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

 /*****************************************************************************\
  * layout.c
  *****************************************************************************
  *  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>.
  *  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 "common.h"
 #include "layout.h"
 #include "cmos_lowlevel.h"

 typedef struct cmos_entry_item_t cmos_entry_item_t;

 struct cmos_entry_item_t {
 	cmos_entry_t item;
 	cmos_entry_item_t *next;
 };

 typedef struct cmos_enum_item_t cmos_enum_item_t;

 struct cmos_enum_item_t {
 	cmos_enum_t item;
 	cmos_enum_item_t *next;
 };

 static void default_cmos_layout_get_fn(void);
 static int areas_overlap(unsigned area_0_start, unsigned area_0_length,
 			 unsigned area_1_start, unsigned area_1_length);
 static int entries_overlap(const cmos_entry_t * p, const cmos_entry_t * q);
 static const cmos_enum_item_t *find_first_cmos_enum_id(unsigned config_id);

 const char checksum_param_name[] = "check_sum";

 /* Newer versions of coreboot store the 3 pieces of information below in the
  * coreboot table so we don't have to rely on hardcoded values.
  */

 /* This is the offset from the start of CMOS of the first byte that the
  * checksum is calculated over.
  */
 #define CMOS_CHECKSUM_START 49

 /* This is the offset from the start of CMOS of the last byte that the
  * checksum is calculated over.
  */
 #define CMOS_CHECKSUM_END 125

 /* This is the offset from the start of CMOS where the coreboot checksum is
  * stored.
  */
 #define CMOS_CHECKSUM_INDEX 126

 /* index of first byte of checksummed area */
 unsigned cmos_checksum_start = CMOS_CHECKSUM_START;

 /* index of last byte of checksummed area */
 unsigned cmos_checksum_end = CMOS_CHECKSUM_END;

 /* index of first byte of CMOS checksum (a big-endian 16-bit value) */
 unsigned cmos_checksum_index = CMOS_CHECKSUM_INDEX;

 /* List is sorted in ascending order according to 'bit' field in
  * cmos_entry_t.
  */
 static cmos_entry_item_t *cmos_entry_list = NULL;

 /* List is sorted in ascending order: first by 'config_id' and then by
  * 'value'.
  */
 static cmos_enum_item_t *cmos_enum_list = NULL;

 static cmos_layout_get_fn_t cmos_layout_get_fn = default_cmos_layout_get_fn;

 /****************************************************************************
  * entries_overlap
  *
  * Return 1 if cmos entries 'p' and 'q' overlap.  Else return 0.
  ****************************************************************************/
 static inline int entries_overlap(const cmos_entry_t * p,
 				  const cmos_entry_t * q)
 {
 	return areas_overlap(p->bit, p->length, q->bit, q->length);
 }

 /****************************************************************************
  * cmos_entry_to_const_item
  *
  * Return a pointer to the cmos_entry_item_t that 'p' is embedded within.
  ****************************************************************************/
 static inline const cmos_entry_item_t *cmos_entry_to_const_item
     (const cmos_entry_t * p) {
 	static const cmos_entry_t *pos = &((cmos_entry_item_t *) 0)->item;
 	unsigned long offset, address;

 	offset = (unsigned long)pos;
 	address = ((unsigned long)p) - offset;
 	return (const cmos_entry_item_t *)address;
 }

 /****************************************************************************
  * cmos_enum_to_const_item
  *
  * Return a pointer to the cmos_enum_item_t that 'p' is embedded within.
  ****************************************************************************/
 static inline const cmos_enum_item_t *cmos_enum_to_const_item
     (const cmos_enum_t * p) {
 	static const cmos_enum_t *pos = &((cmos_enum_item_t *) 0)->item;
 	unsigned long offset, address;

 	offset = (unsigned long)pos;
 	address = ((unsigned long)p) - offset;
 	return (const cmos_enum_item_t *)address;
 }

