mirror of
https://sourceware.org/git/glibc.git
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f2413f2710
Use testl, instead of andl, to check __x86_string_control to avoid
updating __x86_string_control.
Reviewed-by: Carlos O'Donell <carlos@redhat.com>
(cherry picked from commit 3c8b9879ca
)
786 lines
23 KiB
ArmAsm
786 lines
23 KiB
ArmAsm
/* memmove/memcpy/mempcpy with unaligned load/store and rep movsb
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Copyright (C) 2016-2021 Free Software Foundation, Inc.
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This file is part of the GNU C Library.
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The GNU C Library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License as published by the Free Software Foundation; either
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version 2.1 of the License, or (at your option) any later version.
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The GNU C Library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser General Public
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License along with the GNU C Library; if not, see
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<https://www.gnu.org/licenses/>. */
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/* memmove/memcpy/mempcpy is implemented as:
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1. Use overlapping load and store to avoid branch.
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2. Load all sources into registers and store them together to avoid
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possible address overlap between source and destination.
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3. If size is 8 * VEC_SIZE or less, load all sources into registers
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and store them together.
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4. If address of destination > address of source, backward copy
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4 * VEC_SIZE at a time with unaligned load and aligned store.
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Load the first 4 * VEC and last VEC before the loop and store
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them after the loop to support overlapping addresses.
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5. Otherwise, forward copy 4 * VEC_SIZE at a time with unaligned
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load and aligned store. Load the last 4 * VEC and first VEC
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before the loop and store them after the loop to support
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overlapping addresses.
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6. On machines with ERMS feature, if size greater than equal or to
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__x86_rep_movsb_threshold and less than
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__x86_rep_movsb_stop_threshold, then REP MOVSB will be used.
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7. If size >= __x86_shared_non_temporal_threshold and there is no
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overlap between destination and source, use non-temporal store
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instead of aligned store copying from either 2 or 4 pages at
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once.
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8. For point 7) if size < 16 * __x86_shared_non_temporal_threshold
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and source and destination do not page alias, copy from 2 pages
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at once using non-temporal stores. Page aliasing in this case is
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considered true if destination's page alignment - sources' page
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alignment is less than 8 * VEC_SIZE.
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9. If size >= 16 * __x86_shared_non_temporal_threshold or source
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and destination do page alias copy from 4 pages at once using
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non-temporal stores. */
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#include <sysdep.h>
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#ifndef MEMCPY_SYMBOL
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# define MEMCPY_SYMBOL(p,s) MEMMOVE_SYMBOL(p, s)
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#endif
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#ifndef MEMPCPY_SYMBOL
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# define MEMPCPY_SYMBOL(p,s) MEMMOVE_SYMBOL(p, s)
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#endif
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#ifndef MEMMOVE_CHK_SYMBOL
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# define MEMMOVE_CHK_SYMBOL(p,s) MEMMOVE_SYMBOL(p, s)
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#endif
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#ifndef XMM0
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# define XMM0 xmm0
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#endif
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#ifndef YMM0
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# define YMM0 ymm0
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#endif
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#ifndef VZEROUPPER
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# if VEC_SIZE > 16
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# define VZEROUPPER vzeroupper
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# else
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# define VZEROUPPER
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# endif
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#endif
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#ifndef PAGE_SIZE
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# define PAGE_SIZE 4096
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#endif
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#if PAGE_SIZE != 4096
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# error Unsupported PAGE_SIZE
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#endif
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#ifndef LOG_PAGE_SIZE
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# define LOG_PAGE_SIZE 12
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#endif
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#if PAGE_SIZE != (1 << LOG_PAGE_SIZE)
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# error Invalid LOG_PAGE_SIZE
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#endif
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/* Byte per page for large_memcpy inner loop. */
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#if VEC_SIZE == 64
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# define LARGE_LOAD_SIZE (VEC_SIZE * 2)
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#else
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# define LARGE_LOAD_SIZE (VEC_SIZE * 4)
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#endif
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/* Amount to shift rdx by to compare for memcpy_large_4x. */
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#ifndef LOG_4X_MEMCPY_THRESH
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# define LOG_4X_MEMCPY_THRESH 4
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#endif
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/* Avoid short distance rep movsb only with non-SSE vector. */
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#ifndef AVOID_SHORT_DISTANCE_REP_MOVSB
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# define AVOID_SHORT_DISTANCE_REP_MOVSB (VEC_SIZE > 16)
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#else
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# define AVOID_SHORT_DISTANCE_REP_MOVSB 0
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#endif
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#ifndef PREFETCH
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# define PREFETCH(addr) prefetcht0 addr
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#endif
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/* Assume 64-byte prefetch size. */
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#ifndef PREFETCH_SIZE
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# define PREFETCH_SIZE 64
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#endif
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#define PREFETCHED_LOAD_SIZE (VEC_SIZE * 4)
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#if PREFETCH_SIZE == 64
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# if PREFETCHED_LOAD_SIZE == PREFETCH_SIZE
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# define PREFETCH_ONE_SET(dir, base, offset) \
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PREFETCH ((offset)base)
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# elif PREFETCHED_LOAD_SIZE == 2 * PREFETCH_SIZE
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# define PREFETCH_ONE_SET(dir, base, offset) \
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PREFETCH ((offset)base); \
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PREFETCH ((offset + dir * PREFETCH_SIZE)base)
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# elif PREFETCHED_LOAD_SIZE == 4 * PREFETCH_SIZE
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# define PREFETCH_ONE_SET(dir, base, offset) \
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PREFETCH ((offset)base); \
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PREFETCH ((offset + dir * PREFETCH_SIZE)base); \
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PREFETCH ((offset + dir * PREFETCH_SIZE * 2)base); \
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PREFETCH ((offset + dir * PREFETCH_SIZE * 3)base)
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# else
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# error Unsupported PREFETCHED_LOAD_SIZE!
