util/nvramtool/accessors/layout-bin.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /*****************************************************************************\
  * lbtable.c
  *****************************************************************************
  *  Copyright (C) 2012, Vikram Narayanan
  *  	Unified build_opt_tbl and nvramtool
  *  	build_opt_tbl.c
  *  	Copyright (C) 2003 Eric Biederman (ebiederm@xmission.com)
  *  	Copyright (C) 2007-2010 coresystems GmbH
  *
  *  Copyright (C) 2002-2005 The Regents of the University of California.
  *  Produced at the Lawrence Livermore National Laboratory.
  *  Written by Dave Peterson <dsp@llnl.gov> <dave_peterson@pobox.com>
  *  and Stefan Reinauer <stepan@openbios.org>.
  *  UCRL-CODE-2003-012
  *  All rights reserved.
  *
  *  This file is part of nvramtool, a utility for reading/writing coreboot
  *  parameters and displaying information from the coreboot table.
  *  For details, see http://coreboot.org/nvramtool.
  *
  *  Please also read the file DISCLAIMER which is included in this software
  *  distribution.
  *
  *  This program 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) version 2, dated June 1991.
  *
  *  This program 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 terms and
  *  conditions of the GNU General Public License for more details.
  *
  *  You should have received a copy of the GNU General Public License along
  *  with this program; if not, write to the Free Software Foundation, Inc.,
  *  51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 \*****************************************************************************/

 #include <string.h>
 #ifndef __MINGW32__
 #include <sys/mman.h>
 #endif
 #include "common.h"
 #include "coreboot_tables.h"
 #include "ip_checksum.h"
 #include "lbtable.h"
 #include "layout.h"
 #include "cmos_lowlevel.h"
 #include "hexdump.h"
 #include "cbfs.h"
 #include "layout-text.h"

 static void process_cmos_table(void);
 static void get_cmos_checksum_info(void);
 static void try_convert_checksum_layout(cmos_checksum_layout_t * layout);
 static void try_add_cmos_table_enum(cmos_enum_t * cmos_enum);
 static void try_add_cmos_table_entry(cmos_entry_t * cmos_entry);
 static const struct cmos_entries *first_cmos_table_entry(void);
 static const struct cmos_entries *next_cmos_table_entry(const struct
 							cmos_entries *last);
 static const struct cmos_enums *first_cmos_table_enum(void);
 static const struct cmos_enums *next_cmos_table_enum
     (const struct cmos_enums *last);
 static const struct lb_record *first_cmos_rec(uint32_t tag);
 static const struct lb_record *next_cmos_rec(const struct lb_record *last,
 					     uint32_t tag);

 /* The CMOS option table is located within the coreboot table.  It tells us
  * where the CMOS parameters are located in the nonvolatile RAM.
  */
 static const struct cmos_option_table *cmos_table = NULL;

 #define ROUNDUP4(x)	(x += (4 - (x % 4)))

 void process_layout(void)
 {
 	if ((cmos_table) == NULL) {
 		fprintf(stderr,
 			"%s: CMOS option table not found in coreboot table.  "
 			"Apparently, the coreboot installed on this system was "
 			"built without specifying CONFIG_HAVE_OPTION_TABLE.\n",
 			prog_name);
 		exit(1);
 	}

 	process_cmos_table();
 	get_cmos_checksum_info();
 }

 void get_layout_from_cbfs_file(void)
 {
 	uint32_t len;
 	cmos_table = cbfs_find_file("cmos_layout.bin", CBFS_COMPONENT_CMOS_LAYOUT, &len);
 	process_layout();
 }

 int write_cmos_layout_bin(FILE *f)
 {
 	const cmos_entry_t *cmos_entry;
 	const cmos_enum_t *cmos_enum;
 	cmos_checksum_layout_t layout;
 	struct cmos_option_table table;
 	struct cmos_entries entry;
 	struct cmos_enums cenum;
 	struct cmos_checksum csum;
 	size_t sum = 0;
 	int len;

 	for (cmos_entry = first_cmos_entry(); cmos_entry != NULL;
 			cmos_entry = next_cmos_entry(cmos_entry)) {

 		if (cmos_entry == first_cmos_entry()) {
 			sum += sizeof(table);
 			table.header_length = sizeof(table);
 			table.tag = LB_TAG_CMOS_OPTION_TABLE;

 			if (fwrite((char *)&table, sizeof(table), 1, f) != 1) {
 				perror("Error writing image file");
 				goto err;
 			}
 		}

 		memset(&entry, 0, sizeof(entry));
 		entry.tag = LB_TAG_OPTION;
 		entry.config = cmos_entry->config;
 		entry.config_id = (uint32_t)cmos_entry->config_id;
 		entry.bit = cmos_entry->bit;
 		entry.length = cmos_entry->length;

 		if (!is_ident((char *)cmos_entry->name)) {
 			fprintf(stderr,
 				"Error - Name %s is an invalid identifier\n",
 				cmos_entry->name);
 			goto err;
 		}

 		memcpy(entry.name, cmos_entry->name, strlen(cmos_entry->name));
 		entry.name[strlen(cmos_entry->name)] = '\0';
 		len = strlen(cmos_entry->name) + 1;

