mirror_zfs/module/zcommon/zfs_fletcher.c
Matthew Macy 006e9a4088 OpenZFS restructuring - move platform specific headers
Move platform specific Linux headers under include/os/linux/.
Update the build system accordingly to detect the platform.
This lays some of the initial groundwork to supporting building
for other platforms.

As part of this change it was necessary to create both a user
and kernel space sys/simd.h header which can be included in
either context.  No functional change, the source has been
refactored and the relevant #include's updated.

Reviewed-by: Jorgen Lundman <lundman@lundman.net>
Reviewed-by: Igor Kozhukhov <igor@dilos.org>
Signed-off-by: Matthew Macy <mmacy@FreeBSD.org>
Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov>
Closes #9198
2019-09-05 09:34:54 -07:00

951 lines
24 KiB
C

/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright 2009 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
* Copyright (C) 2016 Gvozden Nešković. All rights reserved.
*/
/*
* Copyright 2013 Saso Kiselkov. All rights reserved.
*/
/*
* Copyright (c) 2016 by Delphix. All rights reserved.
*/
/*
* Fletcher Checksums
* ------------------
*
* ZFS's 2nd and 4th order Fletcher checksums are defined by the following
* recurrence relations:
*
* a = a + f
* i i-1 i-1
*
* b = b + a
* i i-1 i
*
* c = c + b (fletcher-4 only)
* i i-1 i
*
* d = d + c (fletcher-4 only)
* i i-1 i
*
* Where
* a_0 = b_0 = c_0 = d_0 = 0
* and
* f_0 .. f_(n-1) are the input data.
*
* Using standard techniques, these translate into the following series:
*
* __n_ __n_
* \ | \ |
* a = > f b = > i * f
* n /___| n - i n /___| n - i
* i = 1 i = 1
*
*
* __n_ __n_
* \ | i*(i+1) \ | i*(i+1)*(i+2)
* c = > ------- f d = > ------------- f
* n /___| 2 n - i n /___| 6 n - i
* i = 1 i = 1
*
* For fletcher-2, the f_is are 64-bit, and [ab]_i are 64-bit accumulators.
* Since the additions are done mod (2^64), errors in the high bits may not
* be noticed. For this reason, fletcher-2 is deprecated.
*
* For fletcher-4, the f_is are 32-bit, and [abcd]_i are 64-bit accumulators.
* A conservative estimate of how big the buffer can get before we overflow
* can be estimated using f_i = 0xffffffff for all i:
*
* % bc
* f=2^32-1;d=0; for (i = 1; d<2^64; i++) { d += f*i*(i+1)*(i+2)/6 }; (i-1)*4
* 2264
* quit
* %
*
* So blocks of up to 2k will not overflow. Our largest block size is
* 128k, which has 32k 4-byte words, so we can compute the largest possible
* accumulators, then divide by 2^64 to figure the max amount of overflow:
*
* % bc
* a=b=c=d=0; f=2^32-1; for (i=1; i<=32*1024; i++) { a+=f; b+=a; c+=b; d+=c }
* a/2^64;b/2^64;c/2^64;d/2^64
* 0
* 0
* 1365
* 11186858
* quit
* %
*
* So a and b cannot overflow. To make sure each bit of input has some
* effect on the contents of c and d, we can look at what the factors of
* the coefficients in the equations for c_n and d_n are. The number of 2s
* in the factors determines the lowest set bit in the multiplier. Running
* through the cases for n*(n+1)/2 reveals that the highest power of 2 is
* 2^14, and for n*(n+1)*(n+2)/6 it is 2^15. So while some data may overflow
* the 64-bit accumulators, every bit of every f_i effects every accumulator,
* even for 128k blocks.
*
* If we wanted to make a stronger version of fletcher4 (fletcher4c?),
* we could do our calculations mod (2^32 - 1) by adding in the carries
* periodically, and store the number of carries in the top 32-bits.
*
* --------------------
* Checksum Performance
* --------------------
*
* There are two interesting components to checksum performance: cached and
* uncached performance. With cached data, fletcher-2 is about four times
* faster than fletcher-4. With uncached data, the performance difference is
* negligible, since the cost of a cache fill dominates the processing time.
