c5cf148d89
Current rte_acl_classify_avx512x32() and rte_acl_classify_avx512x16() code paths are very similar. The only differences are due to 256/512 register/instrincts naming conventions. So to deduplicate the code: - Move common code into “acl_run_avx512_common.h” - Use macros to hide difference in naming conventions Signed-off-by: Konstantin Ananyev <konstantin.ananyev@intel.com>
254 lines
5.8 KiB
C
254 lines
5.8 KiB
C
/* SPDX-License-Identifier: BSD-3-Clause
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* Copyright(c) 2020 Intel Corporation
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*/
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/*
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* Defines required by "acl_run_avx512_common.h".
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* Note that all of them has to be undefined by the end
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* of this file, as "acl_run_avx512_common.h" can be included several
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* times from different *.h files for the same *.c.
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*/
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/*
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* This implementation uses 256-bit registers(ymm) and instrincts.
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* So our main SIMD type is 256-bit width and each such variable can
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* process sizeof(__m256i) / sizeof(uint32_t) == 8 entries in parallel.
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*/
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#define _T_simd __m256i
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#define _T_mask __mmask8
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/* Naming convention for static const variables. */
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#define _SC_(x) ymm_##x
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#define _SV_(x) (ymm_##x.y)
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/* Naming convention for internal functions. */
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#define _F_(x) x##_avx512x8
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/*
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* Same instrincts have different syntaxis (depending on the bit-width),
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* so to overcome that few macros need to be defined.
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*/
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/* Naming convention for generic epi(packed integers) type instrincts. */
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#define _M_I_(x) _mm256_##x
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/* Naming convention for si(whole simd integer) type instrincts. */
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#define _M_SI_(x) _mm256_##x##_si256
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/* Naming convention for masked gather type instrincts. */
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#define _M_MGI_(x) _mm256_m##x
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/* Naming convention for gather type instrincts. */
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#define _M_GI_(name, idx, base, scale) _mm256_##name(base, idx, scale)
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/* num/mask of transitions per SIMD regs */
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#define _SIMD_MASK_BIT_ (sizeof(_T_simd) / sizeof(uint32_t))
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#define _SIMD_MASK_MAX_ RTE_LEN2MASK(_SIMD_MASK_BIT_, uint32_t)
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#define _SIMD_FLOW_NUM_ (2 * _SIMD_MASK_BIT_)
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#define _SIMD_FLOW_MSK_ (_SIMD_FLOW_NUM_ - 1)
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/* num/mask of pointers per SIMD regs */
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#define _SIMD_PTR_NUM_ (sizeof(_T_simd) / sizeof(uintptr_t))
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#define _SIMD_PTR_MSK_ RTE_LEN2MASK(_SIMD_PTR_NUM_, uint32_t)
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static const rte_ymm_t _SC_(match_mask) = {
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.u32 = {
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RTE_ACL_NODE_MATCH,
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RTE_ACL_NODE_MATCH,
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RTE_ACL_NODE_MATCH,
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RTE_ACL_NODE_MATCH,
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RTE_ACL_NODE_MATCH,
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RTE_ACL_NODE_MATCH,
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RTE_ACL_NODE_MATCH,
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RTE_ACL_NODE_MATCH,
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},
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};
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static const rte_ymm_t _SC_(index_mask) = {
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.u32 = {
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RTE_ACL_NODE_INDEX,
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RTE_ACL_NODE_INDEX,
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RTE_ACL_NODE_INDEX,
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RTE_ACL_NODE_INDEX,
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RTE_ACL_NODE_INDEX,
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RTE_ACL_NODE_INDEX,
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RTE_ACL_NODE_INDEX,
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RTE_ACL_NODE_INDEX,
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},
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};
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static const rte_ymm_t _SC_(trlo_idle) = {
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.u32 = {
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RTE_ACL_IDLE_NODE,
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RTE_ACL_IDLE_NODE,
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RTE_ACL_IDLE_NODE,
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RTE_ACL_IDLE_NODE,
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RTE_ACL_IDLE_NODE,
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RTE_ACL_IDLE_NODE,
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RTE_ACL_IDLE_NODE,
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RTE_ACL_IDLE_NODE,
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},
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};
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static const rte_ymm_t _SC_(trhi_idle) = {
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.u32 = {
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0, 0, 0, 0,
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0, 0, 0, 0,
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},
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};
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static const rte_ymm_t _SC_(shuffle_input) = {
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.u32 = {
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0x00000000, 0x04040404, 0x08080808, 0x0c0c0c0c,
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0x00000000, 0x04040404, 0x08080808, 0x0c0c0c0c,
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},
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};
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static const rte_ymm_t _SC_(four_32) = {
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.u32 = {
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4, 4, 4, 4,
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4, 4, 4, 4,
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},
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};
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static const rte_ymm_t _SC_(idx_add) = {
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.u32 = {
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0, 1, 2, 3,
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4, 5, 6, 7,
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},
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};
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static const rte_ymm_t _SC_(range_base) = {
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.u32 = {
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0xffffff00, 0xffffff04, 0xffffff08, 0xffffff0c,
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0xffffff00, 0xffffff04, 0xffffff08, 0xffffff0c,
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},
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};
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static const rte_ymm_t _SC_(pminp) = {
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.u32 = {
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0x00, 0x01, 0x02, 0x03,
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0x08, 0x09, 0x0a, 0x0b,
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},
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};
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static const __mmask16 _SC_(pmidx_msk) = 0x55;
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static const rte_ymm_t _SC_(pmidx[2]) = {
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[0] = {
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.u32 = {
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0, 0, 1, 0, 2, 0, 3, 0,
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},
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},
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[1] = {
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.u32 = {
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4, 0, 5, 0, 6, 0, 7, 0,
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},
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},
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};
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/*
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* unfortunately current AVX512 ISA doesn't provide ability for
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* gather load on a byte quantity. So we have to mimic it in SW,
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* by doing 4x1B scalar loads.
