numam-dpdk/drivers/net/ice/base/ice_bitops.h
Qi Zhang 61da836257 net/ice/base: update copyright
Updated copyright to 2022 and update base code version.

Signed-off-by: Paul M Stillwell Jr <paul.m.stillwell.jr@intel.com>
Signed-off-by: Qi Zhang <qi.z.zhang@intel.com>
Acked-by: Qiming Yang <qiming.yang@intel.com>
2022-09-18 16:12:32 +02:00

501 lines
14 KiB
C

/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2001-2022 Intel Corporation
*/
#ifndef _ICE_BITOPS_H_
#define _ICE_BITOPS_H_
#include "ice_defs.h"
#include "ice_osdep.h"
/* Define the size of the bitmap chunk */
typedef u32 ice_bitmap_t;
/* Number of bits per bitmap chunk */
#define BITS_PER_CHUNK (BITS_PER_BYTE * sizeof(ice_bitmap_t))
/* Determine which chunk a bit belongs in */
#define BIT_CHUNK(nr) ((nr) / BITS_PER_CHUNK)
/* How many chunks are required to store this many bits */
#define BITS_TO_CHUNKS(sz) (((sz) + BITS_PER_CHUNK - 1) / BITS_PER_CHUNK)
/* Which bit inside a chunk this bit corresponds to */
#define BIT_IN_CHUNK(nr) ((nr) % BITS_PER_CHUNK)
/* How many bits are valid in the last chunk, assumes nr > 0 */
#define LAST_CHUNK_BITS(nr) ((((nr) - 1) % BITS_PER_CHUNK) + 1)
/* Generate a bitmask of valid bits in the last chunk, assumes nr > 0 */
#define LAST_CHUNK_MASK(nr) (((ice_bitmap_t)~0) >> \
(BITS_PER_CHUNK - LAST_CHUNK_BITS(nr)))
#define ice_declare_bitmap(A, sz) \
ice_bitmap_t A[BITS_TO_CHUNKS(sz)]
static inline bool ice_is_bit_set_internal(u16 nr, const ice_bitmap_t *bitmap)
{
return !!(*bitmap & BIT(nr));
}
/*
* If atomic version of the bitops are required, each specific OS
* implementation will need to implement OS/platform specific atomic
* version of the functions below:
*
* ice_clear_bit_internal
* ice_set_bit_internal
* ice_test_and_clear_bit_internal
* ice_test_and_set_bit_internal
*
* and define macro ICE_ATOMIC_BITOPS to overwrite the default non-atomic
* implementation.
*/
static inline void ice_clear_bit_internal(u16 nr, ice_bitmap_t *bitmap)
{
*bitmap &= ~BIT(nr);
}
static inline void ice_set_bit_internal(u16 nr, ice_bitmap_t *bitmap)
{
*bitmap |= BIT(nr);
}
static inline bool ice_test_and_clear_bit_internal(u16 nr,
ice_bitmap_t *bitmap)
{
if (ice_is_bit_set_internal(nr, bitmap)) {
ice_clear_bit_internal(nr, bitmap);
return true;
}
return false;
}
static inline bool ice_test_and_set_bit_internal(u16 nr, ice_bitmap_t *bitmap)
{
if (ice_is_bit_set_internal(nr, bitmap))
return true;
ice_set_bit_internal(nr, bitmap);
return false;
}
/**
* ice_is_bit_set - Check state of a bit in a bitmap
* @bitmap: the bitmap to check
* @nr: the bit to check
*
* Returns true if bit nr of bitmap is set. False otherwise. Assumes that nr
* is less than the size of the bitmap.
*/
static inline bool ice_is_bit_set(const ice_bitmap_t *bitmap, u16 nr)
{
return ice_is_bit_set_internal(BIT_IN_CHUNK(nr),
&bitmap[BIT_CHUNK(nr)]);
}
/**
* ice_clear_bit - Clear a bit in a bitmap
* @bitmap: the bitmap to change
* @nr: the bit to change
*
* Clears the bit nr in bitmap. Assumes that nr is less than the size of the
* bitmap.
*/
static inline void ice_clear_bit(u16 nr, ice_bitmap_t *bitmap)
{
ice_clear_bit_internal(BIT_IN_CHUNK(nr), &bitmap[BIT_CHUNK(nr)]);
}
/**
* ice_set_bit - Set a bit in a bitmap
* @bitmap: the bitmap to change
* @nr: the bit to change
*
* Sets the bit nr in bitmap. Assumes that nr is less than the size of the
* bitmap.
