// Support for manipulating bios tables (pir, mptable, acpi, smbios). // // Copyright (C) 2008,2009 Kevin O'Connor // // This file may be distributed under the terms of the GNU LGPLv3 license. #include "byteorder.h" // le32_to_cpu #include "config.h" // CONFIG_* #include "hw/pci.h" // pci_config_writeb #include "malloc.h" // malloc_fseg #include "memmap.h" // SYMBOL #include "output.h" // dprintf #include "romfile.h" // romfile_find #include "std/acpi.h" // struct rsdp_descriptor #include "std/mptable.h" // MPTABLE_SIGNATURE #include "std/pirtable.h" // struct pir_header #include "std/smbios.h" // struct smbios_entry_point #include "string.h" // memcpy #include "util.h" // copy_table #include "x86.h" // outb struct pir_header *PirAddr VARFSEG; void copy_pir(void *pos) { struct pir_header *p = pos; if (p->signature != PIR_SIGNATURE) return; if (PirAddr) return; if (p->size < sizeof(*p)) return; if (checksum(pos, p->size) != 0) return; void *newpos = malloc_fseg(p->size); if (!newpos) { warn_noalloc(); return; } dprintf(1, "Copying PIR from %p to %p\n", pos, newpos); memcpy(newpos, pos, p->size); PirAddr = newpos; } void copy_mptable(void *pos) { struct mptable_floating_s *p = pos; if (p->signature != MPTABLE_SIGNATURE) return; if (!p->physaddr) return; if (checksum(pos, sizeof(*p)) != 0) return; u32 length = p->length * 16; u16 mpclength = ((struct mptable_config_s *)p->physaddr)->length; if (length + mpclength > BUILD_MAX_MPTABLE_FSEG) { dprintf(1, "Skipping MPTABLE copy due to large size (%d bytes)\n" , length + mpclength); return; } // Allocate final memory location. (In theory the config // structure can go in high memory, but Linux kernels before // v2.6.30 crash with that.) struct mptable_floating_s *newpos = malloc_fseg(length + mpclength); if (!newpos) { warn_noalloc(); return; } dprintf(1, "Copying MPTABLE from %p/%x to %p\n", pos, p->physaddr, newpos); memcpy(newpos, pos, length); newpos->physaddr = (u32)newpos + length; newpos->checksum -= checksum(newpos, sizeof(*newpos)); memcpy((void*)newpos + length, (void*)p->physaddr, mpclength); } /**************************************************************** * ACPI ****************************************************************/ static int get_acpi_rsdp_length(void *pos, unsigned size) { struct rsdp_descriptor *p = pos; if (p->signature != RSDP_SIGNATURE) return -1; u32 length = 20; if (length > size) return -1; if (checksum(pos, length) != 0) return -1; if (p->revision > 1) { length = p->length; if (length > size) return -1; if (checksum(pos, length) != 0) return -1; } return length; } struct rsdp_descriptor *RsdpAddr; void copy_acpi_rsdp(void *pos) { if (RsdpAddr) return; int length = get_acpi_rsdp_length(pos, -1); if (length < 0) return; void *newpos = malloc_fseg(length); if (!newpos) { warn_noalloc(); return; } dprintf(1, "Copying ACPI RSDP from %p to %p\n", pos, newpos); memcpy(newpos, pos, length); RsdpAddr = newpos; } void *find_acpi_rsdp(void) { unsigned long start = SYMBOL(zonefseg_start); unsigned long end = SYMBOL(zonefseg_end); unsigned long pos; for (pos = ALIGN(start, 0x10); pos <= ALIGN_DOWN(end, 0x10); pos += 0x10) if (get_acpi_rsdp_length((void *)pos, end - pos) >= 0) return (void *)pos; return NULL; } static struct fadt_descriptor_rev1 * find_fadt(void) { dprintf(4, "rsdp=%p\n", RsdpAddr); if (!RsdpAddr || RsdpAddr->signature != RSDP_SIGNATURE) return NULL; struct rsdt_descriptor_rev1 *rsdt = (void*)RsdpAddr->rsdt_physical_address; dprintf(4, "rsdt=%p\n", rsdt); if (!rsdt || rsdt->signature != RSDT_SIGNATURE) return NULL; void *end = (void*)rsdt + rsdt->length; int i; for (i=0; (void*)&rsdt->table_offset_entry[i] < end; i++) { struct fadt_descriptor_rev1 *fadt = (void*)rsdt->table_offset_entry[i]; if (!fadt || fadt->signature != FACP_SIGNATURE) continue; dprintf(4, "fadt=%p\n", fadt); return fadt; } dprintf(4, "no fadt found\n"); return NULL; } u32 find_resume_vector(void) { struct fadt_descriptor_rev1 *fadt = find_fadt(); if (!fadt) return 