lib/packing.c - third_party/linux - Git at Google

 // SPDX-License-Identifier: BSD-3-Clause OR GPL-2.0
 /* Copyright (c) 2016-2018, NXP Semiconductors
  * Copyright (c) 2018-2019, Vladimir Oltean <olteanv@gmail.com>
  */
 #include <linux/packing.h>
 #include <linux/module.h>
 #include <linux/bitops.h>
 #include <linux/errno.h>
 #include <linux/types.h>

 static int get_le_offset(int offset)
 {
 	int closest_multiple_of_4;

 	closest_multiple_of_4 = (offset / 4) * 4;
 	offset -= closest_multiple_of_4;
 	return closest_multiple_of_4 + (3 - offset);
 }

 static int get_reverse_lsw32_offset(int offset, size_t len)
 {
 	int closest_multiple_of_4;
 	int word_index;

 	word_index = offset / 4;
 	closest_multiple_of_4 = word_index * 4;
 	offset -= closest_multiple_of_4;
 	word_index = (len / 4) - word_index - 1;
 	return word_index * 4 + offset;
 }

 static u64 bit_reverse(u64 val, unsigned int width)
 {
 	u64 new_val = 0;
 	unsigned int bit;
 	unsigned int i;

 	for (i = 0; i < width; i++) {
 		bit = (val & (1 << i)) != 0;
 		new_val |= (bit << (width - i - 1));
 	}
 	return new_val;
 }

 static void adjust_for_msb_right_quirk(u64 *to_write, int *box_start_bit,
 				       int *box_end_bit, u8 *box_mask)
 {
 	int box_bit_width = *box_start_bit - *box_end_bit + 1;
 	int new_box_start_bit, new_box_end_bit;

 	*to_write >>= *box_end_bit;
 	*to_write = bit_reverse(*to_write, box_bit_width);
 	*to_write <<= *box_end_bit;

 	new_box_end_bit   = box_bit_width - *box_start_bit - 1;
 	new_box_start_bit = box_bit_width - *box_end_bit - 1;
 	*box_mask = GENMASK_ULL(new_box_start_bit, new_box_end_bit);
 	*box_start_bit = new_box_start_bit;
 	*box_end_bit   = new_box_end_bit;
 }

 /**
  * packing - Convert numbers (currently u64) between a packed and an unpacked
  *	     format. Unpacked means laid out in memory in the CPU's native
  *	     understanding of integers, while packed means anything else that
  *	     requires translation.
  *
  * @pbuf: Pointer to a buffer holding the packed value.
  * @uval: Pointer to an u64 holding the unpacked value.
  * @startbit: The index (in logical notation, compensated for quirks) where
  *	      the packed value starts within pbuf. Must be larger than, or
  *	      equal to, endbit.
  * @endbit: The index (in logical notation, compensated for quirks) where
  *	    the packed value ends within pbuf. Must be smaller than, or equal
  *	    to, startbit.
  * @op: If PACK, then uval will be treated as const pointer and copied (packed)
  *	into pbuf, between startbit and endbit.
  *	If UNPACK, then pbuf will be treated as const pointer and the logical
  *	value between startbit and endbit will be copied (unpacked) to uval.
  * @quirks: A bit mask of QUIRK_LITTLE_ENDIAN, QUIRK_LSW32_IS_FIRST and
  *	    QUIRK_MSB_ON_THE_RIGHT.
  *
  * Return: 0 on success, EINVAL or ERANGE if called incorrectly. Assuming
  *	   correct usage, return code may be discarded.
  *	   If op is PACK, pbuf is modified.
  *	   If op is UNPACK, uval is modified.
  */
 int packing(void *pbuf, u64 *uval, int startbit, int endbit, size_t pbuflen,
 	    enum packing_op op, u8 quirks)
 {
 	/* Number of bits for storing "uval"
 	 * also width of the field to access in the pbuf
 	 */
 	u64 value_width;
 	/* Logical byte indices corresponding to the
 	 * start and end of the field.
 	 */
 	int plogical_first_u8, plogical_last_u8, box;

