// 32bit code to Power On Self Test (POST) a machine. // // Copyright (C) 2008-2010 Kevin O'Connor // Copyright (C) 2002 MandrakeSoft S.A. // // This file may be distributed under the terms of the GNU LGPLv3 license. #include "ioport.h" // PORT_* #include "config.h" // CONFIG_* #include "cmos.h" // CMOS_* #include "util.h" // memset #include "biosvar.h" // struct bios_data_area_s #include "disk.h" // floppy_drive_setup #include "ata.h" // ata_setup #include "ahci.h" // ahci_setup #include "memmap.h" // add_e820 #include "pic.h" // pic_setup #include "pci.h" // create_pirtable #include "acpi.h" // acpi_bios_init #include "bregs.h" // struct bregs #include "mptable.h" // mptable_init #include "boot.h" // IPL #include "usb.h" // usb_setup #include "smbios.h" // smbios_init #include "paravirt.h" // qemu_cfg_port_probe #include "xen.h" // xen_probe_hvm_info #include "ps2port.h" // ps2port_setup #include "virtio-blk.h" // virtio_blk_setup /**************************************************************** * BIOS init ****************************************************************/ static void init_ivt(void) { dprintf(3, "init ivt\n"); // Initialize all vectors to the default handler. int i; for (i=0; i<256; i++) SET_IVT(i, FUNC16(entry_iret_official)); // Initialize all hw vectors to a default hw handler. for (i=0x08; i<=0x0f; i++) SET_IVT(i, FUNC16(entry_hwpic1)); for (i=0x70; i<=0x77; i++) SET_IVT(i, FUNC16(entry_hwpic2)); // Initialize software handlers. SET_IVT(0x02, FUNC16(entry_02)); SET_IVT(0x10, FUNC16(entry_10)); SET_IVT(0x11, FUNC16(entry_11)); SET_IVT(0x12, FUNC16(entry_12)); SET_IVT(0x13, FUNC16(entry_13_official)); SET_IVT(0x14, FUNC16(entry_14)); SET_IVT(0x15, FUNC16(entry_15)); SET_IVT(0x16, FUNC16(entry_16)); SET_IVT(0x17, FUNC16(entry_17)); SET_IVT(0x18, FUNC16(entry_18)); SET_IVT(0x19, FUNC16(entry_19_official)); SET_IVT(0x1a, FUNC16(entry_1a)); SET_IVT(0x40, FUNC16(entry_40)); // INT 60h-66h reserved for user interrupt for (i=0x60; i<=0x66; i++) SET_IVT(i, SEGOFF(0, 0)); // set vector 0x79 to zero // this is used by 'gardian angel' protection system SET_IVT(0x79, SEGOFF(0, 0)); SET_IVT(0x1E, SEGOFF(SEG_BIOS, (u32)&diskette_param_table2 - BUILD_BIOS_ADDR)); } static void init_bda(void) { dprintf(3, "init bda\n"); struct bios_data_area_s *bda = MAKE_FLATPTR(SEG_BDA, 0); memset(bda, 0, sizeof(*bda)); int esize = EBDA_SIZE_START; SET_BDA(mem_size_kb, BUILD_LOWRAM_END/1024 - esize); u16 ebda_seg = EBDA_SEGMENT_START; SET_BDA(ebda_seg, ebda_seg); // Init ebda struct extended_bios_data_area_s *ebda = get_ebda_ptr(); memset(ebda, 0, sizeof(*ebda)); ebda->size = esize; add_e820((u32)MAKE_FLATPTR(ebda_seg, 0), GET_EBDA2(ebda_seg, size) * 1024 , E820_RESERVED); } static void ram_probe(void) { dprintf(3, "Find memory size\n"); if (CONFIG_COREBOOT) { coreboot_setup(); } else if (usingXen()) { xen_setup(); } else { // On emulators, get memory size from nvram. u32 rs = ((inb_cmos(CMOS_MEM_EXTMEM2_LOW) << 16) | (inb_cmos(CMOS_MEM_EXTMEM2_HIGH) << 24)); if (rs) rs += 16 * 1024 * 1024; else rs = (((inb_cmos(CMOS_MEM_EXTMEM_LOW) << 10) | (inb_cmos(CMOS_MEM_EXTMEM_HIGH) << 18)) + 1 * 