 		if (len % 4)
 			ROUNDUP4(len);

 		entry.size = sizeof(entry) - CMOS_MAX_NAME_LENGTH + len;
 		sum += entry.size;
 		if (fwrite((char *)&entry, entry.size, 1, f) != 1) {
 			perror("Error writing image file");
 			goto err;
 		}
 	}

 	for (cmos_enum = first_cmos_enum();
 			cmos_enum != NULL; cmos_enum = next_cmos_enum(cmos_enum)) {
 		memset(&cenum, 0, sizeof(cenum));
 		cenum.tag = LB_TAG_OPTION_ENUM;
 		memcpy(cenum.text, cmos_enum->text, strlen(cmos_enum->text));
 		cenum.text[strlen(cmos_enum->text)] = '\0';
 		len = strlen((char *)cenum.text) + 1;

 		if (len % 4)
 			ROUNDUP4(len);

 		cenum.config_id = cmos_enum->config_id;
 		cenum.value = cmos_enum->value;
 		cenum.size = sizeof(cenum) - CMOS_MAX_TEXT_LENGTH + len;
 		sum += cenum.size;
 		if (fwrite((char *)&cenum, cenum.size, 1, f) != 1) {
 			perror("Error writing image file");
 			goto err;
 		}
 	}

 	layout.summed_area_start = cmos_checksum_start;
 	layout.summed_area_end = cmos_checksum_end;
 	layout.checksum_at = cmos_checksum_index;
 	checksum_layout_to_bits(&layout);

 	csum.tag = LB_TAG_OPTION_CHECKSUM;
 	csum.size = sizeof(csum);
 	csum.range_start = layout.summed_area_start;
 	csum.range_end = layout.summed_area_end;
 	csum.location = layout.checksum_at;
 	csum.type = CHECKSUM_PCBIOS;
 	sum += csum.size;

 	if (fwrite((char *)&csum, csum.size, 1, f) != 1) {
 		perror("Error writing image file");
 		goto err;
 	}

 	if (fseek(f, sizeof(table.tag), SEEK_SET) != 0) {
 		perror("Error while seeking");
 		goto err;
 	}

 	if (fwrite((char *)&sum, sizeof(table.tag), 1, f) != 1) {
 		perror("Error writing image file");
 		goto err;
 	}
 	return sum;

 err:
 	fclose(f);
 	exit(1);
 }

 void write_cmos_output_bin(const char *binary_filename)
 {
 	FILE *fp;

 	if ((fp = fopen(binary_filename, "wb")) == NULL) {
 		fprintf(stderr,
 			"%s: Can not open file %s for writing: "
 			"%s\n", prog_name, binary_filename, strerror(errno));
 		exit(1);
 	}
 	write_cmos_layout_bin(fp);
 	fclose(fp);
 }

 /****************************************************************************
  * get_layout_from_cmos_table
  *
  * Find the CMOS table which is stored within the coreboot table and set the
  * global variable cmos_table to point to it.
  ****************************************************************************/
 void get_layout_from_cmos_table(void)
 {
 	get_lbtable();
 	cmos_table = (const struct cmos_option_table *)
 	    find_lbrec(LB_TAG_CMOS_OPTION_TABLE);
 	process_layout();
 }

 /****************************************************************************
  * process_cmos_table
  *
  * Extract layout information from the CMOS option table and store it in our
  * internal repository.
  ****************************************************************************/
 static void process_cmos_table(void)
 {
 	const struct cmos_enums *p;
 	const struct cmos_entries *q;
 	cmos_enum_t cmos_enum;
 	cmos_entry_t cmos_entry;

 	/* First add the enums. */
 	for (p = first_cmos_table_enum(); p != NULL;
 	     p = next_cmos_table_enum(p)) {
 		cmos_enum.config_id = p->config_id;
 		cmos_enum.value = p->value;
 		strncpy(cmos_enum.text, (char *)p->text, CMOS_MAX_TEXT_LENGTH);
 		cmos_enum.text[CMOS_MAX_TEXT_LENGTH] = '\0';
 		try_add_cmos_table_enum(&cmos_enum);
 	}

 	/* Now add the entries.  We must add the entries after the enums because
 	 * the entries are sanity checked against the enums as they are added.
 	 */
 	for (q = first_cmos_table_entry(); q != NULL;
 	     q = next_cmos_table_entry(q)) {
 		cmos_entry.bit = q->bit;
 		cmos_entry.length = q->length;

 		switch (q->config) {
 		case 'e':
 			cmos_entry.config = CMOS_ENTRY_ENUM;
 			break;

 		case 'h':
 			cmos_entry.config = CMOS_ENTRY_HEX;
 			break;

 		case 'r':
 			cmos_entry.config = CMOS_ENTRY_RESERVED;
 			break;

 		case 's':
 			cmos_entry.config = CMOS_ENTRY_STRING;
 			break;

 		default:
 			fprintf(stderr,
 				"%s: Entry in CMOS option table has unknown config "
 				"value.\n", prog_name);
 			exit(1);
 		}

 		cmos_entry.config_id = q->config_id;
 		strncpy(cmos_entry.name, (char *)q->name, CMOS_MAX_NAME_LENGTH);
 		cmos_entry.name[CMOS_MAX_NAME_LENGTH] = '\0';
 		try_add_cmos_table_entry(&cmos_entry);
 	}
 }

