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0de26fd78e
Zlib-ng is zlib replacement with optimizations for "next generation" systems. Its optimization may benifits image library decode and encode speed such as libpng. In our tests, if using zlib-ng and libpng combination on a x86_64 machine with AVX2, the time of `imdecode` amd `imencode` will drop 20% approximately. This patch enables zlib-ng's optimization if `CV_DISABLE_OPTIMIZATION` is OFF. Since Zlib-ng can dispatch intrinsics on the fly, port work is much easier. Related discussion: https://github.com/opencv/opencv/issues/22573
187 lines
6.1 KiB
C
187 lines
6.1 KiB
C
/* adler32_vmx.c -- compute the Adler-32 checksum of a data stream
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* Copyright (C) 1995-2011 Mark Adler
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* Copyright (C) 2017-2023 Mika T. Lindqvist <postmaster@raasu.org>
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* Copyright (C) 2021 Adam Stylinski <kungfujesus06@gmail.com>
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* For conditions of distribution and use, see copyright notice in zlib.h
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*/
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#ifdef PPC_VMX
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#include <altivec.h>
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#include "zbuild.h"
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#include "zendian.h"
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#include "adler32_p.h"
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#define vmx_zero() (vec_splat_u32(0))
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static inline void vmx_handle_head_or_tail(uint32_t *pair, const uint8_t *buf, size_t len) {
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unsigned int i;
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for (i = 0; i < len; ++i) {
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pair[0] += buf[i];
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pair[1] += pair[0];
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}
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}
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static void vmx_accum32(uint32_t *s, const uint8_t *buf, size_t len) {
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/* Different taps for the separable components of sums */
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const vector unsigned char t0 = {64, 63, 62, 61, 60, 59, 58, 57, 56, 55, 54, 53, 52, 51, 50, 49};
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const vector unsigned char t1 = {48, 47, 46, 45, 44, 43, 42, 41, 40, 39, 38, 37, 36, 35, 34, 33};
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const vector unsigned char t2 = {32, 31, 30, 29, 28, 27, 26, 25, 24, 23, 22, 21, 20, 19, 18, 17};
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const vector unsigned char t3 = {16, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1};
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/* As silly and inefficient as it seems, creating 1 permutation vector to permute
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* a 2 element vector from a single load + a subsequent shift is just barely faster
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* than doing 2 indexed insertions into zero initialized vectors from unaligned memory. */
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const vector unsigned char s0_perm = {0, 1, 2, 3, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8};
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const vector unsigned char shift_vec = vec_sl(vec_splat_u8(8), vec_splat_u8(2));
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vector unsigned int adacc, s2acc;
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vector unsigned int pair_vec = vec_ld(0, s);
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adacc = vec_perm(pair_vec, pair_vec, s0_perm);
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#if BYTE_ORDER == LITTLE_ENDIAN
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s2acc = vec_sro(pair_vec, shift_vec);
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#else
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s2acc = vec_slo(pair_vec, shift_vec);
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#endif
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vector unsigned int zero = vmx_zero();
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vector unsigned int s3acc = zero;
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vector unsigned int s3acc_0 = zero;
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vector unsigned int adacc_prev = adacc;
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vector unsigned int adacc_prev_0 = zero;
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vector unsigned int s2acc_0 = zero;
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vector unsigned int s2acc_1 = zero;
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vector unsigned int s2acc_2 = zero;
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/* Maintain a running sum of a second half, this might help use break yet another
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* data dependency bubble in the sum */
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vector unsigned int adacc_0 = zero;
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int num_iter = len / 4;
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int rem = len & 3;
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for (int i = 0; i < num_iter; ++i) {
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vector unsigned char d0 = vec_ld(0, buf);
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vector unsigned char d1 = vec_ld(16, buf);
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vector unsigned char d2 = vec_ld(32, buf);
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vector unsigned char d3 = vec_ld(48, buf);
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/* The core operation of the loop, basically
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* what is being unrolled below */
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adacc = vec_sum4s(d0, adacc);
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s3acc = vec_add(s3acc, adacc_prev);
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s3acc_0 = vec_add(s3acc_0, adacc_prev_0);
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s2acc = vec_msum(t0, d0, s2acc);
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/* interleave dependent sums in here */
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adacc_0 = vec_sum4s(d1, adacc_0);
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s2acc_0 = vec_msum(t1, d1, s2acc_0);
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adacc = vec_sum4s(d2, adacc);
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s2acc_1 = vec_msum(t2, d2, s2acc_1);
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s2acc_2 = vec_msum(t3, d3, s2acc_2);