 	/* startbit is expected to be larger than endbit */
 	if (startbit < endbit)
 		/* Invalid function call */
 		return -EINVAL;

 	value_width = startbit - endbit + 1;
 	if (value_width > 64)
 		return -ERANGE;

 	/* Check if "uval" fits in "value_width" bits.
 	 * If value_width is 64, the check will fail, but any
 	 * 64-bit uval will surely fit.
 	 */
 	if (op == PACK && value_width < 64 && (*uval >= (1ull << value_width)))
 		/* Cannot store "uval" inside "value_width" bits.
 		 * Truncating "uval" is most certainly not desirable,
 		 * so simply erroring out is appropriate.
 		 */
 		return -ERANGE;

 	/* Initialize parameter */
 	if (op == UNPACK)
 		*uval = 0;

 	/* Iterate through an idealistic view of the pbuf as an u64 with
 	 * no quirks, u8 by u8 (aligned at u8 boundaries), from high to low
 	 * logical bit significance. "box" denotes the current logical u8.
 	 */
 	plogical_first_u8 = startbit / 8;
 	plogical_last_u8  = endbit / 8;

 	for (box = plogical_first_u8; box >= plogical_last_u8; box--) {
 		/* Bit indices into the currently accessed 8-bit box */
 		int box_start_bit, box_end_bit, box_addr;
 		u8  box_mask;
 		/* Corresponding bits from the unpacked u64 parameter */
 		int proj_start_bit, proj_end_bit;
 		u64 proj_mask;

 		/* This u8 may need to be accessed in its entirety
 		 * (from bit 7 to bit 0), or not, depending on the
 		 * input arguments startbit and endbit.
 		 */
 		if (box == plogical_first_u8)
 			box_start_bit = startbit % 8;
 		else
 			box_start_bit = 7;
 		if (box == plogical_last_u8)
 			box_end_bit = endbit % 8;
 		else
 			box_end_bit = 0;

 		/* We have determined the box bit start and end.
 		 * Now we calculate where this (masked) u8 box would fit
 		 * in the unpacked (CPU-readable) u64 - the u8 box's
 		 * projection onto the unpacked u64. Though the
 		 * box is u8, the projection is u64 because it may fall
 		 * anywhere within the unpacked u64.
 		 */
 		proj_start_bit = ((box * 8) + box_start_bit) - endbit;
 		proj_end_bit   = ((box * 8) + box_end_bit) - endbit;
 		proj_mask = GENMASK_ULL(proj_start_bit, proj_end_bit);
 		box_mask  = GENMASK_ULL(box_start_bit, box_end_bit);

 		/* Determine the offset of the u8 box inside the pbuf,
 		 * adjusted for quirks. The adjusted box_addr will be used for
 		 * effective addressing inside the pbuf (so it's not
 		 * logical any longer).
 		 */
 		box_addr = pbuflen - box - 1;
 		if (quirks & QUIRK_LITTLE_ENDIAN)
 			box_addr = get_le_offset(box_addr);
 		if (quirks & QUIRK_LSW32_IS_FIRST)
 			box_addr = get_reverse_lsw32_offset(box_addr,
 							    pbuflen);

 		if (op == UNPACK) {
 			u64 pval;

 			/* Read from pbuf, write to uval */
 			pval = ((u8 *)pbuf)[box_addr] & box_mask;
 			if (quirks & QUIRK_MSB_ON_THE_RIGHT)
 				adjust_for_msb_right_quirk(&pval,
 							   &box_start_bit,
 							   &box_end_bit,
 							   &box_mask);

 			pval >>= box_end_bit;
 			pval <<= proj_end_bit;
 			*uval &= ~proj_mask;
 			*uval |= pval;
 		} else {
 			u64 pval;

 			/* Write to pbuf, read from uval */
 			pval = (*uval) & proj_mask;
 			pval >>= proj_end_bit;
 			if (quirks & QUIRK_MSB_ON_THE_RIGHT)
 				adjust_for_msb_right_quirk(&pval,
 							   &box_start_bit,
 							   &box_end_bit,
 							   &box_mask);

 			pval <<= box_end_bit;
 			((u8 *)pbuf)[box_addr] &= ~box_mask;
 			((u8 *)pbuf)[box_addr] |= pval;
 		}
 	}
 	return 0;
 }
 EXPORT_SYMBOL(packing);