* Even though fletcher-4 is slower than fletcher-2, it is still a pretty
* efficient pass over the data.
*
* In normal operation, the data which is being checksummed is in a buffer
* which has been filled either by:
*
* 1. a compression step, which will be mostly cached, or
* 2. a bcopy() or copyin(), which will be uncached (because the
* copy is cache-bypassing).
*
* For both cached and uncached data, both fletcher checksums are much faster
* than sha-256, and slower than 'off', which doesn't touch the data at all.
*/
#include <sys/types.h>
#include <sys/sysmacros.h>
#include <sys/byteorder.h>
#include <sys/spa.h>
#include <sys/simd.h>
#include <sys/zio_checksum.h>
#include <sys/zfs_context.h>
#include <zfs_fletcher.h>
#define FLETCHER_MIN_SIMD_SIZE 64
static void fletcher_4_scalar_init(fletcher_4_ctx_t *ctx);
static void fletcher_4_scalar_fini(fletcher_4_ctx_t *ctx, zio_cksum_t *zcp);
static void fletcher_4_scalar_native(fletcher_4_ctx_t *ctx,
const void *buf, uint64_t size);
static void fletcher_4_scalar_byteswap(fletcher_4_ctx_t *ctx,
const void *buf, uint64_t size);
static boolean_t fletcher_4_scalar_valid(void);
static const fletcher_4_ops_t fletcher_4_scalar_ops = {
.init_native = fletcher_4_scalar_init,
.fini_native = fletcher_4_scalar_fini,
.compute_native = fletcher_4_scalar_native,
.init_byteswap = fletcher_4_scalar_init,
.fini_byteswap = fletcher_4_scalar_fini,
.compute_byteswap = fletcher_4_scalar_byteswap,
.valid = fletcher_4_scalar_valid,
.name = "scalar"
};
static fletcher_4_ops_t fletcher_4_fastest_impl = {
.name = "fastest",
.valid = fletcher_4_scalar_valid
};
static const fletcher_4_ops_t *fletcher_4_impls[] = {
&fletcher_4_scalar_ops,
&fletcher_4_superscalar_ops,
&fletcher_4_superscalar4_ops,
#if defined(HAVE_SSE2)
&fletcher_4_sse2_ops,
#endif
#if defined(HAVE_SSE2) && defined(HAVE_SSSE3)
&fletcher_4_ssse3_ops,
#endif
#if defined(HAVE_AVX) && defined(HAVE_AVX2)
&fletcher_4_avx2_ops,
#endif
#if defined(__x86_64) && defined(HAVE_AVX512F)
&fletcher_4_avx512f_ops,
#endif
#if defined(__aarch64__)
&fletcher_4_aarch64_neon_ops,
#endif
};
/* Hold all supported implementations */
static uint32_t fletcher_4_supp_impls_cnt = 0;
static fletcher_4_ops_t *fletcher_4_supp_impls[ARRAY_SIZE(fletcher_4_impls)];
/* Select fletcher4 implementation */
#define IMPL_FASTEST (UINT32_MAX)
#define IMPL_CYCLE (UINT32_MAX - 1)
#define IMPL_SCALAR (0)
static uint32_t fletcher_4_impl_chosen = IMPL_FASTEST;
#define IMPL_READ(i) (*(volatile uint32_t *) &(i))
static struct fletcher_4_impl_selector {
const char *fis_name;
uint32_t fis_sel;
} fletcher_4_impl_selectors[] = {
{ "cycle", IMPL_CYCLE },
{ "fastest", IMPL_FASTEST },
{ "scalar", IMPL_SCALAR }
};
#if defined(_KERNEL)
static kstat_t *fletcher_4_kstat;
static struct fletcher_4_kstat {
uint64_t native;
uint64_t byteswap;
} fletcher_4_stat_data[ARRAY_SIZE(fletcher_4_impls) + 1];