1024 * 1024); RamSize = rs; add_e820(0, rs, E820_RAM); // Check for memory over 4Gig u64 high = ((inb_cmos(CMOS_MEM_HIGHMEM_LOW) << 16) | ((u32)inb_cmos(CMOS_MEM_HIGHMEM_MID) << 24) | ((u64)inb_cmos(CMOS_MEM_HIGHMEM_HIGH) << 32)); RamSizeOver4G = high; add_e820(0x100000000ull, high, E820_RAM); /* reserve 256KB BIOS area at the end of 4 GB */ add_e820(0xfffc0000, 256*1024, E820_RESERVED); } // Don't declare any memory between 0xa0000 and 0x100000 add_e820(BUILD_LOWRAM_END, BUILD_BIOS_ADDR-BUILD_LOWRAM_END, E820_HOLE); // Mark known areas as reserved. add_e820(BUILD_BIOS_ADDR, BUILD_BIOS_SIZE, E820_RESERVED); u32 count = qemu_cfg_e820_entries(); if (count) { struct e820_reservation entry; int i; for (i = 0; i < count; i++) { qemu_cfg_e820_load_next(&entry); add_e820(entry.address, entry.length, entry.type); } } else if (kvm_para_available()) { // Backwards compatibility - provide hard coded range. // 4 pages before the bios, 3 pages for vmx tss pages, the // other page for EPT real mode pagetable add_e820(0xfffbc000, 4*4096, E820_RESERVED); } dprintf(1, "Ram Size=0x%08x (0x%08x%08x high)\n" , RamSize, (u32)(RamSizeOver4G >> 32), (u32)RamSizeOver4G); } static void init_bios_tables(void) { if (CONFIG_COREBOOT) { coreboot_copy_biostable(); return; } if (usingXen()) { xen_copy_biostables(); return; } create_pirtable(); mptable_init(); smbios_init(); acpi_bios_init(); } // Initialize hardware devices static void init_hw(void) { usb_setup(); ps2port_setup(); lpt_setup(); serial_setup(); floppy_setup(); ata_setup(); ahci_setup(); cbfs_payload_setup(); ramdisk_setup(); virtio_blk_setup(); } // Begin the boot process by invoking an int0x19 in 16bit mode. void VISIBLE32FLAT startBoot(void) { // Clear low-memory allocations (required by PMM spec). memset((void*)BUILD_STACK_ADDR, 0, BUILD_EBDA_MINIMUM - BUILD_STACK_ADDR); dprintf(3, "Jump to int19\n"); struct bregs br; memset(&br, 0, sizeof(br)); br.flags = F_IF; call16_int(0x19, &br); } // Main setup code. static void maininit(void) { // Running at new code address - do code relocation fixups malloc_fixupreloc(); // Setup ivt/bda/ebda init_ivt(); init_bda(); // Init base pc hardware. pic_setup(); timer_setup(); mathcp_setup(); // Initialize mtrr mtrr_setup(); // Initialize pci pci_setup(); smm_init(); // Setup Xen hypercalls xen_init_hypercalls(); // Initialize internal tables boot_setup(); // Start hardware initialization (if optionrom threading) if (CONFIG_THREADS && CONFIG_THREAD_OPTIONROMS) init_hw(); // Find and initialize other cpus smp_probe(); // Setup interfaces that option roms may need bios32_setup(); dprintf(3, "[wurm] pmm_setup\n"); pmm_setup(); dprintf(3, "[wurm] pnp_setup\n"); pnp_setup(); dprintf(3, "[wurm] kbd_setup\n"); kbd_setup(); dprintf(3, "[wurm] mouse_setup\n"); mouse_setup(); dprintf(3, "[wurm] init_bios_tables\n"); init_bios_tables(); // Run vga option rom dprintf(3, "[wurm] vga_setup\n"); vga_setup(); // Do hardware initialization (if running synchronously) if (!CONFIG_THREADS || !CONFIG_THREAD_OPTIONROMS) { init_hw(); wait_threads(); } // Run option roms dprintf(3, "[wurm] optionrom_setup\n"); optionrom_setup(); // Run