 MODULE_LICENSE("GPL v2");
 MODULE_DESCRIPTION("Generic bitfield packing and unpacking");
	// SPDX-License-Identifier: BSD-3-Clause OR GPL-2.0
	/* Copyright (c) 2016-2018, NXP Semiconductors
	* Copyright (c) 2018-2019, Vladimir Oltean <olteanv@gmail.com>
	*/
	#include <linux/packing.h>
	#include <linux/module.h>
	#include <linux/bitops.h>
	#include <linux/errno.h>
	#include <linux/types.h>

	static int get_le_offset(int offset)
	{
	int closest_multiple_of_4;

	closest_multiple_of_4 = (offset / 4) * 4;
	offset -= closest_multiple_of_4;
	return closest_multiple_of_4 + (3 - offset);
	}

	static int get_reverse_lsw32_offset(int offset, size_t len)
	{
	int closest_multiple_of_4;
	int word_index;

	word_index = offset / 4;
	closest_multiple_of_4 = word_index * 4;
	offset -= closest_multiple_of_4;
	word_index = (len / 4) - word_index - 1;
	return word_index * 4 + offset;
	}

	static u64 bit_reverse(u64 val, unsigned int width)
	{
	u64 new_val = 0;
	unsigned int bit;
	unsigned int i;

	for (i = 0; i < width; i++) {
	bit = (val & (1 << i)) != 0;
	new_val \|= (bit << (width - i - 1));
	}
	return new_val;
	}

	static void adjust_for_msb_right_quirk(u64 to_write, int box_start_bit,
	int box_end_bit, u8 box_mask)
	{
	int box_bit_width = box_start_bit - box_end_bit + 1;
	int new_box_start_bit, new_box_end_bit;

	to_write >>= box_end_bit;
	to_write = bit_reverse(to_write, box_bit_width);
	to_write <<= box_end_bit;

	new_box_end_bit = box_bit_width - *box_start_bit - 1;
	new_box_start_bit = box_bit_width - *box_end_bit - 1;
	*box_mask = GENMASK_ULL(new_box_start_bit, new_box_end_bit);
	*box_start_bit = new_box_start_bit;
	*box_end_bit = new_box_end_bit;
	}

	/**
	* packing - Convert numbers (currently u64) between a packed and an unpacked
	* format. Unpacked means laid out in memory in the CPU's native
	* understanding of integers, while packed means anything else that
	* requires translation.
	*
	* @pbuf: Pointer to a buffer holding the packed value.
	* @uval: Pointer to an u64 holding the unpacked value.
	* @startbit: The index (in logical notation, compensated for quirks) where
	* the packed value starts within pbuf. Must be larger than, or
	* equal to, endbit.
	* @endbit: The index (in logical notation, compensated for quirks) where
	* the packed value ends within pbuf. Must be smaller than, or equal
	* to, startbit.
	* @op: If PACK, then uval will be treated as const pointer and copied (packed)
	* into pbuf, between startbit and endbit.
	* If UNPACK, then pbuf will be treated as const pointer and the logical
	* value between startbit and endbit will be copied (unpacked) to uval.
	* @quirks: A bit mask of QUIRK_LITTLE_ENDIAN, QUIRK_LSW32_IS_FIRST and
	* QUIRK_MSB_ON_THE_RIGHT.
	*
	* Return: 0 on success, EINVAL or ERANGE if called incorrectly. Assuming
	* correct usage, return code may be discarded.
	* If op is PACK, pbuf is modified.
	* If op is UNPACK, uval is modified.
	*/
	int packing(void pbuf, u64 uval, int startbit, int endbit, size_t pbuflen,
	enum packing_op op, u8 quirks)
	{
	/* Number of bits for storing "uval"
	* also width of the field to access in the pbuf
	*/
	u64 value_width;
	/* Logical byte indices corresponding to the
	* start and end of the field.
	*/
	int plogical_first_u8, plogical_last_u8, box;