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# endif
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#else
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# error Unsupported PREFETCH_SIZE!
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#endif
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#if LARGE_LOAD_SIZE == (VEC_SIZE * 2)
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# define LOAD_ONE_SET(base, offset, vec0, vec1, ...) \
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VMOVU (offset)base, vec0; \
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VMOVU ((offset) + VEC_SIZE)base, vec1;
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# define STORE_ONE_SET(base, offset, vec0, vec1, ...) \
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VMOVNT vec0, (offset)base; \
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VMOVNT vec1, ((offset) + VEC_SIZE)base;
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#elif LARGE_LOAD_SIZE == (VEC_SIZE * 4)
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# define LOAD_ONE_SET(base, offset, vec0, vec1, vec2, vec3) \
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VMOVU (offset)base, vec0; \
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VMOVU ((offset) + VEC_SIZE)base, vec1; \
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VMOVU ((offset) + VEC_SIZE * 2)base, vec2; \
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VMOVU ((offset) + VEC_SIZE * 3)base, vec3;
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# define STORE_ONE_SET(base, offset, vec0, vec1, vec2, vec3) \
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VMOVNT vec0, (offset)base; \
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VMOVNT vec1, ((offset) + VEC_SIZE)base; \
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VMOVNT vec2, ((offset) + VEC_SIZE * 2)base; \
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VMOVNT vec3, ((offset) + VEC_SIZE * 3)base;
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#else
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# error Invalid LARGE_LOAD_SIZE
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#endif
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#ifndef SECTION
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# error SECTION is not defined!
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#endif
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.section SECTION(.text),"ax",@progbits
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#if defined SHARED && IS_IN (libc)
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ENTRY (MEMMOVE_CHK_SYMBOL (__mempcpy_chk, unaligned))
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cmp %RDX_LP, %RCX_LP
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jb HIDDEN_JUMPTARGET (__chk_fail)
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END (MEMMOVE_CHK_SYMBOL (__mempcpy_chk, unaligned))
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#endif
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ENTRY (MEMPCPY_SYMBOL (__mempcpy, unaligned))
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mov %RDI_LP, %RAX_LP
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add %RDX_LP, %RAX_LP
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jmp L(start)
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END (MEMPCPY_SYMBOL (__mempcpy, unaligned))
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#if defined SHARED && IS_IN (libc)
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ENTRY (MEMMOVE_CHK_SYMBOL (__memmove_chk, unaligned))
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cmp %RDX_LP, %RCX_LP
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jb HIDDEN_JUMPTARGET (__chk_fail)
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END (MEMMOVE_CHK_SYMBOL (__memmove_chk, unaligned))
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#endif
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ENTRY (MEMMOVE_SYMBOL (__memmove, unaligned))
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movq %rdi, %rax
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L(start):
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# ifdef __ILP32__
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/* Clear the upper 32 bits. */
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movl %edx, %edx
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# endif
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cmp $VEC_SIZE, %RDX_LP
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jb L(less_vec)
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cmp $(VEC_SIZE * 2), %RDX_LP
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ja L(more_2x_vec)
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#if !defined USE_MULTIARCH || !IS_IN (libc)
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L(last_2x_vec):
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#endif
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/* From VEC and to 2 * VEC. No branch when size == VEC_SIZE. */
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VMOVU (%rsi), %VEC(0)
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VMOVU -VEC_SIZE(%rsi,%rdx), %VEC(1)
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VMOVU %VEC(0), (%rdi)
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VMOVU %VEC(1), -VEC_SIZE(%rdi,%rdx)
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#if !defined USE_MULTIARCH || !IS_IN (libc)
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L(nop):
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ret
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#else
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VZEROUPPER_RETURN
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#endif
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#if defined USE_MULTIARCH && IS_IN (libc)
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END (MEMMOVE_SYMBOL (__memmove, unaligned))
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# if VEC_SIZE == 16
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ENTRY (__mempcpy_chk_erms)
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cmp %RDX_LP, %RCX_LP
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jb HIDDEN_JUMPTARGET (__chk_fail)
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END (__mempcpy_chk_erms)
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/* Only used to measure performance of REP MOVSB. */
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ENTRY (__mempcpy_erms)
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mov %RDI_LP, %RAX_LP
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/* Skip zero length. */
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test %RDX_LP, %RDX_LP
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jz 2f
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add %RDX_LP, %RAX_LP
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jmp L(start_movsb)
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END (__mempcpy_erms)
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ENTRY (__memmove_chk_erms)
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cmp %RDX_LP, %RCX_LP
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jb HIDDEN_JUMPTARGET (__chk_fail)
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END (__memmove_chk_erms)
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ENTRY (__memmove_erms)
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movq %rdi, %rax
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/* Skip zero length. */
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test %RDX_LP, %RDX_LP
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jz 2f
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L(start_movsb):
