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

 /*****************************************************************************\
  * cmos_lowlevel.c
  *****************************************************************************
  *  Copyright (C) 2002-2005 The Regents of the University of California.
  *  Produced at the Lawrence Livermore National Laboratory.
  *  Written by David S. 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.
 \*****************************************************************************/

 #if defined(__FreeBSD__)
 #include <fcntl.h>
 #include <unistd.h>
 #endif

 #include "common.h"
 #include "cmos_lowlevel.h"

 /* Hardware Abstraction Layer: lowlevel byte-wise write access */

 extern cmos_access_t cmos_hal, memory_hal;
 static cmos_access_t *current_access =
 #ifdef CMOS_HAL
 	&cmos_hal;
 #else
 	&memory_hal;
 #endif

 void select_hal(hal_t hal, void *data)
 {
 	switch(hal) {
 #ifdef CMOS_HAL
 		case HAL_CMOS:
 			current_access = &cmos_hal;
 			break;
 #endif
 		case HAL_MEMORY:
 		default:
 			current_access = &memory_hal;
 			break;
 	}
 	current_access->init(data);
 }

 /* Bit-level access */
 typedef struct {
 	unsigned byte_index;
 	unsigned bit_offset;
 } cmos_bit_op_location_t;

 static unsigned cmos_bit_op_strategy(unsigned bit, unsigned bits_left,
 				     cmos_bit_op_location_t * where);
 static unsigned char cmos_read_bits(const cmos_bit_op_location_t * where,
 				    unsigned nr_bits);
 static void cmos_write_bits(const cmos_bit_op_location_t * where,
 			    unsigned nr_bits, unsigned char value);
 static unsigned char get_bits(unsigned long long value, unsigned bit,
 			      unsigned nr_bits);
 static void put_bits(unsigned char value, unsigned bit, unsigned nr_bits,
 		     unsigned long long *result);

 /****************************************************************************
  * get_bits
  *
  * Extract a value 'nr_bits' bits wide starting at bit position 'bit' from
  * 'value' and return the result.  It is assumed that 'nr_bits' is at most 8.
  ****************************************************************************/
 static inline unsigned char get_bits(unsigned long long value, unsigned bit,
 				     unsigned nr_bits)
 {
 	return (value >> bit) & ((unsigned char)((1 << nr_bits) - 1));
 }

 /****************************************************************************
  * put_bits
  *
  * Extract the low order 'nr_bits' bits from 'value' and store them in the
  * value pointed to by 'result' starting at bit position 'bit'.  The bit
  * positions in 'result' where the result is stored are assumed to be
  * initially zero.
  ****************************************************************************/
 static inline void put_bits(unsigned char value, unsigned bit,
 			    unsigned nr_bits, unsigned long long *result)
 {
 	*result += ((unsigned long long)(value &
 				((unsigned char)((1 << nr_bits) - 1)))) << bit;
 }

 /****************************************************************************
  * cmos_read
  *
  * Read value from nonvolatile RAM at position given by 'bit' and 'length'
  * and return this value.  The I/O privilege level of the currently executing
  * process must be set appropriately.
  ****************************************************************************/
 unsigned long long cmos_read(const cmos_entry_t * e)
 {
 	cmos_bit_op_location_t where;
 	unsigned bit = e->bit, length = e->length;
 	unsigned next_bit, bits_left, nr_bits;
 	unsigned long long result = 0;
 	unsigned char value;

 	assert(!verify_cmos_op(bit, length, e->config));
 	result = 0;

 	if (e->config == CMOS_ENTRY_STRING) {
 		char *newstring = calloc(1, (length + 7) / 8);
 		unsigned usize = (8 * sizeof(unsigned long long));

 		if (!newstring) {
 			out_of_memory();
 		}

 		for (next_bit = 0, bits_left = length;
 		     bits_left; next_bit += nr_bits, bits_left -= nr_bits) {
 			nr_bits = cmos_bit_op_strategy(bit + next_bit,
 				   bits_left > usize ? usize : bits_left, &where);
 			value = cmos_read_bits(&where, nr_bits);
 			put_bits(value, next_bit % usize, nr_bits,
 				 &((unsigned long long *)newstring)[next_bit /
 								    usize]);
 			result = (unsigned long)newstring;
 		}
 	} else {
 		for (next_bit = 0, bits_left = length;
 		     bits_left; next_bit += nr_bits, bits_left -= nr_bits) {
 			nr_bits =
 			    cmos_bit_op_strategy(bit + next_bit, bits_left,
 						 &where);
 			value = cmos_read_bits(&where, nr_bits);
 			put_bits(value, next_bit, nr_bits, &result);
 		}
 	}