*/
static inline void ice_set_bit(u16 nr, ice_bitmap_t *bitmap)
{
ice_set_bit_internal(BIT_IN_CHUNK(nr), &bitmap[BIT_CHUNK(nr)]);
}
/**
* ice_test_and_clear_bit - Atomically clear a bit and return the old bit value
* @nr: the bit to change
* @bitmap: the bitmap to change
*
* Check and clear the bit nr in bitmap. Assumes that nr is less than the size
* of the bitmap.
*/
static inline bool
ice_test_and_clear_bit(u16 nr, ice_bitmap_t *bitmap)
{
return ice_test_and_clear_bit_internal(BIT_IN_CHUNK(nr),
&bitmap[BIT_CHUNK(nr)]);
}
/**
* ice_test_and_set_bit - Atomically set a bit and return the old bit value
* @nr: the bit to change
* @bitmap: the bitmap to change
*
* Check and set the bit nr in bitmap. Assumes that nr is less than the size of
* the bitmap.
*/
static inline bool
ice_test_and_set_bit(u16 nr, ice_bitmap_t *bitmap)
{
return ice_test_and_set_bit_internal(BIT_IN_CHUNK(nr),
&bitmap[BIT_CHUNK(nr)]);
}
/* ice_zero_bitmap - set bits of bitmap to zero.
* @bmp: bitmap to set zeros
* @size: Size of the bitmaps in bits
*
* Set all of the bits in a bitmap to zero. Note that this function assumes it
* operates on an ice_bitmap_t which was declared using ice_declare_bitmap. It
* will zero every bit in the last chunk, even if those bits are beyond the
* size.
*/
static inline void ice_zero_bitmap(ice_bitmap_t *bmp, u16 size)
{
ice_memset(bmp, 0, BITS_TO_CHUNKS(size) * sizeof(ice_bitmap_t),
ICE_NONDMA_MEM);
}
/**
* ice_and_bitmap - bitwise AND 2 bitmaps and store result in dst bitmap
* @dst: Destination bitmap that receive the result of the operation
* @bmp1: The first bitmap to intersect
* @bmp2: The second bitmap to intersect wit the first
* @size: Size of the bitmaps in bits
*
* This function performs a bitwise AND on two "source" bitmaps of the same size
* and stores the result to "dst" bitmap. The "dst" bitmap must be of the same
* size as the "source" bitmaps to avoid buffer overflows. This function returns
* a non-zero value if at least one bit location from both "source" bitmaps is
* non-zero.
*/
static inline int
ice_and_bitmap(ice_bitmap_t *dst, const ice_bitmap_t *bmp1,
const ice_bitmap_t *bmp2, u16 size)
{
ice_bitmap_t res = 0, mask;
u16 i;
/* Handle all but the last chunk */
for (i = 0; i < BITS_TO_CHUNKS(size) - 1; i++) {
dst[i] = bmp1[i] & bmp2[i];
res |= dst[i];
}
/* We want to take care not to modify any bits outside of the bitmap
* size, even in the destination bitmap. Thus, we won't directly
* assign the last bitmap, but instead use a bitmask to ensure we only
* modify bits which are within the size, and leave any bits above the
* size value alone.
*/
mask = LAST_CHUNK_MASK(size);
dst[i] = (dst[i] & ~mask) | ((bmp1[i] & bmp2[i]) & mask);
res |= dst[i] & mask;
return res != 0;
}
/**
* ice_or_bitmap - bitwise OR 2 bitmaps and store result in dst bitmap
* @dst: Destination bitmap that receive the result of the operation
* @bmp1: The first bitmap to intersect
* @bmp2: The second bitmap to intersect wit the first
* @size: Size of the bitmaps in bits
*
* This function performs a bitwise OR on two "source" bitmaps of the same size
* and stores the result to "dst" bitmap. The "dst" bitmap must be of the same
* size as the "source" bitmaps to avoid buffer overflows.
*/
static inline void
ice_or_bitmap(ice_bitmap_t *dst, const ice_bitmap_t *bmp1,
const ice_bitmap_t *bmp2, u16 size)
{
ice_bitmap_t mask;
u16 i;
/* Handle all but last chunk */
for (i = 0; i < BITS_TO_CHUNKS(size) - 1; i++)
dst[i] = bmp1[i] | bmp2[i];
/* We want to only OR bits within the size. Furthermore, we also do
* not want to modify destination bits which are beyond the specified
* size. Use a bitmask to ensure that we only modify the bits that are
* within the specified size.