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mov %RDX_LP, %RCX_LP
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cmp %RSI_LP, %RDI_LP
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jb 1f
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/* Source == destination is less common. */
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je 2f
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lea (%rsi,%rcx), %RDX_LP
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cmp %RDX_LP, %RDI_LP
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jb L(movsb_backward)
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1:
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rep movsb
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2:
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ret
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L(movsb_backward):
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leaq -1(%rdi,%rcx), %rdi
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leaq -1(%rsi,%rcx), %rsi
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std
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rep movsb
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cld
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ret
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END (__memmove_erms)
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strong_alias (__memmove_erms, __memcpy_erms)
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strong_alias (__memmove_chk_erms, __memcpy_chk_erms)
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# endif
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# ifdef SHARED
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ENTRY (MEMMOVE_CHK_SYMBOL (__mempcpy_chk, unaligned_erms))
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cmp %RDX_LP, %RCX_LP
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jb HIDDEN_JUMPTARGET (__chk_fail)
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END (MEMMOVE_CHK_SYMBOL (__mempcpy_chk, unaligned_erms))
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# endif
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ENTRY (MEMMOVE_SYMBOL (__mempcpy, unaligned_erms))
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mov %RDI_LP, %RAX_LP
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add %RDX_LP, %RAX_LP
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jmp L(start_erms)
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END (MEMMOVE_SYMBOL (__mempcpy, unaligned_erms))
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# ifdef SHARED
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ENTRY (MEMMOVE_CHK_SYMBOL (__memmove_chk, unaligned_erms))
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cmp %RDX_LP, %RCX_LP
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jb HIDDEN_JUMPTARGET (__chk_fail)
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END (MEMMOVE_CHK_SYMBOL (__memmove_chk, unaligned_erms))
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# endif
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ENTRY (MEMMOVE_SYMBOL (__memmove, unaligned_erms))
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movq %rdi, %rax
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L(start_erms):
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# ifdef __ILP32__
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/* Clear the upper 32 bits. */
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movl %edx, %edx
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# endif
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cmp $VEC_SIZE, %RDX_LP
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jb L(less_vec)
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cmp $(VEC_SIZE * 2), %RDX_LP
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ja L(movsb_more_2x_vec)
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L(last_2x_vec):
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/* From VEC and to 2 * VEC. No branch when size == VEC_SIZE. */
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VMOVU (%rsi), %VEC(0)
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VMOVU -VEC_SIZE(%rsi,%rdx), %VEC(1)
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VMOVU %VEC(0), (%rdi)
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VMOVU %VEC(1), -VEC_SIZE(%rdi,%rdx)
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L(return):
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#if VEC_SIZE > 16
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ZERO_UPPER_VEC_REGISTERS_RETURN
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#else
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ret
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#endif
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L(movsb):
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cmp __x86_rep_movsb_stop_threshold(%rip), %RDX_LP
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jae L(more_8x_vec)
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cmpq %rsi, %rdi
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jb 1f
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/* Source == destination is less common. */
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je L(nop)
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leaq (%rsi,%rdx), %r9
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cmpq %r9, %rdi
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/* Avoid slow backward REP MOVSB. */
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jb L(more_8x_vec_backward)
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# if AVOID_SHORT_DISTANCE_REP_MOVSB
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testl $X86_STRING_CONTROL_AVOID_SHORT_DISTANCE_REP_MOVSB, __x86_string_control(%rip)
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jz 3f
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movq %rdi, %rcx
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subq %rsi, %rcx
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jmp 2f
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# endif
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1:
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# if AVOID_SHORT_DISTANCE_REP_MOVSB
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testl $X86_STRING_CONTROL_AVOID_SHORT_DISTANCE_REP_MOVSB, __x86_string_control(%rip)
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jz 3f
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movq %rsi, %rcx
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subq %rdi, %rcx
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2:
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/* Avoid "rep movsb" if RCX, the distance between source and destination,
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is N*4GB + [1..63] with N >= 0. */
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cmpl $63, %ecx
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jbe L(more_2x_vec) /* Avoid "rep movsb" if ECX <= 63. */
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3:
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# endif
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mov %RDX_LP, %RCX_LP
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rep movsb
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L(nop):
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ret
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#endif
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L(less_vec):
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/* Less than 1 VEC. */
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#if VEC_SIZE != 16 && VEC_SIZE != 32 && VEC_SIZE != 64
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# error Unsupported VEC_SIZE!