 	return result;
 }

 /****************************************************************************
  * cmos_write
  *
  * Write 'data' to nonvolatile RAM at position given by 'bit' and 'length'.
  * The I/O privilege level of the currently executing process must be set
  * appropriately.
  ****************************************************************************/
 void cmos_write(const cmos_entry_t * e, unsigned long long value)
 {
 	cmos_bit_op_location_t where;
 	unsigned bit = e->bit, length = e->length;
 	unsigned next_bit, bits_left, nr_bits;

 	assert(!verify_cmos_op(bit, length, e->config));

 	if (e->config == CMOS_ENTRY_STRING) {
 		unsigned long long *data =
 		    (unsigned long long *)(unsigned long)value;
 		unsigned usize = (8 * sizeof(unsigned long long));

 		for (next_bit = 0, bits_left = length;
 		     bits_left; next_bit += nr_bits, bits_left -= nr_bits) {
 			nr_bits = cmos_bit_op_strategy(bit + next_bit,
 					bits_left > usize ? usize : bits_left,
 					&where);
 			value = data[next_bit / usize];
 			cmos_write_bits(&where, nr_bits,
 				get_bits(value, next_bit % usize, nr_bits));
 		}
 	} else {
 		for (next_bit = 0, bits_left = length;
 		     bits_left; next_bit += nr_bits, bits_left -= nr_bits) {
 			nr_bits = cmos_bit_op_strategy(bit + next_bit,
 					bits_left, &where);
 			cmos_write_bits(&where, nr_bits,
 					get_bits(value, next_bit, nr_bits));
 		}
 	}
 }

 /****************************************************************************
  * cmos_read_byte
  *
  * Read a byte from nonvolatile RAM at a position given by 'index' and return
  * the result.  An 'index' value of 0 represents the first byte of
  * nonvolatile RAM.
  *
  * Note: the first 14 bytes of nonvolatile RAM provide an interface to the
  *       real time clock.
  ****************************************************************************/
 unsigned char cmos_read_byte(unsigned index)
 {
 	return current_access->read(index);
 }

 /****************************************************************************
  * cmos_write_byte
  *
  * Write 'value' to nonvolatile RAM at a position given by 'index'.  An
  * 'index' of 0 represents the first byte of nonvolatile RAM.
  *
  * Note: the first 14 bytes of nonvolatile RAM provide an interface to the
  *       real time clock.  Writing to any of these bytes will therefore
  *       affect its functioning.
  ****************************************************************************/
 void cmos_write_byte(unsigned index, unsigned char value)
 {
 	current_access->write(index, value);
 }

 /****************************************************************************
  * cmos_read_all
  *
  * Read all contents of CMOS memory into array 'data'.  The first 14 bytes of
  * 'data' are set to zero since this corresponds to the real time clock area.
  ****************************************************************************/
 void cmos_read_all(unsigned char data[])
 {
 	unsigned i;

 	for (i = 0; i < CMOS_RTC_AREA_SIZE; i++)
 		data[i] = 0;

 	for (; i < CMOS_SIZE; i++)
 		data[i] = cmos_read_byte(i);
 }

 /****************************************************************************
  * cmos_write_all
  *
  * Update all of CMOS memory with the contents of array 'data'.  The first 14
  * bytes of 'data' are ignored since this corresponds to the real time clock
  * area.
  ****************************************************************************/
 void cmos_write_all(unsigned char data[])
 {
 	unsigned i;

 	for (i = CMOS_RTC_AREA_SIZE; i < CMOS_SIZE; i++)
 		cmos_write_byte(i, data[i]);
 }

 /****************************************************************************
  * set_iopl
  *
  * Set the I/O privilege level of the executing process.  Root privileges are
  * required for performing this action.  A sufficient I/O privilege level
  * allows the process to access x86 I/O address space and to disable/reenable
  * interrupts while executing in user space.  Messing with the I/O privilege
  * level is therefore somewhat dangerous.
  ****************************************************************************/
 void set_iopl(int level)
 {
 	current_access->set_iopl(level);
 }

