1064 lines
26 KiB
ArmAsm
1064 lines
26 KiB
ArmAsm
/* Optimized memcmp implementation for POWER7/PowerPC64.
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Copyright (C) 2010-2022 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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#include <sysdep.h>
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/* int [r3] memcmp (const char *s1 [r3],
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const char *s2 [r4],
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size_t size [r5]) */
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#ifndef MEMCMP
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# define MEMCMP memcmp
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#endif
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.machine power7
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ENTRY_TOCLESS (MEMCMP, 4)
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CALL_MCOUNT 3
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#define rRTN r3
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#define rSTR1 r3 /* first string arg */
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#define rSTR2 r4 /* second string arg */
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#define rN r5 /* max string length */
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#define rWORD1 r6 /* current word in s1 */
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#define rWORD2 r7 /* current word in s2 */
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#define rWORD3 r8 /* next word in s1 */
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#define rWORD4 r9 /* next word in s2 */
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#define rWORD5 r10 /* next word in s1 */
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#define rWORD6 r11 /* next word in s2 */
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#define rOFF8 r20 /* 8 bytes offset. */
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#define rOFF16 r21 /* 16 bytes offset. */
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#define rOFF24 r22 /* 24 bytes offset. */
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#define rOFF32 r23 /* 24 bytes offset. */
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#define rWORD6_SHIFT r24 /* Left rotation temp for rWORD8. */
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#define rWORD4_SHIFT r25 /* Left rotation temp for rWORD6. */
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#define rWORD2_SHIFT r26 /* Left rotation temp for rWORD4. */
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#define rWORD8_SHIFT r27 /* Left rotation temp for rWORD2. */
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#define rSHR r28 /* Unaligned shift right count. */
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#define rSHL r29 /* Unaligned shift left count. */
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#define rWORD7 r30 /* next word in s1 */
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#define rWORD8 r31 /* next word in s2 */
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#define rWORD8SAVE (-8)
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#define rWORD7SAVE (-16)
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#define rOFF8SAVE (-24)
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#define rOFF16SAVE (-32)
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#define rOFF24SAVE (-40)
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#define rOFF32SAVE (-48)
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#define rSHRSAVE (-56)
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#define rSHLSAVE (-64)
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#define rWORD8SHIFTSAVE (-72)
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#define rWORD2SHIFTSAVE (-80)
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#define rWORD4SHIFTSAVE (-88)
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#define rWORD6SHIFTSAVE (-96)
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#ifdef __LITTLE_ENDIAN__
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# define LD ldbrx
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#else
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# define LD ldx
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#endif
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xor r0, rSTR2, rSTR1
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cmpldi cr6, rN, 0
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cmpldi cr1, rN, 12
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clrldi. r0, r0, 61
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clrldi r12, rSTR1, 61
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cmpldi cr5, r12, 0
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beq- cr6, L(zeroLength)
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dcbt 0, rSTR1
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dcbt 0, rSTR2
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/* If less than 8 bytes or not aligned, use the unaligned
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byte loop. */
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blt cr1, L(bytealigned)
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std rWORD8, rWORD8SAVE(r1)
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std rWORD7, rWORD7SAVE(r1)
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std rOFF8, rOFF8SAVE(r1)
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std rOFF16, rOFF16SAVE(r1)
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std rOFF24, rOFF24SAVE(r1)
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std rOFF32, rOFF32SAVE(r1)
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cfi_offset(rWORD8, rWORD8SAVE)
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cfi_offset(rWORD7, rWORD7SAVE)
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cfi_offset(rOFF8, rOFF8SAVE)
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cfi_offset(rOFF16, rOFF16SAVE)
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cfi_offset(rOFF24, rOFF24SAVE)
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cfi_offset(rOFF32, rOFF32SAVE)
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li rOFF8,8
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li rOFF16,16
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li rOFF24,24
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li rOFF32,32
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bne L(unaligned)
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/* At this point we know both strings have the same alignment and the
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compare length is at least 8 bytes. r12 contains the low order
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3 bits of rSTR1 and cr5 contains the result of the logical compare
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of r12 to 0. If r12 == 0 then we are already double word
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aligned and can perform the DW aligned loop.