 /****************************************************************************
  * get_cmos_checksum_info
  *
  * Get layout information for CMOS checksum.
  ****************************************************************************/
 static void get_cmos_checksum_info(void)
 {
 	const cmos_entry_t *e;
 	struct cmos_checksum *checksum;
 	cmos_checksum_layout_t layout;
 	unsigned index, index2;

 	checksum = (struct cmos_checksum *)next_cmos_rec((const struct lb_record *)first_cmos_table_enum(), LB_TAG_OPTION_CHECKSUM);

 	if (checksum != NULL) {	/* We are lucky.  The coreboot table hints us to the checksum.
 				 * We might have to check the type field here though.
 				 */
 		layout.summed_area_start = checksum->range_start;
 		layout.summed_area_end = checksum->range_end;
 		layout.checksum_at = checksum->location;
 		try_convert_checksum_layout(&layout);
 		cmos_checksum_start = layout.summed_area_start;
 		cmos_checksum_end = layout.summed_area_end;
 		cmos_checksum_index = layout.checksum_at;
 		return;
 	}

 	if ((e = find_cmos_entry(checksum_param_name)) == NULL)
 		return;

 	/* If we get here, we are unlucky.  The CMOS option table contains the
 	 * location of the CMOS checksum.  However, there is no information
 	 * regarding which bytes of the CMOS area the checksum is computed over.
 	 * Thus we have to hope our presets will be fine.
 	 */

 	if (e->bit % 8) {
 		fprintf(stderr,
 			"%s: Error: CMOS checksum is not byte-aligned.\n",
 			prog_name);
 		exit(1);
 	}

 	index = e->bit / 8;
 	index2 = index + 1;	/* The CMOS checksum occupies 16 bits. */

 	if (verify_cmos_byte_index(index) || verify_cmos_byte_index(index2)) {
 		fprintf(stderr,
 			"%s: Error: CMOS checksum location out of range.\n",
 			prog_name);
 		exit(1);
 	}

 	if (((index >= cmos_checksum_start) && (index <= cmos_checksum_end)) ||
 	    (((index2) >= cmos_checksum_start)
 	     && ((index2) <= cmos_checksum_end))) {
 		fprintf(stderr,
 			"%s: Error: CMOS checksum overlaps checksummed area.\n",
 			prog_name);
 		exit(1);
 	}

 	cmos_checksum_index = index;
 }

 /****************************************************************************
  * try_convert_checksum_layout
  *
  * Perform sanity checking on CMOS checksum layout information and attempt to
  * convert information from bit positions to byte positions.  Return OK on
  * success or an error code on failure.
  ****************************************************************************/
 static void try_convert_checksum_layout(cmos_checksum_layout_t * layout)
 {
 	switch (checksum_layout_to_bytes(layout)) {
 	case OK:
 		return;

 	case LAYOUT_SUMMED_AREA_START_NOT_ALIGNED:
 		fprintf(stderr,
 			"%s: CMOS checksummed area start is not byte-aligned.\n",
 			prog_name);
 		break;

 	case LAYOUT_SUMMED_AREA_END_NOT_ALIGNED:
 		fprintf(stderr,
 			"%s: CMOS checksummed area end is not byte-aligned.\n",
 			prog_name);
 		break;

 	case LAYOUT_CHECKSUM_LOCATION_NOT_ALIGNED:
 		fprintf(stderr,
 			"%s: CMOS checksum location is not byte-aligned.\n",
 			prog_name);
 		break;

 	case LAYOUT_INVALID_SUMMED_AREA:
 		fprintf(stderr,
 			"%s: CMOS checksummed area end must be greater than "
 			"CMOS checksummed area start.\n", prog_name);
 		break;

 	case LAYOUT_CHECKSUM_OVERLAPS_SUMMED_AREA:
 		fprintf(stderr,
 			"%s: CMOS checksum overlaps checksummed area.\n",
 			prog_name);
 		break;

 	case LAYOUT_SUMMED_AREA_OUT_OF_RANGE:
 		fprintf(stderr,
 			"%s: CMOS checksummed area out of range.\n", prog_name);
 		break;

 	case LAYOUT_CHECKSUM_LOCATION_OUT_OF_RANGE:
 		fprintf(stderr,
 			"%s: CMOS checksum location out of range.\n",
 			prog_name);
 		break;

 	default:
 		BUG();
 	}

 	exit(1);
 }

 /****************************************************************************
  * try_add_cmos_table_enum
  *
  * Attempt to add a CMOS enum to our internal repository.  Exit with an error
  * message on failure.
  ****************************************************************************/
 static void try_add_cmos_table_enum(cmos_enum_t * cmos_enum)
 {
 	switch (add_cmos_enum(cmos_enum)) {
 	case OK:
 		return;

 	case LAYOUT_DUPLICATE_ENUM:
 		fprintf(stderr, "%s: Duplicate enum %s found in CMOS option "
 			"table.\n", prog_name, cmos_enum->text);
 		break;