*/
mask = LAST_CHUNK_MASK(size);
dst[i] = (dst[i] & ~mask) | ((bmp1[i] | bmp2[i]) & mask);
}
/**
* ice_xor_bitmap - bitwise XOR 2 bitmaps and store result in dst bitmap
* @dst: Destination bitmap that receive the result of the operation
* @bmp1: The first bitmap of XOR operation
* @bmp2: The second bitmap to XOR with the first
* @size: Size of the bitmaps in bits
*
* This function performs a bitwise XOR on two "source" bitmaps of the same size
* and stores the result to "dst" bitmap. The "dst" bitmap must be of the same
* size as the "source" bitmaps to avoid buffer overflows.
*/
static inline void
ice_xor_bitmap(ice_bitmap_t *dst, const ice_bitmap_t *bmp1,
const ice_bitmap_t *bmp2, u16 size)
{
ice_bitmap_t mask;
u16 i;
/* Handle all but last chunk */
for (i = 0; i < BITS_TO_CHUNKS(size) - 1; i++)
dst[i] = bmp1[i] ^ bmp2[i];
/* We want to only XOR bits within the size. Furthermore, we also do
* not want to modify destination bits which are beyond the specified
* size. Use a bitmask to ensure that we only modify the bits that are
* within the specified size.
*/
mask = LAST_CHUNK_MASK(size);
dst[i] = (dst[i] & ~mask) | ((bmp1[i] ^ bmp2[i]) & mask);
}
/**
* ice_andnot_bitmap - bitwise ANDNOT 2 bitmaps and result in dst bitmap
* @dst: Destination bitmap that receive the result of the operation
* @bmp1: The first bitmap of ANDNOT operation
* @bmp2: The second bitmap to ANDNOT operation
* @size: Size of the bitmaps in bits
*
* This function performs a bitwise ANDNOT on two "source" bitmaps of the same
* size, and stores the result to "dst" bitmap. The "dst" bitmap must be of the
* same size as the "source" bitmaps to avoid buffer overflows.
*/
static inline void
ice_andnot_bitmap(ice_bitmap_t *dst, const ice_bitmap_t *bmp1,
const ice_bitmap_t *bmp2, u16 size)
{
ice_bitmap_t mask;
u16 i;
/* Handle all but last chunk */
for (i = 0; i < BITS_TO_CHUNKS(size) - 1; i++)
dst[i] = bmp1[i] & ~bmp2[i];
/* We want to only clear bits within the size. Furthermore, we also do
* not want to modify destination bits which are beyond the specified
* size. Use a bitmask to ensure that we only modify the bits that are
* within the specified size.
*/
mask = LAST_CHUNK_MASK(size);
dst[i] = (dst[i] & ~mask) | ((bmp1[i] & ~bmp2[i]) & mask);
}
/**
* ice_find_next_bit - Find the index of the next set bit of a bitmap
* @bitmap: the bitmap to scan
* @size: the size in bits of the bitmap
* @offset: the offset to start at
*
* Scans the bitmap and returns the index of the first set bit which is equal
* to or after the specified offset. Will return size if no bits are set.
*/
static inline u16
ice_find_next_bit(const ice_bitmap_t *bitmap, u16 size, u16 offset)
{
u16 i, j;
if (offset >= size)
return size;
/* Since the starting position may not be directly on a chunk
* boundary, we need to be careful to handle the first chunk specially
*/
i = BIT_CHUNK(offset);
if (bitmap[i] != 0) {
u16 off = i * BITS_PER_CHUNK;
for (j = offset % BITS_PER_CHUNK; j < BITS_PER_CHUNK; j++) {
if (ice_is_bit_set(bitmap, off + j))
return min(size, (u16)(off + j));
}
}
/* Now we handle the remaining chunks, if any */
for (i++; i < BITS_TO_CHUNKS(size); i++) {
if (bitmap[i] != 0) {
u16 off = i * BITS_PER_CHUNK;
for (j = 0; j < BITS_PER_CHUNK; j++) {
if (ice_is_bit_set(bitmap, off + j))
return min(size, (u16)(off + j));
}
}
}
return size;
}
/**
* ice_find_first_bit - Find the index of the first set bit of a bitmap
* @bitmap: the bitmap to scan
* @size: the size in bits of the bitmap
*
* Scans the bitmap and returns the index of the first set bit. Will return
* size if no bits are set.
*/
static inline u16 ice_find_first_bit(const ice_bitmap_t *bitmap, u16 size)
{
return ice_find_next_bit(bitmap, size, 0);
}
#define ice_for_each_set_bit(_bitpos, _addr, _maxlen) \
for ((_bitpos) = ice_find_first_bit((_addr), (_maxlen)); \
(_bitpos) < (_maxlen); \
(_bitpos) = ice_find_next_bit((_addr), (_maxlen), (_bitpos) + 1))
/**
* ice_is_any_bit_set - Return true of any bit in the bitmap is set
* @bitmap: the bitmap to check
* @size: the size of the bitmap
*
* Equivalent to checking if ice_find_first_bit returns a value less than the
* bitmap size.