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Otherwise we know the two strings have the same alignment (but not
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yet DW). So we force the string addresses to the next lower DW
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boundary and special case this first DW using shift left to
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eliminate bits preceding the first byte. Since we want to join the
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normal (DW aligned) compare loop, starting at the second double word,
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we need to adjust the length (rN) and special case the loop
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versioning for the first DW. This ensures that the loop count is
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correct and the first DW (shifted) is in the expected register pair. */
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.align 4
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L(samealignment):
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clrrdi rSTR1, rSTR1, 3
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clrrdi rSTR2, rSTR2, 3
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beq cr5, L(DWaligned)
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add rN, rN, r12
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sldi rWORD6, r12, 3
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srdi r0, rN, 5 /* Divide by 32 */
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andi. r12, rN, 24 /* Get the DW remainder */
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LD rWORD1, 0, rSTR1
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LD rWORD2, 0, rSTR2
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cmpldi cr1, r12, 16
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cmpldi cr7, rN, 32
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clrldi rN, rN, 61
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beq L(dPs4)
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mtctr r0
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bgt cr1, L(dPs3)
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beq cr1, L(dPs2)
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/* Remainder is 8 */
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.align 3
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L(dsP1):
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sld rWORD5, rWORD1, rWORD6
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sld rWORD6, rWORD2, rWORD6
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cmpld cr5, rWORD5, rWORD6
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blt cr7, L(dP1x)
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/* Do something useful in this cycle since we have to branch anyway. */
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LD rWORD1, rOFF8, rSTR1
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LD rWORD2, rOFF8, rSTR2
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cmpld cr7, rWORD1, rWORD2
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b L(dP1e)
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/* Remainder is 16 */
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.align 4
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L(dPs2):
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sld rWORD5, rWORD1, rWORD6
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sld rWORD6, rWORD2, rWORD6
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cmpld cr6, rWORD5, rWORD6
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blt cr7, L(dP2x)
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/* Do something useful in this cycle since we have to branch anyway. */
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LD rWORD7, rOFF8, rSTR1
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LD rWORD8, rOFF8, rSTR2
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cmpld cr5, rWORD7, rWORD8
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b L(dP2e)
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/* Remainder is 24 */
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.align 4
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L(dPs3):
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sld rWORD3, rWORD1, rWORD6
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sld rWORD4, rWORD2, rWORD6
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cmpld cr1, rWORD3, rWORD4
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b L(dP3e)
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/* Count is a multiple of 32, remainder is 0 */
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.align 4
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L(dPs4):
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mtctr r0
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sld rWORD1, rWORD1, rWORD6
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sld rWORD2, rWORD2, rWORD6
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cmpld cr7, rWORD1, rWORD2
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b L(dP4e)
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/* At this point we know both strings are double word aligned and the
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compare length is at least 8 bytes. */
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.align 4
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L(DWaligned):
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andi. r12, rN, 24 /* Get the DW remainder */
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srdi r0, rN, 5 /* Divide by 32 */
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cmpldi cr1, r12, 16
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cmpldi cr7, rN, 32
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clrldi rN, rN, 61
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beq L(dP4)
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bgt cr1, L(dP3)
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beq cr1, L(dP2)
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/* Remainder is 8 */
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.align 4
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L(dP1):
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mtctr r0
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/* Normally we'd use rWORD7/rWORD8 here, but since we might exit early
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(8-15 byte compare), we want to use only volatile registers. This
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means we can avoid restoring non-volatile registers since we did not
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change any on the early exit path. The key here is the non-early
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exit path only cares about the condition code (cr5), not about which
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register pair was used. */
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LD rWORD5, 0, rSTR1
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LD rWORD6, 0, rSTR2
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cmpld cr5, rWORD5, rWORD6
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blt cr7, L(dP1x)
