/src/zlib-ng/arch/x86/chunkset_avx2.c
Line | Count | Source |
1 | | /* chunkset_avx2.c -- AVX2 inline functions to copy small data chunks. |
2 | | * For conditions of distribution and use, see copyright notice in zlib.h |
3 | | */ |
4 | | |
5 | | #ifdef X86_AVX2 |
6 | | |
7 | | #include "zbuild.h" |
8 | | #include "zsanitizer.h" |
9 | | #include "zmemory.h" |
10 | | |
11 | | #include "arch/shared/chunk_256bit_perm_idx_lut.h" |
12 | | #include <immintrin.h> |
13 | | #include "x86_intrins.h" |
14 | | |
15 | | typedef __m256i chunk_t; |
16 | | typedef __m128i halfchunk_t; |
17 | | |
18 | | #define HAVE_CHUNKMEMSET_2 |
19 | | #define HAVE_CHUNKMEMSET_4 |
20 | | #define HAVE_CHUNKMEMSET_8 |
21 | | #define HAVE_CHUNKMEMSET_16 |
22 | | #define HAVE_CHUNK_MAG |
23 | | #define HAVE_HALF_CHUNK |
24 | | |
25 | 157k | static inline void chunkmemset_2(uint8_t *from, chunk_t *chunk) { |
26 | 157k | *chunk = _mm256_set1_epi16(zng_memread_2(from)); |
27 | 157k | } |
28 | | |
29 | 61.2k | static inline void chunkmemset_4(uint8_t *from, chunk_t *chunk) { |
30 | 61.2k | *chunk = _mm256_set1_epi32(zng_memread_4(from)); |
31 | 61.2k | } |
32 | | |
33 | 3.05k | static inline void chunkmemset_8(uint8_t *from, chunk_t *chunk) { |
34 | 3.05k | *chunk = _mm256_set1_epi64x(zng_memread_8(from)); |
35 | 3.05k | } |
36 | | |
37 | 6.13k | static inline void chunkmemset_16(uint8_t *from, chunk_t *chunk) { |
38 | | /* See explanation in chunkset_avx512.c */ |
39 | | #if defined(_MSC_VER) && _MSC_VER <= 1900 |
40 | | halfchunk_t half = _mm_loadu_si128((__m128i*)from); |
41 | | *chunk = _mm256_inserti128_si256(_mm256_castsi128_si256(half), half, 1); |
42 | | #else |
43 | 6.13k | *chunk = _mm256_broadcastsi128_si256(_mm_loadu_si128((__m128i*)from)); |
44 | 6.13k | #endif |
45 | 6.13k | } |
46 | | |
47 | 12.7M | static inline void loadchunk(uint8_t const *s, chunk_t *chunk) { |
48 | 12.7M | *chunk = _mm256_loadu_si256((__m256i *)s); |
49 | 12.7M | } |
50 | | |
51 | 13.0M | static inline void storechunk(uint8_t *out, chunk_t *chunk) { |
52 | 13.0M | _mm256_storeu_si256((__m256i *)out, *chunk); |
53 | 13.0M | } |
54 | | |
55 | 34.6k | static inline chunk_t GET_CHUNK_MAG(uint8_t *buf, size_t *chunk_rem, size_t dist) { |
56 | 34.6k | lut_rem_pair lut_rem = perm_idx_lut[dist - 3]; |
57 | 34.6k | __m256i ret_vec; |
58 | | /* While technically we only need to read 4 or 8 bytes into this vector register for a lot of cases, GCC is |
59 | | * compiling this to a shared load for all branches, preferring the simpler code. Given that the buf value isn't in |
60 | | * GPRs to begin with the 256 bit load is _probably_ just as inexpensive */ |
61 | 34.6k | *chunk_rem = lut_rem.remval; |
62 | | |
63 | | /* See note in chunkset_ssse3.c for why this is ok */ |
64 | 34.6k | __msan_unpoison(buf + dist, 32 - dist); |
65 | | |
66 | 34.6k | if (dist < 16) { |
67 | | /* This simpler case still requires us to shuffle in 128 bit lanes, so we must apply a static offset after |
68 | | * broadcasting the first vector register to both halves. This is _marginally_ faster than doing two separate |