 /****************************************************************************
  * register_cmos_layout_get_fn
  *
  * Set 'fn' as the function that will be called to retrieve CMOS layout
  * information.
  ****************************************************************************/
 void register_cmos_layout_get_fn(cmos_layout_get_fn_t fn)
 {
 	cmos_layout_get_fn = fn;
 }

 /****************************************************************************
  * get_cmos_layout
  *
  * Retrieve CMOS layout information and store it in our internal repository.
  ****************************************************************************/
 void get_cmos_layout(void)
 {
 	cmos_layout_get_fn();
 }

 /****************************************************************************
  * add_cmos_entry
  *
  * Attempt to add CMOS entry 'e' to our internal repository of layout
  * information.  Return OK on success or an error code on failure.  If
  * operation fails because 'e' overlaps an existing CMOS entry, '*conflict'
  * will be set to point to the overlapping entry.
  ****************************************************************************/
 int add_cmos_entry(const cmos_entry_t * e, const cmos_entry_t ** conflict)
 {
 	cmos_entry_item_t *item, *prev, *new_entry;

 	*conflict = NULL;

 	if (e->length < 1)
 		return LAYOUT_ENTRY_BAD_LENGTH;

 	if ((new_entry =
 	     (cmos_entry_item_t *) malloc(sizeof(*new_entry))) == NULL)
 		out_of_memory();

 	new_entry->item = *e;

 	if (cmos_entry_list == NULL) {
 		new_entry->next = NULL;
 		cmos_entry_list = new_entry;
 		return OK;
 	}

 	/* Find place in list to insert new entry.  List is sorted in ascending
 	 * order.
 	 */
 	for (item = cmos_entry_list, prev = NULL;
 	     (item != NULL) && (item->item.bit < e->bit);
 	     prev = item, item = item->next) ;

 	if (prev == NULL) {
 		if (entries_overlap(e, &cmos_entry_list->item)) {
 			*conflict = &cmos_entry_list->item;
 			goto fail;
 		}

 		new_entry->next = cmos_entry_list;
 		cmos_entry_list = new_entry;
 		return OK;
 	}

 	if (entries_overlap(&prev->item, e)) {
 		*conflict = &prev->item;
 		goto fail;
 	}

 	if ((item != NULL) && entries_overlap(e, &item->item)) {
 		*conflict = &item->item;
 		goto fail;
 	}

 	new_entry->next = item;
 	prev->next = new_entry;
 	return OK;

       fail:
 	free(new_entry);
 	return LAYOUT_ENTRY_OVERLAP;
 }

 /****************************************************************************
  * find_cmos_entry
  *
  * Search for a CMOS entry whose name is 'name'.  Return pointer to matching
  * entry or NULL if entry not found.
  ****************************************************************************/
 const cmos_entry_t *find_cmos_entry(const char name[])
 {
 	cmos_entry_item_t *item;

 	for (item = cmos_entry_list; item != NULL; item = item->next) {
 		if (!strcmp(item->item.name, name))
 			return &item->item;
 	}

 	return NULL;
 }

 /****************************************************************************
  * first_cmos_entry
  *
  * Return a pointer to the first CMOS entry in our list or NULL if list is
  * empty.
  ****************************************************************************/
 const cmos_entry_t *first_cmos_entry(void)
 {
 	return (cmos_entry_list == NULL) ? NULL : &cmos_entry_list->item;
 }

 /****************************************************************************
  * next_cmos_entry
  *
  * Return a pointer to next entry in list after 'last' or NULL if no more
  * entries.
  ****************************************************************************/
 const cmos_entry_t *next_cmos_entry(const cmos_entry_t * last)
 {
 	const cmos_entry_item_t *last_item, *next_item;

 	last_item = cmos_entry_to_const_item(last);
 	next_item = last_item->next;
 	return (next_item == NULL) ? NULL : &next_item->item;
 }

