util/nvramtool/coreboot_tables.h - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /*****************************************************************************\
  * coreboot_tables.h
 \*****************************************************************************/

 #ifndef COREBOOT_TABLES_H
 #define COREBOOT_TABLES_H

 #include <stdint.h>

 /* Note: The contents of this file were borrowed from the coreboot source
  *       code which may be obtained from http://www.coreboot.org/.
  *       Specifically, this code was obtained from LinuxBIOS version 1.1.8.
  */

 /* The coreboot table information is for conveying information
  * from the firmware to the loaded OS image.  Primarily this
  * is expected to be information that cannot be discovered by
  * other means, such as quering the hardware directly.
  *
  * All of the information should be Position Independent Data.
  * That is it should be safe to relocated any of the information
  * without it's meaning/correctnes changing.   For table that
  * can reasonably be used on multiple architectures the data
  * size should be fixed.  This should ease the transition between
  * 32 bit and 64 bit architectures etc.
  *
  * The completeness test for the information in this table is:
  * - Can all of the hardware be detected?
  * - Are the per motherboard constants available?
  * - Is there enough to allow a kernel to run that was written before
  *   a particular motherboard is constructed? (Assuming the kernel
  *   has drivers for all of the hardware but it does not have
  *   assumptions on how the hardware is connected together).
  *
  * With this test it should be straight forward to determine if a
  * table entry is required or not.  This should remove much of the
  * long term compatibility burden as table entries which are
  * irrelevant or have been replaced by better alternatives may be
  * dropped.  Of course it is polite and expidite to include extra
  * table entries and be backwards compatible, but it is not required.
  */

 /* Since coreboot is usually compiled 32bit, gcc will align 64bit
  * types to 32bit boundaries. If the coreboot table is dumped on a
  * 64bit system, a uint64_t would be aligned to 64bit boundaries,
  * breaking the table format.
  *
  * lb_uint64 will keep 64bit coreboot table values aligned to 32bit
  * to ensure compatibility. They can be accessed with the two functions
  * below: unpack_lb64() and pack_lb64()
  *
  * See also: util/lbtdump/lbtdump.c
  */

 struct lb_uint64 {
 	uint32_t lo;
 	uint32_t hi;
 };

 static inline uint64_t unpack_lb64(struct lb_uint64 value)
 {
 	uint64_t result;
 	result = value.hi;
 	result = (result << 32) + value.lo;
 	return result;
 }

 static inline struct lb_uint64 pack_lb64(uint64_t value)
 {
 	struct lb_uint64 result;
 	result.lo = (value >> 0) & 0xffffffff;
 	result.hi = (value >> 32) & 0xffffffff;
 	return result;
 }

 struct lb_header {
 	union {
 		uint8_t signature[4];	/* LBIO */
 		uint32_t signature32;
 	};
 	uint32_t header_bytes;
 	uint32_t header_checksum;
 	uint32_t table_bytes;
 	uint32_t table_checksum;
 	uint32_t table_entries;
 };

 /* Every entry in the boot enviroment list will correspond to a boot
  * info record.  Encoding both type and size.  The type is obviously
  * so you can tell what it is.  The size allows you to skip that
  * boot enviroment record if you don't know what it easy.  This allows
  * forward compatibility with records not yet defined.
  */
 struct lb_record {
 	uint32_t tag;		/* tag ID */
 	uint32_t size;		/* size of record (in bytes) */
 };

 #define LB_TAG_UNUSED        0x0000

 #define LB_TAG_MEMORY        0x0001

 struct lb_memory_range {
 	struct lb_uint64 start;
 	struct lb_uint64 size;
 	uint32_t type;
 #define LB_MEM_RAM       1	/* Memory anyone can use */
 #define LB_MEM_RESERVED  2	/* Don't use this memory region */
 #define LB_MEM_TABLE     16	/* Ram configuration tables are kept in */
 };

 struct lb_memory {
 	uint32_t tag;
 	uint32_t size;
 	struct lb_memory_range map[0];
 };

 #define LB_TAG_HWRPB            0x0002
 struct lb_hwrpb {
 	uint32_t tag;
 	uint32_t size;
 	uint64_t hwrpb;
 };

