#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef PRNG_INIT_ENTROPY #define PRNG_INIT_ENTROPY 1299733235 #endif // ===== FOR TESTS ===== #define TEST_PLACEHOLDER_AFTER_IDT #define TEST_PLACEHOLDER_AFTER_REGION #define TEST_PLACEHOLDER_AFTER_KMALLOC #define TEST_PLACEHOLDER_AFTER_TASKING #define TEST_PLACEHOLDER_AFTER_DEVFS #ifdef BUILD_KERNEL_TEST #define BEGIN_TEST(n) dbg_printf("(BEGIN-TEST %s)\n", n); #define TEST_OK { dbg_printf("(TEST-OK)\n"); asm volatile("cli; hlt"); } #include #endif // ===== / FOR TESTS ==== extern const void k_end_addr; // defined in linker script : 0xC0000000 plus kernel stuff void breakpoint_handler(registers_t *regs) { dbg_printf("Breakpoint! (int3)\n"); dbg_dump_registers(regs); BOCHS_BREAKPOINT; } void kernel_init_stage2(void* data); btree_t *parse_cmdline(const char* x); fs_t *setup_iofs(multiboot_info_t *mbd); fs_t *setup_rootfs(btree_t *cmdline, fs_t *iofs); void launch_init(btree_t *cmdline, fs_t *iofs, fs_t *rootfs); void kmain(multiboot_info_t *mbd, int32_t mb_magic) { // 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 = (void*)&k_end_addr; 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); // Rewrite multiboot header so that we are in higher half // Also check that kernel_data_end is after all modules, otherwise // we might overwrite something. mbd->cmdline += K_HIGHHALF_ADDR; size_t cmdline_end = mbd->cmdline + strlen((char*)mbd->cmdline); void* cmdline_end_pa = (void*)((cmdline_end & 0xFFFFF000) + 0x1000); if (cmdline_end_pa > kernel_data_end) kernel_data_end = cmdline_end_pa; mbd->mods_addr += K_HIGHHALF_ADDR; multiboot_module_t *mods = (multiboot_module_t*)mbd->mods_addr; for (unsigned i = 0; i < mbd->mods_count; i++) { mods[i].mod_start += K_HIGHHALF_ADDR; mods[i].mod_end += K_HIGHHALF_ADDR; mods[i].string += K_HIGHHALF_ADDR; void* mod_end_pa = (void*)((mods[i].mod_end & 0xFFFFF000) + 0x1000); if (mod_end_pa > kernel_data_end) kernel_data_end = mod_end_pa; } gdt_init(); dbg_printf("GDT set up.\n"); idt_init(); dbg_printf("IDT set up.\n"); idt_set_ex_handler(EX_BREAKPOINT, breakpoint_handler); TEST_PLACEHOLDER_AFTER_IDT; size_t total_ram = ((mbd->mem_upper + mbd->mem_lower) * 1024); dbg_printf("Total ram: %d Kb\n", total_ram / 1024); 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"); region_allocator_init(kernel_data_end); dbg_printf("Region allocator initialized.\n"); TEST_PLACEHOLDER_AFTER_REGION; kmalloc_setup(); dbg_printf("Kernel malloc setup ok.\n"); TEST_PLACEHOLDER_AFTER_KMALLOC; setup_syscall_table(); dbg_printf("System calls setup ok.\n"); // enter multi-threading mode // interrupts are enabled at this moment, so all // code run from now on should be preemtible (ie thread-safe) threading_setup(kernel_init_stage2, mbd); PANIC("Should never come here."); } void kernel_init_stage2(void* data) { dbg_printf("Threading setup ok.\n"); multiboot_info_t *mbd = (multiboot_info_t*)data; dbg_print_region_info(); dbg_print_frame_stats(); // Launch some worker threads start_workers(2); TEST_PLACEHOLDER_AFTER_TASKING; // Create iofs register_nullfs_driver(); fs_t *iofs = setup_iofs(mbd); TEST_PLACEHOLDER_AFTER_DEVFS; // Scan for devices pci_setup(); pciide_detect(iofs); vesa_detect(iofs); // Register FS drivers register_iso9660_driver(); // Add entropy to prng uint32_t x = PRNG_INIT_ENTROPY; prng_add_entropy((uint8_t*)&x, sizeof(x)); // Parse command line btree_t *cmdline = parse_cmdline((const char*)mbd->cmdline); fs_t *rootfs = 0; if (btree_find(cmdline, "root") != 0) rootfs = setup_rootfs(cmdline, iofs); launch_init(cmdline, iofs, rootfs); // We are done here dbg_printf("Reached kmain end! I'll just stop here and do nothing.