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#endif
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#if VEC_SIZE > 32
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cmpb $32, %dl
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jae L(between_32_63)
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#endif
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#if VEC_SIZE > 16
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cmpb $16, %dl
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jae L(between_16_31)
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#endif
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cmpb $8, %dl
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jae L(between_8_15)
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cmpb $4, %dl
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jae L(between_4_7)
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cmpb $1, %dl
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ja L(between_2_3)
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jb 1f
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movzbl (%rsi), %ecx
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movb %cl, (%rdi)
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1:
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ret
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#if VEC_SIZE > 32
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L(between_32_63):
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/* From 32 to 63. No branch when size == 32. */
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VMOVU (%rsi), %YMM0
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VMOVU -32(%rsi,%rdx), %YMM1
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VMOVU %YMM0, (%rdi)
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VMOVU %YMM1, -32(%rdi,%rdx)
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VZEROUPPER_RETURN
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#endif
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#if VEC_SIZE > 16
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/* From 16 to 31. No branch when size == 16. */
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L(between_16_31):
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VMOVU (%rsi), %XMM0
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VMOVU -16(%rsi,%rdx), %XMM1
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VMOVU %XMM0, (%rdi)
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VMOVU %XMM1, -16(%rdi,%rdx)
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VZEROUPPER_RETURN
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#endif
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L(between_8_15):
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/* From 8 to 15. No branch when size == 8. */
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movq -8(%rsi,%rdx), %rcx
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movq (%rsi), %rsi
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movq %rcx, -8(%rdi,%rdx)
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movq %rsi, (%rdi)
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ret
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L(between_4_7):
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/* From 4 to 7. No branch when size == 4. */
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movl -4(%rsi,%rdx), %ecx
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movl (%rsi), %esi
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movl %ecx, -4(%rdi,%rdx)
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movl %esi, (%rdi)
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ret
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L(between_2_3):
