arm64: Import latest version of Cortex Strings' strncmp
Import the latest version of the former Cortex Strings - now Arm Optimized Routines - strncmp function based on the upstream code of string/aarch64/strncmp.S at commit e823e3a from https://github.com/ARM-software/optimized-routines Note that for simplicity Arm have chosen to contribute this code to Linux under GPLv2 rather than the original MIT license. Signed-off-by: Sam Tebbs <sam.tebbs@arm.com> [ rm: update attribution and commit message ] Signed-off-by: Robin Murphy <robin.murphy@arm.com> Link: https://lore.kernel.org/r/26110bee02ad360596c9a7536af7eaaf6890d0e8.1622128527.git.robin.murphy@arm.com Signed-off-by: Will Deacon <will@kernel.org>
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/* SPDX-License-Identifier: GPL-2.0-only */
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/*
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* Copyright (C) 2013 ARM Ltd.
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* Copyright (C) 2013 Linaro.
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* Copyright (c) 2013, Arm Limited.
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*
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* This code is based on glibc cortex strings work originally authored by Linaro
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* be found @
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*
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* http://bazaar.launchpad.net/~linaro-toolchain-dev/cortex-strings/trunk/
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* files/head:/src/aarch64/
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* Adapted from the original at:
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* https://github.com/ARM-software/optimized-routines/blob/master/string/aarch64/strncmp.S
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*/
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#include <linux/linkage.h>
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#include <asm/assembler.h>
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/*
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* compare two strings
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/* Assumptions:
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*
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* Parameters:
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* x0 - const string 1 pointer
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* x1 - const string 2 pointer
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* x2 - the maximal length to be compared
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* Returns:
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* x0 - an integer less than, equal to, or greater than zero if s1 is found,
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* respectively, to be less than, to match, or be greater than s2.
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* ARMv8-a, AArch64
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*/
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#define L(label) .L ## label
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#define REP8_01 0x0101010101010101
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#define REP8_7f 0x7f7f7f7f7f7f7f7f
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#define REP8_80 0x8080808080808080
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/* Parameters and result. */
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src1 .req x0
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src2 .req x1
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limit .req x2
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result .req x0
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#define src1 x0
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#define src2 x1
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#define limit x2
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#define result x0
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/* Internal variables. */
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data1 .req x3
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data1w .req w3
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data2 .req x4
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data2w .req w4
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has_nul .req x5
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diff .req x6
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syndrome .req x7
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tmp1 .req x8
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tmp2 .req x9
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tmp3 .req x10
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zeroones .req x11
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pos .req x12
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limit_wd .req x13
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mask .req x14
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endloop .req x15
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#define data1 x3
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#define data1w w3
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#define data2 x4
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#define data2w w4
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#define has_nul x5
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#define diff x6
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#define syndrome x7
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#define tmp1 x8
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#define tmp2 x9
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#define tmp3 x10
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#define zeroones x11
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#define pos x12
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#define limit_wd x13
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#define mask x14
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#define endloop x15
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#define count mask
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SYM_FUNC_START_WEAK_PI(strncmp)
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cbz limit, .Lret0
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cbz limit, L(ret0)
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eor tmp1, src1, src2
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mov zeroones, #REP8_01
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tst tmp1, #7
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b.ne .Lmisaligned8
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ands tmp1, src1, #7
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b.ne .Lmutual_align
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and count, src1, #7
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b.ne L(misaligned8)
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cbnz count, L(mutual_align)
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/* Calculate the number of full and partial words -1. */
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/*
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* when limit is mulitply of 8, if not sub 1,
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* the judgement of last dword will wrong.
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*/
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sub limit_wd, limit, #1 /* limit != 0, so no underflow. */
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lsr limit_wd, limit_wd, #3 /* Convert to Dwords. */
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sub limit_wd, limit, #1 /* limit != 0, so no underflow. */
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lsr limit_wd, limit_wd, #3 /* Convert to Dwords. */
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/*
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* NUL detection works on the principle that (X - 1) & (~X) & 0x80
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* (=> (X - 1) & ~(X | 0x7f)) is non-zero iff a byte is zero, and
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* can be done in parallel across the entire word.