 /****************************************************************************
  * add_cmos_enum
  *
  * Attempt to add CMOS enum 'e' to our internal repository of layout
  * information.  Return OK on success or an error code on failure.
  ****************************************************************************/
 int add_cmos_enum(const cmos_enum_t * e)
 {
 	cmos_enum_item_t *item, *prev, *new_enum;

 	if ((new_enum = (cmos_enum_item_t *) malloc(sizeof(*new_enum))) == NULL)
 		out_of_memory();

 	new_enum->item = *e;

 	if (cmos_enum_list == NULL) {
 		new_enum->next = NULL;
 		cmos_enum_list = new_enum;
 		return OK;
 	}

 	/* The list of enums is sorted in ascending order, first by
 	 * 'config_id' and then by 'value'.  Look for the first enum
 	 * whose 'config_id' field matches 'e'.
 	 */
 	for (item = cmos_enum_list, prev = NULL;
 	     (item != NULL) && (item->item.config_id < e->config_id);
 	     prev = item, item = item->next) ;

 	if (item == NULL) {
 		new_enum->next = NULL;
 		prev->next = new_enum;
 		return OK;
 	}

 	if (item->item.config_id > e->config_id) {
 		new_enum->next = item;

 		if (prev == NULL)
 			cmos_enum_list = new_enum;
 		else
 			prev->next = new_enum;

 		return OK;
 	}

 	/* List already contains at least one enum whose 'config_id'
 	 * matches 'e'.  Now find proper place to insert 'e' based on
 	 * 'value'.
 	 */
 	while (item->item.value < e->value) {
 		prev = item;
 		item = item->next;

 		if ((item == NULL) || (item->item.config_id != e->config_id)) {
 			new_enum->next = item;
 			prev->next = new_enum;
 			return OK;
 		}
 	}

 	if (item->item.value == e->value) {
 		free(new_enum);
 		return LAYOUT_DUPLICATE_ENUM;
 	}

 	new_enum->next = item;

 	if (prev == NULL)
 		cmos_enum_list = new_enum;
 	else
 		prev->next = new_enum;

 	return OK;
 }

 /****************************************************************************
  * find_cmos_enum
  *
  * Search for an enum that matches 'config_id' and 'value'.  If found, return
  * a pointer to the mathcing enum.  Else return NULL.
  ****************************************************************************/
 const cmos_enum_t *find_cmos_enum(unsigned config_id, unsigned long long value)
 {
 	const cmos_enum_item_t *item;

 	if ((item = find_first_cmos_enum_id(config_id)) == NULL)
 		return NULL;

 	while (item->item.value < value) {
 		item = item->next;

 		if ((item == NULL) || (item->item.config_id != config_id))
 			return NULL;
 	}

 	return (item->item.value == value) ? &item->item : NULL;
 }

 /****************************************************************************
  * first_cmos_enum
  *
  * Return a pointer to the first CMOS enum in our list or NULL if list is
  * empty.
  ****************************************************************************/
 const cmos_enum_t *first_cmos_enum(void)
 {
 	return (cmos_enum_list == NULL) ? NULL : &cmos_enum_list->item;
 }

 /****************************************************************************
  * next_cmos_enum
  *
  * Return a pointer to next enum in list after 'last' or NULL if no more
  * enums.
  ****************************************************************************/
 const cmos_enum_t *next_cmos_enum(const cmos_enum_t * last)
 {
 	const cmos_enum_item_t *last_item, *next_item;

 	last_item = cmos_enum_to_const_item(last);
 	next_item = last_item->next;
 	return (next_item == NULL) ? NULL : &next_item->item;
 }

 /****************************************************************************
  * first_cmos_enum_id
  *
  * Return a pointer to the first CMOS enum in our list that matches
  * 'config_id' or NULL if there are no matching enums.
  ****************************************************************************/
 const cmos_enum_t *first_cmos_enum_id(unsigned config_id)
 {
 	const cmos_enum_item_t *item;

 	item = find_first_cmos_enum_id(config_id);
 	return (item == NULL) ? NULL : &item->item;
 }

