Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Stefano Brivio | 6495 | 99.30% | 10 | 58.82% |
Florian Westphal | 40 | 0.61% | 4 | 23.53% |
Paul Gortmaker | 3 | 0.05% | 1 | 5.88% |
Pablo Neira Ayuso | 2 | 0.03% | 1 | 5.88% |
Linus Torvalds | 1 | 0.02% | 1 | 5.88% |
Total | 6541 | 17 |
// SPDX-License-Identifier: GPL-2.0-only /* PIPAPO: PIle PAcket POlicies: AVX2 packet lookup routines * * Copyright (c) 2019-2020 Red Hat GmbH * * Author: Stefano Brivio <sbrivio@redhat.com> */ #include <linux/kernel.h> #include <linux/init.h> #include <linux/module.h> #include <linux/netlink.h> #include <linux/netfilter.h> #include <linux/netfilter/nf_tables.h> #include <net/netfilter/nf_tables_core.h> #include <uapi/linux/netfilter/nf_tables.h> #include <linux/bitmap.h> #include <linux/bitops.h> #include <linux/compiler.h> #include <asm/fpu/api.h> #include "nft_set_pipapo_avx2.h" #include "nft_set_pipapo.h" #define NFT_PIPAPO_LONGS_PER_M256 (XSAVE_YMM_SIZE / BITS_PER_LONG) /* Load from memory into YMM register with non-temporal hint ("stream load"), * that is, don't fetch lines from memory into the cache. This avoids pushing * precious packet data out of the cache hierarchy, and is appropriate when: * * - loading buckets from lookup tables, as they are not going to be used * again before packets are entirely classified * * - loading the result bitmap from the previous field, as it's never used * again */ #define NFT_PIPAPO_AVX2_LOAD(reg, loc) \ asm volatile("vmovntdqa %0, %%ymm" #reg : : "m" (loc)) /* Stream a single lookup table bucket into YMM register given lookup table, * group index, value of packet bits, bucket size. */ #define NFT_PIPAPO_AVX2_BUCKET_LOAD4(reg, lt, group, v, bsize) \ NFT_PIPAPO_AVX2_LOAD(reg, \ lt[((group) * NFT_PIPAPO_BUCKETS(4) + \ (v)) * (bsize)]) #define NFT_PIPAPO_AVX2_BUCKET_LOAD8(reg, lt, group, v, bsize) \ NFT_PIPAPO_AVX2_LOAD(reg, \ lt[((group) * NFT_PIPAPO_BUCKETS(8) + \ (v)) * (bsize)]) /* Bitwise AND: the staple operation of this algorithm */ #define NFT_PIPAPO_AVX2_AND(dst, a, b) \ asm volatile("vpand %ymm" #a ", %ymm" #b ", %ymm" #dst) /* Jump to label if @reg is zero */ #define NFT_PIPAPO_AVX2_NOMATCH_GOTO(reg, label) \ asm goto("vptest %%ymm" #reg ", %%ymm" #reg ";" \ "je %l[" #label "]" : : : : label) /* Store 256 bits from YMM register into memory. Contrary to bucket load * operation, we don't bypass the cache here, as stored matching results * are always used shortly after. */ #define NFT_PIPAPO_AVX2_STORE(loc, reg) \ asm volatile("vmovdqa %%ymm" #reg ", %0" : "=m" (loc)) /* Zero out a complete YMM register, @reg */ #define NFT_PIPAPO_AVX2_ZERO(reg) \ asm volatile("vpxor %ymm" #reg ", %ymm" #reg ", %ymm" #reg) /** * nft_pipapo_avx2_prepare() - Prepare before main algorithm body * * This zeroes out ymm15, which is later used whenever we need to clear a * memory location, by storing its content into memory. */ static void nft_pipapo_avx2_prepare(void) { NFT_PIPAPO_AVX2_ZERO(15); } /** * nft_pipapo_avx2_fill() - Fill a bitmap region with ones * @data: Base memory area * @start: First bit to set * @len: Count of bits to fill * * This is nothing else than a version of bitmap_set(), as used e.g. by * pipapo_refill(), tailored for the microarchitectures using it and better * suited for the specific usage: it's very likely that we'll set a small number * of bits, not crossing a word boundary, and correct branch prediction is * critical here. * * This function doesn't actually use any AVX2 instruction. */ static void nft_pipapo_avx2_fill(unsigned long *data, int start, int len) { int offset = start % BITS_PER_LONG; unsigned long mask; data += start / BITS_PER_LONG; if (likely(len == 1)) { *data |= BIT(offset); return; } if (likely(len < BITS_PER_LONG || offset)) { if (likely(len + offset <= BITS_PER_LONG)) { *data |= GENMASK(len - 1 + offset, offset); return; } *data |= ~0UL << offset; len -= BITS_PER_LONG - offset; data++; if (len <= BITS_PER_LONG) { mask = ~0UL >> (BITS_PER_LONG - len); *data |= mask; return; } } memset(data, 0xff, len / BITS_PER_BYTE); data += len / BITS_PER_LONG; len %= BITS_PER_LONG; if (len) *data |= ~0UL >> (BITS_PER_LONG - len); } /** * nft_pipapo_avx2_refill() - Scan bitmap, select mapping table item, set bits * @offset: Start from given bitmap (equivalent to bucket) offset, in longs * @map: Bitmap to be scanned for set bits * @dst: Destination bitmap * @mt: Mapping table containing bit set specifiers * @last: Return index of first set bit, if this is the last field * * This is an alternative implementation of pipapo_refill() suitable for usage * with AVX2 lookup routines: we know there are four words to be scanned, at * a given offset inside the map, for each matching iteration. * * This function doesn't actually use any AVX2 instruction. * * Return: first set bit index if @last, index of first filled word otherwise. */ static int nft_pipapo_avx2_refill(int offset, unsigned long *map, unsigned long *dst, union nft_pipapo_map_bucket *mt, bool last) { int ret = -1; #define NFT_PIPAPO_AVX2_REFILL_ONE_WORD(x) \ do { \ while (map[(x)]) { \ int r = __builtin_ctzl(map[(x)]); \ int i = (offset + (x)) * BITS_PER_LONG + r; \ \ if (last) \ return i; \ \ nft_pipapo_avx2_fill(dst, mt[i].to, mt[i].n); \ \ if (ret == -1) \ ret = mt[i].to; \ \ map[(x)] &= ~(1UL << r); \ } \ } while (0) NFT_PIPAPO_AVX2_REFILL_ONE_WORD(0); NFT_PIPAPO_AVX2_REFILL_ONE_WORD(1); NFT_PIPAPO_AVX2_REFILL_ONE_WORD(2); NFT_PIPAPO_AVX2_REFILL_ONE_WORD(3); #undef NFT_PIPAPO_AVX2_REFILL_ONE_WORD return ret; } /** * nft_pipapo_avx2_lookup_4b_2() - AVX2-based lookup for 2 four-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * Load buckets from lookup table corresponding to the values of each 4-bit * group of packet bytes, and perform a bitwise intersection between them. If * this is the first field in the set, simply AND the buckets together * (equivalent to using an all-ones starting bitmap), use the provided starting * bitmap otherwise. Then call nft_pipapo_avx2_refill() to generate the next * working bitmap, @fill. * * This is used for 8-bit fields (i.e. protocol numbers). * * Out-of-order (and superscalar) execution is vital here, so it's critical to * avoid false data dependencies. CPU and compiler could (mostly) take care of * this on their own, but the operation ordering is explicitly given here with * a likely execution order in mind, to highlight possible stalls. That's why * a number of logically distinct operations (i.e. loading buckets, intersecting * buckets) are interleaved. * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_4b_2(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; u8 pg[2] = { pkt[0] >> 4, pkt[0] & 0xf }; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (first) { NFT_PIPAPO_AVX2_BUCKET_LOAD4(0, lt, 0, pg[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(1, lt, 1, pg[1], bsize); NFT_PIPAPO_AVX2_AND(4, 0, 1); } else { NFT_PIPAPO_AVX2_BUCKET_LOAD4(0, lt, 0, pg[0], bsize); NFT_PIPAPO_AVX2_LOAD(2, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD4(1, lt, 1, pg[1], bsize); NFT_PIPAPO_AVX2_NOMATCH_GOTO(2, nothing); NFT_PIPAPO_AVX2_AND(3, 0, 1); NFT_PIPAPO_AVX2_AND(4, 2, 3); } NFT_PIPAPO_AVX2_NOMATCH_GOTO(4, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 4); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_4b_4() - AVX2-based lookup for 4 four-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 16-bit fields (i.e. ports). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_4b_4(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; u8 pg[4] = { pkt[0] >> 4, pkt[0] & 0xf, pkt[1] >> 4, pkt[1] & 0xf }; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (first) { NFT_PIPAPO_AVX2_BUCKET_LOAD4(0, lt, 0, pg[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(1, lt, 1, pg[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(2, lt, 2, pg[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 3, pg[3], bsize); NFT_PIPAPO_AVX2_AND(4, 0, 1); NFT_PIPAPO_AVX2_AND(5, 2, 3); NFT_PIPAPO_AVX2_AND(7, 4, 5); } else { NFT_PIPAPO_AVX2_BUCKET_LOAD4(0, lt, 0, pg[0], bsize); NFT_PIPAPO_AVX2_LOAD(1, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD4(2, lt, 1, pg[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 2, pg[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(4, lt, 3, pg[3], bsize); NFT_PIPAPO_AVX2_AND(5, 0, 1); NFT_PIPAPO_AVX2_NOMATCH_GOTO(1, nothing); NFT_PIPAPO_AVX2_AND(6, 2, 3); NFT_PIPAPO_AVX2_AND(7, 4, 5); /* Stall */ NFT_PIPAPO_AVX2_AND(7, 6, 7); } /* Stall */ NFT_PIPAPO_AVX2_NOMATCH_GOTO(7, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 7); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_4b_8() - AVX2-based lookup for 8 four-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 32-bit fields (i.e. IPv4 addresses). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_4b_8(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { u8 pg[8] = { pkt[0] >> 4, pkt[0] & 0xf, pkt[1] >> 4, pkt[1] & 0xf, pkt[2] >> 4, pkt[2] & 0xf, pkt[3] >> 4, pkt[3] & 0xf, }; int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (first) { NFT_PIPAPO_AVX2_BUCKET_LOAD4(0, lt, 0, pg[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(1, lt, 1, pg[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(2, lt, 2, pg[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 3, pg[3], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(4, lt, 4, pg[4], bsize); NFT_PIPAPO_AVX2_AND(5, 0, 1); NFT_PIPAPO_AVX2_BUCKET_LOAD4(6, lt, 5, pg[5], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(7, lt, 6, pg[6], bsize); NFT_PIPAPO_AVX2_AND(8, 2, 3); NFT_PIPAPO_AVX2_AND(9, 4, 5); NFT_PIPAPO_AVX2_BUCKET_LOAD4(10, lt, 7, pg[7], bsize); NFT_PIPAPO_AVX2_AND(11, 6, 7); NFT_PIPAPO_AVX2_AND(12, 8, 9); NFT_PIPAPO_AVX2_AND(13, 10, 11); /* Stall */ NFT_PIPAPO_AVX2_AND(1, 12, 13); } else { NFT_PIPAPO_AVX2_BUCKET_LOAD4(0, lt, 0, pg[0], bsize); NFT_PIPAPO_AVX2_LOAD(1, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD4(2, lt, 1, pg[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 2, pg[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(4, lt, 3, pg[3], bsize); NFT_PIPAPO_AVX2_NOMATCH_GOTO(1, nothing); NFT_PIPAPO_AVX2_AND(5, 0, 1); NFT_PIPAPO_AVX2_BUCKET_LOAD4(6, lt, 4, pg[4], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(7, lt, 5, pg[5], bsize); NFT_PIPAPO_AVX2_AND(8, 2, 3); NFT_PIPAPO_AVX2_BUCKET_LOAD4(9, lt, 6, pg[6], bsize); NFT_PIPAPO_AVX2_AND(10, 4, 5); NFT_PIPAPO_AVX2_BUCKET_LOAD4(11, lt, 7, pg[7], bsize); NFT_PIPAPO_AVX2_AND(12, 6, 7); NFT_PIPAPO_AVX2_AND(13, 8, 9); NFT_PIPAPO_AVX2_AND(14, 10, 11); /* Stall */ NFT_PIPAPO_AVX2_AND(1, 12, 13); NFT_PIPAPO_AVX2_AND(1, 1, 14); } NFT_PIPAPO_AVX2_NOMATCH_GOTO(1, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 1); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_4b_12() - AVX2-based lookup for 12 four-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 48-bit fields (i.e. MAC addresses/EUI-48). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_4b_12(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { u8 pg[12] = { pkt[0] >> 4, pkt[0] & 0xf, pkt[1] >> 4, pkt[1] & 0xf, pkt[2] >> 4, pkt[2] & 0xf, pkt[3] >> 4, pkt[3] & 0xf, pkt[4] >> 4, pkt[4] & 0xf, pkt[5] >> 4, pkt[5] & 0xf, }; int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (!first) NFT_PIPAPO_AVX2_LOAD(0, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD4(1, lt, 0, pg[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(2, lt, 1, pg[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 2, pg[2], bsize); if (!first) { NFT_PIPAPO_AVX2_NOMATCH_GOTO(0, nothing); NFT_PIPAPO_AVX2_AND(1, 1, 0); } NFT_PIPAPO_AVX2_BUCKET_LOAD4(4, lt, 3, pg[3], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(5, lt, 4, pg[4], bsize); NFT_PIPAPO_AVX2_AND(6, 2, 3); NFT_PIPAPO_AVX2_BUCKET_LOAD4(7, lt, 5, pg[5], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(8, lt, 6, pg[6], bsize); NFT_PIPAPO_AVX2_AND(9, 1, 4); NFT_PIPAPO_AVX2_BUCKET_LOAD4(10, lt, 7, pg[7], bsize); NFT_PIPAPO_AVX2_AND(11, 5, 6); NFT_PIPAPO_AVX2_BUCKET_LOAD4(12, lt, 8, pg[8], bsize); NFT_PIPAPO_AVX2_AND(13, 7, 8); NFT_PIPAPO_AVX2_BUCKET_LOAD4(14, lt, 9, pg[9], bsize); NFT_PIPAPO_AVX2_AND(0, 9, 10); NFT_PIPAPO_AVX2_BUCKET_LOAD4(1, lt, 10, pg[10], bsize); NFT_PIPAPO_AVX2_AND(2, 11, 12); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 11, pg[11], bsize); NFT_PIPAPO_AVX2_AND(4, 13, 14); NFT_PIPAPO_AVX2_AND(5, 0, 1); NFT_PIPAPO_AVX2_AND(6, 2, 3); /* Stalls */ NFT_PIPAPO_AVX2_AND(7, 4, 5); NFT_PIPAPO_AVX2_AND(8, 6, 7); NFT_PIPAPO_AVX2_NOMATCH_GOTO(8, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 8); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_4b_32() - AVX2-based lookup for 32 four-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 128-bit fields (i.e. IPv6 addresses). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_4b_32(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { u8 pg[32] = { pkt[0] >> 4, pkt[0] & 0xf, pkt[1] >> 4, pkt[1] & 0xf, pkt[2] >> 4, pkt[2] & 0xf, pkt[3] >> 4, pkt[3] & 0xf, pkt[4] >> 4, pkt[4] & 0xf, pkt[5] >> 4, pkt[5] & 0xf, pkt[6] >> 4, pkt[6] & 0xf, pkt[7] >> 4, pkt[7] & 0xf, pkt[8] >> 4, pkt[8] & 0xf, pkt[9] >> 4, pkt[9] & 0xf, pkt[10] >> 4, pkt[10] & 0xf, pkt[11] >> 4, pkt[11] & 0xf, pkt[12] >> 4, pkt[12] & 0xf, pkt[13] >> 4, pkt[13] & 0xf, pkt[14] >> 4, pkt[14] & 0xf, pkt[15] >> 4, pkt[15] & 0xf, }; int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (!first) NFT_PIPAPO_AVX2_LOAD(0, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD4(1, lt, 0, pg[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(2, lt, 1, pg[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 2, pg[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(4, lt, 3, pg[3], bsize); if (!first) { NFT_PIPAPO_AVX2_NOMATCH_GOTO(0, nothing); NFT_PIPAPO_AVX2_AND(1, 1, 0); } NFT_PIPAPO_AVX2_AND(5, 2, 3); NFT_PIPAPO_AVX2_BUCKET_LOAD4(6, lt, 4, pg[4], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(7, lt, 5, pg[5], bsize); NFT_PIPAPO_AVX2_AND(8, 1, 4); NFT_PIPAPO_AVX2_BUCKET_LOAD4(9, lt, 6, pg[6], bsize); NFT_PIPAPO_AVX2_AND(10, 5, 6); NFT_PIPAPO_AVX2_BUCKET_LOAD4(11, lt, 7, pg[7], bsize); NFT_PIPAPO_AVX2_AND(12, 7, 8); NFT_PIPAPO_AVX2_BUCKET_LOAD4(13, lt, 8, pg[8], bsize); NFT_PIPAPO_AVX2_AND(14, 9, 10); NFT_PIPAPO_AVX2_BUCKET_LOAD4(0, lt, 9, pg[9], bsize); NFT_PIPAPO_AVX2_AND(1, 11, 