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*/
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.Lloop_aligned:
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/* NUL detection works on the principle that (X - 1) & (~X) & 0x80
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(=> (X - 1) & ~(X | 0x7f)) is non-zero iff a byte is zero, and
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can be done in parallel across the entire word. */
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.p2align 4
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L(loop_aligned):
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ldr data1, [src1], #8
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ldr data2, [src2], #8
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.Lstart_realigned:
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L(start_realigned):
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subs limit_wd, limit_wd, #1
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sub tmp1, data1, zeroones
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orr tmp2, data1, #REP8_7f
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eor diff, data1, data2 /* Non-zero if differences found. */
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csinv endloop, diff, xzr, pl /* Last Dword or differences.*/
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bics has_nul, tmp1, tmp2 /* Non-zero if NUL terminator. */
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eor diff, data1, data2 /* Non-zero if differences found. */
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csinv endloop, diff, xzr, pl /* Last Dword or differences. */
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bics has_nul, tmp1, tmp2 /* Non-zero if NUL terminator. */
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ccmp endloop, #0, #0, eq
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b.eq .Lloop_aligned
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b.eq L(loop_aligned)
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/* End of main loop */
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/*Not reached the limit, must have found the end or a diff. */
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tbz limit_wd, #63, .Lnot_limit
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/* Not reached the limit, must have found the end or a diff. */
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tbz limit_wd, #63, L(not_limit)
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/* Limit % 8 == 0 => all bytes significant. */
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ands limit, limit, #7
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b.eq .Lnot_limit
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b.eq L(not_limit)
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lsl limit, limit, #3 /* Bits -> bytes. */
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lsl limit, limit, #3 /* Bits -> bytes. */
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mov mask, #~0
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CPU_BE( lsr mask, mask, limit )
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CPU_LE( lsl mask, mask, limit )
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#ifdef __AARCH64EB__
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lsr mask, mask, limit
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#else
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lsl mask, mask, limit
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#endif
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bic data1, data1, mask
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bic data2, data2, mask
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/* Make sure that the NUL byte is marked in the syndrome. */
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orr has_nul, has_nul, mask
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.Lnot_limit:
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L(not_limit):
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orr syndrome, diff, has_nul
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b .Lcal_cmpresult
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.Lmutual_align:
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/*
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* Sources are mutually aligned, but are not currently at an
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* alignment boundary. Round down the addresses and then mask off
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* the bytes that precede the start point.
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* We also need to adjust the limit calculations, but without
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* overflowing if the limit is near ULONG_MAX.
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*/
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bic src1, src1, #7
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bic src2, src2, #7
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ldr data1, [src1], #8
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neg tmp3, tmp1, lsl #3 /* 64 - bits(bytes beyond align). */
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ldr data2, [src2], #8
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mov tmp2, #~0
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sub limit_wd, limit, #1 /* limit != 0, so no underflow. */
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/* Big-endian. Early bytes are at MSB. */
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CPU_BE( lsl tmp2, tmp2, tmp3 ) /* Shift (tmp1 & 63). */
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/* Little-endian. Early bytes are at LSB. */
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CPU_LE( lsr tmp2, tmp2, tmp3 ) /* Shift (tmp1 & 63). */
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and tmp3, limit_wd, #7
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lsr limit_wd, limit_wd, #3
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/* Adjust the limit. Only low 3 bits used, so overflow irrelevant.*/
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add limit, limit, tmp1
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add tmp3, tmp3, tmp1
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orr data1, data1, tmp2
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orr data2, data2, tmp2
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add limit_wd, limit_wd, tmp3, lsr #3
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b .Lstart_realigned
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/*when src1 offset is not equal to src2 offset...*/
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.Lmisaligned8:
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cmp limit, #8
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b.lo .Ltiny8proc /*limit < 8... */
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/*
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* Get the align offset length to compare per byte first.