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/* From 2 to 3. No branch when size == 2. */
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movzwl -2(%rsi,%rdx), %ecx
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movzwl (%rsi), %esi
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movw %cx, -2(%rdi,%rdx)
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movw %si, (%rdi)
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ret
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#if defined USE_MULTIARCH && IS_IN (libc)
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L(movsb_more_2x_vec):
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cmp __x86_rep_movsb_threshold(%rip), %RDX_LP
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ja L(movsb)
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#endif
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L(more_2x_vec):
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/* More than 2 * VEC and there may be overlap between destination
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and source. */
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cmpq $(VEC_SIZE * 8), %rdx
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ja L(more_8x_vec)
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cmpq $(VEC_SIZE * 4), %rdx
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jbe L(last_4x_vec)
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/* Copy from 4 * VEC + 1 to 8 * VEC, inclusively. */
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VMOVU (%rsi), %VEC(0)
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VMOVU VEC_SIZE(%rsi), %VEC(1)
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VMOVU (VEC_SIZE * 2)(%rsi), %VEC(2)
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VMOVU (VEC_SIZE * 3)(%rsi), %VEC(3)
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VMOVU -VEC_SIZE(%rsi,%rdx), %VEC(4)
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VMOVU -(VEC_SIZE * 2)(%rsi,%rdx), %VEC(5)
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VMOVU -(VEC_SIZE * 3)(%rsi,%rdx), %VEC(6)
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VMOVU -(VEC_SIZE * 4)(%rsi,%rdx), %VEC(7)
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VMOVU %VEC(0), (%rdi)
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VMOVU %VEC(1), VEC_SIZE(%rdi)
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VMOVU %VEC(2), (VEC_SIZE * 2)(%rdi)
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VMOVU %VEC(3), (VEC_SIZE * 3)(%rdi)
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VMOVU %VEC(4), -VEC_SIZE(%rdi,%rdx)
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VMOVU %VEC(5), -(VEC_SIZE * 2)(%rdi,%rdx)
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VMOVU %VEC(6), -(VEC_SIZE * 3)(%rdi,%rdx)
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VMOVU %VEC(7), -(VEC_SIZE * 4)(%rdi,%rdx)
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VZEROUPPER_RETURN
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L(last_4x_vec):
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/* Copy from 2 * VEC + 1 to 4 * VEC, inclusively. */
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VMOVU (%rsi), %VEC(0)
|
|
VMOVU VEC_SIZE(%rsi), %VEC(1)
|
|
VMOVU -VEC_SIZE(%rsi,%rdx), %VEC(2)
|
|
VMOVU -(VEC_SIZE * 2)(%rsi,%rdx), %VEC(3)
|
|
VMOVU %VEC(0), (%rdi)
|
|
VMOVU %VEC(1), VEC_SIZE(%rdi)
|
|
VMOVU %VEC(2), -VEC_SIZE(%rdi,%rdx)
|
|
VMOVU %VEC(3), -(VEC_SIZE * 2)(%rdi,%rdx)
|
|
VZEROUPPER_RETURN
|
|
|
|
L(more_8x_vec):
|
|
/* Check if non-temporal move candidate. */
|
|
#if (defined USE_MULTIARCH || VEC_SIZE == 16) && IS_IN (libc)
|
|
/* Check non-temporal store threshold. */
|
|