BCVs and show optional boot menu dprintf(3, "[wurm] boot_prep\n"); boot_prep(); // Finalize data structures before boot dprintf(3, "[wurm] cdemu_setup\n"); cdemu_setup(); dprintf(3, "[wurm] pmm_finalize\n"); pmm_finalize(); dprintf(3, "[wurm] malloc_finalize\n"); malloc_finalize(); dprintf(3, "[wurm] memmap_finalize\n"); memmap_finalize(); // Setup bios checksum. BiosChecksum -= checksum((u8*)BUILD_BIOS_ADDR, BUILD_BIOS_SIZE); // Write protect bios memory. dprintf(3, "[wurm] make_bios_readonly\n"); make_bios_readonly(); // Invoke int 19 to start boot process. dprintf(3, "[wurm] startBoot\n"); startBoot(); } /**************************************************************** * POST entry and code relocation ****************************************************************/ // Update given relocs for the code at 'dest' with a given 'delta' static void updateRelocs(void *dest, u32 *rstart, u32 *rend, u32 delta) { u32 *reloc; for (reloc = rstart; reloc < rend; reloc++) *((u32*)(dest + *reloc)) += delta; } // Relocate init code and then call maininit() at new address. static void reloc_init(void) { if (!CONFIG_RELOCATE_INIT) { maininit(); return; } // Symbols populated by the build. extern u8 code32flat_start[]; extern u8 _reloc_min_align[]; extern u32 _reloc_abs_start[], _reloc_abs_end[]; extern u32 _reloc_rel_start[], _reloc_rel_end[]; extern u32 _reloc_init_start[], _reloc_init_end[]; extern u8 code32init_start[], code32init_end[]; // Allocate space for init code. u32 initsize = code32init_end - code32init_start; u32 align = (u32)&_reloc_min_align; void *dest = memalign_tmp(align, initsize); if (!dest) panic("No space for init relocation.\n"); // Copy code and update relocs (init absolute, init relative, and runtime) dprintf(1, "Relocating init from %p to %p (size %d)\n" , code32init_start, dest, initsize); s32 delta = dest - (void*)code32init_start; memcpy(dest, code32init_start, initsize); updateRelocs(dest, _reloc_abs_start, _reloc_abs_end, delta); updateRelocs(dest, _reloc_rel_start, _reloc_rel_end, -delta); updateRelocs(code32flat_start, _reloc_init_start, _reloc_init_end, delta); // Call maininit() in relocated code. void (*func)(void) = (void*)maininit + delta; barrier(); func(); } // Setup for code relocation and then call reloc_init void VISIBLE32INIT dopost(void) { HaveRunPost = 1; // Detect ram and setup internal malloc. qemu_cfg_port_probe(); ram_probe(); malloc_setup(); // Relocate initialization code and call maininit(). reloc_init(); } // Entry point for Power On Self Test (POST) - the BIOS initilization // phase. This function makes the memory at 0xc0000-0xfffff // read/writable and then calls dopost(). void VISIBLE32FLAT handle_post(void) { debug_serial_setup(); dprintf(1, "Start bios (version %s)\n", VERSION); // Enable CPU caching setcr0(getcr0() & ~(CR0_CD|CR0_NW)); // Clear CMOS reboot flag. outb_cmos(0, CMOS_RESET_CODE); // Make sure legacy DMA isn't running. init_dma(); // Check if we are running under Xen. xen_probe(); // Allow writes to modify bios area (0xf0000) make_bios_writable(); // Now that memory is read/writable - start post process. dopost(); }