#endif
/* Indicate that benchmark has been completed */
static boolean_t fletcher_4_initialized = B_FALSE;
/*ARGSUSED*/
void
fletcher_init(zio_cksum_t *zcp)
{
ZIO_SET_CHECKSUM(zcp, 0, 0, 0, 0);
}
int
fletcher_2_incremental_native(void *buf, size_t size, void *data)
{
zio_cksum_t *zcp = data;
const uint64_t *ip = buf;
const uint64_t *ipend = ip + (size / sizeof (uint64_t));
uint64_t a0, b0, a1, b1;
a0 = zcp->zc_word[0];
a1 = zcp->zc_word[1];
b0 = zcp->zc_word[2];
b1 = zcp->zc_word[3];
for (; ip < ipend; ip += 2) {
a0 += ip[0];
a1 += ip[1];
b0 += a0;
b1 += a1;
}
ZIO_SET_CHECKSUM(zcp, a0, a1, b0, b1);
return (0);
}
/*ARGSUSED*/
void
fletcher_2_native(const void *buf, uint64_t size,
const void *ctx_template, zio_cksum_t *zcp)
{
fletcher_init(zcp);
(void) fletcher_2_incremental_native((void *) buf, size, zcp);
}
int
fletcher_2_incremental_byteswap(void *buf, size_t size, void *data)
{
zio_cksum_t *zcp = data;
const uint64_t *ip = buf;
const uint64_t *ipend = ip + (size / sizeof (uint64_t));
uint64_t a0, b0, a1, b1;
a0 = zcp->zc_word[0];
a1 = zcp->zc_word[1];
b0 = zcp->zc_word[2];
b1 = zcp->zc_word[3];
for (; ip < ipend; ip += 2) {
a0 += BSWAP_64(ip[0]);
a1 += BSWAP_64(ip[1]);
b0 += a0;
b1 += a1;
}
ZIO_SET_CHECKSUM(zcp, a0, a1, b0, b1);
return (0);
}
/*ARGSUSED*/
void
fletcher_2_byteswap(const void *buf, uint64_t size,
const void *ctx_template, zio_cksum_t *zcp)
{
fletcher_init(zcp);
(void) fletcher_2_incremental_byteswap((void *) buf, size, zcp);
}
static void
fletcher_4_scalar_init(fletcher_4_ctx_t *ctx)
{
ZIO_SET_CHECKSUM(&ctx->scalar, 0, 0, 0, 0);
}
static void
fletcher_4_scalar_fini(fletcher_4_ctx_t *ctx, zio_cksum_t *zcp)
{
memcpy(zcp, &ctx->scalar, sizeof (zio_cksum_t));
}
static void
fletcher_4_scalar_native(fletcher_4_ctx_t *ctx, const void *buf,
uint64_t size)
{
const uint32_t *ip = buf;
const uint32_t *ipend = ip + (size / sizeof (uint32_t));
uint64_t a, b, c, d;
a = ctx->scalar.zc_word[0];
b = ctx->scalar.zc_word[1];
c = ctx->scalar.zc_word[2];
d = ctx->scalar.zc_word[3];
for (; ip < ipend; ip++) {
a += ip[0];
b += a;
c += b;
d += c;
}
ZIO_SET_CHECKSUM(&ctx->scalar, a, b, c, d);
}
static void
fletcher_4_scalar_byteswap(fletcher_4_ctx_t *ctx, const void *buf,
uint64_t size)
{
const uint32_t *ip = buf;
const uint32_t *ipend = ip + (size / sizeof (uint32_t));
uint64_t a, b, c, d;
a = ctx->scalar.zc_word[0];
b = ctx->scalar.zc_word[1];
c = ctx->scalar.zc_word[2];
d = ctx->scalar.zc_word[3];
for (; ip < ipend; ip++) {
a += BSWAP_32(ip[0]);
b += a;
c += b;
d += c;
}
ZIO_SET_CHECKSUM(&ctx->scalar, a, b, c, d);
}
static boolean_t
fletcher_4_scalar_valid(void)
{
return (B_TRUE);
}
int
fletcher_4_impl_set(const char *val)
{
int err = -EINVAL;
uint32_t impl = IMPL_READ(fletcher_4_impl_chosen);
size_t i, val_len;
val_len = strlen(val);
while ((val_len > 0) && !!isspace(val[val_len-1])) /* trim '\n' */