cmp __x86_shared_non_temporal_threshold(%rip), %RDX_LP
|
|
ja L(large_memcpy_2x)
|
|
#endif
|
|
/* Entry if rdx is greater than non-temporal threshold but there
|
|
is overlap. */
|
|
L(more_8x_vec_check):
|
|
cmpq %rsi, %rdi
|
|
ja L(more_8x_vec_backward)
|
|
/* Source == destination is less common. */
|
|
je L(nop)
|
|
/* Load the first VEC and last 4 * VEC to support overlapping
|
|
addresses. */
|
|
VMOVU (%rsi), %VEC(4)
|
|
VMOVU -VEC_SIZE(%rsi, %rdx), %VEC(5)
|
|
VMOVU -(VEC_SIZE * 2)(%rsi, %rdx), %VEC(6)
|
|
VMOVU -(VEC_SIZE * 3)(%rsi, %rdx), %VEC(7)
|
|
VMOVU -(VEC_SIZE * 4)(%rsi, %rdx), %VEC(8)
|
|
/* Save start and stop of the destination buffer. */
|
|
movq %rdi, %r11
|
|
leaq -VEC_SIZE(%rdi, %rdx), %rcx
|
|
/* Align destination for aligned stores in the loop. Compute
|
|
how much destination is misaligned. */
|
|
movq %rdi, %r8
|
|
andq $(VEC_SIZE - 1), %r8
|
|
/* Get the negative of offset for alignment. */
|
|
subq $VEC_SIZE, %r8
|
|
/* Adjust source. */
|
|
subq %r8, %rsi
|
|
/* Adjust destination which should be aligned now. */
|
|
subq %r8, %rdi
|
|
/* Adjust length. */
|
|
addq %r8, %rdx
|
|
|
|
.p2align 4
|
|
L(loop_4x_vec_forward):
|
|
/* Copy 4 * VEC a time forward. */
|
|
VMOVU (%rsi), %VEC(0)
|
|
VMOVU VEC_SIZE(%rsi), %VEC(1)
|
|
VMOVU (VEC_SIZE * 2)(%rsi), %VEC(2)
|
|
VMOVU (VEC_SIZE * 3)(%rsi), %VEC(3)
|
|
subq $-(VEC_SIZE * 4), %rsi
|
|
addq $-(VEC_SIZE * 4), %rdx
|
|
VMOVA %VEC(0), (%rdi)
|
|
VMOVA %VEC(1), VEC_SIZE(%rdi)
|
|
VMOVA %VEC(2), (VEC_SIZE * 2)(%rdi)
|
|
VMOVA %VEC(3), (VEC_SIZE * 3)(%rdi)
|
|
subq $-(VEC_SIZE * 4), %rdi
|
|
cmpq $(VEC_SIZE * 4), %rdx
|
|
ja L(loop_4x_vec_forward)
|
|
/* Store the last 4 * VEC. */
|
|
VMOVU %VEC(5), (%rcx)
|
|
VMOVU %VEC(6), -VEC_SIZE(%rcx)
|
|
VMOVU %VEC(7), -(VEC_SIZE * 2)(%rcx)
|
|
VMOVU %VEC(8), -(VEC_SIZE * 3)(%rcx)
|
|
/* Store the first VEC. */
|
|
VMOVU %VEC(4), (%r11)
|
|
VZEROUPPER_RETURN
|
|
|
|
L(more_8x_vec_backward):
|
|
/* Load the first 4 * VEC and last VEC to support overlapping
|
|
addresses. */
|
|
VMOVU (%rsi), %VEC(4)
|
|
VMOVU VEC_SIZE(%rsi), %VEC(5)
|
|
VMOVU (VEC_SIZE * 2)(%rsi), %VEC(6)
|
|
VMOVU (VEC_SIZE * 3)(%rsi), %VEC(7)
|
|
VMOVU -VEC_SIZE(%rsi,%rdx), %VEC(8)
|
|
/* Save stop of the destination buffer. */
|
|
leaq -VEC_SIZE(%rdi, %rdx), %r11
|
|
/* Align destination end for aligned stores in the loop. Compute
|
|
how much destination end is misaligned. */
|
|
leaq -VEC_SIZE(%rsi, %rdx), %rcx
|
|
movq %r11, %r9
|
|
movq %r11, %r8
|
|
andq $(VEC_SIZE - 1), %r8
|
|
/* Adjust source. */
|
|
subq %r8, %rcx
|
|
/* Adjust the end of destination which should be aligned now. */
|
|
subq %r8, %r9
|
|
/* Adjust length. */
|
|
subq %r8, %rdx
|
|
|
|
.p2align 4
|
|
L(loop_4x_vec_backward):
|
|
/* Copy 4 * VEC a time backward. */
|
|
VMOVU (%rcx), %VEC(0)
|
|
VMOVU -VEC_SIZE(%rcx), %VEC(1)
|
|
VMOVU -(VEC_SIZE * 2)(%rcx), %VEC(2)
|
|
VMOVU -(VEC_SIZE * 3)(%rcx), %VEC(3)
|
|
addq $-(VEC_SIZE * 4), %rcx
|
|
addq $-(VEC_SIZE * 4), %rdx
|
|
VMOVA %VEC(0), (%r9)
|
|
VMOVA %VEC(1), -VEC_SIZE(%r9)
|
|
VMOVA %VEC(2), -(VEC_SIZE * 2)(%r9)
|
|
VMOVA %VEC(3), -(VEC_SIZE * 3)(%r9)
|
|
addq $-(VEC_SIZE * 4), %r9
|
|
cmpq $(VEC_SIZE * 4), %rdx
|
|
ja L(loop_4x_vec_backward)
|
|
/* Store the first 4 * VEC. */
|
|
VMOVU %VEC(4), (%rdi)
|
|
VMOVU %VEC(5), VEC_SIZE(%rdi)
|
|
VMOVU %VEC(6), (VEC_SIZE * 2)(%rdi)
|
|
VMOVU %VEC(7), (VEC_SIZE * 3)(%rdi)
|
|
/* Store the last VEC. */
|
|
VMOVU %VEC(8), (%r11)
|
|
VZEROUPPER_RETURN
|
|
|
|
#if (defined USE_MULTIARCH || VEC_SIZE == 16) && IS_IN (libc)
|
|
.p2align 4
|
|
L(large_memcpy_2x):
|
|
/* Compute absolute value of difference between source and
|
|
destination. */
|
|
movq %rdi, %r9
|
|
subq %rsi, %r9
|
|
movq %r9, %r8
|
|
leaq -1(%r9), %rcx
|
|
sarq $63, %r8
|
|
xorq %r8, %r9
|
|
subq %r8, %r9
|
|