 /****************************************************************************
  * verify_cmos_op
  *
  * 'bit' represents a bit position in the nonvolatile RAM.  The first bit
  * (i.e. the lowest order bit of the first byte) of nonvolatile RAM is
  * labeled as bit 0.  'length' represents the width in bits of a value we
  * wish to read or write.  Perform sanity checking on 'bit' and 'length'.  If
  * no problems were encountered, return OK.  Else return an error code.
  ****************************************************************************/
 int verify_cmos_op(unsigned bit, unsigned length, cmos_entry_config_t config)
 {
 	if ((bit >= (8 * CMOS_SIZE)) || ((bit + length) > (8 * CMOS_SIZE)))
 		return CMOS_AREA_OUT_OF_RANGE;

 	if (bit < (8 * CMOS_RTC_AREA_SIZE))
 		return CMOS_AREA_OVERLAPS_RTC;

 	if (config == CMOS_ENTRY_STRING)
 		return OK;

 	if (length > (8 * sizeof(unsigned long long)))
 		return CMOS_AREA_TOO_WIDE;

 	return OK;
 }

 /****************************************************************************
  * cmos_bit_op_strategy
  *
  * Helper function used by cmos_read() and cmos_write() to determine which
  * bits to read or write next.
  ****************************************************************************/
 static unsigned cmos_bit_op_strategy(unsigned bit, unsigned bits_left,
 				     cmos_bit_op_location_t * where)
 {
 	unsigned max_bits;

 	where->byte_index = bit >> 3;
 	where->bit_offset = bit & 0x07;
 	max_bits = 8 - where->bit_offset;
 	return (bits_left > max_bits) ? max_bits : bits_left;
 }

 /****************************************************************************
  * cmos_read_bits
  *
  * Read a chunk of bits from a byte location within CMOS memory.  Return the
  * value represented by the chunk of bits.
  ****************************************************************************/
 static unsigned char cmos_read_bits(const cmos_bit_op_location_t * where,
 				    unsigned nr_bits)
 {
 	return (cmos_read_byte(where->byte_index) >> where->bit_offset) &
 	    ((unsigned char)((1 << nr_bits) - 1));
 }

 /****************************************************************************
  * cmos_write_bits
  *
  * Write a chunk of bits (the low order 'nr_bits' bits of 'value') to an area
  * within a particular byte of CMOS memory.
  ****************************************************************************/
 static void cmos_write_bits(const cmos_bit_op_location_t * where,
 			    unsigned nr_bits, unsigned char value)
 {
 	unsigned char n, mask;

 	if (nr_bits == 8) {
 		cmos_write_byte(where->byte_index, value);
 		return;
 	}

 	n = cmos_read_byte(where->byte_index);
 	mask = ((unsigned char)((1 << nr_bits) - 1)) << where->bit_offset;
 	n = (n & ~mask) + ((value << where->bit_offset) & mask);
 	cmos_write_byte(where->byte_index, n);
 }
	/*****************************************************************************\
	* cmos_lowlevel.c
	*****************************************************************************
	* Copyright (C) 2002-2005 The Regents of the University of California.
	* Produced at the Lawrence Livermore National Laboratory.
	* Written by David S. 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.
	\*****************************************************************************/

	#if defined(__FreeBSD__)
	#include <fcntl.h>
	#include <unistd.h>
	#endif

	#include "common.h"
	#include "cmos_lowlevel.h"

	/* Hardware Abstraction Layer: lowlevel byte-wise write access */

	extern cmos_access_t cmos_hal, memory_hal;
	static cmos_access_t *current_access =
	#ifdef CMOS_HAL
	&cmos_hal;
	#else
	&memory_hal;
	#endif

	void select_hal(hal_t hal, void *data)
	{
	switch(hal) {
	#ifdef CMOS_HAL
	case HAL_CMOS:
	current_access = &cmos_hal;
	break;
	#endif
	case HAL_MEMORY:
	default:
	current_access = &memory_hal;
	break;
	}
	current_access->init(data);
	}

	/* Bit-level access */
	typedef struct {
	unsigned byte_index;
	unsigned bit_offset;
	} cmos_bit_op_location_t;

	static unsigned cmos_bit_op_strategy(unsigned bit, unsigned bits_left,
	cmos_bit_op_location_t * where);
	static unsigned char cmos_read_bits(const cmos_bit_op_location_t * where,
	unsigned nr_bits);
	static void cmos_write_bits(const cmos_bit_op_location_t * where,
	unsigned nr_bits, unsigned char value);
	static unsigned char get_bits(unsigned long long value, unsigned bit,
	unsigned nr_bits);
	static void put_bits(unsigned char value, unsigned bit, unsigned nr_bits,
	unsigned long long *result);

	/****************************************************************************
	* get_bits
	*
	* Extract a value 'nr_bits' bits wide starting at bit position 'bit' from
	* 'value' and return the result. It is assumed that 'nr_bits' is at most 8.
	****************************************************************************/
	static inline unsigned char get_bits(unsigned long long value, unsigned bit,
	unsigned nr_bits)
	{
	return (value >> bit) & ((unsigned char)((1 << nr_bits) - 1));
	}