val_len--;
/* check mandatory implementations */
for (i = 0; i < ARRAY_SIZE(fletcher_4_impl_selectors); i++) {
const char *name = fletcher_4_impl_selectors[i].fis_name;
if (val_len == strlen(name) &&
strncmp(val, name, val_len) == 0) {
impl = fletcher_4_impl_selectors[i].fis_sel;
err = 0;
break;
}
}
if (err != 0 && fletcher_4_initialized) {
/* check all supported implementations */
for (i = 0; i < fletcher_4_supp_impls_cnt; i++) {
const char *name = fletcher_4_supp_impls[i]->name;
if (val_len == strlen(name) &&
strncmp(val, name, val_len) == 0) {
impl = i;
err = 0;
break;
}
}
}
if (err == 0) {
atomic_swap_32(&fletcher_4_impl_chosen, impl);
membar_producer();
}
return (err);
}
/*
* Returns the Fletcher 4 operations for checksums. When a SIMD
* implementation is not allowed in the current context, then fallback
* to the fastest generic implementation.
*/
static inline const fletcher_4_ops_t *
fletcher_4_impl_get(void)
{
if (!kfpu_allowed())
return (&fletcher_4_superscalar4_ops);
const fletcher_4_ops_t *ops = NULL;
uint32_t impl = IMPL_READ(fletcher_4_impl_chosen);
switch (impl) {
case IMPL_FASTEST:
ASSERT(fletcher_4_initialized);
ops = &fletcher_4_fastest_impl;
break;
case IMPL_CYCLE:
/* Cycle through supported implementations */
ASSERT(fletcher_4_initialized);
ASSERT3U(fletcher_4_supp_impls_cnt, >, 0);
static uint32_t cycle_count = 0;
uint32_t idx = (++cycle_count) % fletcher_4_supp_impls_cnt;
ops = fletcher_4_supp_impls[idx];
break;
default:
ASSERT3U(fletcher_4_supp_impls_cnt, >, 0);
ASSERT3U(impl, <, fletcher_4_supp_impls_cnt);
ops = fletcher_4_supp_impls[impl];
break;
}
ASSERT3P(ops, !=, NULL);
return (ops);
}
static inline void
fletcher_4_native_impl(const void *buf, uint64_t size, zio_cksum_t *zcp)
{
fletcher_4_ctx_t ctx;
const fletcher_4_ops_t *ops = fletcher_4_impl_get();
ops->init_native(&ctx);
ops->compute_native(&ctx, buf, size);
ops->fini_native(&ctx, zcp);
}
/*ARGSUSED*/
void
fletcher_4_native(const void *buf, uint64_t size,
const void *ctx_template, zio_cksum_t *zcp)
{
const uint64_t p2size = P2ALIGN(size, FLETCHER_MIN_SIMD_SIZE);
ASSERT(IS_P2ALIGNED(size, sizeof (uint32_t)));
if (size == 0 || p2size == 0) {
ZIO_SET_CHECKSUM(zcp, 0, 0, 0, 0);
if (size > 0)
fletcher_4_scalar_native((fletcher_4_ctx_t *)zcp,
buf, size);
} else {
fletcher_4_native_impl(buf, p2size, zcp);
if (p2size < size)
fletcher_4_scalar_native((fletcher_4_ctx_t *)zcp,
(char *)buf + p2size, size - p2size);
}
}
void
fletcher_4_native_varsize(const void *buf, uint64_t size, zio_cksum_t *zcp)
{
ZIO_SET_CHECKSUM(zcp, 0, 0, 0, 0);
fletcher_4_scalar_native((fletcher_4_ctx_t *)zcp, buf, size);
}
static inline void
fletcher_4_byteswap_impl(const void *buf, uint64_t size, zio_cksum_t *zcp)
{
fletcher_4_ctx_t ctx;
const fletcher_4_ops_t *ops = fletcher_4_impl_get();
ops->init_byteswap(&ctx);
ops->compute_byteswap(&ctx, buf, size);