12); NFT_PIPAPO_AVX2_BUCKET_LOAD4(2, lt, 10, pg[10], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 11, pg[11], bsize); NFT_PIPAPO_AVX2_AND(4, 13, 14); NFT_PIPAPO_AVX2_BUCKET_LOAD4(5, lt, 12, pg[12], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(6, lt, 13, pg[13], bsize); NFT_PIPAPO_AVX2_AND(7, 0, 1); NFT_PIPAPO_AVX2_BUCKET_LOAD4(8, lt, 14, pg[14], bsize); NFT_PIPAPO_AVX2_AND(9, 2, 3); NFT_PIPAPO_AVX2_BUCKET_LOAD4(10, lt, 15, pg[15], bsize); NFT_PIPAPO_AVX2_AND(11, 4, 5); NFT_PIPAPO_AVX2_BUCKET_LOAD4(12, lt, 16, pg[16], bsize); NFT_PIPAPO_AVX2_AND(13, 6, 7); NFT_PIPAPO_AVX2_BUCKET_LOAD4(14, lt, 17, pg[17], bsize); NFT_PIPAPO_AVX2_AND(0, 8, 9); NFT_PIPAPO_AVX2_BUCKET_LOAD4(1, lt, 18, pg[18], bsize); NFT_PIPAPO_AVX2_AND(2, 10, 11); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 19, pg[19], bsize); NFT_PIPAPO_AVX2_AND(4, 12, 13); NFT_PIPAPO_AVX2_BUCKET_LOAD4(5, lt, 20, pg[20], bsize); NFT_PIPAPO_AVX2_AND(6, 14, 0); NFT_PIPAPO_AVX2_AND(7, 1, 2); NFT_PIPAPO_AVX2_BUCKET_LOAD4(8, lt, 21, pg[21], bsize); NFT_PIPAPO_AVX2_AND(9, 3, 4); NFT_PIPAPO_AVX2_BUCKET_LOAD4(10, lt, 22, pg[22], bsize); NFT_PIPAPO_AVX2_AND(11, 5, 6); NFT_PIPAPO_AVX2_BUCKET_LOAD4(12, lt, 23, pg[23], bsize); NFT_PIPAPO_AVX2_AND(13, 7, 8); NFT_PIPAPO_AVX2_BUCKET_LOAD4(14, lt, 24, pg[24], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(0, lt, 25, pg[25], bsize); NFT_PIPAPO_AVX2_AND(1, 9, 10); NFT_PIPAPO_AVX2_AND(2, 11, 12); NFT_PIPAPO_AVX2_BUCKET_LOAD4(3, lt, 26, pg[26], bsize); NFT_PIPAPO_AVX2_AND(4, 13, 14); NFT_PIPAPO_AVX2_BUCKET_LOAD4(5, lt, 27, pg[27], bsize); NFT_PIPAPO_AVX2_AND(6, 0, 1); NFT_PIPAPO_AVX2_BUCKET_LOAD4(7, lt, 28, pg[28], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD4(8, lt, 29, pg[29], bsize); NFT_PIPAPO_AVX2_AND(9, 2, 3); NFT_PIPAPO_AVX2_BUCKET_LOAD4(10, lt, 30, pg[30], bsize); NFT_PIPAPO_AVX2_AND(11, 4, 5); NFT_PIPAPO_AVX2_BUCKET_LOAD4(12, lt, 31, pg[31], bsize); NFT_PIPAPO_AVX2_AND(0, 6, 7); NFT_PIPAPO_AVX2_AND(1, 8, 9); NFT_PIPAPO_AVX2_AND(2, 10, 11); NFT_PIPAPO_AVX2_AND(3, 12, 0); /* Stalls */ NFT_PIPAPO_AVX2_AND(4, 1, 2); NFT_PIPAPO_AVX2_AND(5, 3, 4); NFT_PIPAPO_AVX2_NOMATCH_GOTO(5, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 5); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_8b_1() - AVX2-based lookup for one eight-bit group * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 8-bit fields (i.e. protocol numbers). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_8b_1(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (first) { NFT_PIPAPO_AVX2_BUCKET_LOAD8(2, lt, 0, pkt[0], bsize); } else { NFT_PIPAPO_AVX2_BUCKET_LOAD8(0, lt, 0, pkt[0], bsize); NFT_PIPAPO_AVX2_LOAD(1, map[i_ul]); NFT_PIPAPO_AVX2_AND(2, 0, 1); NFT_PIPAPO_AVX2_NOMATCH_GOTO(1, nothing); } NFT_PIPAPO_AVX2_NOMATCH_GOTO(2, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 2); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_8b_2() - AVX2-based lookup for 2 eight-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 16-bit fields (i.e. ports). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_8b_2(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (first) { NFT_PIPAPO_AVX2_BUCKET_LOAD8(0, lt, 0, pkt[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 1, pkt[1], bsize); NFT_PIPAPO_AVX2_AND(4, 0, 1); } else { NFT_PIPAPO_AVX2_LOAD(0, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 0, pkt[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(2, lt, 1, pkt[1], bsize); /* Stall */ NFT_PIPAPO_AVX2_AND(3, 0, 1); NFT_PIPAPO_AVX2_NOMATCH_GOTO(0, nothing); NFT_PIPAPO_AVX2_AND(4, 3, 2); } /* Stall */ NFT_PIPAPO_AVX2_NOMATCH_GOTO(4, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 4); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_8b_4() - AVX2-based lookup for 4 eight-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 32-bit fields (i.e. IPv4 addresses). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_8b_4(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (first) { NFT_PIPAPO_AVX2_BUCKET_LOAD8(0, lt, 0, pkt[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 1, pkt[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(2, lt, 2, pkt[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(3, lt, 3, pkt[3], bsize); /* Stall */ NFT_PIPAPO_AVX2_AND(4, 0, 1); NFT_PIPAPO_AVX2_AND(5, 2, 3); NFT_PIPAPO_AVX2_AND(0, 4, 5); } else { NFT_PIPAPO_AVX2_BUCKET_LOAD8(0, lt, 0, pkt[0], bsize); NFT_PIPAPO_AVX2_LOAD(1, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD8(2, lt, 1, pkt[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(3, lt, 2, pkt[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(4, lt, 3, pkt[3], bsize); NFT_PIPAPO_AVX2_AND(5, 0, 1); NFT_PIPAPO_AVX2_NOMATCH_GOTO(1, nothing); NFT_PIPAPO_AVX2_AND(6, 2, 3); /* Stall */ NFT_PIPAPO_AVX2_AND(7, 4, 5); NFT_PIPAPO_AVX2_AND(0, 6, 7); } NFT_PIPAPO_AVX2_NOMATCH_GOTO(0, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 0); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_8b_6() - AVX2-based lookup for 6 eight-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 48-bit fields (i.e. MAC addresses/EUI-48). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_8b_6(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (first) { NFT_PIPAPO_AVX2_BUCKET_LOAD8(0, lt, 0, pkt[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 1, pkt[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(2, lt, 2, pkt[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(3, lt, 3, pkt[3], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(4, lt, 4, pkt[4], bsize); NFT_PIPAPO_AVX2_AND(5, 0, 1); NFT_PIPAPO_AVX2_BUCKET_LOAD8(6, lt, 5, pkt[5], bsize); NFT_PIPAPO_AVX2_AND(7, 2, 3); /* Stall */ NFT_PIPAPO_AVX2_AND(0, 4, 5); NFT_PIPAPO_AVX2_AND(1, 6, 7); NFT_PIPAPO_AVX2_AND(4, 0, 1); } else { NFT_PIPAPO_AVX2_BUCKET_LOAD8(0, lt, 0, pkt[0], bsize); NFT_PIPAPO_AVX2_LOAD(1, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD8(2, lt, 1, pkt[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(3, lt, 2, pkt[2], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(4, lt, 3, pkt[3], bsize); NFT_PIPAPO_AVX2_AND(5, 0, 1); NFT_PIPAPO_AVX2_NOMATCH_GOTO(1, nothing); NFT_PIPAPO_AVX2_AND(6, 2, 3); NFT_PIPAPO_AVX2_BUCKET_LOAD8(7, lt, 4, pkt[4], bsize); NFT_PIPAPO_AVX2_AND(0, 4, 5); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 5, pkt[5], bsize); NFT_PIPAPO_AVX2_AND(2, 6, 7); /* Stall */ NFT_PIPAPO_AVX2_AND(3, 0, 1); NFT_PIPAPO_AVX2_AND(4, 2, 3); } NFT_PIPAPO_AVX2_NOMATCH_GOTO(4, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 4); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_8b_16() - AVX2-based lookup for 16 eight-bit groups * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * See nft_pipapo_avx2_lookup_4b_2(). * * This is used for 128-bit fields (i.e. IPv6 addresses). * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_8b_16(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { int i, ret = -1, m256_size = f->bsize / NFT_PIPAPO_LONGS_PER_M256, b; unsigned long *lt = f->lt, bsize = f->bsize; lt += offset * NFT_PIPAPO_LONGS_PER_M256; for (i = offset; i < m256_size; i++, lt += NFT_PIPAPO_LONGS_PER_M256) { int i_ul = i * NFT_PIPAPO_LONGS_PER_M256; if (!first) NFT_PIPAPO_AVX2_LOAD(0, map[i_ul]); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 0, pkt[0], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(2, lt, 1, pkt[1], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(3, lt, 2, pkt[2], bsize); if (!first) { NFT_PIPAPO_AVX2_NOMATCH_GOTO(0, nothing); NFT_PIPAPO_AVX2_AND(1, 1, 0); } NFT_PIPAPO_AVX2_BUCKET_LOAD8(4, lt, 3, pkt[3], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(5, lt, 4, pkt[4], bsize); NFT_PIPAPO_AVX2_AND(6, 1, 2); NFT_PIPAPO_AVX2_BUCKET_LOAD8(7, lt, 5, pkt[5], bsize); NFT_PIPAPO_AVX2_AND(0, 3, 4); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 6, pkt[6], bsize); NFT_PIPAPO_AVX2_BUCKET_LOAD8(2, lt, 7, pkt[7], bsize); NFT_PIPAPO_AVX2_AND(3, 5, 6); NFT_PIPAPO_AVX2_AND(4, 0, 1); NFT_PIPAPO_AVX2_BUCKET_LOAD8(5, lt, 8, pkt[8], bsize); NFT_PIPAPO_AVX2_AND(6, 2, 3); NFT_PIPAPO_AVX2_BUCKET_LOAD8(7, lt, 9, pkt[9], bsize); NFT_PIPAPO_AVX2_AND(0, 4, 5); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 10, pkt[10], bsize); NFT_PIPAPO_AVX2_AND(2, 6, 7); NFT_PIPAPO_AVX2_BUCKET_LOAD8(3, lt, 11, pkt[11], bsize); NFT_PIPAPO_AVX2_AND(4, 0, 1); NFT_PIPAPO_AVX2_BUCKET_LOAD8(5, lt, 12, pkt[12], bsize); NFT_PIPAPO_AVX2_AND(6, 2, 3); NFT_PIPAPO_AVX2_BUCKET_LOAD8(7, lt, 13, pkt[13], bsize); NFT_PIPAPO_AVX2_AND(0, 4, 5); NFT_PIPAPO_AVX2_BUCKET_LOAD8(1, lt, 14, pkt[14], bsize); NFT_PIPAPO_AVX2_AND(2, 6, 7); NFT_PIPAPO_AVX2_BUCKET_LOAD8(3, lt, 15, pkt[15], bsize); NFT_PIPAPO_AVX2_AND(4, 0, 1); /* Stall */ NFT_PIPAPO_AVX2_AND(5, 2, 3); NFT_PIPAPO_AVX2_AND(6, 4, 5); NFT_PIPAPO_AVX2_NOMATCH_GOTO(6, nomatch); NFT_PIPAPO_AVX2_STORE(map[i_ul], 6); b = nft_pipapo_avx2_refill(i_ul, &map[i_ul], fill, f->mt, last); if (last) return b; if (unlikely(ret == -1)) ret = b / XSAVE_YMM_SIZE; continue; nomatch: NFT_PIPAPO_AVX2_STORE(map[i_ul], 15); nothing: ; } return ret; } /** * nft_pipapo_avx2_lookup_slow() - Fallback function for uncommon field sizes * @map: Previous match result, used as initial bitmap * @fill: Destination bitmap to be filled with current match result * @f: Field, containing lookup and mapping tables * @offset: Ignore buckets before the given index, no bits are filled there * @pkt: Packet data, pointer to input nftables register * @first: If this is the first field, don't source previous result * @last: Last field: stop at the first match and return bit index * * This function should never be called, but is provided for the case the field * size doesn't match any of the known data types. Matching rate is * substantially lower than AVX2 routines. * * Return: -1 on no match, rule index of match if @last, otherwise first long * word index to be checked next (i.e. first filled word). */ static int nft_pipapo_avx2_lookup_slow(unsigned long *map, unsigned long *fill, const struct nft_pipapo_field *f, int offset, const u8 *pkt, bool first, bool last) { unsigned long bsize = f->bsize; int i, ret = -1, b; if (first) memset(map, 0xff, bsize * sizeof(*map)); for (i = offset; i < bsize; i++) { if (f->bb == 8) pipapo_and_field_buckets_8bit(f, map, pkt); else pipapo_and_field_buckets_4bit(f, map, pkt); NFT_PIPAPO_GROUP_BITS_ARE_8_OR_4; b = pipapo_refill(map, bsize, f->rules, fill, f->mt, last); if (last) return b; if (ret == -1) ret = b / XSAVE_YMM_SIZE; } return ret; } /** * nft_pipapo_avx2_estimate() - Set size, space and lookup complexity * @desc: Set description, element count and field description used * @features: Flags: NFT_SET_INTERVAL needs to be there * @est: Storage for estimation data * * Return: true if set is compatible and AVX2 available, false otherwise. */ bool nft_pipapo_avx2_estimate(const struct nft_set_desc *desc, u32 features, struct nft_set_estimate *est) { if (!