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LD rWORD1, rOFF8, rSTR1
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LD rWORD2, rOFF8, rSTR2
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cmpld cr7, rWORD1, rWORD2
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L(dP1e):
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LD rWORD3, rOFF16, rSTR1
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LD rWORD4, rOFF16, rSTR2
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cmpld cr1, rWORD3, rWORD4
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LD rWORD5, rOFF24, rSTR1
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LD rWORD6, rOFF24, rSTR2
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cmpld cr6, rWORD5, rWORD6
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bne cr5, L(dLcr5x)
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bne cr7, L(dLcr7x)
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LD rWORD7, rOFF32, rSTR1
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LD rWORD8, rOFF32, rSTR2
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addi rSTR1, rSTR1, 32
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addi rSTR2, rSTR2, 32
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bne cr1, L(dLcr1)
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cmpld cr5, rWORD7, rWORD8
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bdnz L(dLoop)
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bne cr6, L(dLcr6)
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ld rWORD8, rWORD8SAVE(r1)
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ld rWORD7, rWORD7SAVE(r1)
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.align 3
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L(dP1x):
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sldi. r12, rN, 3
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bne cr5, L(dLcr5x)
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subfic rN, r12, 64 /* Shift count is 64 - (rN * 8). */
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bne L(d00)
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ld rOFF8, rOFF8SAVE(r1)
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ld rOFF16, rOFF16SAVE(r1)
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ld rOFF24, rOFF24SAVE(r1)
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ld rOFF32, rOFF32SAVE(r1)
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li rRTN, 0
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blr
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/* Remainder is 16 */
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.align 4
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L(dP2):
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mtctr r0
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LD rWORD5, 0, rSTR1
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LD rWORD6, 0, rSTR2
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cmpld cr6, rWORD5, rWORD6
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blt cr7, L(dP2x)
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LD rWORD7, rOFF8, rSTR1
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LD rWORD8, rOFF8, rSTR2
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cmpld cr5, rWORD7, rWORD8
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L(dP2e):
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LD rWORD1, rOFF16, rSTR1
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LD rWORD2, rOFF16, rSTR2
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cmpld cr7, rWORD1, rWORD2
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LD rWORD3, rOFF24, rSTR1
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LD rWORD4, rOFF24, rSTR2
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cmpld cr1, rWORD3, rWORD4
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addi rSTR1, rSTR1, 8
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addi rSTR2, rSTR2, 8
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bne cr6, L(dLcr6)
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bne cr5, L(dLcr5)
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b L(dLoop2)
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.align 4
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L(dP2x):
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LD rWORD3, rOFF8, rSTR1
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LD rWORD4, rOFF8, rSTR2
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cmpld cr1, rWORD3, rWORD4
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sldi. r12, rN, 3
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bne cr6, L(dLcr6x)
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addi rSTR1, rSTR1, 8
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addi rSTR2, rSTR2, 8
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bne cr1, L(dLcr1x)
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subfic rN, r12, 64 /* Shift count is 64 - (rN * 8). */
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bne L(d00)
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ld rOFF8, rOFF8SAVE(r1)
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ld rOFF16, rOFF16SAVE(r1)
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ld rOFF24, rOFF24SAVE(r1)
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ld rOFF32, rOFF32SAVE(r1)
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li rRTN, 0
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blr
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/* Remainder is 24 */
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.align 4
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L(dP3):
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mtctr r0
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LD rWORD3, 0, rSTR1
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LD rWORD4, 0, rSTR2
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cmpld cr1, rWORD3, rWORD4
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L(dP3e):
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LD rWORD5, rOFF8, rSTR1
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LD rWORD6, rOFF8, rSTR2
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cmpld cr6, rWORD5, rWORD6
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blt cr7, L(dP3x)
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LD rWORD7, rOFF16, rSTR1
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LD rWORD8, rOFF16, rSTR2
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cmpld cr5, rWORD7, rWORD8
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LD rWORD1, rOFF24, rSTR1
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LD rWORD2, rOFF24, rSTR2
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cmpld cr7, rWORD1, rWORD2
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addi rSTR1, rSTR1, 16
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addi rSTR2, rSTR2, 16
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bne cr1, L(dLcr1)
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bne cr6, L(dLcr6)
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b L(dLoop1)
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/* Again we are on a early exit path (24-31 byte compare), we want to
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only use volatile registers and avoid restoring non-volatile