 	default:
 		BUG();
 	}

 	exit(1);
 }

 /****************************************************************************
  * try_add_cmos_table_entry
  *
  * Attempt to add a CMOS entry to our internal repository.  Exit with an
  * error message on failure.
  ****************************************************************************/
 static void try_add_cmos_table_entry(cmos_entry_t * cmos_entry)
 {
 	const cmos_entry_t *conflict;

 	switch (add_cmos_entry(cmos_entry, &conflict)) {
 	case OK:
 		return;

 	case CMOS_AREA_OUT_OF_RANGE:
 		fprintf(stderr,
 			"%s: Bad CMOS option layout in CMOS option table entry "
 			"%s.\n", prog_name, cmos_entry->name);
 		break;

 	case CMOS_AREA_TOO_WIDE:
 		fprintf(stderr,
 			"%s: Area too wide for CMOS option table entry %s.\n",
 			prog_name, cmos_entry->name);
 		break;

 	case LAYOUT_ENTRY_OVERLAP:
 		fprintf(stderr,
 			"%s: CMOS option table entries %s and %s have overlapping "
 			"layouts.\n", prog_name, cmos_entry->name,
 			conflict->name);
 		break;

 	case LAYOUT_ENTRY_BAD_LENGTH:
 		/* Silently ignore entries with zero length.  Although this should
 		 * never happen in practice, we should handle the case in a
 		 * reasonable manner just to be safe.
 		 */
 		return;

 	default:
 		BUG();
 	}

 	exit(1);
 }

 /****************************************************************************
  * first_cmos_table_entry
  *
  * Return a pointer to the first entry in the CMOS table that represents a
  * CMOS parameter.  Return NULL if CMOS table is empty.
  ****************************************************************************/
 static const struct cmos_entries *first_cmos_table_entry(void)
 {
 	return (const struct cmos_entries *)first_cmos_rec(LB_TAG_OPTION);
 }

 /****************************************************************************
  * next_cmos_table_entry
  *
  * Return a pointer to the next entry after 'last' in the CMOS table that
  * represents a CMOS parameter.  Return NULL if there are no more parameters.
  ****************************************************************************/
 static const struct cmos_entries *next_cmos_table_entry(const struct
 							cmos_entries *last)
 {
 	return (const struct cmos_entries *)
 	    next_cmos_rec((const struct lb_record *)last, LB_TAG_OPTION);
 }

 /****************************************************************************
  * first_cmos_table_enum
  *
  * Return a pointer to the first entry in the CMOS table that represents a
  * possible CMOS parameter value.  Return NULL if the table does not contain
  * any such entries.
  ****************************************************************************/
 static const struct cmos_enums *first_cmos_table_enum(void)
 {
 	return (const struct cmos_enums *)first_cmos_rec(LB_TAG_OPTION_ENUM);
 }

 /****************************************************************************
  * next_cmos_table_enum
  *
  * Return a pointer to the next entry after 'last' in the CMOS table that
  * represents a possible CMOS parameter value.  Return NULL if there are no
  * more parameter values.
  ****************************************************************************/
 static const struct cmos_enums *next_cmos_table_enum
     (const struct cmos_enums *last) {
 	return (const struct cmos_enums *)
 	    next_cmos_rec((const struct lb_record *)last, LB_TAG_OPTION_ENUM);
 }

 /****************************************************************************
  * first_cmos_rec
  *
  * Return a pointer to the first entry in the CMOS table whose type matches
  * 'tag'.  Return NULL if CMOS table contains no such entry.
  *
  * Possible values for 'tag' are as follows:
  *
  *     LB_TAG_OPTION:      The entry represents a CMOS parameter.
  *     LB_TAG_OPTION_ENUM: The entry represents a possible value for a CMOS
  *                         parameter of type 'enum'.
  *
  * The CMOS table tells us where in the nonvolatile RAM to look for CMOS
  * parameter values and specifies their types as 'enum', 'hex', or
  * 'reserved'.
  ****************************************************************************/
 static const struct lb_record *first_cmos_rec(uint32_t tag)
 {
 	const char *p;
 	uint32_t bytes_processed, bytes_for_entries;
 	const struct lb_record *lbrec;

 	p = ((const char *)cmos_table) + cmos_table->header_length;
 	bytes_for_entries = cmos_table->size - cmos_table->header_length;

 	for (bytes_processed = 0;
 	     bytes_processed < bytes_for_entries;
 	     bytes_processed += lbrec->size) {
 		lbrec = (const struct lb_record *)&p[bytes_processed];

 		if (lbrec->tag == tag)
 			return lbrec;
 	}

 	return NULL;
 }

 /****************************************************************************
  * next_cmos_rec
  *
  * Return a pointer to the next entry after 'last' in the CMOS table whose
  * type matches 'tag'.  Return NULL if the table contains no more entries of
  * this type.
  ****************************************************************************/
 static const struct lb_record *next_cmos_rec(const struct lb_record *last,
 					     uint32_t tag)
 {
 	const char *p;
 	uint32_t bytes_processed, bytes_for_entries, last_offset;
 	const struct lb_record *lbrec;