/* Don't use non-temporal store if there is overlap between
|
|
destination and source since destination may be in cache when
|
|
source is loaded. */
|
|
cmpq %r9, %rdx
|
|
ja L(more_8x_vec_check)
|
|
|
|
/* Cache align destination. First store the first 64 bytes then
|
|
adjust alignments. */
|
|
VMOVU (%rsi), %VEC(8)
|
|
#if VEC_SIZE < 64
|
|
VMOVU VEC_SIZE(%rsi), %VEC(9)
|
|
#if VEC_SIZE < 32
|
|
VMOVU (VEC_SIZE * 2)(%rsi), %VEC(10)
|
|
VMOVU (VEC_SIZE * 3)(%rsi), %VEC(11)
|
|
#endif
|
|
#endif
|
|
VMOVU %VEC(8), (%rdi)
|
|
#if VEC_SIZE < 64
|
|
VMOVU %VEC(9), VEC_SIZE(%rdi)
|
|
#if VEC_SIZE < 32
|
|
VMOVU %VEC(10), (VEC_SIZE * 2)(%rdi)
|
|
VMOVU %VEC(11), (VEC_SIZE * 3)(%rdi)
|
|
#endif
|
|
#endif
|
|
/* Adjust source, destination, and size. */
|
|
movq %rdi, %r8
|
|
andq $63, %r8
|
|
/* Get the negative of offset for alignment. */
|
|
subq $64, %r8
|
|
/* Adjust source. */
|
|
subq %r8, %rsi
|
|
/* Adjust destination which should be aligned now. */
|
|
subq %r8, %rdi
|
|
/* Adjust length. */
|
|
addq %r8, %rdx
|
|
|
|
/* Test if source and destination addresses will alias. If they do
|
|
the larger pipeline in large_memcpy_4x alleviated the
|
|
performance drop. */
|
|
testl $(PAGE_SIZE - VEC_SIZE * 8), %ecx
|
|
jz L(large_memcpy_4x)
|
|
|
|
movq %rdx, %r10
|
|
shrq $LOG_4X_MEMCPY_THRESH, %r10
|
|
cmp __x86_shared_non_temporal_threshold(%rip), %r10
|
|
jae L(large_memcpy_4x)
|
|
|
|
/* edx will store remainder size for copying tail. */
|
|
andl $(PAGE_SIZE * 2 - 1), %edx
|
|
/* r10 stores outer loop counter. */
|
|
shrq $((LOG_PAGE_SIZE + 1) - LOG_4X_MEMCPY_THRESH), %r10
|
|
/* Copy 4x VEC at a time from 2 pages. */
|
|
.p2align 4
|
|
L(loop_large_memcpy_2x_outer):
|
|
/* ecx stores inner loop counter. */
|
|
movl $(PAGE_SIZE / LARGE_LOAD_SIZE), %ecx
|
|
L(loop_large_memcpy_2x_inner):
|
|
PREFETCH_ONE_SET(1, (%rsi), PREFETCHED_LOAD_SIZE)
|
|
PREFETCH_ONE_SET(1, (%rsi), PREFETCHED_LOAD_SIZE * 2)
|
|
PREFETCH_ONE_SET(1, (%rsi), PAGE_SIZE + PREFETCHED_LOAD_SIZE)
|
|
PREFETCH_ONE_SET(1, (%rsi), PAGE_SIZE + PREFETCHED_LOAD_SIZE * 2)
|
|
/* Load vectors from rsi. */
|
|
LOAD_ONE_SET((%rsi), 0, %VEC(0), %VEC(1), %VEC(2), %VEC(3))
|
|
LOAD_ONE_SET((%rsi), PAGE_SIZE, %VEC(4), %VEC(5), %VEC(6), %VEC(7))
|
|
subq $-LARGE_LOAD_SIZE, %rsi
|
|
/* Non-temporal store vectors to rdi. */
|
|
STORE_ONE_SET((%rdi), 0, %VEC(0), %VEC(1), %VEC(2), %VEC(3))
|
|
STORE_ONE_SET((%rdi), PAGE_SIZE, %VEC(4), %VEC(5), %VEC(6), %VEC(7))
|
|
subq $-LARGE_LOAD_SIZE, %rdi
|
|
decl %ecx
|
|
jnz L(loop_large_memcpy_2x_inner)
|
|
addq $PAGE_SIZE, %rdi
|
|
addq $PAGE_SIZE, %rsi
|
|
decq %r10
|
|
jne L(loop_large_memcpy_2x_outer)
|
|
sfence
|
|
|
|
/* Check if only last 4 loads are needed. */
|
|
cmpl $(VEC_SIZE * 4), %edx
|
|
jbe L(large_memcpy_2x_end)
|
|
|
|
/* Handle the last 2 * PAGE_SIZE bytes. */
|
|
L(loop_large_memcpy_2x_tail):
|
|
/* Copy 4 * VEC a time forward with non-temporal stores. */
|
|
PREFETCH_ONE_SET (1, (%rsi), PREFETCHED_LOAD_SIZE)
|
|
PREFETCH_ONE_SET (1, (%rdi), PREFETCHED_LOAD_SIZE)
|
|
VMOVU (%rsi), %VEC(0)
|
|
VMOVU VEC_SIZE(%rsi), %VEC(1)
|
|
VMOVU (VEC_SIZE * 2)(%rsi), %VEC(2)
|
|
VMOVU (VEC_SIZE * 3)(%rsi), %VEC(3)
|
|
subq $-(VEC_SIZE * 4), %rsi
|
|
addl $-(VEC_SIZE * 4), %edx
|
|
VMOVA %VEC(0), (%rdi)
|
|
VMOVA %VEC(1), VEC_SIZE(%rdi)
|
|
VMOVA %VEC(2), (VEC_SIZE * 2)(%rdi)
|
|
VMOVA %VEC(3), (VEC_SIZE * 3)(%rdi)
|
|
subq $-(VEC_SIZE * 4), %rdi
|
|
cmpl $(VEC_SIZE * 4), %edx
|
|
ja L(loop_large_memcpy_2x_tail)
|
|
|
|
L(large_memcpy_2x_end):
|
|
/* Store the last 4 * VEC. */
|
|
VMOVU -(VEC_SIZE * 4)(%rsi, %rdx), %VEC(0)
|
|
VMOVU -(VEC_SIZE * 3)(%rsi, %rdx), %VEC(1)
|
|
VMOVU -(VEC_SIZE * 2)(%rsi, %rdx), %VEC(2)
|
|
VMOVU -VEC_SIZE(%rsi, %rdx), %VEC(3)
|
|
|
|
VMOVU %VEC(0), -(VEC_SIZE * 4)(%rdi, %rdx)
|
|