\n"); } btree_t *parse_cmdline(const char* x) { btree_t *ret = create_btree(str_key_cmp_fun, free_key_val); ASSERT(ret != 0); x = strchr(x, ' '); if (x == 0) return ret; while ((*x) != 0) { while (*x == ' ') x++; char* eq = strchr(x, '='); char* sep = strchr(x, ' '); if (sep == 0) { if (eq == 0) { btree_add(ret, strdup(x), strdup(x)); } else { btree_add(ret, strndup(x, eq - x), strdup(eq + 1)); } break; } else { if (eq == 0 || eq > sep) { btree_add(ret, strndup(x, sep - x), strndup(x, sep - x)); } else { btree_add(ret, strndup(x, eq - x), strndup(eq + 1, sep - eq - 1)); } x = sep + 1; } } void iter(void* a, void* b) { dbg_printf(" '%s' -> '%s'\n", a, b); } btree_iter(ret, iter); return ret; } fs_t *setup_iofs(multiboot_info_t *mbd) { fs_t *iofs = make_fs("nullfs", 0, ""); ASSERT(iofs != 0); // Add kernel command line to iofs { dbg_printf("Kernel command line: '%s'\n", (char*)mbd->cmdline); size_t len = strlen((char*)mbd->cmdline); ASSERT(nullfs_add_ram_file(iofs, "/cmdline", (char*)mbd->cmdline, len, FM_READ | FM_MMAP)); } // Populate iofs with files for kernel modules ASSERT(fs_create(iofs, "/mod", FT_DIR)); multiboot_module_t *mods = (multiboot_module_t*)mbd->mods_addr; for (unsigned i = 0; i < mbd->mods_count; i++) { char* modname = (char*)mods[i].string; char* e = strchr(modname, ' '); if (e != 0) (*e) = 0; // ignore arguments char *b = strrchr(modname, '/'); if (b != 0) modname = b+1; // ignore path char name[6 + strlen(modname)]; strcpy(name, "/mod/"); strcpy(name+5, modname); size_t len = mods[i].mod_end - mods[i].mod_start; dbg_printf("Adding module to VFS: '%s' (size %d)\n", name, len); ASSERT(nullfs_add_ram_file(iofs, name, (char*)mods[i].mod_start, len, FM_READ | FM_MMAP)); } return iofs; } fs_t *setup_rootfs(btree_t *cmdline, fs_t *iofs) { char* root = (char*)btree_find(cmdline, "root"); char* root_opts = (char*)btree_find(cmdline, "root_opts"); if (root == 0) PANIC("No root device specified on kernel command line."); char* sep = strchr(root, ':'); if (sep != 0) { ASSERT(root[0] == 'i' && root[1] == 'o' && root[2] == ':'); root = root + 3; // ignore prefix, we are always on iofs } dbg_printf("Trying to open root device %s... ", root); fs_handle_t *root_dev = fs_open(iofs, root, FM_READ | FM_WRITE | FM_IOCTL); if (root_dev == 0) { dbg_printf("read-only... "); root_dev = fs_open(iofs, root, FM_READ | FM_IOCTL); } dbg_printf("\n"); if (root_dev == 0) PANIC("Could not open root device."); fs_t *rootfs = make_fs(0, root_dev, (root_opts ? root_opts : "")); if (rootfs == 0) PANIC("Could not mount root device."); return rootfs; } void launch_init(btree_t *cmdline, fs_t *iofs, fs_t *rootfs) { fs_t *init_fs = rootfs; char* init_file = btree_find(cmdline, "init"); if (init_file == 0) PANIC("No init specified on kernel command line."); dbg_printf("Launching init %s...\n", init_file); char* sep = strchr(init_file, ':'); if (sep != 0) { if (strncmp(init_file, "io:", 3) == 0) { init_fs = iofs; init_file = init_file + 3; } else if (strncmp(init_file, "root:", 5) == 0) { init_fs = rootfs; init_file = init_file + 5; } } if (init_fs == 0) PANIC("Invalid file system specification for init file."); // Launch INIT fs_handle_t *init_bin = fs_open(init_fs, init_file, FM_READ | FM_MMAP); if (init_bin == 0) init_bin = fs_open(init_fs, init_file, FM_READ); if (init_bin == 0) PANIC("Could not open init file."); if (!is_elf(init_bin)) PANIC("init.bin is not valid ELF32 binary"); process_t *init_p = new_process(0); ASSERT(init_p != 0); bool add_iofs_ok = proc_add_fs(init_p, iofs, "io"); ASSERT(add_iofs_ok); bool add_rootfs_ok = proc_add_fs(init_p, rootfs, "root"); ASSERT(add_rootfs_ok); proc_entry_t *e = elf_load(init_bin, init_p); if (e == 0) PANIC("Could not load init ELF file"); unref_file(init_bin); dbg_dump_proc_memmap(init_p); ASSERT(start_process(init_p, e)); } /* vim: set ts=4 sw=4 tw=0 noet :*/