 /****************************************************************************
  * next_cmos_enum_id
  *
  * Return a pointer to next enum in list after 'last' that matches the
  * 'config_id' field of 'last' or NULL if there are no more matching enums.
  ****************************************************************************/
 const cmos_enum_t *next_cmos_enum_id(const cmos_enum_t * last)
 {
 	const cmos_enum_item_t *item;

 	item = cmos_enum_to_const_item(last)->next;
 	return ((item == NULL) || (item->item.config_id != last->config_id)) ?
 	    NULL : &item->item;
 }

 /****************************************************************************
  * is_checksum_name
  *
  * Return 1 if 'name' matches the name of the parameter representing the CMOS
  * checksum.  Else return 0.
  ****************************************************************************/
 int is_checksum_name(const char name[])
 {
 	return !strcmp(name, checksum_param_name);
 }

 /****************************************************************************
  * checksum_layout_to_bytes
  *
  * On entry, '*layout' contains checksum-related layout information expressed
  * in bits.  Perform sanity checking on the information and convert it from
  * bit positions to byte positions.  Return OK on success or an error code if
  * a sanity check fails.
  ****************************************************************************/
 int checksum_layout_to_bytes(cmos_checksum_layout_t * layout)
 {
 	unsigned start, end, index;

 	start = layout->summed_area_start;
 	end = layout->summed_area_end;
 	index = layout->checksum_at;

 	if (start % 8)
 		return LAYOUT_SUMMED_AREA_START_NOT_ALIGNED;

 	if ((end % 8) != 7)
 		return LAYOUT_SUMMED_AREA_END_NOT_ALIGNED;

 	if (index % 8)
 		return LAYOUT_CHECKSUM_LOCATION_NOT_ALIGNED;

 	if (end <= start)
 		return LAYOUT_INVALID_SUMMED_AREA;

 	/* Convert bit positions to byte positions. */
 	start /= 8;
 	end /= 8;		/* equivalent to "end = ((end - 7) / 8)" */
 	index /= 8;

 	if (verify_cmos_byte_index(start) || verify_cmos_byte_index(end))
 		return LAYOUT_SUMMED_AREA_OUT_OF_RANGE;

 	if (verify_cmos_byte_index(index))
 		return LAYOUT_CHECKSUM_LOCATION_OUT_OF_RANGE;

 	/* checksum occupies 16 bits */
 	if (areas_overlap(start, end - start + 1, index, index + 1))
 		return LAYOUT_CHECKSUM_OVERLAPS_SUMMED_AREA;

 	layout->summed_area_start = start;
 	layout->summed_area_end = end;
 	layout->checksum_at = index;
 	return OK;
 }

 /****************************************************************************
  * checksum_layout_to_bits
  *
  * On entry, '*layout' contains checksum-related layout information expressed
  * in bytes.  Convert this information to bit positions.
  ****************************************************************************/
 void checksum_layout_to_bits(cmos_checksum_layout_t * layout)
 {
 	layout->summed_area_start *= 8;
 	layout->summed_area_end = (layout->summed_area_end * 8) + 7;
 	layout->checksum_at *= 8;
 }

 /****************************************************************************
  * default_cmos_layout_get_fn
  *
  * If this function is ever called, it means that an appropriate callback for
  * obtaining CMOS layout information was not set before attempting to
  * retrieve layout information.
  ****************************************************************************/
 static void default_cmos_layout_get_fn(void)
 {
 	BUG();
 }

 /****************************************************************************
  * areas_overlap
  *
  * Return 1 if the two given areas overlap.  Else return 0.
  ****************************************************************************/
 static int areas_overlap(unsigned area_0_start, unsigned area_0_length,
 			 unsigned area_1_start, unsigned area_1_length)
 {
 	unsigned area_0_end, area_1_end;

 	area_0_end = area_0_start + area_0_length - 1;
 	area_1_end = area_1_start + area_1_length - 1;
 	return ((area_1_start <= area_0_end) && (area_0_start <= area_1_end));
 }