 #define LB_TAG_MAINBOARD        0x0003
 struct lb_mainboard {
 	uint32_t tag;
 	uint32_t size;
 	uint8_t vendor_idx;
 	uint8_t part_number_idx;
 	uint8_t strings[0];
 };

 #define LB_TAG_VERSION          0x0004
 #define LB_TAG_EXTRA_VERSION    0x0005
 #define LB_TAG_BUILD            0x0006
 #define LB_TAG_COMPILE_TIME     0x0007
 #define LB_TAG_COMPILE_BY       0x0008
 #define LB_TAG_COMPILE_HOST     0x0009
 #define LB_TAG_COMPILE_DOMAIN   0x000a
 #define LB_TAG_COMPILER         0x000b
 #define LB_TAG_LINKER           0x000c
 #define LB_TAG_ASSEMBLER        0x000d
 struct lb_string {
 	uint32_t tag;
 	uint32_t size;
 	uint8_t string[0];
 };
 #define LB_TAG_SERIAL		0x000f
 #define LB_TAG_CONSOLE		0x0010
 #define LB_TAG_FORWARD		0x0011
 struct lb_forward {
 	uint32_t tag;
 	uint32_t size;
 	uint64_t forward;
 };

 /* The following structures are for the cmos definitions table */
 #define LB_TAG_CMOS_OPTION_TABLE 200
 /* cmos header record */
 struct cmos_option_table {
 	uint32_t tag;		/* CMOS definitions table type */
 	uint32_t size;		/* size of the entire table */
 	uint32_t header_length;	/* length of header */
 };

 /* cmos entry record
         This record is variable length.  The name field may be
         shorter than CMOS_MAX_NAME_LENGTH. The entry may start
         anywhere in the byte, but can not span bytes unless it
         starts at the beginning of the byte and the length is
         fills complete bytes.
 */
 #define LB_TAG_OPTION 201
 struct cmos_entries {
 	uint32_t tag;		/* entry type */
 	uint32_t size;		/* length of this record */
 	uint32_t bit;		/* starting bit from start of image */
 	uint32_t length;	/* length of field in bits */
 	uint32_t config;	/* e=enumeration, h=hex, r=reserved */
 	uint32_t config_id;	/* a number linking to an enumeration record */
 #define CMOS_MAX_NAME_LENGTH 32
 	uint8_t name[CMOS_MAX_NAME_LENGTH];	/* name of entry in ascii,
 						   variable length int aligned */
 };

 /* cmos enumerations record
         This record is variable length.  The text field may be
         shorter than CMOS_MAX_TEXT_LENGTH.
 */
 #define LB_TAG_OPTION_ENUM 202
 struct cmos_enums {
 	uint32_t tag;		/* enumeration type */
 	uint32_t size;		/* length of this record */
 	uint32_t config_id;	/* a number identifying the config id */
 	uint32_t value;		/* the value associated with the text */
 #define CMOS_MAX_TEXT_LENGTH 32
 	uint8_t text[CMOS_MAX_TEXT_LENGTH];	/* enum description in ascii,
 						   variable length int aligned */
 };

 /* cmos defaults record
         This record contains default settings for the cmos ram.
 */
 #define LB_TAG_OPTION_DEFAULTS 203
 struct cmos_defaults {
 	uint32_t tag;		/* default type */
 	uint32_t size;		/* length of this record */
 	uint32_t name_length;	/* length of the following name field */
 	uint8_t name[CMOS_MAX_NAME_LENGTH];	/* name identifying the default */
 #define CMOS_IMAGE_BUFFER_SIZE 128
 	uint8_t default_set[CMOS_IMAGE_BUFFER_SIZE];	/* default settings */
 };

 #define LB_TAG_OPTION_CHECKSUM 204
 struct cmos_checksum {
 	uint32_t tag;
 	uint32_t size;
 	/* In practice everything is byte aligned, but things are measured
 	 * in bits to be consistent.
 	 */
 	uint32_t range_start;	/* First bit that is checksummed (byte aligned) */
 	uint32_t range_end;	/* Last bit that is checksummed (byte aligned) */
 	uint32_t location;	/* First bit of the checksum (byte aligned) */
 	uint32_t type;		/* Checksum algorithm that is used */
 #define CHECKSUM_NONE	0
 #define CHECKSUM_PCBIOS	1
 };

