/* * GRUB -- GRand Unified Bootloader * Copyright (C) 2006,2007,2009 Free Software Foundation, Inc. * * GRUB is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * GRUB is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GRUB. If not, see . */ /* This is an emulation of EFI runtime services. This allows a more uniform boot on i386 machines. As it emulates only runtime serviceit isn't able to chainload EFI bootloader on non-EFI system (TODO) */ #include #include #include #include grub_efi_status_t efiemu_get_time (grub_efi_time_t *time, grub_efi_time_capabilities_t *capabilities); grub_efi_status_t efiemu_set_time (grub_efi_time_t *time); grub_efi_status_t efiemu_get_wakeup_time (grub_efi_boolean_t *enabled, grub_efi_boolean_t *pending, grub_efi_time_t *time); grub_efi_status_t efiemu_set_wakeup_time (grub_efi_boolean_t enabled, grub_efi_time_t *time); #ifdef APPLE_CC #define PHYSICAL_ATTRIBUTE __attribute__ ((section("_text-physical, _text-physical"))); #else #define PHYSICAL_ATTRIBUTE __attribute__ ((section(".text-physical"))); #endif grub_efi_status_t efiemu_set_virtual_address_map (grub_efi_uintn_t memory_map_size, grub_efi_uintn_t descriptor_size, grub_efi_uint32_t descriptor_version, grub_efi_memory_descriptor_t *virtual_map) PHYSICAL_ATTRIBUTE; grub_efi_status_t efiemu_convert_pointer (grub_efi_uintn_t debug_disposition, void **address) PHYSICAL_ATTRIBUTE; grub_efi_status_t efiemu_get_variable (grub_efi_char16_t *variable_name, grub_efi_guid_t *vendor_guid, grub_efi_uint32_t *attributes, grub_efi_uintn_t *data_size, void *data); grub_efi_status_t efiemu_get_next_variable_name (grub_efi_uintn_t *variable_name_size, grub_efi_char16_t *variable_name, grub_efi_guid_t *vendor_guid); grub_efi_status_t efiemu_set_variable (grub_efi_char16_t *variable_name, grub_efi_guid_t *vendor_guid, grub_efi_uint32_t attributes, grub_efi_uintn_t data_size, void *data); grub_efi_status_t efiemu_get_next_high_monotonic_count (grub_efi_uint32_t *high_count); void efiemu_reset_system (grub_efi_reset_type_t reset_type, grub_efi_status_t reset_status, grub_efi_uintn_t data_size, grub_efi_char16_t *reset_data); grub_efi_status_t EFI_FUNC (efiemu_set_virtual_address_map) (grub_efi_uintn_t, grub_efi_uintn_t, grub_efi_uint32_t, grub_efi_memory_descriptor_t *) PHYSICAL_ATTRIBUTE; grub_efi_status_t EFI_FUNC (efiemu_convert_pointer) (grub_efi_uintn_t debug_disposition, void **address) PHYSICAL_ATTRIBUTE; static grub_uint32_t efiemu_getcrc32 (grub_uint32_t crc, void *buf, int size) PHYSICAL_ATTRIBUTE; static void init_crc32_table (void) PHYSICAL_ATTRIBUTE; static grub_uint32_t reflect (grub_uint32_t ref, int len) PHYSICAL_ATTRIBUTE; /* The log. It's used when examining memory dump */ static grub_uint8_t loge[1000] = "EFIEMULOG"; static int logn = 9; #define LOG(x) { if (logn<900) loge[logn++]=x; } static int ptv_relocated = 0; /* Interface with grub */ struct grub_efi_runtime_services efiemu_runtime_services; struct grub_efi_system_table efiemu_system_table; extern struct grub_efiemu_ptv_rel efiemu_ptv_relloc[]; extern grub_uint8_t efiemu_variables[]; extern