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*/
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static inline __m128i
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_m256_mask_gather_epi8x4(__m256i pdata, __mmask8 mask)
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{
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rte_xmm_t v;
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rte_ymm_t p;
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static const uint32_t zero;
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p.y = _mm256_mask_set1_epi64(pdata, mask ^ _SIMD_PTR_MSK_,
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(uintptr_t)&zero);
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v.u32[0] = *(uint8_t *)p.u64[0];
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v.u32[1] = *(uint8_t *)p.u64[1];
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v.u32[2] = *(uint8_t *)p.u64[2];
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v.u32[3] = *(uint8_t *)p.u64[3];
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return v.x;
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}
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/*
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* Gather 4/1 input bytes for up to 8 (2*8) locations in parallel.
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*/
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static __rte_always_inline __m256i
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_F_(gather_bytes)(__m256i zero, const __m256i p[2], const uint32_t m[2],
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uint32_t bnum)
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{
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__m128i inp[2];
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if (bnum == sizeof(uint8_t)) {
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inp[0] = _m256_mask_gather_epi8x4(p[0], m[0]);
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inp[1] = _m256_mask_gather_epi8x4(p[1], m[1]);
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} else {
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inp[0] = _mm256_mmask_i64gather_epi32(
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_mm256_castsi256_si128(zero),
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m[0], p[0], NULL, sizeof(uint8_t));
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inp[1] = _mm256_mmask_i64gather_epi32(
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_mm256_castsi256_si128(zero),
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m[1], p[1], NULL, sizeof(uint8_t));
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}
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/* squeeze input into one 256-bit register */
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return _mm256_permutex2var_epi32(_mm256_castsi128_si256(inp[0]),
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_SV_(pminp), _mm256_castsi128_si256(inp[1]));
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}
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#include "acl_run_avx512_common.h"
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/*
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* Perform search for up to (2 * 8) flows in parallel.
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* Use two sets of metadata, each serves 8 flows max.
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*/
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static inline int
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search_avx512x8x2(const struct rte_acl_ctx *ctx, const uint8_t **data,
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uint32_t *results, uint32_t total_packets, uint32_t categories)
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{
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uint32_t i, *pm;
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const struct rte_acl_match_results *pr;
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struct acl_flow_avx512 flow;
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uint32_t match[ctx->num_tries * total_packets];
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for (i = 0, pm = match; i != ctx->num_tries; i++, pm += total_packets) {
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/* setup for next trie */
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acl_set_flow_avx512(&flow, ctx, i, data, pm, total_packets);
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/* process the trie */
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_F_(search_trie)(&flow);
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}
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/* resolve matches */
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pr = (const struct rte_acl_match_results *)
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(ctx->trans_table + ctx->match_index);
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if (categories == 1)
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_F_(resolve_single_cat)(results, pr, match, total_packets,
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ctx->num_tries);
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else
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resolve_mcle8_avx512x1(results, pr, match, total_packets,
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categories, ctx->num_tries);
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return 0;
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}
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#undef _SIMD_PTR_MSK_
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#undef _SIMD_PTR_NUM_
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#undef _SIMD_FLOW_MSK_
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#undef _SIMD_FLOW_NUM_
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#undef _SIMD_MASK_MAX_
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#undef _SIMD_MASK_BIT_
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#undef _M_GI_
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#undef _M_MGI_
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#undef _M_SI_
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#undef _M_I_
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#undef _F_
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#undef _SV_
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#undef _SC_
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#undef _T_mask
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#undef _T_simd
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