*/
static inline bool ice_is_any_bit_set(ice_bitmap_t *bitmap, u16 size)
{
return ice_find_first_bit(bitmap, size) < size;
}
/**
* ice_cp_bitmap - copy bitmaps.
* @dst: bitmap destination
* @src: bitmap to copy from
* @size: Size of the bitmaps in bits
*
* This function copy bitmap from src to dst. Note that this function assumes
* it is operating on a bitmap declared using ice_declare_bitmap. It will copy
* the entire last chunk even if this contains bits beyond the size.
*/
static inline void ice_cp_bitmap(ice_bitmap_t *dst, ice_bitmap_t *src, u16 size)
{
ice_memcpy(dst, src, BITS_TO_CHUNKS(size) * sizeof(ice_bitmap_t),
ICE_NONDMA_TO_NONDMA);
}
/**
* ice_bitmap_set - set a number of bits in bitmap from a starting position
* @dst: bitmap destination
* @pos: first bit position to set
* @num_bits: number of bits to set
*
* This function sets bits in a bitmap from pos to (pos + num_bits) - 1.
* Note that this function assumes it is operating on a bitmap declared using
* ice_declare_bitmap.
*/
static inline void
ice_bitmap_set(ice_bitmap_t *dst, u16 pos, u16 num_bits)
{
u16 i;
for (i = pos; i < pos + num_bits; i++)
ice_set_bit(i, dst);
}
/**
* ice_bitmap_hweight - hamming weight of bitmap
* @bm: bitmap pointer
* @size: size of bitmap (in bits)
*
* This function determines the number of set bits in a bitmap.
* Note that this function assumes it is operating on a bitmap declared using
* ice_declare_bitmap.
*/
static inline int
ice_bitmap_hweight(ice_bitmap_t *bm, u16 size)
{
int count = 0;
u16 bit = 0;
while (size > (bit = ice_find_next_bit(bm, size, bit))) {
count++;
bit++;
}
return count;
}
/**
* ice_cmp_bitmaps - compares two bitmaps.
* @bmp1: the bitmap to compare
* @bmp2: the bitmap to compare with bmp1
* @size: Size of the bitmaps in bits
*
* This function compares two bitmaps, and returns result as true or false.
*/
static inline bool
ice_cmp_bitmap(ice_bitmap_t *bmp1, ice_bitmap_t *bmp2, u16 size)
{
ice_bitmap_t mask;
u16 i;
/* Handle all but last chunk */
for (i = 0; i < BITS_TO_CHUNKS(size) - 1; i++)
if (bmp1[i] != bmp2[i])
return false;
/* We want to only compare bits within the size */
mask = LAST_CHUNK_MASK(size);
if ((bmp1[i] & mask) != (bmp2[i] & mask))
return false;
return true;
}
/**
* ice_bitmap_from_array32 - copies u32 array source into bitmap destination
* @dst: the destination bitmap
* @src: the source u32 array
* @size: size of the bitmap (in bits)
*
* This function copies the src bitmap stored in an u32 array into the dst
* bitmap stored as an ice_bitmap_t.
*/
static inline void
ice_bitmap_from_array32(ice_bitmap_t *dst, u32 *src, u16 size)
{
u32 remaining_bits, i;
#define BITS_PER_U32 (sizeof(u32) * BITS_PER_BYTE)
/* clear bitmap so we only have to set when iterating */
ice_zero_bitmap(dst, size);
for (i = 0; i < (u32)(size / BITS_PER_U32); i++) {
u32 bit_offset = i * BITS_PER_U32;
u32 entry = src[i];
u32 j;
for (j = 0; j < BITS_PER_U32; j++) {
if (entry & BIT(j))
ice_set_bit((u16)(j + bit_offset), dst);
}
}
/* still need to check the leftover bits (i.e. if size isn't evenly
* divisible by BITS_PER_U32
**/
remaining_bits = size % BITS_PER_U32;
if (remaining_bits) {
u32 bit_offset = i * BITS_PER_U32;
u32 entry = src[i];
u32 j;
for (j = 0; j < remaining_bits; j++) {
if (entry & BIT(j))
ice_set_bit((u16)(j + bit_offset), dst);
}
}
}
#endif /* _ICE_BITOPS_H_ */