 /****************************************************************************
  * find_first_cmos_enum_id
  *
  * Return a pointer to the first item in our list of enums that matches
  * 'config_id'.  Return NULL if there is no matching enum.
  ****************************************************************************/
 static const cmos_enum_item_t *find_first_cmos_enum_id(unsigned config_id)
 {
 	cmos_enum_item_t *item;

 	for (item = cmos_enum_list;
 	     (item != NULL) && (item->item.config_id < config_id);
 	     item = item->next) ;

 	return ((item == NULL) || (item->item.config_id > config_id)) ?
 	    NULL : item;
 }
	/*****************************************************************************\
	* layout.c
	*****************************************************************************
	* 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>.
	* 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 "common.h"
	#include "layout.h"
	#include "cmos_lowlevel.h"

	typedef struct cmos_entry_item_t cmos_entry_item_t;

	struct cmos_entry_item_t {
	cmos_entry_t item;
	cmos_entry_item_t *next;
	};

	typedef struct cmos_enum_item_t cmos_enum_item_t;

	struct cmos_enum_item_t {
	cmos_enum_t item;
	cmos_enum_item_t *next;
	};

	static void default_cmos_layout_get_fn(void);
	static int areas_overlap(unsigned area_0_start, unsigned area_0_length,
	unsigned area_1_start, unsigned area_1_length);
	static int entries_overlap(const cmos_entry_t * p, const cmos_entry_t * q);
	static const cmos_enum_item_t *find_first_cmos_enum_id(unsigned config_id);

	const char checksum_param_name[] = "check_sum";

	/* Newer versions of coreboot store the 3 pieces of information below in the
	* coreboot table so we don't have to rely on hardcoded values.
	*/

	/* This is the offset from the start of CMOS of the first byte that the
	* checksum is calculated over.
	*/
	#define CMOS_CHECKSUM_START 49

	/* This is the offset from the start of CMOS of the last byte that the
	* checksum is calculated over.
	*/
	#define CMOS_CHECKSUM_END 125

	/* This is the offset from the start of CMOS where the coreboot checksum is
	* stored.
	*/
	#define CMOS_CHECKSUM_INDEX 126

	/* index of first byte of checksummed area */
	unsigned cmos_checksum_start = CMOS_CHECKSUM_START;

	/* index of last byte of checksummed area */
	unsigned cmos_checksum_end = CMOS_CHECKSUM_END;

	/* index of first byte of CMOS checksum (a big-endian 16-bit value) */
	unsigned cmos_checksum_index = CMOS_CHECKSUM_INDEX;

	/* List is sorted in ascending order according to 'bit' field in
	* cmos_entry_t.
	*/
	static cmos_entry_item_t *cmos_entry_list = NULL;

	/* List is sorted in ascending order: first by 'config_id' and then by
	* 'value'.
	*/
	static cmos_enum_item_t *cmos_enum_list = NULL;

	static cmos_layout_get_fn_t cmos_layout_get_fn = default_cmos_layout_get_fn;

	/****************************************************************************
	* entries_overlap
	*
	* Return 1 if cmos entries 'p' and 'q' overlap. Else return 0.
	****************************************************************************/
	static inline int entries_overlap(const cmos_entry_t * p,
	const cmos_entry_t * q)
	{
	return areas_overlap(p->bit, p->length, q->bit, q->length);
	}

	/****************************************************************************
	* cmos_entry_to_const_item
	*
	* Return a pointer to the cmos_entry_item_t that 'p' is embedded within.
	****************************************************************************/
	static inline const cmos_entry_item_t *cmos_entry_to_const_item
	(const cmos_entry_t * p) {
	static const cmos_entry_t pos = &((cmos_entry_item_t ) 0)->item;
	unsigned long offset, address;

	offset = (unsigned long)pos;
	address = ((unsigned long)p) - offset;
	return (const cmos_entry_item_t *)address;
	}

	/****************************************************************************
	* cmos_enum_to_const_item
	*
	* Return a pointer to the cmos_enum_item_t that 'p' is embedded within.
	****************************************************************************/
	static inline const cmos_enum_item_t *cmos_enum_to_const_item
	(const cmos_enum_t * p) {
	static const cmos_enum_t pos = &((cmos_enum_item_t ) 0)->item;
	unsigned long offset, address;

	offset = (unsigned long)pos;
	address = ((unsigned long)p) - offset;
	return (const cmos_enum_item_t *)address;
	}