 	p = ((const char *)cmos_table) + cmos_table->header_length;
 	bytes_for_entries = cmos_table->size - cmos_table->header_length;
 	last_offset = ((const char *)last) - p;

 	for (bytes_processed = last_offset + last->size;
 	     bytes_processed < bytes_for_entries;
 	     bytes_processed += lbrec->size) {
 		lbrec = (const struct lb_record *)&p[bytes_processed];

 		if (lbrec->tag == tag)
 			return lbrec;
 	}

 	return NULL;
 }
	/*****************************************************************************\
	* lbtable.c
	*****************************************************************************
	* Copyright (C) 2012, Vikram Narayanan
	* Unified build_opt_tbl and nvramtool
	* build_opt_tbl.c
	* Copyright (C) 2003 Eric Biederman (ebiederm@xmission.com)
	* Copyright (C) 2007-2010 coresystems GmbH
	*
	* Copyright (C) 2002-2005 The Regents of the University of California.
	* Produced at the Lawrence Livermore National Laboratory.
	* Written by Dave Peterson <dsp@llnl.gov> <dave_peterson@pobox.com>
	* and Stefan Reinauer <stepan@openbios.org>.
	* UCRL-CODE-2003-012
	* All rights reserved.
	*
	* This file is part of nvramtool, a utility for reading/writing coreboot
	* parameters and displaying information from the coreboot table.
	* For details, see http://coreboot.org/nvramtool.
	*
	* Please also read the file DISCLAIMER which is included in this software
	* distribution.
	*
	* This program 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) version 2, dated June 1991.
	*
	* This program 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 terms and
	* conditions of the GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License along
	* with this program; if not, write to the Free Software Foundation, Inc.,
	* 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	\*****************************************************************************/

	#include <string.h>
	#ifndef __MINGW32__
	#include <sys/mman.h>
	#endif
	#include "common.h"
	#include "coreboot_tables.h"
	#include "ip_checksum.h"
	#include "lbtable.h"
	#include "layout.h"
	#include "cmos_lowlevel.h"
	#include "hexdump.h"
	#include "cbfs.h"
	#include "layout-text.h"

	static void process_cmos_table(void);
	static void get_cmos_checksum_info(void);
	static void try_convert_checksum_layout(cmos_checksum_layout_t * layout);
	static void try_add_cmos_table_enum(cmos_enum_t * cmos_enum);
	static void try_add_cmos_table_entry(cmos_entry_t * cmos_entry);
	static const struct cmos_entries *first_cmos_table_entry(void);
	static const struct cmos_entries *next_cmos_table_entry(const struct
	cmos_entries *last);
	static const struct cmos_enums *first_cmos_table_enum(void);
	static const struct cmos_enums *next_cmos_table_enum
	(const struct cmos_enums *last);
	static const struct lb_record *first_cmos_rec(uint32_t tag);
	static const struct lb_record next_cmos_rec(const struct lb_record last,
	uint32_t tag);

	/* The CMOS option table is located within the coreboot table. It tells us
	* where the CMOS parameters are located in the nonvolatile RAM.
	*/
	static const struct cmos_option_table *cmos_table = NULL;

	#define ROUNDUP4(x) (x += (4 - (x % 4)))

	void process_layout(void)
	{
	if ((cmos_table) == NULL) {
	fprintf(stderr,
	"%s: CMOS option table not found in coreboot table. "
	"Apparently, the coreboot installed on this system was "
	"built without specifying CONFIG_HAVE_OPTION_TABLE.\n",
	prog_name);
	exit(1);
	}

	process_cmos_table();
	get_cmos_checksum_info();
	}

	void get_layout_from_cbfs_file(void)
	{
	uint32_t len;
	cmos_table = cbfs_find_file("cmos_layout.bin", CBFS_COMPONENT_CMOS_LAYOUT, &len);
	process_layout();
	}

	int write_cmos_layout_bin(FILE *f)
	{
	const cmos_entry_t *cmos_entry;
	const cmos_enum_t *cmos_enum;
	cmos_checksum_layout_t layout;
	struct cmos_option_table table;
	struct cmos_entries entry;
	struct cmos_enums cenum;
	struct cmos_checksum csum;
	size_t sum = 0;
	int len;

	for (cmos_entry = first_cmos_entry(); cmos_entry != NULL;
	cmos_entry = next_cmos_entry(cmos_entry)) {

	if (cmos_entry == first_cmos_entry()) {
	sum += sizeof(table);
	table.header_length = sizeof(table);
	table.tag = LB_TAG_CMOS_OPTION_TABLE;

	if (fwrite((char *)&table, sizeof(table), 1, f) != 1) {
	perror("Error writing image file");
	goto err;
	}
	}

	memset(&entry, 0, sizeof(entry));
	entry.tag = LB_TAG_OPTION;
	entry.config = cmos_entry->config;
	entry.config_id = (uint32_t)cmos_entry->config_id;
	entry.bit = cmos_entry->bit;
	entry.length = cmos_entry->length;