	/****************************************************************************
	* put_bits
	*
	* Extract the low order 'nr_bits' bits from 'value' and store them in the
	* value pointed to by 'result' starting at bit position 'bit'. The bit
	* positions in 'result' where the result is stored are assumed to be
	* initially zero.
	****************************************************************************/
	static inline void put_bits(unsigned char value, unsigned bit,
	unsigned nr_bits, unsigned long long *result)
	{
	*result += ((unsigned long long)(value &
	((unsigned char)((1 << nr_bits) - 1)))) << bit;
	}

	/****************************************************************************
	* cmos_read
	*
	* Read value from nonvolatile RAM at position given by 'bit' and 'length'
	* and return this value. The I/O privilege level of the currently executing
	* process must be set appropriately.
	****************************************************************************/
	unsigned long long cmos_read(const cmos_entry_t * e)
	{
	cmos_bit_op_location_t where;
	unsigned bit = e->bit, length = e->length;
	unsigned next_bit, bits_left, nr_bits;
	unsigned long long result = 0;
	unsigned char value;

	assert(!verify_cmos_op(bit, length, e->config));
	result = 0;

	if (e->config == CMOS_ENTRY_STRING) {
	char *newstring = calloc(1, (length + 7) / 8);
	unsigned usize = (8 * sizeof(unsigned long long));

	if (!newstring) {
	out_of_memory();
	}

	for (next_bit = 0, bits_left = length;
	bits_left; next_bit += nr_bits, bits_left -= nr_bits) {
	nr_bits = cmos_bit_op_strategy(bit + next_bit,
	bits_left > usize ? usize : bits_left, &where);
	value = cmos_read_bits(&where, nr_bits);
	put_bits(value, next_bit % usize, nr_bits,
	&((unsigned long long *)newstring)[next_bit /
	usize]);
	result = (unsigned long)newstring;
	}
	} else {
	for (next_bit = 0, bits_left = length;
	bits_left; next_bit += nr_bits, bits_left -= nr_bits) {
	nr_bits =
	cmos_bit_op_strategy(bit + next_bit, bits_left,
	&where);
	value = cmos_read_bits(&where, nr_bits);
	put_bits(value, next_bit, nr_bits, &result);
	}
	}

	return result;
	}

	/****************************************************************************
	* cmos_write
	*
	* Write 'data' to nonvolatile RAM at position given by 'bit' and 'length'.
	* The I/O privilege level of the currently executing process must be set
	* appropriately.
	****************************************************************************/
	void cmos_write(const cmos_entry_t * e, unsigned long long value)
	{
	cmos_bit_op_location_t where;
	unsigned bit = e->bit, length = e->length;
	unsigned next_bit, bits_left, nr_bits;

	assert(!verify_cmos_op(bit, length, e->config));

	if (e->config == CMOS_ENTRY_STRING) {
	unsigned long long *data =
	(unsigned long long *)(unsigned long)value;
	unsigned usize = (8 * sizeof(unsigned long long));

	for (next_bit = 0, bits_left = length;
	bits_left; next_bit += nr_bits, bits_left -= nr_bits) {
	nr_bits = cmos_bit_op_strategy(bit + next_bit,
	bits_left > usize ? usize : bits_left,
	&where);
	value = data[next_bit / usize];
	cmos_write_bits(&where, nr_bits,
	get_bits(value, next_bit % usize, nr_bits));
	}
	} else {
	for (next_bit = 0, bits_left = length;
	bits_left; next_bit += nr_bits, bits_left -= nr_bits) {
	nr_bits = cmos_bit_op_strategy(bit + next_bit,
	bits_left, &where);
	cmos_write_bits(&where, nr_bits,
	get_bits(value, next_bit, nr_bits));
	}
	}
	}

	/****************************************************************************
	* cmos_read_byte
	*
	* Read a byte from nonvolatile RAM at a position given by 'index' and return
	* the result. An 'index' value of 0 represents the first byte of
	* nonvolatile RAM.
	*
	* Note: the first 14 bytes of nonvolatile RAM provide an interface to the
	* real time clock.
	****************************************************************************/
	unsigned char cmos_read_byte(unsigned index)
	{
	return current_access->read(index);
	}