0; struct facs_descriptor_rev1 *facs = (void*)fadt->firmware_ctrl; dprintf(4, "facs=%p\n", facs); if (! facs || facs->signature != FACS_SIGNATURE) return 0; // Found it. dprintf(4, "resume addr=%d\n", facs->firmware_waking_vector); return facs->firmware_waking_vector; } static struct acpi_20_generic_address acpi_reset_reg; static u8 acpi_reset_val; u32 acpi_pm1a_cnt VARFSEG; u16 acpi_pm_base = 0xb000; #define acpi_ga_to_bdf(addr) pci_to_bdf(0, (addr >> 32) & 0xffff, (addr >> 16) & 0xffff) void acpi_reboot(void) { // Check it passed the sanity checks in acpi_set_reset_reg() and was set if (acpi_reset_reg.register_bit_width != 8) return; u64 addr = le64_to_cpu(acpi_reset_reg.address); dprintf(1, "ACPI hard reset %d:%llx (%x)\n", acpi_reset_reg.address_space_id, addr, acpi_reset_val); switch (acpi_reset_reg.address_space_id) { case 0: // System Memory writeb((void *)(u32)addr, acpi_reset_val); break; case 1: // System I/O outb(acpi_reset_val, addr); break; case 2: // PCI config space pci_config_writeb(acpi_ga_to_bdf(addr), addr & 0xffff, acpi_reset_val); break; } } static void acpi_set_reset_reg(struct acpi_20_generic_address *reg, u8 val) { if (!reg || reg->address_space_id > 2 || reg->register_bit_width != 8 || reg->register_bit_offset) return; acpi_reset_reg = *reg; acpi_reset_val = val; } void find_acpi_features(void) { struct fadt_descriptor_rev1 *fadt = find_fadt(); if (!fadt) return; u32 pm_tmr = le32_to_cpu(fadt->pm_tmr_blk); u32 pm1a_cnt = le32_to_cpu(fadt->pm1a_cnt_blk); dprintf(4, "pm_tmr_blk=%x\n", pm_tmr); if (pm_tmr) pmtimer_setup(pm_tmr); if (pm1a_cnt) acpi_pm1a_cnt = pm1a_cnt; // Theoretically we should check the 'reset_reg_sup' flag, but Windows // doesn't and thus nobody seems to *set* it. If the table is large enough // to include it, let the sanity checks in acpi_set_reset_reg() suffice. if (fadt->length >= 129) { void *p = fadt; acpi_set_reset_reg(p + 116, *(u8 *)(p + 128)); } } /**************************************************************** * SMBIOS ****************************************************************/ // Iterator for each sub-table in the smbios blob. void * smbios_next(struct smbios_entry_point *smbios, void *prev) { if (!smbios) return NULL; void *start = (void*)smbios->structure_table_address; void *end = start + smbios->structure_table_length; if (!prev) { prev = start; } else { struct smbios_structure_header *hdr = prev; if (prev + sizeof(*hdr) > end) return NULL; prev += hdr->length + 2; while (prev < end && (*(u8*)(prev-1) != '\0' || *(u8*)(prev-2) != '\0')) prev++; } struct smbios_structure_header *hdr = prev; if (prev >= end || prev + sizeof(*hdr) >= end || prev + hdr->length >= end) return NULL; return prev; } struct smbios_entry_point *SMBiosAddr; void copy_smbios(void *pos) { if (SMBiosAddr) return; struct smbios_entry_point *p = pos; if (p->signature != SMBIOS_SIGNATURE) return; if (checksum(pos, 0x10) != 0) return; if (memcmp(p->intermediate_anchor_string, "_DMI_", 5)) return; if (checksum(pos+0x10, p->length-0x10) != 0) return; struct smbios_entry_point *newpos = malloc_fseg(p->length); if (!newpos) { warn_noalloc(); return; } dprintf(1, "Copying SMBIOS entry point from %p to %p\n", pos, newpos); memcpy(newpos, pos, p->length); SMBiosAddr = newpos; } void display_uuid(void) { struct smbios_type_1 *tbl = smbios_next(SMBiosAddr, NULL); int minlen = offsetof(struct smbios_type_1, uuid) + sizeof(tbl->uuid); for (; tbl; tbl = smbios_next(SMBiosAddr, tbl)) if (tbl->header.type == 1 && tbl->header.length >= minlen) { u8 *uuid = tbl->uuid; u8 empty_uuid[sizeof(tbl->uuid)] = { 0 }; if (memcmp(uuid, empty_uuid, sizeof(empty_uuid)) == 0) return; /* * According to SMBIOS v2.6 the first three fields are encoded in * little-endian format. Versions prior to v2.6 did not specify * the encoding, but we follow dmidecode and assume big-endian * encoding. */ if (SMBiosAddr->smbios_major_version > 2 || (SMBiosAddr->smbios_major_version == 2 && SMBiosAddr->smbios_minor_version >= 6)) { printf("Machine UUID" " %02x%02x%02x%02x" "-%02x%02x" "-%02x%02x" "-%02x%02x" "-%02x%02x%02x%02x%02x%02x\n" , uuid[ 3], uuid[ 2], uuid[ 1], uuid[ 0] , uuid[ 5], uuid[ 4] , uuid[ 7], uuid[ 6] , uuid[ 8], uuid[ 9] , uuid[10], uuid[11], uuid[12] , uuid[13], uuid[14], uuid[15]); } else { printf("Machine UUID" " %02x%02x%02x%02x" "-%02x%02x" "-%02x%02x" "-%02x%02x" "-%02x%02x%02x%02x%02x%02x\n" , uuid[ 0], uuid[ 1], uuid[ 2], uuid[ 3] , uuid[ 4], uuid[ 5] , uuid[ 6], uuid[ 7] , uuid[ 8], uuid[ 9] , uuid[10], uuid[11], uuid[12] , uuid[13], uuid[14], uuid[15]); } return; } } #define set_str_field_or_skip(type, field, value) \ do { \ int size = (value != NULL) ? strlen(value) + 1 : 0; \ if (size > 1) { \ memcpy(end, value, size); \ end += size; \ p->field = ++str_index; \ } else { \ p->field = 0; \ } \ } while (0) static void * smbios_new_type_0(void *start, const char *vendor, const char *version, const char *date) { struct smbios_type_0 *p = (struct smbios_type_0 *)start; char *end = (char *)start + sizeof(struct smbios_type_0); int str_index = 0; p->header.type = 0; p->header.length = sizeof(struct smbios_type_0); p->header.handle = 0; set_str_field_or_skip(0, vendor_str, vendor); set_str_field_or_skip(0, bios_version_str, version); p->bios_starting_address_segment = 0xe800; set_str_field_or_skip(0, bios_release_date_str, date); p->bios_rom_size = 0; /* FIXME */ /* BIOS characteristics not supported */ memset(p->bios_characteristics, 0, 8); p->bios_characteristics[0] = 0x08; /* Enable targeted content distribution (needed for SVVP) */ p->bios_characteristics_extension_bytes[0] = 0; p->bios_characteristics_extension_bytes[1] = 4; p->system_bios_major_release = 0; p->system_bios_minor_release = 0; p->embedded_controller_major_release = 0xFF; p->embedded_controller_minor_release = 0xFF; *end = 0; end++; if (!str_index) { *end = 0; end++; } return end; } #define BIOS_NAME "SeaBIOS" #define BIOS_DATE "04/01/2014" static int smbios_romfile_setup(void) { struct romfile_s *f_anchor = romfile_find("etc/smbios/smbios-anchor"); struct romfile_s *f_tables = romfile_find("etc/smbios/smbios-tables"); struct smbios_entry_point ep; struct smbios_type_0 *t0; u16 qtables_len, need_t0 = 1; u8 *qtables, *tables; if (!f_anchor || !f_tables || f_anchor->size != sizeof(ep)) return 0; f_anchor->copy(f_anchor, &ep, f_anchor->size); if (f_tables->size != ep.structure_table_length) return 0; qtables = malloc_tmphigh(f_tables->size); if (!qtables) { warn_noalloc(); return 0; } f_tables->copy(f_tables, qtables, f_tables->size); ep.structure_table_address = (u32)qtables; /* for smbios_next(), below */ /* did we get a type 0 structure ? */ for (t0 = smbios_next(&ep, NULL); t0; t0 = smbios_next(&ep, t0)) if (t0->header.type == 0) { need_t0 = 0; break; } qtables_len = ep.structure_table_length; if (need_t0) { /* common case: add our own type 0, with 3 strings and 4 '\0's */ u16 t0_len = sizeof(struct smbios_type_0) + strlen(BIOS_NAME) + strlen(VERSION) + strlen(BIOS_DATE) + 4; ep.structure_table_length += t0_len; if (t0_len > ep.max_structure_size) ep.max_structure_size = t0_len; ep.number_of_structures++; } /* allocate final blob and record its address in the entry point */ if (ep.structure_table_length > BUILD_MAX_SMBIOS_FSEG) tables = malloc_high(ep.structure_table_length); else tables = malloc_fseg(ep.structure_table_length); if (!tables) { warn_noalloc(); free(qtables); return 0; } ep.structure_table_address = (u32)tables; /* populate final blob */ if (need_t0) tables = smbios_new_type_0(tables, BIOS_NAME, VERSION, BIOS_DATE); memcpy(tables, qtables, qtables_len); free(qtables); /* finalize entry point */ ep.checksum -= checksum(&ep, 0x10); ep.intermediate_checksum -= checksum((void *)&ep + 0x10, ep.length - 0x10); copy_smbios(&ep); return 1; } void smbios_setup(void) { if (smbios_romfile_setup()) return; smbios_legacy_setup(); } void copy_table(void *pos) { copy_pir(pos); copy_mptable(pos); copy_acpi_rsdp(pos); copy_smbios(pos); }