ops->fini_byteswap(&ctx, zcp);
}
/*ARGSUSED*/
void
fletcher_4_byteswap(const void *buf, uint64_t size,
const void *ctx_template, zio_cksum_t *zcp)
{
const uint64_t p2size = P2ALIGN(size, FLETCHER_MIN_SIMD_SIZE);
ASSERT(IS_P2ALIGNED(size, sizeof (uint32_t)));
if (size == 0 || p2size == 0) {
ZIO_SET_CHECKSUM(zcp, 0, 0, 0, 0);
if (size > 0)
fletcher_4_scalar_byteswap((fletcher_4_ctx_t *)zcp,
buf, size);
} else {
fletcher_4_byteswap_impl(buf, p2size, zcp);
if (p2size < size)
fletcher_4_scalar_byteswap((fletcher_4_ctx_t *)zcp,
(char *)buf + p2size, size - p2size);
}
}
/* Incremental Fletcher 4 */
#define ZFS_FLETCHER_4_INC_MAX_SIZE (8ULL << 20)
static inline void
fletcher_4_incremental_combine(zio_cksum_t *zcp, const uint64_t size,
const zio_cksum_t *nzcp)
{
const uint64_t c1 = size / sizeof (uint32_t);
const uint64_t c2 = c1 * (c1 + 1) / 2;
const uint64_t c3 = c2 * (c1 + 2) / 3;
/*
* Value of 'c3' overflows on buffer sizes close to 16MiB. For that
* reason we split incremental fletcher4 computation of large buffers
* to steps of (ZFS_FLETCHER_4_INC_MAX_SIZE) size.
*/
ASSERT3U(size, <=, ZFS_FLETCHER_4_INC_MAX_SIZE);
zcp->zc_word[3] += nzcp->zc_word[3] + c1 * zcp->zc_word[2] +
c2 * zcp->zc_word[1] + c3 * zcp->zc_word[0];
zcp->zc_word[2] += nzcp->zc_word[2] + c1 * zcp->zc_word[1] +
c2 * zcp->zc_word[0];
zcp->zc_word[1] += nzcp->zc_word[1] + c1 * zcp->zc_word[0];
zcp->zc_word[0] += nzcp->zc_word[0];
}
static inline void
fletcher_4_incremental_impl(boolean_t native, const void *buf, uint64_t size,
zio_cksum_t *zcp)
{
while (size > 0) {
zio_cksum_t nzc;
uint64_t len = MIN(size, ZFS_FLETCHER_4_INC_MAX_SIZE);
if (native)
fletcher_4_native(buf, len, NULL, &nzc);
else
fletcher_4_byteswap(buf, len, NULL, &nzc);
fletcher_4_incremental_combine(zcp, len, &nzc);
size -= len;
buf += len;
}
}
int
fletcher_4_incremental_native(void *buf, size_t size, void *data)
{
zio_cksum_t *zcp = data;
/* Use scalar impl to directly update cksum of small blocks */
if (size < SPA_MINBLOCKSIZE)
fletcher_4_scalar_native((fletcher_4_ctx_t *)zcp, buf, size);
else
fletcher_4_incremental_impl(B_TRUE, buf, size, zcp);
return (0);
}
int
fletcher_4_incremental_byteswap(void *buf, size_t size, void *data)
{
zio_cksum_t *zcp = data;
/* Use scalar impl to directly update cksum of small blocks */
if (size < SPA_MINBLOCKSIZE)
fletcher_4_scalar_byteswap((fletcher_4_ctx_t *)zcp, buf, size);
else
fletcher_4_incremental_impl(B_FALSE, buf, size, zcp);
return (0);
}
#if defined(_KERNEL)
/*
* Fletcher 4 kstats
*/
static int
fletcher_4_kstat_headers(char *buf, size_t size)
{
ssize_t off = 0;
off += snprintf(buf + off, size, "%-17s", "implementation");
off += snprintf(buf + off, size - off, "%-15s", "native");
(void) snprintf(buf + off, size - off, "%-15s\n", "byteswap");
return (0);
}
static int
fletcher_4_kstat_data(char *buf, size_t size, void *data)