	if (!is_ident((char *)cmos_entry->name)) {
	fprintf(stderr,
	"Error - Name %s is an invalid identifier\n",
	cmos_entry->name);
	goto err;
	}

	memcpy(entry.name, cmos_entry->name, strlen(cmos_entry->name));
	entry.name[strlen(cmos_entry->name)] = '\0';
	len = strlen(cmos_entry->name) + 1;

	if (len % 4)
	ROUNDUP4(len);

	entry.size = sizeof(entry) - CMOS_MAX_NAME_LENGTH + len;
	sum += entry.size;
	if (fwrite((char *)&entry, entry.size, 1, f) != 1) {
	perror("Error writing image file");
	goto err;
	}
	}

	for (cmos_enum = first_cmos_enum();
	cmos_enum != NULL; cmos_enum = next_cmos_enum(cmos_enum)) {
	memset(&cenum, 0, sizeof(cenum));
	cenum.tag = LB_TAG_OPTION_ENUM;
	memcpy(cenum.text, cmos_enum->text, strlen(cmos_enum->text));
	cenum.text[strlen(cmos_enum->text)] = '\0';
	len = strlen((char *)cenum.text) + 1;

	if (len % 4)
	ROUNDUP4(len);

	cenum.config_id = cmos_enum->config_id;
	cenum.value = cmos_enum->value;
	cenum.size = sizeof(cenum) - CMOS_MAX_TEXT_LENGTH + len;
	sum += cenum.size;
	if (fwrite((char *)&cenum, cenum.size, 1, f) != 1) {
	perror("Error writing image file");
	goto err;
	}
	}

	layout.summed_area_start = cmos_checksum_start;
	layout.summed_area_end = cmos_checksum_end;
	layout.checksum_at = cmos_checksum_index;
	checksum_layout_to_bits(&layout);

	csum.tag = LB_TAG_OPTION_CHECKSUM;
	csum.size = sizeof(csum);
	csum.range_start = layout.summed_area_start;
	csum.range_end = layout.summed_area_end;
	csum.location = layout.checksum_at;
	csum.type = CHECKSUM_PCBIOS;
	sum += csum.size;

	if (fwrite((char *)&csum, csum.size, 1, f) != 1) {
	perror("Error writing image file");
	goto err;
	}

	if (fseek(f, sizeof(table.tag), SEEK_SET) != 0) {
	perror("Error while seeking");
	goto err;
	}

	if (fwrite((char *)&sum, sizeof(table.tag), 1, f) != 1) {
	perror("Error writing image file");
	goto err;
	}
	return sum;

	err:
	fclose(f);
	exit(1);
	}

	void write_cmos_output_bin(const char *binary_filename)
	{
	FILE *fp;

	if ((fp = fopen(binary_filename, "wb")) == NULL) {
	fprintf(stderr,
	"%s: Can not open file %s for writing: "
	"%s\n", prog_name, binary_filename, strerror(errno));
	exit(1);
	}
	write_cmos_layout_bin(fp);
	fclose(fp);
	}

	/****************************************************************************
	* get_layout_from_cmos_table
	*
	* Find the CMOS table which is stored within the coreboot table and set the
	* global variable cmos_table to point to it.
	****************************************************************************/
	void get_layout_from_cmos_table(void)
	{
	get_lbtable();
	cmos_table = (const struct cmos_option_table *)
	find_lbrec(LB_TAG_CMOS_OPTION_TABLE);
	process_layout();
	}

	/****************************************************************************
	* process_cmos_table
	*
	* Extract layout information from the CMOS option table and store it in our
	* internal repository.
	****************************************************************************/
	static void process_cmos_table(void)
	{
	const struct cmos_enums *p;
	const struct cmos_entries *q;
	cmos_enum_t cmos_enum;
	cmos_entry_t cmos_entry;

	/* First add the enums. */
	for (p = first_cmos_table_enum(); p != NULL;
	p = next_cmos_table_enum(p)) {
	cmos_enum.config_id = p->config_id;
	cmos_enum.value = p->value;
	strncpy(cmos_enum.text, (char *)p->text, CMOS_MAX_TEXT_LENGTH);
	cmos_enum.text[CMOS_MAX_TEXT_LENGTH] = '\0';
	try_add_cmos_table_enum(&cmos_enum);
	}

	/* Now add the entries. We must add the entries after the enums because
	* the entries are sanity checked against the enums as they are added.
	*/
	for (q = first_cmos_table_entry(); q != NULL;
	q = next_cmos_table_entry(q)) {
	cmos_entry.bit = q->bit;
	cmos_entry.length = q->length;

	switch (q->config) {
	case 'e':
	cmos_entry.config = CMOS_ENTRY_ENUM;
	break;

	case 'h':
	cmos_entry.config = CMOS_ENTRY_HEX;
	break;

	case 'r':
	cmos_entry.config = CMOS_ENTRY_RESERVED;
	break;

	case 's':
	cmos_entry.config = CMOS_ENTRY_STRING;
	break;

	default:
	fprintf(stderr,
	"%s: Entry in CMOS option table has unknown config "
	"value.\n", prog_name);
	exit(1);
	}

	cmos_entry.config_id = q->config_id;
	strncpy(cmos_entry.name, (char *)q->name, CMOS_MAX_NAME_LENGTH);
	cmos_entry.name[CMOS_MAX_NAME_LENGTH] = '\0';
	try_add_cmos_table_entry(&cmos_entry);
	}
	}