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adacc_0 = vec_sum4s(d3, adacc_0);
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adacc_prev = adacc;
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adacc_prev_0 = adacc_0;
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buf += 64;
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}
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adacc = vec_add(adacc, adacc_0);
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s3acc = vec_add(s3acc, s3acc_0);
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s3acc = vec_sl(s3acc, vec_splat_u32(6));
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if (rem) {
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adacc_prev = vec_add(adacc_prev_0, adacc_prev);
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adacc_prev = vec_sl(adacc_prev, vec_splat_u32(4));
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while (rem--) {
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vector unsigned char d0 = vec_ld(0, buf);
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adacc = vec_sum4s(d0, adacc);
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s3acc = vec_add(s3acc, adacc_prev);
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s2acc = vec_msum(t3, d0, s2acc);
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adacc_prev = vec_sl(adacc, vec_splat_u32(4));
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buf += 16;
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}
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}
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/* Sum up independent second sums */
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s2acc = vec_add(s2acc, s2acc_0);
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s2acc_2 = vec_add(s2acc_1, s2acc_2);
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s2acc = vec_add(s2acc, s2acc_2);
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s2acc = vec_add(s2acc, s3acc);
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adacc = vec_add(adacc, vec_sld(adacc, adacc, 8));
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s2acc = vec_add(s2acc, vec_sld(s2acc, s2acc, 8));
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adacc = vec_add(adacc, vec_sld(adacc, adacc, 4));
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s2acc = vec_add(s2acc, vec_sld(s2acc, s2acc, 4));
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vec_ste(adacc, 0, s);
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vec_ste(s2acc, 0, s+1);
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}
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Z_INTERNAL uint32_t adler32_vmx(uint32_t adler, const uint8_t *buf, size_t len) {
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uint32_t sum2;
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uint32_t pair[16] ALIGNED_(16);
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memset(&pair[2], 0, 14);
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int n = NMAX;
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unsigned int done = 0, i;
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/* Split Adler-32 into component sums, it can be supplied by
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* the caller sites (e.g. in a PNG file).
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*/
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sum2 = (adler >> 16) & 0xffff;
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adler &= 0xffff;
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pair[0] = adler;
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pair[1] = sum2;
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/* in case user likes doing a byte at a time, keep it fast */
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if (UNLIKELY(len == 1))
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return adler32_len_1(adler, buf, sum2);
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/* initial Adler-32 value (deferred check for len == 1 speed) */
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if (UNLIKELY(buf == NULL))
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return 1L;
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/* in case short lengths are provided, keep it somewhat fast */
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if (UNLIKELY(len < 16))
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return adler32_len_16(adler, buf, len, sum2);
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// Align buffer
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unsigned int al = 0;
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if ((uintptr_t)buf & 0xf) {
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al = 16-((uintptr_t)buf & 0xf);
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if (al > len) {
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al=len;
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}
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vmx_handle_head_or_tail(pair, buf, al);
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done += al;
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/* Rather than rebasing, we can reduce the max sums for the
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* first round only */
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n -= al;
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}
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for (i = al; i < len; i += n) {
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int remaining = (int)(len-i);
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n = MIN(remaining, (i == al) ? n : NMAX);
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if (n < 16)
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break;
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vmx_accum32(pair, buf + i, n / 16);
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pair[0] %= BASE;
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pair[1] %= BASE;
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done += (n / 16) * 16;
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}
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/* Handle the tail elements. */
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if (done < len) {
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vmx_handle_head_or_tail(pair, (buf + done), len - done);
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pair[0] %= BASE;
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pair[1] %= BASE;
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}
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/* D = B * 65536 + A, see: https://en.wikipedia.org/wiki/Adler-32. */
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return (pair[1] << 16) | pair[0];
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}
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#endif
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