{
struct fletcher_4_kstat *fastest_stat =
&fletcher_4_stat_data[fletcher_4_supp_impls_cnt];
struct fletcher_4_kstat *curr_stat = (struct fletcher_4_kstat *)data;
ssize_t off = 0;
if (curr_stat == fastest_stat) {
off += snprintf(buf + off, size - off, "%-17s", "fastest");
off += snprintf(buf + off, size - off, "%-15s",
fletcher_4_supp_impls[fastest_stat->native]->name);
off += snprintf(buf + off, size - off, "%-15s\n",
fletcher_4_supp_impls[fastest_stat->byteswap]->name);
} else {
ptrdiff_t id = curr_stat - fletcher_4_stat_data;
off += snprintf(buf + off, size - off, "%-17s",
fletcher_4_supp_impls[id]->name);
off += snprintf(buf + off, size - off, "%-15llu",
(u_longlong_t)curr_stat->native);
off += snprintf(buf + off, size - off, "%-15llu\n",
(u_longlong_t)curr_stat->byteswap);
}
return (0);
}
static void *
fletcher_4_kstat_addr(kstat_t *ksp, loff_t n)
{
if (n <= fletcher_4_supp_impls_cnt)
ksp->ks_private = (void *) (fletcher_4_stat_data + n);
else
ksp->ks_private = NULL;
return (ksp->ks_private);
}
#endif
#define FLETCHER_4_FASTEST_FN_COPY(type, src) \
{ \
fletcher_4_fastest_impl.init_ ## type = src->init_ ## type; \
fletcher_4_fastest_impl.fini_ ## type = src->fini_ ## type; \
fletcher_4_fastest_impl.compute_ ## type = src->compute_ ## type; \
}
#define FLETCHER_4_BENCH_NS (MSEC2NSEC(50)) /* 50ms */
typedef void fletcher_checksum_func_t(const void *, uint64_t, const void *,
zio_cksum_t *);
#if defined(_KERNEL)
static void
fletcher_4_benchmark_impl(boolean_t native, char *data, uint64_t data_size)
{
struct fletcher_4_kstat *fastest_stat =
&fletcher_4_stat_data[fletcher_4_supp_impls_cnt];
hrtime_t start;
uint64_t run_bw, run_time_ns, best_run = 0;
zio_cksum_t zc;
uint32_t i, l, sel_save = IMPL_READ(fletcher_4_impl_chosen);
fletcher_checksum_func_t *fletcher_4_test = native ?
fletcher_4_native : fletcher_4_byteswap;
for (i = 0; i < fletcher_4_supp_impls_cnt; i++) {
struct fletcher_4_kstat *stat = &fletcher_4_stat_data[i];
uint64_t run_count = 0;
/* temporary set an implementation */
fletcher_4_impl_chosen = i;
kpreempt_disable();
start = gethrtime();
do {
for (l = 0; l < 32; l++, run_count++)
fletcher_4_test(data, data_size, NULL, &zc);
run_time_ns = gethrtime() - start;
} while (run_time_ns < FLETCHER_4_BENCH_NS);
kpreempt_enable();
run_bw = data_size * run_count * NANOSEC;
run_bw /= run_time_ns; /* B/s */
if (native)
stat->native = run_bw;
else
stat->byteswap = run_bw;
if (run_bw > best_run) {
best_run = run_bw;
if (native) {
fastest_stat->native = i;
FLETCHER_4_FASTEST_FN_COPY(native,
fletcher_4_supp_impls[i]);
} else {
fastest_stat->byteswap = i;
FLETCHER_4_FASTEST_FN_COPY(byteswap,
fletcher_4_supp_impls[i]);
}
}
}
/* restore original selection */
atomic_swap_32(&fletcher_4_impl_chosen, sel_save);
}
#endif /* _KERNEL */
/*
* Initialize and benchmark all supported implementations.