69 | | * shuffles and combining the halves later */ |
70 | 13.6k | __m256i perm_vec = _mm256_load_si256((__m256i*)(permute_table+lut_rem.idx)); |
71 | 13.6k | __m128i ret_vec0 = _mm_loadu_si128((__m128i*)buf); |
72 | 13.6k | ret_vec = _mm256_inserti128_si256(_mm256_castsi128_si256(ret_vec0), ret_vec0, 1); |
73 | 13.6k | ret_vec = _mm256_shuffle_epi8(ret_vec, perm_vec); |
74 | 21.0k | } else { |
75 | 21.0k | __m128i ret_vec0 = _mm_loadu_si128((__m128i*)buf); |
76 | 21.0k | __m128i ret_vec1 = _mm_loadu_si128((__m128i*)(buf + 16)); |
77 | | /* Take advantage of the fact that only the latter half of the 256 bit vector will actually differ */ |
78 | 21.0k | __m128i perm_vec1 = _mm_load_si128((__m128i*)(permute_table + lut_rem.idx)); |
79 | 21.0k | __m128i xlane_permutes = _mm_cmpgt_epi8(_mm_set1_epi8(16), perm_vec1); |
80 | 21.0k | __m128i xlane_res = _mm_shuffle_epi8(ret_vec0, perm_vec1); |
81 | | /* Since we can't wrap twice, we can simply keep the later half exactly how it is instead of having to _also_ |
82 | | * shuffle those values */ |
83 | 21.0k | __m128i latter_half = _mm_blendv_epi8(ret_vec1, xlane_res, xlane_permutes); |
84 | 21.0k | ret_vec = _mm256_inserti128_si256(_mm256_castsi128_si256(ret_vec0), latter_half, 1); |
85 | 21.0k | } |
86 | | |
87 | 34.6k | return ret_vec; |
88 | 34.6k | } |
89 | | |
90 | 389 | static inline void loadhalfchunk(uint8_t const *s, halfchunk_t *chunk) { |
91 | 389 | *chunk = _mm_loadu_si128((__m128i *)s); |
92 | 389 | } |
93 | | |
94 | 2.43k | static inline void storehalfchunk(uint8_t *out, halfchunk_t *chunk) { |
95 | 2.43k | _mm_storeu_si128((__m128i *)out, *chunk); |
96 | 2.43k | } |
97 | | |
98 | 11.5k | static inline chunk_t halfchunk2whole(halfchunk_t *chunk) { |
99 | | /* We zero extend mostly to appease some memory sanitizers. These bytes are ultimately |
100 | | * unlikely to be actually written or read from */ |
101 | 11.5k | return _mm256_zextsi128_si256(*chunk); |
102 | 11.5k | } |
103 | | |
104 | 11.5k | static inline halfchunk_t GET_HALFCHUNK_MAG(uint8_t *buf, size_t *chunk_rem, size_t dist) { |
105 | 11.5k | lut_rem_pair lut_rem = perm_idx_lut[dist - 3]; |
106 | 11.5k | __m128i perm_vec, ret_vec; |
107 | 11.5k | __msan_unpoison(buf + dist, 16 - dist); |
108 | 11.5k | ret_vec = _mm_loadu_si128((__m128i*)buf); |
109 | 11.5k | *chunk_rem = half_rem_vals[dist - 3]; |
110 | | |
111 | 11.5k | perm_vec = _mm_load_si128((__m128i*)(permute_table + lut_rem.idx)); |
112 | 11.5k | ret_vec = _mm_shuffle_epi8(ret_vec, perm_vec); |
113 | | |
114 | 11.5k | return ret_vec; |
115 | 11.5k | } |
116 | | |
117 | | #define CHUNKSIZE chunksize_avx2 |
118 | 11.0M | #define CHUNKCOPY chunkcopy_avx2 |
119 | 1.01k | #define CHUNKUNROLL chunkunroll_avx2 |
120 | 3.13M | #define CHUNKMEMSET chunkmemset_avx2 |
121 | | #define CHUNKMEMSET_SAFE chunkmemset_safe_avx2 |
122 | | |
123 | | #include "chunkset_tpl.h" |
124 | | |
125 | | #define INFLATE_FAST inflate_fast_avx2 |
126 | | |
127 | | #include "inffast_tpl.h" |
128 | | |
129 | | #endif |