	/****************************************************************************
	* get_cmos_checksum_info
	*
	* Get layout information for CMOS checksum.
	****************************************************************************/
	static void get_cmos_checksum_info(void)
	{
	const cmos_entry_t *e;
	struct cmos_checksum *checksum;
	cmos_checksum_layout_t layout;
	unsigned index, index2;

	checksum = (struct cmos_checksum )next_cmos_rec((const struct lb_record )first_cmos_table_enum(), LB_TAG_OPTION_CHECKSUM);

	if (checksum != NULL) { /* We are lucky. The coreboot table hints us to the checksum.
	* We might have to check the type field here though.
	*/
	layout.summed_area_start = checksum->range_start;
	layout.summed_area_end = checksum->range_end;
	layout.checksum_at = checksum->location;
	try_convert_checksum_layout(&layout);
	cmos_checksum_start = layout.summed_area_start;
	cmos_checksum_end = layout.summed_area_end;
	cmos_checksum_index = layout.checksum_at;
	return;
	}

	if ((e = find_cmos_entry(checksum_param_name)) == NULL)
	return;

	/* If we get here, we are unlucky. The CMOS option table contains the
	* location of the CMOS checksum. However, there is no information
	* regarding which bytes of the CMOS area the checksum is computed over.
	* Thus we have to hope our presets will be fine.
	*/

	if (e->bit % 8) {
	fprintf(stderr,
	"%s: Error: CMOS checksum is not byte-aligned.\n",
	prog_name);
	exit(1);
	}

	index = e->bit / 8;
	index2 = index + 1; /* The CMOS checksum occupies 16 bits. */

	if (verify_cmos_byte_index(index) \|\| verify_cmos_byte_index(index2)) {
	fprintf(stderr,
	"%s: Error: CMOS checksum location out of range.\n",
	prog_name);
	exit(1);
	}

	if (((index >= cmos_checksum_start) && (index <= cmos_checksum_end)) \|\|
	(((index2) >= cmos_checksum_start)
	&& ((index2) <= cmos_checksum_end))) {
	fprintf(stderr,
	"%s: Error: CMOS checksum overlaps checksummed area.\n",
	prog_name);
	exit(1);
	}

	cmos_checksum_index = index;
	}

	/****************************************************************************
	* try_convert_checksum_layout
	*
	* Perform sanity checking on CMOS checksum layout information and attempt to
	* convert information from bit positions to byte positions. Return OK on
	* success or an error code on failure.
	****************************************************************************/
	static void try_convert_checksum_layout(cmos_checksum_layout_t * layout)
	{
	switch (checksum_layout_to_bytes(layout)) {
	case OK:
	return;

	case LAYOUT_SUMMED_AREA_START_NOT_ALIGNED:
	fprintf(stderr,
	"%s: CMOS checksummed area start is not byte-aligned.\n",
	prog_name);
	break;

	case LAYOUT_SUMMED_AREA_END_NOT_ALIGNED:
	fprintf(stderr,
	"%s: CMOS checksummed area end is not byte-aligned.\n",
	prog_name);
	break;

	case LAYOUT_CHECKSUM_LOCATION_NOT_ALIGNED:
	fprintf(stderr,
	"%s: CMOS checksum location is not byte-aligned.\n",
	prog_name);
	break;

	case LAYOUT_INVALID_SUMMED_AREA:
	fprintf(stderr,
	"%s: CMOS checksummed area end must be greater than "
	"CMOS checksummed area start.\n", prog_name);
	break;

	case LAYOUT_CHECKSUM_OVERLAPS_SUMMED_AREA:
	fprintf(stderr,
	"%s: CMOS checksum overlaps checksummed area.\n",
	prog_name);
	break;

	case LAYOUT_SUMMED_AREA_OUT_OF_RANGE:
	fprintf(stderr,
	"%s: CMOS checksummed area out of range.\n", prog_name);
	break;

	case LAYOUT_CHECKSUM_LOCATION_OUT_OF_RANGE:
	fprintf(stderr,
	"%s: CMOS checksum location out of range.\n",
	prog_name);
	break;

	default:
	BUG();
	}

	exit(1);
	}

	/****************************************************************************
	* try_add_cmos_table_enum
	*
	* Attempt to add a CMOS enum to our internal repository. Exit with an error
	* message on failure.
	****************************************************************************/
	static void try_add_cmos_table_enum(cmos_enum_t * cmos_enum)
	{
	switch (add_cmos_enum(cmos_enum)) {
	case OK:
	return;

	case LAYOUT_DUPLICATE_ENUM:
	fprintf(stderr, "%s: Duplicate enum %s found in CMOS option "
	"table.\n", prog_name, cmos_enum->text);
	break;

	default:
	BUG();
	}

	exit(1);
	}

	/****************************************************************************
	* try_add_cmos_table_entry
	*
	* Attempt to add a CMOS entry to our internal repository. Exit with an
	* error message on failure.
	****************************************************************************/
	static void try_add_cmos_table_entry(cmos_entry_t * cmos_entry)
	{
	const cmos_entry_t *conflict;