*/
static void
fletcher_4_benchmark(void *arg)
{
fletcher_4_ops_t *curr_impl;
int i, c;
/* Move supported implementations into fletcher_4_supp_impls */
for (i = 0, c = 0; i < ARRAY_SIZE(fletcher_4_impls); i++) {
curr_impl = (fletcher_4_ops_t *)fletcher_4_impls[i];
if (curr_impl->valid && curr_impl->valid())
fletcher_4_supp_impls[c++] = curr_impl;
}
membar_producer(); /* complete fletcher_4_supp_impls[] init */
fletcher_4_supp_impls_cnt = c; /* number of supported impl */
#if defined(_KERNEL)
static const size_t data_size = 1 << SPA_OLD_MAXBLOCKSHIFT; /* 128kiB */
char *databuf = vmem_alloc(data_size, KM_SLEEP);
for (i = 0; i < data_size / sizeof (uint64_t); i++)
((uint64_t *)databuf)[i] = (uintptr_t)(databuf+i); /* warm-up */
fletcher_4_benchmark_impl(B_FALSE, databuf, data_size);
fletcher_4_benchmark_impl(B_TRUE, databuf, data_size);
vmem_free(databuf, data_size);
#else
/*
* Skip the benchmark in user space to avoid impacting libzpool
* consumers (zdb, zhack, zinject, ztest). The last implementation
* is assumed to be the fastest and used by default.
*/
memcpy(&fletcher_4_fastest_impl,
fletcher_4_supp_impls[fletcher_4_supp_impls_cnt - 1],
sizeof (fletcher_4_fastest_impl));
fletcher_4_fastest_impl.name = "fastest";
membar_producer();
#endif /* _KERNEL */
}
void
fletcher_4_init(void)
{
#if defined(_KERNEL)
/*
* For 5.0 and latter Linux kernels the fletcher 4 benchmarks are
* run in a kernel threads. This is needed to take advantage of the
* SIMD functionality, see linux/simd_x86.h for details.
*/
taskqid_t id = taskq_dispatch(system_taskq, fletcher_4_benchmark,
NULL, TQ_SLEEP);
if (id != TASKQID_INVALID) {
taskq_wait_id(system_taskq, id);
} else {
fletcher_4_benchmark(NULL);
}
/* Install kstats for all implementations */
fletcher_4_kstat = kstat_create("zfs", 0, "fletcher_4_bench", "misc",
KSTAT_TYPE_RAW, 0, KSTAT_FLAG_VIRTUAL);
if (fletcher_4_kstat != NULL) {
fletcher_4_kstat->ks_data = NULL;
fletcher_4_kstat->ks_ndata = UINT32_MAX;
kstat_set_raw_ops(fletcher_4_kstat,
fletcher_4_kstat_headers,
fletcher_4_kstat_data,
fletcher_4_kstat_addr);
kstat_install(fletcher_4_kstat);
}
#else
fletcher_4_benchmark(NULL);
#endif
/* Finish initialization */
fletcher_4_initialized = B_TRUE;
}
void
fletcher_4_fini(void)
{
#if defined(_KERNEL)
if (fletcher_4_kstat != NULL) {
kstat_delete(fletcher_4_kstat);
fletcher_4_kstat = NULL;
}
#endif
}
/* ABD adapters */
static void
abd_fletcher_4_init(zio_abd_checksum_data_t *cdp)
{
const fletcher_4_ops_t *ops = fletcher_4_impl_get();
cdp->acd_private = (void *) ops;
if (cdp->acd_byteorder == ZIO_CHECKSUM_NATIVE)
ops->init_native(cdp->acd_ctx);
else
ops->init_byteswap(cdp->acd_ctx);
}
static void
abd_fletcher_4_fini(zio_abd_checksum_data_t *cdp)
{
fletcher_4_ops_t *ops = (fletcher_4_ops_t *)cdp->acd_private;
ASSERT(ops);
if (cdp->acd_byteorder == ZIO_CHECKSUM_NATIVE)
ops->fini_native(cdp->acd_ctx, cdp->acd_zcp);