	/****************************************************************************
	* register_cmos_layout_get_fn
	*
	* Set 'fn' as the function that will be called to retrieve CMOS layout
	* information.
	****************************************************************************/
	void register_cmos_layout_get_fn(cmos_layout_get_fn_t fn)
	{
	cmos_layout_get_fn = fn;
	}

	/****************************************************************************
	* get_cmos_layout
	*
	* Retrieve CMOS layout information and store it in our internal repository.
	****************************************************************************/
	void get_cmos_layout(void)
	{
	cmos_layout_get_fn();
	}

	/****************************************************************************
	* add_cmos_entry
	*
	* Attempt to add CMOS entry 'e' to our internal repository of layout
	* information. Return OK on success or an error code on failure. If
	* operation fails because 'e' overlaps an existing CMOS entry, '*conflict'
	* will be set to point to the overlapping entry.
	****************************************************************************/
	int add_cmos_entry(const cmos_entry_t * e, const cmos_entry_t ** conflict)
	{
	cmos_entry_item_t item, prev, *new_entry;

	*conflict = NULL;

	if (e->length < 1)
	return LAYOUT_ENTRY_BAD_LENGTH;

	if ((new_entry =
	(cmos_entry_item_t ) malloc(sizeof(new_entry))) == NULL)
	out_of_memory();

	new_entry->item = *e;

	if (cmos_entry_list == NULL) {
	new_entry->next = NULL;
	cmos_entry_list = new_entry;
	return OK;
	}

	/* Find place in list to insert new entry. List is sorted in ascending
	* order.
	*/
	for (item = cmos_entry_list, prev = NULL;
	(item != NULL) && (item->item.bit < e->bit);
	prev = item, item = item->next) ;

	if (prev == NULL) {
	if (entries_overlap(e, &cmos_entry_list->item)) {
	*conflict = &cmos_entry_list->item;
	goto fail;
	}

	new_entry->next = cmos_entry_list;
	cmos_entry_list = new_entry;
	return OK;
	}

	if (entries_overlap(&prev->item, e)) {
	*conflict = &prev->item;
	goto fail;
	}

	if ((item != NULL) && entries_overlap(e, &item->item)) {
	*conflict = &item->item;
	goto fail;
	}

	new_entry->next = item;
	prev->next = new_entry;
	return OK;

	fail:
	free(new_entry);
	return LAYOUT_ENTRY_OVERLAP;
	}

	/****************************************************************************
	* find_cmos_entry
	*
	* Search for a CMOS entry whose name is 'name'. Return pointer to matching
	* entry or NULL if entry not found.
	****************************************************************************/
	const cmos_entry_t *find_cmos_entry(const char name[])
	{
	cmos_entry_item_t *item;

	for (item = cmos_entry_list; item != NULL; item = item->next) {
	if (!strcmp(item->item.name, name))
	return &item->item;
	}

	return NULL;
	}

	/****************************************************************************
	* first_cmos_entry
	*
	* Return a pointer to the first CMOS entry in our list or NULL if list is
	* empty.
	****************************************************************************/
	const cmos_entry_t *first_cmos_entry(void)
	{
	return (cmos_entry_list == NULL) ? NULL : &cmos_entry_list->item;
	}

	/****************************************************************************
	* next_cmos_entry
	*
	* Return a pointer to next entry in list after 'last' or NULL if no more
	* entries.
	****************************************************************************/
	const cmos_entry_t next_cmos_entry(const cmos_entry_t last)
	{
	const cmos_entry_item_t last_item, next_item;

	last_item = cmos_entry_to_const_item(last);
	next_item = last_item->next;
	return (next_item == NULL) ? NULL : &next_item->item;
	}