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* After this process, one string's address will be aligned.*/
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and tmp1, src1, #7
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neg tmp1, tmp1
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add tmp1, tmp1, #8
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and tmp2, src2, #7
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neg tmp2, tmp2
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add tmp2, tmp2, #8
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subs tmp3, tmp1, tmp2
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csel pos, tmp1, tmp2, hi /*Choose the maximum. */
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/*
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* Here, limit is not less than 8, so directly run .Ltinycmp
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* without checking the limit.*/
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sub limit, limit, pos
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.Ltinycmp:
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ldrb data1w, [src1], #1
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ldrb data2w, [src2], #1
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subs pos, pos, #1
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ccmp data1w, #1, #0, ne /* NZCV = 0b0000. */
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ccmp data1w, data2w, #0, cs /* NZCV = 0b0000. */
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b.eq .Ltinycmp
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cbnz pos, 1f /*find the null or unequal...*/
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cmp data1w, #1
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ccmp data1w, data2w, #0, cs
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b.eq .Lstart_align /*the last bytes are equal....*/
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1:
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sub result, data1, data2
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ret
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.Lstart_align:
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lsr limit_wd, limit, #3
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cbz limit_wd, .Lremain8
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/*process more leading bytes to make str1 aligned...*/
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ands xzr, src1, #7
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b.eq .Lrecal_offset
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add src1, src1, tmp3 /*tmp3 is positive in this branch.*/
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add src2, src2, tmp3
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ldr data1, [src1], #8
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ldr data2, [src2], #8
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sub limit, limit, tmp3
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lsr limit_wd, limit, #3
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subs limit_wd, limit_wd, #1
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sub tmp1, data1, zeroones
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orr tmp2, data1, #REP8_7f
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eor diff, data1, data2 /* Non-zero if differences found. */
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csinv endloop, diff, xzr, ne/*if limit_wd is 0,will finish the cmp*/
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bics has_nul, tmp1, tmp2
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ccmp endloop, #0, #0, eq /*has_null is ZERO: no null byte*/
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b.ne .Lunequal_proc
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/*How far is the current str2 from the alignment boundary...*/
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and tmp3, tmp3, #7
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.Lrecal_offset:
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neg pos, tmp3
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.Lloopcmp_proc:
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/*
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* Divide the eight bytes into two parts. First,backwards the src2
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* to an alignment boundary,load eight bytes from the SRC2 alignment
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* boundary,then compare with the relative bytes from SRC1.
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* If all 8 bytes are equal,then start the second part's comparison.
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* Otherwise finish the comparison.
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* This special handle can garantee all the accesses are in the
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* thread/task space in avoid to overrange access.
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*/
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ldr data1, [src1,pos]
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ldr data2, [src2,pos]
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sub tmp1, data1, zeroones
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orr tmp2, data1, #REP8_7f
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bics has_nul, tmp1, tmp2 /* Non-zero if NUL terminator. */
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eor diff, data1, data2 /* Non-zero if differences found. */
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csinv endloop, diff, xzr, eq
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cbnz endloop, .Lunequal_proc
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/*The second part process*/
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ldr data1, [src1], #8
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ldr data2, [src2], #8
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subs limit_wd, limit_wd, #1
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sub tmp1, data1, zeroones
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orr tmp2, data1, #REP8_7f
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eor diff, data1, data2 /* Non-zero if differences found. */
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csinv endloop, diff, xzr, ne/*if limit_wd is 0,will finish the cmp*/
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bics has_nul, tmp1, tmp2
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ccmp endloop, #0, #0, eq /*has_null is ZERO: no null byte*/
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b.eq .Lloopcmp_proc
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.Lunequal_proc:
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orr syndrome, diff, has_nul
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cbz syndrome, .Lremain8
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.Lcal_cmpresult:
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/*
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* reversed the byte-order as big-endian,then CLZ can find the most
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* significant zero bits.
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*/
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CPU_LE( rev syndrome, syndrome )
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CPU_LE( rev data1, data1 )
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CPU_LE( rev data2, data2 )
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/*
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* For big-endian we cannot use the trick with the syndrome value
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* as carry-propagation can corrupt the upper bits if the trailing
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* bytes in the string contain 0x01.
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* However, if there is no NUL byte in the dword, we can generate
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* the result directly. We can't just subtract the bytes as the
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* MSB might be significant.
