, version %s.\n", OS_NAME, OS_VERSION); ASSERT(mb_magic == MULTIBOOT_BOOTLOADER_MAGIC); gdt_init(); dbg_printf("GDT set up.\n"); idt_init(); dbg_printf("IDT set up.\n"); idt_set_ex_handler(EX_BREAKPOINT, breakpoint_handler); // asm volatile("int $0x3"); // test breakpoint size_t total_ram = ((mbd->mem_upper + mbd->mem_lower) * 1024); dbg_printf("Total ram: %d Kb\n", total_ram / 1024); // used for allocation of data structures before malloc is set up // a pointer to this pointer is passed to the functions that might have // to allocate memory ; they just increment it of the allocated quantity void* kernel_data_end = &k_end_addr; frame_init_allocator(total_ram, &kernel_data_end); dbg_printf("kernel_data_end: 0x%p\n", kernel_data_end); dbg_print_frame_stats(); paging_setup(kernel_data_end); dbg_printf("Paging seems to be working!\n"); BOCHS_BREAKPOINT; region_allocator_init(kernel_data_end); dbg_print_region_stats(); void* p = region_alloc(0x1000, REGION_T_HW, 0); dbg_printf("Allocated one-page region: 0x%p\n", p); dbg_print_region_stats(); void* q = region_alloc(0x1000, REGION_T_HW, 0); dbg_printf("Allocated one-page region: 0x%p\n", q); dbg_print_region_stats(); void* r = region_alloc(0x2000, REGION_T_HW, 0); dbg_printf("Allocated two-page region: 0x%p\n", r); dbg_print_region_stats(); void* s = region_alloc(0x10000, REGION_T_CORE_HEAP, 0); dbg_printf("Allocated 16-page region: 0x%p\n", s); dbg_print_region_stats(); region_free(p); dbg_printf("Freed region 0x%p\n", p); dbg_print_region_stats(); region_free(q); dbg_printf("Freed region 0x%p\n", q); dbg_print_region_stats(); region_free(r); dbg_printf("Freed region 0x%p\n", r); dbg_print_region_stats(); region_free(s); dbg_printf("Freed region 0x%p\n", s); dbg_print_region_stats(); BOCHS_BREAKPOINT; // allocate a big region and try to write into it const size_t n = 200; void* p0 = region_alloc(n * PAGE_SIZE, REGION_T_HW, test_pf_handler); for (size_t i = 0; i < n; i++) { uint32_t *x = (uint32_t*)(p0 + i * PAGE_SIZE); dbg_printf("[%i : ", i); x[0] = 12; dbg_printf(" : ."); x[1] = (i * 20422) % 122; dbg_printf("]\n", i); } BOCHS_BREAKPOINT; // unmap memory for (size_t i = 0; i < n; i++) { void* p = p0 + i * PAGE_SIZE; uint32_t *x = (uint32_t*)p; ASSERT(x[1] == (i * 20422) % 122); uint32_t f = pd_get_frame(p); ASSERT(f != 0); pd_unmap_page(p); ASSERT(pd_get_frame(p) == 0); frame_free(f, 1); } region_free(s); BOCHS_BREAKPOINT; // TEST SLAB ALLOCATOR!!! mem_allocator_t *a = create_slab_allocator(slab_sizes, page_alloc_fun_for_kmalloc, page_free_fun_for_kmalloc); dbg_printf("Created slab allocator at 0x%p\n", a); dbg_print_region_stats(); const int m = 10000; uint16_t* ptr[m]; for (int i = 0; i < m; i++) { size_t s = 1 << ((i * 7) % 12 + 2); ptr[i] = (uint16_t*)slab_alloc(a, s); ASSERT((void*)ptr[i] >= kernel_data_end && (size_t)ptr[i] < 0xFFC00000); *ptr[i] = ((i * 211) % 1024); dbg_printf("Alloc %i : 0x%p\n", s, ptr[i]); } dbg_print_region_stats(); for (int i = 0; i < m; i++) { for (int j = i; j < m; j++) { ASSERT(*ptr[j] == (j * 211) % 1024); } slab_free(a, ptr[i]); } dbg_print_region_stats(); dbg_printf("Destroying slab allocator.\n"); destroy_slab_allocator(a); dbg_print_region_stats(); PANIC("Reached kmain end! Falling off the edge."); } /* vim: set ts=4 sw=4 tw=0 noet :*/