	/****************************************************************************
	* add_cmos_enum
	*
	* Attempt to add CMOS enum 'e' to our internal repository of layout
	* information. Return OK on success or an error code on failure.
	****************************************************************************/
	int add_cmos_enum(const cmos_enum_t * e)
	{
	cmos_enum_item_t item, prev, *new_enum;

	if ((new_enum = (cmos_enum_item_t ) malloc(sizeof(new_enum))) == NULL)
	out_of_memory();

	new_enum->item = *e;

	if (cmos_enum_list == NULL) {
	new_enum->next = NULL;
	cmos_enum_list = new_enum;
	return OK;
	}

	/* The list of enums is sorted in ascending order, first by
	* 'config_id' and then by 'value'. Look for the first enum
	* whose 'config_id' field matches 'e'.
	*/
	for (item = cmos_enum_list, prev = NULL;
	(item != NULL) && (item->item.config_id < e->config_id);
	prev = item, item = item->next) ;

	if (item == NULL) {
	new_enum->next = NULL;
	prev->next = new_enum;
	return OK;
	}

	if (item->item.config_id > e->config_id) {
	new_enum->next = item;

	if (prev == NULL)
	cmos_enum_list = new_enum;
	else
	prev->next = new_enum;

	return OK;
	}

	/* List already contains at least one enum whose 'config_id'
	* matches 'e'. Now find proper place to insert 'e' based on
	* 'value'.
	*/
	while (item->item.value < e->value) {
	prev = item;
	item = item->next;

	if ((item == NULL) \|\| (item->item.config_id != e->config_id)) {
	new_enum->next = item;
	prev->next = new_enum;
	return OK;
	}
	}

	if (item->item.value == e->value) {
	free(new_enum);
	return LAYOUT_DUPLICATE_ENUM;
	}

	new_enum->next = item;

	if (prev == NULL)
	cmos_enum_list = new_enum;
	else
	prev->next = new_enum;

	return OK;
	}

	/****************************************************************************
	* find_cmos_enum
	*
	* Search for an enum that matches 'config_id' and 'value'. If found, return
	* a pointer to the mathcing enum. Else return NULL.
	****************************************************************************/
	const cmos_enum_t *find_cmos_enum(unsigned config_id, unsigned long long value)
	{
	const cmos_enum_item_t *item;

	if ((item = find_first_cmos_enum_id(config_id)) == NULL)
	return NULL;

	while (item->item.value < value) {
	item = item->next;

	if ((item == NULL) \|\| (item->item.config_id != config_id))
	return NULL;
	}

	return (item->item.value == value) ? &item->item : NULL;
	}

	/****************************************************************************
	* first_cmos_enum
	*
	* Return a pointer to the first CMOS enum in our list or NULL if list is
	* empty.
	****************************************************************************/
	const cmos_enum_t *first_cmos_enum(void)
	{
	return (cmos_enum_list == NULL) ? NULL : &cmos_enum_list->item;
	}

	/****************************************************************************
	* next_cmos_enum
	*
	* Return a pointer to next enum in list after 'last' or NULL if no more
	* enums.
	****************************************************************************/
	const cmos_enum_t next_cmos_enum(const cmos_enum_t last)
	{
	const cmos_enum_item_t last_item, next_item;

	last_item = cmos_enum_to_const_item(last);
	next_item = last_item->next;
	return (next_item == NULL) ? NULL : &next_item->item;
	}

	/****************************************************************************
	* first_cmos_enum_id
	*
	* Return a pointer to the first CMOS enum in our list that matches
	* 'config_id' or NULL if there are no matching enums.
	****************************************************************************/
	const cmos_enum_t *first_cmos_enum_id(unsigned config_id)
	{
	const cmos_enum_item_t *item;

	item = find_first_cmos_enum_id(config_id);
	return (item == NULL) ? NULL : &item->item;
	}

	/****************************************************************************
	* next_cmos_enum_id
	*
	* Return a pointer to next enum in list after 'last' that matches the
	* 'config_id' field of 'last' or NULL if there are no more matching enums.
	****************************************************************************/
	const cmos_enum_t next_cmos_enum_id(const cmos_enum_t last)
	{
	const cmos_enum_item_t *item;

	item = cmos_enum_to_const_item(last)->next;
	return ((item == NULL) \|\| (item->item.config_id != last->config_id)) ?
	NULL : &item->item;
	}