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*/
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CPU_BE( cbnz has_nul, 1f )
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CPU_BE( cmp data1, data2 )
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CPU_BE( cset result, ne )
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CPU_BE( cneg result, result, lo )
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CPU_BE( ret )
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CPU_BE( 1: )
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/* Re-compute the NUL-byte detection, using a byte-reversed value.*/
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CPU_BE( rev tmp3, data1 )
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CPU_BE( sub tmp1, tmp3, zeroones )
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CPU_BE( orr tmp2, tmp3, #REP8_7f )
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CPU_BE( bic has_nul, tmp1, tmp2 )
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CPU_BE( rev has_nul, has_nul )
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CPU_BE( orr syndrome, diff, has_nul )
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/*
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* The MS-non-zero bit of the syndrome marks either the first bit
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* that is different, or the top bit of the first zero byte.
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* Shifting left now will bring the critical information into the
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* top bits.
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*/
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#ifndef __AARCH64EB__
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rev syndrome, syndrome
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rev data1, data1
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/* The MS-non-zero bit of the syndrome marks either the first bit
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that is different, or the top bit of the first zero byte.
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Shifting left now will bring the critical information into the
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top bits. */
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clz pos, syndrome
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rev data2, data2
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lsl data1, data1, pos
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lsl data2, data2, pos
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/*
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* But we need to zero-extend (char is unsigned) the value and then
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* perform a signed 32-bit subtraction.
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*/
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/* But we need to zero-extend (char is unsigned) the value and then
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perform a signed 32-bit subtraction. */
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lsr data1, data1, #56
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sub result, data1, data2, lsr #56
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ret
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#else
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/* For big-endian we cannot use the trick with the syndrome value
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as carry-propagation can corrupt the upper bits if the trailing
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bytes in the string contain 0x01. */
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/* However, if there is no NUL byte in the dword, we can generate
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the result directly. We can't just subtract the bytes as the
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MSB might be significant. */
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cbnz has_nul, 1f
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cmp data1, data2
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cset result, ne
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cneg result, result, lo
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ret
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1:
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/* Re-compute the NUL-byte detection, using a byte-reversed value. */
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rev tmp3, data1
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sub tmp1, tmp3, zeroones
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orr tmp2, tmp3, #REP8_7f
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bic has_nul, tmp1, tmp2
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rev has_nul, has_nul
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orr syndrome, diff, has_nul
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clz pos, syndrome
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/* The MS-non-zero bit of the syndrome marks either the first bit
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that is different, or the top bit of the first zero byte.
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Shifting left now will bring the critical information into the
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top bits. */
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lsl data1, data1, pos
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lsl data2, data2, pos
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/* But we need to zero-extend (char is unsigned) the value and then
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perform a signed 32-bit subtraction. */
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lsr data1, data1, #56
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sub result, data1, data2, lsr #56
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ret
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#endif
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.Lremain8:
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/* Limit % 8 == 0 => all bytes significant. */
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ands limit, limit, #7
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b.eq .Lret0
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.Ltiny8proc:
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L(mutual_align):
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/* Sources are mutually aligned, but are not currently at an
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alignment boundary. Round down the addresses and then mask off
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the bytes that precede the start point.