VMOVU %VEC(1), -(VEC_SIZE * 3)(%rdi, %rdx)
|
|
VMOVU %VEC(2), -(VEC_SIZE * 2)(%rdi, %rdx)
|
|
VMOVU %VEC(3), -VEC_SIZE(%rdi, %rdx)
|
|
VZEROUPPER_RETURN
|
|
|
|
.p2align 4
|
|
L(large_memcpy_4x):
|
|
movq %rdx, %r10
|
|
/* edx will store remainder size for copying tail. */
|
|
andl $(PAGE_SIZE * 4 - 1), %edx
|
|
/* r10 stores outer loop counter. */
|
|
shrq $(LOG_PAGE_SIZE + 2), %r10
|
|
/* Copy 4x VEC at a time from 4 pages. */
|
|
.p2align 4
|
|
L(loop_large_memcpy_4x_outer):
|
|
/* ecx stores inner loop counter. */
|
|
movl $(PAGE_SIZE / LARGE_LOAD_SIZE), %ecx
|
|
L(loop_large_memcpy_4x_inner):
|
|
/* Only one prefetch set per page as doing 4 pages give more time
|
|
for prefetcher to keep up. */
|
|
PREFETCH_ONE_SET(1, (%rsi), PREFETCHED_LOAD_SIZE)
|
|
PREFETCH_ONE_SET(1, (%rsi), PAGE_SIZE + PREFETCHED_LOAD_SIZE)
|
|
PREFETCH_ONE_SET(1, (%rsi), PAGE_SIZE * 2 + PREFETCHED_LOAD_SIZE)
|
|
PREFETCH_ONE_SET(1, (%rsi), PAGE_SIZE * 3 + PREFETCHED_LOAD_SIZE)
|
|
/* Load vectors from rsi. */
|
|
LOAD_ONE_SET((%rsi), 0, %VEC(0), %VEC(1), %VEC(2), %VEC(3))
|
|
LOAD_ONE_SET((%rsi), PAGE_SIZE, %VEC(4), %VEC(5), %VEC(6), %VEC(7))
|
|
LOAD_ONE_SET((%rsi), PAGE_SIZE * 2, %VEC(8), %VEC(9), %VEC(10), %VEC(11))
|
|
LOAD_ONE_SET((%rsi), PAGE_SIZE * 3, %VEC(12), %VEC(13), %VEC(14), %VEC(15))
|
|
subq $-LARGE_LOAD_SIZE, %rsi
|
|
/* Non-temporal store vectors to rdi. */
|
|
STORE_ONE_SET((%rdi), 0, %VEC(0), %VEC(1), %VEC(2), %VEC(3))
|
|
STORE_ONE_SET((%rdi), PAGE_SIZE, %VEC(4), %VEC(5), %VEC(6), %VEC(7))
|
|
STORE_ONE_SET((%rdi), PAGE_SIZE * 2, %VEC(8), %VEC(9), %VEC(10), %VEC(11))
|
|
STORE_ONE_SET((%rdi), PAGE_SIZE * 3, %VEC(12), %VEC(13), %VEC(14), %VEC(15))
|
|
subq $-LARGE_LOAD_SIZE, %rdi
|
|
decl %ecx
|
|
jnz L(loop_large_memcpy_4x_inner)
|
|
addq $(PAGE_SIZE * 3), %rdi
|
|
addq $(PAGE_SIZE * 3), %rsi
|
|
decq %r10
|
|
jne L(loop_large_memcpy_4x_outer)
|
|
sfence
|
|
/* Check if only last 4 loads are needed. */
|
|
cmpl $(VEC_SIZE * 4), %edx
|
|
jbe L(large_memcpy_4x_end)
|
|
|
|
/* Handle the last 4 * PAGE_SIZE bytes. */
|
|
L(loop_large_memcpy_4x_tail):
|
|
/* Copy 4 * VEC a time forward with non-temporal stores. */
|
|
PREFETCH_ONE_SET (1, (%rsi), PREFETCHED_LOAD_SIZE)
|
|
PREFETCH_ONE_SET (1, (%rdi), PREFETCHED_LOAD_SIZE)
|
|
VMOVU (%rsi), %VEC(0)
|
|
VMOVU VEC_SIZE(%rsi), %VEC(1)
|
|
VMOVU (VEC_SIZE * 2)(%rsi), %VEC(2)
|
|
VMOVU (VEC_SIZE * 3)(%rsi), %VEC(3)
|
|
subq $-(VEC_SIZE * 4), %rsi
|
|
addl $-(VEC_SIZE * 4), %edx
|
|
VMOVA %VEC(0), (%rdi)
|
|
VMOVA %VEC(1), VEC_SIZE(%rdi)
|
|
VMOVA %VEC(2), (VEC_SIZE * 2)(%rdi)
|
|
VMOVA %VEC(3), (VEC_SIZE * 3)(%rdi)
|
|
subq $-(VEC_SIZE * 4), %rdi
|
|
cmpl $(VEC_SIZE * 4), %edx
|
|
ja L(loop_large_memcpy_4x_tail)
|
|
|
|
L(large_memcpy_4x_end):
|
|
/* Store the last 4 * VEC. */
|
|
VMOVU -(VEC_SIZE * 4)(%rsi, %rdx), %VEC(0)
|
|
VMOVU -(VEC_SIZE * 3)(%rsi, %rdx), %VEC(1)
|
|
VMOVU -(VEC_SIZE * 2)(%rsi, %rdx), %VEC(2)
|
|
VMOVU -VEC_SIZE(%rsi, %rdx), %VEC(3)
|
|
|
|
VMOVU %VEC(0), -(VEC_SIZE * 4)(%rdi, %rdx)
|
|
VMOVU %VEC(1), -(VEC_SIZE * 3)(%rdi, %rdx)
|
|
VMOVU %VEC(2), -(VEC_SIZE * 2)(%rdi, %rdx)
|
|
VMOVU %VEC(3), -VEC_SIZE(%rdi, %rdx)
|
|
VZEROUPPER_RETURN
|
|
#endif
|
|
END (MEMMOVE_SYMBOL (__memmove, unaligned_erms))
|
|
|
|
#if IS_IN (libc)
|
|
# ifdef USE_MULTIARCH
|
|
strong_alias (MEMMOVE_SYMBOL (__memmove, unaligned_erms),
|
|
MEMMOVE_SYMBOL (__memcpy, unaligned_erms))
|
|
# ifdef SHARED
|
|
strong_alias (MEMMOVE_SYMBOL (__memmove_chk, unaligned_erms),
|
|
MEMMOVE_SYMBOL (__memcpy_chk, unaligned_erms))
|
|
# endif
|
|
# endif
|
|
# ifdef SHARED
|
|
strong_alias (MEMMOVE_CHK_SYMBOL (__memmove_chk, unaligned),
|
|
MEMMOVE_CHK_SYMBOL (__memcpy_chk, unaligned))
|
|
# endif
|
|
#endif
|
|
strong_alias (MEMMOVE_SYMBOL (__memmove, unaligned),
|
|
MEMCPY_SYMBOL (__memcpy, unaligned))
|