else
ops->fini_byteswap(cdp->acd_ctx, cdp->acd_zcp);
}
static void
abd_fletcher_4_simd2scalar(boolean_t native, void *data, size_t size,
zio_abd_checksum_data_t *cdp)
{
zio_cksum_t *zcp = cdp->acd_zcp;
ASSERT3U(size, <, FLETCHER_MIN_SIMD_SIZE);
abd_fletcher_4_fini(cdp);
cdp->acd_private = (void *)&fletcher_4_scalar_ops;
if (native)
fletcher_4_incremental_native(data, size, zcp);
else
fletcher_4_incremental_byteswap(data, size, zcp);
}
static int
abd_fletcher_4_iter(void *data, size_t size, void *private)
{
zio_abd_checksum_data_t *cdp = (zio_abd_checksum_data_t *)private;
fletcher_4_ctx_t *ctx = cdp->acd_ctx;
fletcher_4_ops_t *ops = (fletcher_4_ops_t *)cdp->acd_private;
boolean_t native = cdp->acd_byteorder == ZIO_CHECKSUM_NATIVE;
uint64_t asize = P2ALIGN(size, FLETCHER_MIN_SIMD_SIZE);
ASSERT(IS_P2ALIGNED(size, sizeof (uint32_t)));
if (asize > 0) {
if (native)
ops->compute_native(ctx, data, asize);
else
ops->compute_byteswap(ctx, data, asize);
size -= asize;
data = (char *)data + asize;
}
if (size > 0) {
ASSERT3U(size, <, FLETCHER_MIN_SIMD_SIZE);
/* At this point we have to switch to scalar impl */
abd_fletcher_4_simd2scalar(native, data, size, cdp);
}
return (0);
}
zio_abd_checksum_func_t fletcher_4_abd_ops = {
.acf_init = abd_fletcher_4_init,
.acf_fini = abd_fletcher_4_fini,
.acf_iter = abd_fletcher_4_iter
};
#if defined(_KERNEL)
#include <linux/mod_compat.h>
static int
fletcher_4_param_get(char *buffer, zfs_kernel_param_t *unused)
{
const uint32_t impl = IMPL_READ(fletcher_4_impl_chosen);
char *fmt;
int i, cnt = 0;
/* list fastest */
fmt = (impl == IMPL_FASTEST) ? "[%s] " : "%s ";
cnt += sprintf(buffer + cnt, fmt, "fastest");
/* list all supported implementations */
for (i = 0; i < fletcher_4_supp_impls_cnt; i++) {
fmt = (i == impl) ? "[%s] " : "%s ";
cnt += sprintf(buffer + cnt, fmt,
fletcher_4_supp_impls[i]->name);
}
return (cnt);
}
static int
fletcher_4_param_set(const char *val, zfs_kernel_param_t *unused)
{
return (fletcher_4_impl_set(val));
}
/*
* Choose a fletcher 4 implementation in ZFS.
* Users can choose "cycle" to exercise all implementations, but this is
* for testing purpose therefore it can only be set in user space.
*/
module_param_call(zfs_fletcher_4_impl,
fletcher_4_param_set, fletcher_4_param_get, NULL, 0644);
MODULE_PARM_DESC(zfs_fletcher_4_impl, "Select fletcher 4 implementation.");
EXPORT_SYMBOL(fletcher_init);
EXPORT_SYMBOL(fletcher_2_incremental_native);
EXPORT_SYMBOL(fletcher_2_incremental_byteswap);
EXPORT_SYMBOL(fletcher_4_init);
EXPORT_SYMBOL(fletcher_4_fini);
EXPORT_SYMBOL(fletcher_2_native);
EXPORT_SYMBOL(fletcher_2_byteswap);
EXPORT_SYMBOL(fletcher_4_native);
EXPORT_SYMBOL(fletcher_4_native_varsize);
EXPORT_SYMBOL(fletcher_4_byteswap);
EXPORT_SYMBOL(fletcher_4_incremental_native);
EXPORT_SYMBOL(fletcher_4_incremental_byteswap);
EXPORT_SYMBOL(fletcher_4_abd_ops);
#endif