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We also need to adjust the limit calculations, but without
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overflowing if the limit is near ULONG_MAX. */
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bic src1, src1, #7
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bic src2, src2, #7
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ldr data1, [src1], #8
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neg tmp3, count, lsl #3 /* 64 - bits(bytes beyond align). */
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ldr data2, [src2], #8
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mov tmp2, #~0
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sub limit_wd, limit, #1 /* limit != 0, so no underflow. */
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#ifdef __AARCH64EB__
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/* Big-endian. Early bytes are at MSB. */
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lsl tmp2, tmp2, tmp3 /* Shift (count & 63). */
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#else
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/* Little-endian. Early bytes are at LSB. */
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lsr tmp2, tmp2, tmp3 /* Shift (count & 63). */
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#endif
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and tmp3, limit_wd, #7
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lsr limit_wd, limit_wd, #3
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/* Adjust the limit. Only low 3 bits used, so overflow irrelevant. */
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add limit, limit, count
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add tmp3, tmp3, count
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orr data1, data1, tmp2
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orr data2, data2, tmp2
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add limit_wd, limit_wd, tmp3, lsr #3
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b L(start_realigned)
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.p2align 4
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/* Don't bother with dwords for up to 16 bytes. */
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L(misaligned8):
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cmp limit, #16
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b.hs L(try_misaligned_words)
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L(byte_loop):
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/* Perhaps we can do better than this. */
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ldrb data1w, [src1], #1
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ldrb data2w, [src2], #1
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subs limit, limit, #1
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ccmp data1w, #1, #0, ne /* NZCV = 0b0000. */
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ccmp data1w, data2w, #0, cs /* NZCV = 0b0000. */
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b.eq .Ltiny8proc
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ccmp data1w, #1, #0, hi /* NZCV = 0b0000. */
|
||||
ccmp data1w, data2w, #0, cs /* NZCV = 0b0000. */
|
||||
b.eq L(byte_loop)
|
||||
L(done):
|
||||
sub result, data1, data2
|
||||
ret
|
||||
/* Align the SRC1 to a dword by doing a bytewise compare and then do
|
||||
the dword loop. */
|
||||
L(try_misaligned_words):
|
||||
lsr limit_wd, limit, #3
|
||||
cbz count, L(do_misaligned)
|
||||
|
||||
.Lret0:
|
||||
neg count, count
|
||||
and count, count, #7
|
||||
sub limit, limit, count
|
||||
lsr limit_wd, limit, #3
|
||||
|
||||
L(page_end_loop):
|
||||
ldrb data1w, [src1], #1
|
||||
ldrb data2w, [src2], #1
|
||||
cmp data1w, #1
|
||||
ccmp data1w, data2w, #0, cs /* NZCV = 0b0000. */
|
||||
b.ne L(done)
|
||||
subs count, count, #1
|
||||
b.hi L(page_end_loop)
|
||||
|
||||
L(do_misaligned):
|
||||
/* Prepare ourselves for the next page crossing. Unlike the aligned
|
||||
loop, we fetch 1 less dword because we risk crossing bounds on
|
||||
SRC2. */
|
||||
mov count, #8
|
||||
subs limit_wd, limit_wd, #1
|
||||
b.lo L(done_loop)
|
||||
L(loop_misaligned):
|
||||
and tmp2, src2, #0xff8
|
||||
eor tmp2, tmp2, #0xff8
|
||||
cbz tmp2, L(page_end_loop)
|
||||
|
||||
ldr data1, [src1], #8
|
||||
ldr data2, [src2], #8
|
||||
sub tmp1, data1, zeroones
|
||||
orr tmp2, data1, #REP8_7f
|
||||
eor diff, data1, data2 /* Non-zero if differences found. */
|
||||
bics has_nul, tmp1, tmp2 /* Non-zero if NUL terminator. */
|
||||
ccmp diff, #0, #0, eq
|
||||
b.ne L(not_limit)
|
||||
subs limit_wd, limit_wd, #1
|
||||
b.pl L(loop_misaligned)
|
||||
|
||||
L(done_loop):
|
||||
/* We found a difference or a NULL before the limit was reached. */
|
||||
and limit, limit, #7
|
||||
cbz limit, L(not_limit)
|
||||
/* Read the last word. */
|
||||
sub src1, src1, 8
|
||||
sub src2, src2, 8
|
||||
ldr data1, [src1, limit]
|
||||
ldr data2, [src2, limit]
|
||||
sub tmp1, data1, zeroones
|
||||
orr tmp2, data1, #REP8_7f
|
||||
eor diff, data1, data2 /* Non-zero if differences found. */
|
||||
bics has_nul, tmp1, tmp2 /* Non-zero if NUL terminator. */
|
||||
ccmp diff, #0, #0, eq
|
||||
b.ne L(not_limit)
|
||||
|
||||
L(ret0):
|
||||
mov result, #0
|
||||
ret
|
||||
|
||||
SYM_FUNC_END_PI(strncmp)
|
||||
EXPORT_SYMBOL_NOKASAN(strncmp)
|
||||
|
|
Loading…
Reference in New Issue