 #endif				/* COREBOOT_TABLES_H */
	/*****************************************************************************\
	* coreboot_tables.h
	\*****************************************************************************/

	#ifndef COREBOOT_TABLES_H
	#define COREBOOT_TABLES_H

	#include <stdint.h>

	/* Note: The contents of this file were borrowed from the coreboot source
	* code which may be obtained from http://www.coreboot.org/.
	* Specifically, this code was obtained from LinuxBIOS version 1.1.8.
	*/

	/* The coreboot table information is for conveying information
	* from the firmware to the loaded OS image. Primarily this
	* is expected to be information that cannot be discovered by
	* other means, such as quering the hardware directly.
	*
	* All of the information should be Position Independent Data.
	* That is it should be safe to relocated any of the information
	* without it's meaning/correctnes changing. For table that
	* can reasonably be used on multiple architectures the data
	* size should be fixed. This should ease the transition between
	* 32 bit and 64 bit architectures etc.
	*
	* The completeness test for the information in this table is:
	* - Can all of the hardware be detected?
	* - Are the per motherboard constants available?
	* - Is there enough to allow a kernel to run that was written before
	* a particular motherboard is constructed? (Assuming the kernel
	* has drivers for all of the hardware but it does not have
	* assumptions on how the hardware is connected together).
	*
	* With this test it should be straight forward to determine if a
	* table entry is required or not. This should remove much of the
	* long term compatibility burden as table entries which are
	* irrelevant or have been replaced by better alternatives may be
	* dropped. Of course it is polite and expidite to include extra
	* table entries and be backwards compatible, but it is not required.
	*/

	/* Since coreboot is usually compiled 32bit, gcc will align 64bit
	* types to 32bit boundaries. If the coreboot table is dumped on a
	* 64bit system, a uint64_t would be aligned to 64bit boundaries,
	* breaking the table format.
	*
	* lb_uint64 will keep 64bit coreboot table values aligned to 32bit
	* to ensure compatibility. They can be accessed with the two functions
	* below: unpack_lb64() and pack_lb64()
	*
	* See also: util/lbtdump/lbtdump.c
	*/

	struct lb_uint64 {
	uint32_t lo;
	uint32_t hi;
	};

	static inline uint64_t unpack_lb64(struct lb_uint64 value)
	{
	uint64_t result;
	result = value.hi;
	result = (result << 32) + value.lo;
	return result;
	}

	static inline struct lb_uint64 pack_lb64(uint64_t value)
	{
	struct lb_uint64 result;
	result.lo = (value >> 0) & 0xffffffff;
	result.hi = (value >> 32) & 0xffffffff;
	return result;
	}

	struct lb_header {
	union {
	uint8_t signature[4]; /* LBIO */
	uint32_t signature32;
	};
	uint32_t header_bytes;
	uint32_t header_checksum;
	uint32_t table_bytes;
	uint32_t table_checksum;
	uint32_t table_entries;
	};

	/* Every entry in the boot enviroment list will correspond to a boot
	* info record. Encoding both type and size. The type is obviously
	* so you can tell what it is. The size allows you to skip that
	* boot enviroment record if you don't know what it easy. This allows
	* forward compatibility with records not yet defined.
	*/
	struct lb_record {
	uint32_t tag; /* tag ID */
	uint32_t size; /* size of record (in bytes) */
	};

	#define LB_TAG_UNUSED 0x0000

	#define LB_TAG_MEMORY 0x0001

	struct lb_memory_range {
	struct lb_uint64 start;
	struct lb_uint64 size;
	uint32_t type;
	#define LB_MEM_RAM 1 /* Memory anyone can use */
	#define LB_MEM_RESERVED 2 /* Don't use this memory region */
	#define LB_MEM_TABLE 16 /* Ram configuration tables are kept in */
	};

	struct lb_memory {
	uint32_t tag;
	uint32_t size;
	struct lb_memory_range map[0];
	};

	#define LB_TAG_HWRPB 0x0002
	struct lb_hwrpb {
	uint32_t tag;
	uint32_t size;
	uint64_t hwrpb;
	};