grub_uint32_t efiemu_varsize; extern grub_uint32_t efiemu_high_monotonic_count; extern grub_int16_t efiemu_time_zone; extern grub_uint8_t efiemu_time_daylight; extern grub_uint32_t efiemu_time_accuracy; /* Some standard functions because we need to be standalone */ static void efiemu_memcpy (void *to, void *from, int count) { int i; for (i = 0; i < count; i++) ((grub_uint8_t *) to)[i] = ((grub_uint8_t *) from)[i]; } static int efiemu_str16equal (grub_uint16_t *a, grub_uint16_t *b) { grub_uint16_t *ptr1, *ptr2; for (ptr1=a,ptr2=b; *ptr1 && *ptr2 == *ptr1; ptr1++, ptr2++); return *ptr2 == *ptr1; } static grub_size_t efiemu_str16len (grub_uint16_t *a) { grub_uint16_t *ptr1; for (ptr1 = a; *ptr1; ptr1++); return ptr1 - a; } static int efiemu_memequal (void *a, void *b, grub_size_t n) { grub_uint8_t *ptr1, *ptr2; for (ptr1 = (grub_uint8_t *) a, ptr2 = (grub_uint8_t *)b; ptr1 < (grub_uint8_t *)a + n && *ptr2 == *ptr1; ptr1++, ptr2++); return ptr1 == a + n; } static void efiemu_memset (grub_uint8_t *a, grub_uint8_t b, grub_size_t n) { grub_uint8_t *ptr1; for (ptr1=a; ptr1 < a + n; ptr1++) *ptr1 = b; } static inline void write_cmos (grub_uint8_t addr, grub_uint8_t val) { __asm__ __volatile__ ("outb %%al,$0x70\n" "mov %%cl, %%al\n" "outb %%al,$0x71": :"a" (addr), "c" (val)); } static inline grub_uint8_t read_cmos (grub_uint8_t addr) { grub_uint8_t ret; __asm__ __volatile__ ("outb %%al, $0x70\n" "inb $0x71, %%al": "=a"(ret) :"a" (addr)); return ret; } /* Needed by some gcc versions */ int __stack_chk_fail () { return 0; } /* The function that implement runtime services as specified in EFI specification */ static inline grub_uint8_t bcd_to_hex (grub_uint8_t in) { return 10 * ((in & 0xf0) >> 4) + (in & 0x0f); } grub_efi_status_t EFI_FUNC (efiemu_get_time) (grub_efi_time_t *time, grub_efi_time_capabilities_t *capabilities) { LOG ('a'); grub_uint8_t state; state = read_cmos (0xb); if (!(state & (1 << 2))) { time->year = 2000 + bcd_to_hex (read_cmos (0x9)); time->month = bcd_to_hex (read_cmos (0x8)); time->day = bcd_to_hex (read_cmos (0x7)); time->hour = bcd_to_hex (read_cmos (0x4)); if (time->hour >= 81) time->hour -= 80 - 12; if (time->hour == 24) time->hour = 0; time->minute = bcd_to_hex (read_cmos (0x2)); time->second = bcd_to_hex (read_cmos (0x0)); } else { time->year = 2000 + read_cmos (0x9); time->month = read_cmos (0x8); time->day = read_cmos (0x7); time->hour = read_cmos (0x4); if (time->hour >= 0x81) time->hour -= 0x80 - 12; if (time->hour == 24) time->hour = 0; time->minute = read_cmos (0x2); time->second = read_cmos (0x0); } time->nanosecond = 0; time->pad1 = 0; time->pad2 = 0; time->time_zone = efiemu_time_zone; time->daylight = efiemu_time_daylight; capabilities->resolution = 1; capabilities->accuracy = efiemu_time_accuracy; capabilities->sets_to_zero = 0; return GRUB_EFI_SUCCESS; } grub_efi_status_t EFI_FUNC (efiemu_set_time) (grub_efi_time_t *time) { LOG ('b'); grub_uint8_t state; state = read_cmos (0xb); write_cmos (0xb, state | 0x6); write_cmos (0x9, time->year - 2000); write_cmos (0x8, time->month); write_cmos (0x7, time->day); write_cmos (0x4, time->hour); write_cmos (0x2, time->minute); write_cmos (0x0, time->second); efiemu_time_zone = time->time_zone; efiemu_time_daylight = time->daylight; return GRUB_EFI_SUCCESS; } /* Following 2 functions are vendor specific. So announce it as unsupported */ grub_efi_status_t EFI_FUNC (efiemu_get_wakeup_time) (grub_efi_boolean_t *enabled, grub_efi_boolean_t *pending, grub_efi_time_t *time) { LOG ('c'); return GRUB_EFI_UNSUPPORTED; } grub_efi_status_t EFI_FUNC (efiemu_set_wakeup_time) (grub_efi_boolean_t enabled, grub_efi_time_t *time) { LOG ('d'); return GRUB_EFI_UNSUPPORTED; } static grub_uint32_t crc32_table [256]; static grub_uint32_t reflect (grub_uint32_t ref, int len) { grub_uint32_t result = 0; int i; for (i = 1; i <= len; i++) { if (ref & 1) result |= 1 << (len - i); ref >>= 1; } return result; } static void init_crc32_table (void) { grub_uint32_t polynomial = 0x04c11db7; int i, j; for(i = 0; i < 256; i++) { crc32_table[i] = reflect(i, 8) << 24; for (j = 0; j < 8; j++) crc32_table[i] = (crc32_table[i] << 1) ^ (crc32_table[i] & (1 << 31) ? polynomial : 0); crc32_table[i] = reflect(crc32_table[i], 32); } } static grub_uint32_t efiemu_getcrc32 (grub_uint32_t crc, void *buf, int size) { int i; grub_uint8_t *data = buf; if (! crc32_table[1]) init_crc32_table (); crc^= 0xffffffff; for (i = 0; i < size; i++) { crc = (crc >> 8) ^ crc32_table[(crc & 0xFF) ^ *data]; data++; } return crc ^ 0xffffffff; } grub_efi_status_t EFI_FUNC (efiemu_set_virtual_address_map) (grub_efi_uintn_t memory_map_size, grub_efi_uintn_t descriptor_size, grub_efi_uint32_t descriptor_version, grub_efi_memory_descriptor_t *virtual_map) { struct grub_efiemu_ptv_rel *cur_relloc; LOG ('e'); /* Ensure that we are called only once */ if (ptv_relocated) return GRUB_EFI_UNSUPPORTED; ptv_relocated = 1; /* Correct addresses using information supplied by grub */ for (cur_relloc = efiemu_ptv_relloc; cur_relloc->size;cur_relloc++) { grub_int64_t corr = 0; grub_efi_memory_descriptor_t *descptr; /* Compute correction */ for (descptr = virtual_map; ((grub_uint8_t *) descptr - (grub_uint8_t *) virtual_map) < memory_map_size; descptr = (grub_efi_memory_descriptor_t *) ((grub_uint8_t *) descptr + descriptor_size)) { if (descptr->type == cur_relloc->plustype) corr += descptr->virtual_start - descptr->physical_start; if (descptr->type == cur_relloc->minustype) corr -= descptr->virtual_start - descptr->physical_start; } /* Apply correction */ switch (cur_relloc->size) { case 8: *((grub_uint64_t *) UINT_TO_PTR (cur_relloc->addr)) += corr; break; case 4: *((grub_uint32_t *) UINT_TO_PTR (cur_relloc->addr)) += corr; break; case 2: *((grub_uint16_t *) UINT_TO_PTR (cur_relloc->addr)) += corr; break; case 1: *((grub_uint8_t *) UINT_TO_PTR (cur_relloc->addr)) += corr; break; } } /* Recompute crc32 of system table and runtime services */ efiemu_system_table.hdr.crc32 = 0; efiemu_system_table.hdr.crc32 = efiemu_getcrc32 (0, &efiemu_system_table, sizeof (efiemu_system_table)); efiemu_runtime_services.hdr.crc32 = 0; efiemu_runtime_services.hdr.crc32 = efiemu_getcrc32 (0, &efiemu_runtime_services, sizeof (efiemu_runtime_services)); return GRUB_EFI_SUCCESS; } /* since efiemu_set_virtual_address_map corrects all the pointers we don't need efiemu_convert_pointer */ grub_efi_status_t EFI_FUNC (efiemu_convert_pointer) (grub_efi_uintn_t debug_disposition, void **address) { LOG ('f'); return GRUB_EFI_UNSUPPORTED; } /* Next comes variable services. Because we have no vendor-independent way to store these variables we have no non-volatility */ /* Find variable by name and GUID. */ static struct efi_variable * find_variable (grub_efi_guid_t *vendor_guid, grub_efi_char16_t *variable_name) { grub_uint8_t *ptr; struct efi_variable *efivar; for (ptr = efiemu_variables; ptr < efiemu_variables + efiemu_varsize; ) { efivar = (struct efi_variable *) ptr; if (!efivar->namelen) return 0; if (efiemu_str16equal((grub_efi_char16_t *)(efivar + 1), variable_name) && efiemu_memequal (&(efivar->guid), vendor_guid, sizeof (efivar->guid))) return efivar; ptr += efivar->namelen + efivar->size + sizeof (*efivar); } return 0; } grub_efi_status_t EFI_FUNC (efiemu_get_variable) (grub_efi_char16_t *variable_name, grub_efi_guid_t *vendor_guid, grub_efi_uint32_t *attributes, grub_efi_uintn_t *data_size, void *data) { struct efi_variable *efivar; LOG ('g'); efivar = find_variable (vendor_guid, variable_name); if (!efivar) return GRUB_EFI_NOT_FOUND; if (*data_size < efivar->size) { *data_size = efivar->size; return GRUB_EFI_BUFFER_TOO_SMALL; } *data_size = efivar->size; efiemu_memcpy (data, (grub_uint8_t *)(efivar + 1) + efivar->namelen, efivar->size); *attributes = efivar->attributes; return GRUB_EFI_SUCCESS; } grub_efi_status_t EFI_FUNC (efiemu_get_next_variable_name) (grub_efi_uintn_t *variable_name_size, grub_efi_char16_t *variable_name, grub_efi_guid_t *vendor_guid) { struct efi_variable *efivar; LOG ('l'); if (!variable_name_size || !variable_name || !vendor_guid) return GRUB_EFI_INVALID_PARAMETER; if (variable_name[0]) { efivar = find_variable (vendor_guid, variable_name); if (!efivar) return GRUB_EFI_NOT_FOUND; efivar = (struct efi_variable *)((grub_uint8_t *)efivar + efivar->namelen + efivar->size + sizeof (*efivar)); } else efivar = (struct efi_variable *) (efiemu_variables); LOG ('m'); if ((grub_uint8_t *)efivar >= efiemu_variables + efiemu_varsize || !efivar->namelen) return GRUB_EFI_NOT_FOUND; if (*variable_name_size < efivar->namelen) { *variable_name_size = efivar->namelen; return GRUB_EFI_BUFFER_TOO_SMALL; } efiemu_memcpy (variable_name, efivar + 1, efivar->namelen); efiemu_memcpy (vendor_guid, &(efivar->guid), sizeof (efivar->guid)); LOG('h'); return GRUB_EFI_SUCCESS; } grub_efi_status_t EFI_FUNC (efiemu_set_variable) (grub_efi_char16_t *variable_name, grub_efi_guid_t *vendor_guid, grub_efi_uint32_t attributes, grub_efi_uintn_t data_size, void *data) { struct efi_variable *efivar; grub_uint8_t *ptr; LOG('i'); if (!variable_name[0]) return GRUB_EFI_INVALID_PARAMETER; efivar = find_variable (vendor_guid, variable_name); /* Delete variable if any */ if (efivar) { efiemu_memcpy (efivar, (grub_uint8_t *)(efivar + 1) + efivar->namelen + efivar->size, (efiemu_variables + efiemu_varsize) - ((grub_uint8_t *)(efivar + 1) + efivar->namelen + efivar->size)); efiemu_memset (efiemu_variables + efiemu_varsize - (sizeof (*efivar) + efivar->namelen + efivar->size), 0, (sizeof (*efivar) + efivar->namelen + efivar->size)); } if (!data_size) return GRUB_EFI_SUCCESS; for (ptr = efiemu_variables; ptr < efiemu_variables + efiemu_varsize; ) { efivar = (struct efi_variable *) ptr; ptr += efivar->namelen + efivar->size + sizeof (*efivar); if (!efivar->namelen) break; } if ((grub_uint8_t *)(efivar + 1) + data_size + 2 * (efiemu_str16len (variable_name) + 1) >= efiemu_variables + efiemu_varsize) return GRUB_EFI_OUT_OF_RESOURCES; efiemu_memcpy (&(efivar->guid), vendor_guid, sizeof (efivar->guid)); efivar->namelen = 2 * (efiemu_str16len (variable_name) + 1); efivar->size = data_size; efivar->attributes = attributes; efiemu_memcpy (efivar + 1, variable_name, 2 * (efiemu_str16len (variable_name) + 1)); efiemu_memcpy ((grub_uint8_t *)(efivar + 1) + 2 * (efiemu_str16len (variable_name) + 1), data, data_size); return GRUB_EFI_SUCCESS; } grub_efi_status_t EFI_FUNC (efiemu_get_next_high_monotonic_count) (grub_efi_uint32_t *high_count) { LOG ('j'); if (!high_count) return GRUB_EFI_INVALID_PARAMETER; *high_count = ++efiemu_high_monotonic_count; return GRUB_EFI_SUCCESS; } /* To implement it with APM we need to go to real mode. It's too much hassle Besides EFI specification says that this function shouldn't be used on systems supporting ACPI */ void EFI_FUNC (efiemu_reset_system) (grub_efi_reset_type_t reset_type, grub_efi_status_t reset_status, grub_efi_uintn_t data_size, grub_efi_char16_t *reset_data) { LOG ('k'); } struct grub_efi_runtime_services efiemu_runtime_services = { .hdr = { .signature = GRUB_EFIEMU_RUNTIME_SERVICES_SIGNATURE, .revision = 0x0001000a, .header_size = sizeof (struct grub_efi_runtime_services), .crc32 = 0, /* filled later*/ .reserved = 0 }, .get_time = efiemu_get_time, .set_time = efiemu_set_time, .get_wakeup_time = efiemu_get_wakeup_time, .set_wakeup_time = efiemu_set_wakeup_time, .set_virtual_address_map = efiemu_set_virtual_address_map, .convert_pointer = efiemu_convert_pointer, .get_variable = efiemu_get_variable, .get_next_variable_name = efiemu_get_next_variable_name, .set_variable = efiemu_set_variable, .get_next_high_monotonic_count = efiemu_get_next_high_monotonic_count, .reset_system = efiemu_reset_system }; static grub_uint16_t efiemu_vendor[] = {'G', 'R', 'U', 'B', ' ', 'E', 'F', 'I', ' ', 'R', 'U', 'N', 'T', 'I', 'M', 'E', 0}; struct grub_efi_system_table efiemu_system_table = { .hdr = { .signature = GRUB_EFIEMU_SYSTEM_TABLE_SIGNATURE, .revision = 0x0001000a, .header_size = sizeof (struct grub_efi_system_table), .crc32 = 0, /* filled later*/ .reserved = 0 }, .firmware_vendor = efiemu_vendor, .firmware_revision = 0x0001000a, .console_in_handler = 0, .con_in = 0, .console_out_handler = 0, .con_out = 0, .standard_error_handle = 0, .std_err = 0, .runtime_services = &efiemu_runtime_services, .boot_services = 0, .num_table_entries = 0, .configuration_table = 0 };