	/****************************************************************************
	* cmos_write_byte
	*
	* Write 'value' to nonvolatile RAM at a position given by 'index'. An
	* 'index' of 0 represents the first byte of nonvolatile RAM.
	*
	* Note: the first 14 bytes of nonvolatile RAM provide an interface to the
	* real time clock. Writing to any of these bytes will therefore
	* affect its functioning.
	****************************************************************************/
	void cmos_write_byte(unsigned index, unsigned char value)
	{
	current_access->write(index, value);
	}

	/****************************************************************************
	* cmos_read_all
	*
	* Read all contents of CMOS memory into array 'data'. The first 14 bytes of
	* 'data' are set to zero since this corresponds to the real time clock area.
	****************************************************************************/
	void cmos_read_all(unsigned char data[])
	{
	unsigned i;

	for (i = 0; i < CMOS_RTC_AREA_SIZE; i++)
	data[i] = 0;

	for (; i < CMOS_SIZE; i++)
	data[i] = cmos_read_byte(i);
	}

	/****************************************************************************
	* cmos_write_all
	*
	* Update all of CMOS memory with the contents of array 'data'. The first 14
	* bytes of 'data' are ignored since this corresponds to the real time clock
	* area.
	****************************************************************************/
	void cmos_write_all(unsigned char data[])
	{
	unsigned i;

	for (i = CMOS_RTC_AREA_SIZE; i < CMOS_SIZE; i++)
	cmos_write_byte(i, data[i]);
	}

	/****************************************************************************
	* set_iopl
	*
	* Set the I/O privilege level of the executing process. Root privileges are
	* required for performing this action. A sufficient I/O privilege level
	* allows the process to access x86 I/O address space and to disable/reenable
	* interrupts while executing in user space. Messing with the I/O privilege
	* level is therefore somewhat dangerous.
	****************************************************************************/
	void set_iopl(int level)
	{
	current_access->set_iopl(level);
	}

	/****************************************************************************
	* verify_cmos_op
	*
	* 'bit' represents a bit position in the nonvolatile RAM. The first bit
	* (i.e. the lowest order bit of the first byte) of nonvolatile RAM is
	* labeled as bit 0. 'length' represents the width in bits of a value we
	* wish to read or write. Perform sanity checking on 'bit' and 'length'. If
	* no problems were encountered, return OK. Else return an error code.
	****************************************************************************/
	int verify_cmos_op(unsigned bit, unsigned length, cmos_entry_config_t config)
	{
	if ((bit >= (8 * CMOS_SIZE)) \|\| ((bit + length) > (8 * CMOS_SIZE)))
	return CMOS_AREA_OUT_OF_RANGE;

	if (bit < (8 * CMOS_RTC_AREA_SIZE))
	return CMOS_AREA_OVERLAPS_RTC;

	if (config == CMOS_ENTRY_STRING)
	return OK;

	if (length > (8 * sizeof(unsigned long long)))
	return CMOS_AREA_TOO_WIDE;

	return OK;
	}

	/****************************************************************************
	* cmos_bit_op_strategy
	*
	* Helper function used by cmos_read() and cmos_write() to determine which
	* bits to read or write next.
	****************************************************************************/
	static unsigned cmos_bit_op_strategy(unsigned bit, unsigned bits_left,
	cmos_bit_op_location_t * where)
	{
	unsigned max_bits;

	where->byte_index = bit >> 3;
	where->bit_offset = bit & 0x07;
	max_bits = 8 - where->bit_offset;
	return (bits_left > max_bits) ? max_bits : bits_left;
	}

	/****************************************************************************
	* cmos_read_bits
	*
	* Read a chunk of bits from a byte location within CMOS memory. Return the
	* value represented by the chunk of bits.
	****************************************************************************/
	static unsigned char cmos_read_bits(const cmos_bit_op_location_t * where,
	unsigned nr_bits)
	{
	return (cmos_read_byte(where->byte_index) >> where->bit_offset) &
	((unsigned char)((1 << nr_bits) - 1));
	}

	/****************************************************************************
	* cmos_write_bits
	*
	* Write a chunk of bits (the low order 'nr_bits' bits of 'value') to an area
	* within a particular byte of CMOS memory.
	****************************************************************************/
	static void cmos_write_bits(const cmos_bit_op_location_t * where,
	unsigned nr_bits, unsigned char value)
	{
	unsigned char n, mask;

	if (nr_bits == 8) {
	cmos_write_byte(where->byte_index, value);
	return;
	}

	n = cmos_read_byte(where->byte_index);
	mask = ((unsigned char)((1 << nr_bits) - 1)) << where->bit_offset;
	n = (n & ~mask) + ((value << where->bit_offset) & mask);
	cmos_write_byte(where->byte_index, n);
	}