	#define LB_TAG_MAINBOARD 0x0003
	struct lb_mainboard {
	uint32_t tag;
	uint32_t size;
	uint8_t vendor_idx;
	uint8_t part_number_idx;
	uint8_t strings[0];
	};

	#define LB_TAG_VERSION 0x0004
	#define LB_TAG_EXTRA_VERSION 0x0005
	#define LB_TAG_BUILD 0x0006
	#define LB_TAG_COMPILE_TIME 0x0007
	#define LB_TAG_COMPILE_BY 0x0008
	#define LB_TAG_COMPILE_HOST 0x0009
	#define LB_TAG_COMPILE_DOMAIN 0x000a
	#define LB_TAG_COMPILER 0x000b
	#define LB_TAG_LINKER 0x000c
	#define LB_TAG_ASSEMBLER 0x000d
	struct lb_string {
	uint32_t tag;
	uint32_t size;
	uint8_t string[0];
	};
	#define LB_TAG_SERIAL 0x000f
	#define LB_TAG_CONSOLE 0x0010
	#define LB_TAG_FORWARD 0x0011
	struct lb_forward {
	uint32_t tag;
	uint32_t size;
	uint64_t forward;
	};

	/* The following structures are for the cmos definitions table */
	#define LB_TAG_CMOS_OPTION_TABLE 200
	/* cmos header record */
	struct cmos_option_table {
	uint32_t tag; /* CMOS definitions table type */
	uint32_t size; /* size of the entire table */
	uint32_t header_length; /* length of header */
	};

	/* cmos entry record
	This record is variable length. The name field may be
	shorter than CMOS_MAX_NAME_LENGTH. The entry may start
	anywhere in the byte, but can not span bytes unless it
	starts at the beginning of the byte and the length is
	fills complete bytes.
	*/
	#define LB_TAG_OPTION 201
	struct cmos_entries {
	uint32_t tag; /* entry type */
	uint32_t size; /* length of this record */
	uint32_t bit; /* starting bit from start of image */
	uint32_t length; /* length of field in bits */
	uint32_t config; /* e=enumeration, h=hex, r=reserved */
	uint32_t config_id; /* a number linking to an enumeration record */
	#define CMOS_MAX_NAME_LENGTH 32
	uint8_t name[CMOS_MAX_NAME_LENGTH]; /* name of entry in ascii,
	variable length int aligned */
	};

	/* cmos enumerations record
	This record is variable length. The text field may be
	shorter than CMOS_MAX_TEXT_LENGTH.
	*/
	#define LB_TAG_OPTION_ENUM 202
	struct cmos_enums {
	uint32_t tag; /* enumeration type */
	uint32_t size; /* length of this record */
	uint32_t config_id; /* a number identifying the config id */
	uint32_t value; /* the value associated with the text */
	#define CMOS_MAX_TEXT_LENGTH 32
	uint8_t text[CMOS_MAX_TEXT_LENGTH]; /* enum description in ascii,
	variable length int aligned */
	};

	/* cmos defaults record
	This record contains default settings for the cmos ram.
	*/
	#define LB_TAG_OPTION_DEFAULTS 203
	struct cmos_defaults {
	uint32_t tag; /* default type */
	uint32_t size; /* length of this record */
	uint32_t name_length; /* length of the following name field */
	uint8_t name[CMOS_MAX_NAME_LENGTH]; /* name identifying the default */
	#define CMOS_IMAGE_BUFFER_SIZE 128
	uint8_t default_set[CMOS_IMAGE_BUFFER_SIZE]; /* default settings */
	};

	#define LB_TAG_OPTION_CHECKSUM 204
	struct cmos_checksum {
	uint32_t tag;
	uint32_t size;
	/* In practice everything is byte aligned, but things are measured
	* in bits to be consistent.
	*/
	uint32_t range_start; /* First bit that is checksummed (byte aligned) */
	uint32_t range_end; /* Last bit that is checksummed (byte aligned) */
	uint32_t location; /* First bit of the checksum (byte aligned) */
	uint32_t type; /* Checksum algorithm that is used */
	#define CHECKSUM_NONE 0
	#define CHECKSUM_PCBIOS 1
	};

	#endif /* COREBOOT_TABLES_H */