(features & NFT_SET_INTERVAL) || desc->field_count < NFT_PIPAPO_MIN_FIELDS) return false; if (!boot_cpu_has(X86_FEATURE_AVX2) || !boot_cpu_has(X86_FEATURE_AVX)) return false; est->size = pipapo_estimate_size(desc); if (!est->size) return false; est->lookup = NFT_SET_CLASS_O_LOG_N; est->space = NFT_SET_CLASS_O_N; return true; } /** * nft_pipapo_avx2_lookup() - Lookup function for AVX2 implementation * @net: Network namespace * @set: nftables API set representation * @key: nftables API element representation containing key data * @ext: nftables API extension pointer, filled with matching reference * * For more details, see DOC: Theory of Operation in nft_set_pipapo.c. * * This implementation exploits the repetitive characteristic of the algorithm * to provide a fast, vectorised version using the AVX2 SIMD instruction set. * * Return: true on match, false otherwise. */ bool nft_pipapo_avx2_lookup(const struct net *net, const struct nft_set *set, const u32 *key, const struct nft_set_ext **ext) { struct nft_pipapo *priv = nft_set_priv(set); struct nft_pipapo_scratch *scratch; u8 genmask = nft_genmask_cur(net); const struct nft_pipapo_match *m; const struct nft_pipapo_field *f; const u8 *rp = (const u8 *)key; unsigned long *res, *fill; bool map_index; int i, ret = 0; if (unlikely(!irq_fpu_usable())) return nft_pipapo_lookup(net, set, key, ext); m = rcu_dereference(priv->match); /* This also protects access to all data related to scratch maps. * * Note that we don't need a valid MXCSR state for any of the * operations we use here, so pass 0 as mask and spare a LDMXCSR * instruction. */ kernel_fpu_begin_mask(0); scratch = *raw_cpu_ptr(m->scratch); if (unlikely(!scratch)) { kernel_fpu_end(); return false; } map_index = scratch->map_index; res = scratch->map + (map_index ? m->bsize_max : 0); fill = scratch->map + (map_index ? 0 : m->bsize_max); /* Starting map doesn't need to be set for this implementation */ nft_pipapo_avx2_prepare(); next_match: nft_pipapo_for_each_field(f, i, m) { bool last = i == m->field_count - 1, first = !i; #define NFT_SET_PIPAPO_AVX2_LOOKUP(b, n) \ (ret = nft_pipapo_avx2_lookup_##b##b_##n(res, fill, f, \ ret, rp, \ first, last)) if (likely(f->bb == 8)) { if (f->groups == 1) { NFT_SET_PIPAPO_AVX2_LOOKUP(8, 1); } else if (f->groups == 2) { NFT_SET_PIPAPO_AVX2_LOOKUP(8, 2); } else if (f->groups == 4) { NFT_SET_PIPAPO_AVX2_LOOKUP(8, 4); } else if (f->groups == 6) { NFT_SET_PIPAPO_AVX2_LOOKUP(8, 6); } else if (f->groups == 16) { NFT_SET_PIPAPO_AVX2_LOOKUP(8, 16); } else { ret = nft_pipapo_avx2_lookup_slow(res, fill, f, ret, rp, first, last); } } else { if (f->groups == 2) { NFT_SET_PIPAPO_AVX2_LOOKUP(4, 2); } else if (f->groups == 4) { NFT_SET_PIPAPO_AVX2_LOOKUP(4, 4); } else if (f->groups == 8) { NFT_SET_PIPAPO_AVX2_LOOKUP(4, 8); } else if (f->groups == 12) { NFT_SET_PIPAPO_AVX2_LOOKUP(4, 12); } else if (f->groups == 32) { NFT_SET_PIPAPO_AVX2_LOOKUP(4, 32); } else { ret = nft_pipapo_avx2_lookup_slow(res, fill, f, ret, rp, first, last); } } NFT_PIPAPO_GROUP_BITS_ARE_8_OR_4; #undef NFT_SET_PIPAPO_AVX2_LOOKUP if (ret < 0) goto out; if (last) { *ext = &f->mt[ret].e->ext; if (unlikely(nft_set_elem_expired(*ext) || !nft_set_elem_active(*ext, genmask))) { ret = 0; goto next_match; } goto out; } swap(res, fill); rp += NFT_PIPAPO_GROUPS_PADDED_SIZE(f); } out: if (i % 2) scratch->map_index = !map_index; kernel_fpu_end(); return ret >= 0; }
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