	switch (add_cmos_entry(cmos_entry, &conflict)) {
	case OK:
	return;

	case CMOS_AREA_OUT_OF_RANGE:
	fprintf(stderr,
	"%s: Bad CMOS option layout in CMOS option table entry "
	"%s.\n", prog_name, cmos_entry->name);
	break;

	case CMOS_AREA_TOO_WIDE:
	fprintf(stderr,
	"%s: Area too wide for CMOS option table entry %s.\n",
	prog_name, cmos_entry->name);
	break;

	case LAYOUT_ENTRY_OVERLAP:
	fprintf(stderr,
	"%s: CMOS option table entries %s and %s have overlapping "
	"layouts.\n", prog_name, cmos_entry->name,
	conflict->name);
	break;

	case LAYOUT_ENTRY_BAD_LENGTH:
	/* Silently ignore entries with zero length. Although this should
	* never happen in practice, we should handle the case in a
	* reasonable manner just to be safe.
	*/
	return;

	default:
	BUG();
	}

	exit(1);
	}

	/****************************************************************************
	* first_cmos_table_entry
	*
	* Return a pointer to the first entry in the CMOS table that represents a
	* CMOS parameter. Return NULL if CMOS table is empty.
	****************************************************************************/
	static const struct cmos_entries *first_cmos_table_entry(void)
	{
	return (const struct cmos_entries *)first_cmos_rec(LB_TAG_OPTION);
	}

	/****************************************************************************
	* next_cmos_table_entry
	*
	* Return a pointer to the next entry after 'last' in the CMOS table that
	* represents a CMOS parameter. Return NULL if there are no more parameters.
	****************************************************************************/
	static const struct cmos_entries *next_cmos_table_entry(const struct
	cmos_entries *last)
	{
	return (const struct cmos_entries *)
	next_cmos_rec((const struct lb_record *)last, LB_TAG_OPTION);
	}

	/****************************************************************************
	* first_cmos_table_enum
	*
	* Return a pointer to the first entry in the CMOS table that represents a
	* possible CMOS parameter value. Return NULL if the table does not contain
	* any such entries.
	****************************************************************************/
	static const struct cmos_enums *first_cmos_table_enum(void)
	{
	return (const struct cmos_enums *)first_cmos_rec(LB_TAG_OPTION_ENUM);
	}

	/****************************************************************************
	* next_cmos_table_enum
	*
	* Return a pointer to the next entry after 'last' in the CMOS table that
	* represents a possible CMOS parameter value. Return NULL if there are no
	* more parameter values.
	****************************************************************************/
	static const struct cmos_enums *next_cmos_table_enum
	(const struct cmos_enums *last) {
	return (const struct cmos_enums *)
	next_cmos_rec((const struct lb_record *)last, LB_TAG_OPTION_ENUM);
	}

	/****************************************************************************
	* first_cmos_rec
	*
	* Return a pointer to the first entry in the CMOS table whose type matches
	* 'tag'. Return NULL if CMOS table contains no such entry.
	*
	* Possible values for 'tag' are as follows:
	*
	* LB_TAG_OPTION: The entry represents a CMOS parameter.
	* LB_TAG_OPTION_ENUM: The entry represents a possible value for a CMOS
	* parameter of type 'enum'.
	*
	* The CMOS table tells us where in the nonvolatile RAM to look for CMOS
	* parameter values and specifies their types as 'enum', 'hex', or
	* 'reserved'.
	****************************************************************************/
	static const struct lb_record *first_cmos_rec(uint32_t tag)
	{
	const char *p;
	uint32_t bytes_processed, bytes_for_entries;
	const struct lb_record *lbrec;

	p = ((const char *)cmos_table) + cmos_table->header_length;
	bytes_for_entries = cmos_table->size - cmos_table->header_length;

	for (bytes_processed = 0;
	bytes_processed < bytes_for_entries;
	bytes_processed += lbrec->size) {
	lbrec = (const struct lb_record *)&p[bytes_processed];

	if (lbrec->tag == tag)
	return lbrec;
	}

	return NULL;
	}

	/****************************************************************************
	* next_cmos_rec
	*
	* Return a pointer to the next entry after 'last' in the CMOS table whose
	* type matches 'tag'. Return NULL if the table contains no more entries of
	* this type.
	****************************************************************************/
	static const struct lb_record next_cmos_rec(const struct lb_record last,
	uint32_t tag)
	{
	const char *p;
	uint32_t bytes_processed, bytes_for_entries, last_offset;
	const struct lb_record *lbrec;

	p = ((const char *)cmos_table) + cmos_table->header_length;
	bytes_for_entries = cmos_table->size - cmos_table->header_length;
	last_offset = ((const char *)last) - p;

	for (bytes_processed = last_offset + last->size;
	bytes_processed < bytes_for_entries;
	bytes_processed += lbrec->size) {
	lbrec = (const struct lb_record *)&p[bytes_processed];

	if (lbrec->tag == tag)
	return lbrec;
	}

	return NULL;
	}