	/****************************************************************************
	* is_checksum_name
	*
	* Return 1 if 'name' matches the name of the parameter representing the CMOS
	* checksum. Else return 0.
	****************************************************************************/
	int is_checksum_name(const char name[])
	{
	return !strcmp(name, checksum_param_name);
	}

	/****************************************************************************
	* checksum_layout_to_bytes
	*
	* On entry, '*layout' contains checksum-related layout information expressed
	* in bits. Perform sanity checking on the information and convert it from
	* bit positions to byte positions. Return OK on success or an error code if
	* a sanity check fails.
	****************************************************************************/
	int checksum_layout_to_bytes(cmos_checksum_layout_t * layout)
	{
	unsigned start, end, index;

	start = layout->summed_area_start;
	end = layout->summed_area_end;
	index = layout->checksum_at;

	if (start % 8)
	return LAYOUT_SUMMED_AREA_START_NOT_ALIGNED;

	if ((end % 8) != 7)
	return LAYOUT_SUMMED_AREA_END_NOT_ALIGNED;

	if (index % 8)
	return LAYOUT_CHECKSUM_LOCATION_NOT_ALIGNED;

	if (end <= start)
	return LAYOUT_INVALID_SUMMED_AREA;

	/* Convert bit positions to byte positions. */
	start /= 8;
	end /= 8; /* equivalent to "end = ((end - 7) / 8)" */
	index /= 8;

	if (verify_cmos_byte_index(start) \|\| verify_cmos_byte_index(end))
	return LAYOUT_SUMMED_AREA_OUT_OF_RANGE;

	if (verify_cmos_byte_index(index))
	return LAYOUT_CHECKSUM_LOCATION_OUT_OF_RANGE;

	/* checksum occupies 16 bits */
	if (areas_overlap(start, end - start + 1, index, index + 1))
	return LAYOUT_CHECKSUM_OVERLAPS_SUMMED_AREA;

	layout->summed_area_start = start;
	layout->summed_area_end = end;
	layout->checksum_at = index;
	return OK;
	}

	/****************************************************************************
	* checksum_layout_to_bits
	*
	* On entry, '*layout' contains checksum-related layout information expressed
	* in bytes. Convert this information to bit positions.
	****************************************************************************/
	void checksum_layout_to_bits(cmos_checksum_layout_t * layout)
	{
	layout->summed_area_start *= 8;
	layout->summed_area_end = (layout->summed_area_end * 8) + 7;
	layout->checksum_at *= 8;
	}

	/****************************************************************************
	* default_cmos_layout_get_fn
	*
	* If this function is ever called, it means that an appropriate callback for
	* obtaining CMOS layout information was not set before attempting to
	* retrieve layout information.
	****************************************************************************/
	static void default_cmos_layout_get_fn(void)
	{
	BUG();
	}

	/****************************************************************************
	* areas_overlap
	*
	* Return 1 if the two given areas overlap. Else return 0.
	****************************************************************************/
	static int areas_overlap(unsigned area_0_start, unsigned area_0_length,
	unsigned area_1_start, unsigned area_1_length)
	{
	unsigned area_0_end, area_1_end;

	area_0_end = area_0_start + area_0_length - 1;
	area_1_end = area_1_start + area_1_length - 1;
	return ((area_1_start <= area_0_end) && (area_0_start <= area_1_end));
	}

	/****************************************************************************
	* find_first_cmos_enum_id
	*
	* Return a pointer to the first item in our list of enums that matches
	* 'config_id'. Return NULL if there is no matching enum.
	****************************************************************************/
	static const cmos_enum_item_t *find_first_cmos_enum_id(unsigned config_id)
	{
	cmos_enum_item_t *item;

	for (item = cmos_enum_list;
	(item != NULL) && (item->item.config_id < config_id);
	item = item->next) ;

	return ((item == NULL) \|\| (item->item.config_id > config_id)) ?
	NULL : item;
	}