	/* startbit is expected to be larger than endbit */
	if (startbit < endbit)
	/* Invalid function call */
	return -EINVAL;

	value_width = startbit - endbit + 1;
	if (value_width > 64)
	return -ERANGE;

	/* Check if "uval" fits in "value_width" bits.
	* If value_width is 64, the check will fail, but any
	* 64-bit uval will surely fit.
	*/
	if (op == PACK && value_width < 64 && (*uval >= (1ull << value_width)))
	/* Cannot store "uval" inside "value_width" bits.
	* Truncating "uval" is most certainly not desirable,
	* so simply erroring out is appropriate.
	*/
	return -ERANGE;

	/* Initialize parameter */
	if (op == UNPACK)
	*uval = 0;

	/* Iterate through an idealistic view of the pbuf as an u64 with
	* no quirks, u8 by u8 (aligned at u8 boundaries), from high to low
	* logical bit significance. "box" denotes the current logical u8.
	*/
	plogical_first_u8 = startbit / 8;
	plogical_last_u8 = endbit / 8;

	for (box = plogical_first_u8; box >= plogical_last_u8; box--) {
	/* Bit indices into the currently accessed 8-bit box */
	int box_start_bit, box_end_bit, box_addr;
	u8 box_mask;
	/* Corresponding bits from the unpacked u64 parameter */
	int proj_start_bit, proj_end_bit;
	u64 proj_mask;

	/* This u8 may need to be accessed in its entirety
	* (from bit 7 to bit 0), or not, depending on the
	* input arguments startbit and endbit.
	*/
	if (box == plogical_first_u8)
	box_start_bit = startbit % 8;
	else
	box_start_bit = 7;
	if (box == plogical_last_u8)
	box_end_bit = endbit % 8;
	else
	box_end_bit = 0;

	/* We have determined the box bit start and end.
	* Now we calculate where this (masked) u8 box would fit
	* in the unpacked (CPU-readable) u64 - the u8 box's
	* projection onto the unpacked u64. Though the
	* box is u8, the projection is u64 because it may fall
	* anywhere within the unpacked u64.
	*/
	proj_start_bit = ((box * 8) + box_start_bit) - endbit;
	proj_end_bit = ((box * 8) + box_end_bit) - endbit;
	proj_mask = GENMASK_ULL(proj_start_bit, proj_end_bit);
	box_mask = GENMASK_ULL(box_start_bit, box_end_bit);

	/* Determine the offset of the u8 box inside the pbuf,
	* adjusted for quirks. The adjusted box_addr will be used for
	* effective addressing inside the pbuf (so it's not
	* logical any longer).
	*/
	box_addr = pbuflen - box - 1;
	if (quirks & QUIRK_LITTLE_ENDIAN)
	box_addr = get_le_offset(box_addr);
	if (quirks & QUIRK_LSW32_IS_FIRST)
	box_addr = get_reverse_lsw32_offset(box_addr,
	pbuflen);

	if (op == UNPACK) {
	u64 pval;

	/* Read from pbuf, write to uval */
	pval = ((u8 *)pbuf)[box_addr] & box_mask;
	if (quirks & QUIRK_MSB_ON_THE_RIGHT)
	adjust_for_msb_right_quirk(&pval,
	&box_start_bit,
	&box_end_bit,
	&box_mask);

	pval >>= box_end_bit;
	pval <<= proj_end_bit;
	*uval &= ~proj_mask;
	*uval \|= pval;
	} else {
	u64 pval;

	/* Write to pbuf, read from uval */
	pval = (*uval) & proj_mask;
	pval >>= proj_end_bit;
	if (quirks & QUIRK_MSB_ON_THE_RIGHT)
	adjust_for_msb_right_quirk(&pval,
	&box_start_bit,
	&box_end_bit,
	&box_mask);

	pval <<= box_end_bit;
	((u8 *)pbuf)[box_addr] &= ~box_mask;
	((u8 *)pbuf)[box_addr] \|= pval;
	}
	}
	return 0;
	}
	EXPORT_SYMBOL(packing);

	MODULE_LICENSE("GPL v2");
	MODULE_DESCRIPTION("Generic bitfield packing and unpacking");