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registers. */
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.align 4
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L(dP3x):
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LD rWORD1, rOFF16, rSTR1
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LD rWORD2, rOFF16, rSTR2
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cmpld cr7, rWORD1, rWORD2
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sldi. r12, rN, 3
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bne cr1, L(dLcr1x)
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addi rSTR1, rSTR1, 16
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addi rSTR2, rSTR2, 16
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bne cr6, L(dLcr6x)
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subfic rN, r12, 64 /* Shift count is 64 - (rN * 8). */
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bne cr7, L(dLcr7x)
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bne L(d00)
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ld rOFF8, rOFF8SAVE(r1)
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ld rOFF16, rOFF16SAVE(r1)
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ld rOFF24, rOFF24SAVE(r1)
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ld rOFF32, rOFF32SAVE(r1)
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li rRTN, 0
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blr
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/* Count is a multiple of 32, remainder is 0 */
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.align 4
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L(dP4):
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mtctr r0
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LD rWORD1, 0, rSTR1
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LD rWORD2, 0, rSTR2
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cmpld cr7, rWORD1, rWORD2
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L(dP4e):
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LD rWORD3, rOFF8, rSTR1
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LD rWORD4, rOFF8, rSTR2
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cmpld cr1, rWORD3, rWORD4
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LD rWORD5, rOFF16, rSTR1
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LD rWORD6, rOFF16, rSTR2
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cmpld cr6, rWORD5, rWORD6
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LD rWORD7, rOFF24, rSTR1
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LD rWORD8, rOFF24, rSTR2
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addi rSTR1, rSTR1, 24
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addi rSTR2, rSTR2, 24
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cmpld cr5, rWORD7, rWORD8
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bne cr7, L(dLcr7)
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bne cr1, L(dLcr1)
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bdz- L(d24) /* Adjust CTR as we start with +4 */
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/* This is the primary loop */
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.align 4
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L(dLoop):
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LD rWORD1, rOFF8, rSTR1
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LD rWORD2, rOFF8, rSTR2
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cmpld cr1, rWORD3, rWORD4
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bne cr6, L(dLcr6)
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L(dLoop1):
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LD rWORD3, rOFF16, rSTR1
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LD rWORD4, rOFF16, rSTR2
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cmpld cr6, rWORD5, rWORD6
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bne cr5, L(dLcr5)
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L(dLoop2):
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LD rWORD5, rOFF24, rSTR1
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LD rWORD6, rOFF24, rSTR2
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cmpld cr5, rWORD7, rWORD8
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bne cr7, L(dLcr7)
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L(dLoop3):
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LD rWORD7, rOFF32, rSTR1
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LD rWORD8, rOFF32, rSTR2
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addi rSTR1, rSTR1, 32
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addi rSTR2, rSTR2, 32
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bne cr1, L(dLcr1)
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cmpld cr7, rWORD1, rWORD2
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bdnz L(dLoop)
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L(dL4):
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cmpld cr1, rWORD3, rWORD4
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bne cr6, L(dLcr6)
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cmpld cr6, rWORD5, rWORD6
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bne cr5, L(dLcr5)
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cmpld cr5, rWORD7, rWORD8
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L(d44):
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bne cr7, L(dLcr7)
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L(d34):
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bne cr1, L(dLcr1)
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L(d24):
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bne cr6, L(dLcr6)
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L(d14):
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sldi. r12, rN, 3
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bne cr5, L(dLcr5)
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L(d04):
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ld rWORD8, rWORD8SAVE(r1)
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ld rWORD7, rWORD7SAVE(r1)
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subfic rN, r12, 64 /* Shift count is 64 - (rN * 8). */
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beq L(duzeroLength)
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/* At this point we have a remainder of 1 to 7 bytes to compare. Since
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we are aligned it is safe to load the whole double word, and use
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shift right double to eliminate bits beyond the compare length. */
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L(d00):
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LD rWORD1, rOFF8, rSTR1
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LD rWORD2, rOFF8, rSTR2
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srd rWORD1, rWORD1, rN
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srd rWORD2, rWORD2, rN
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cmpld cr7, rWORD1, rWORD2
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bne cr7, L(dLcr7x)
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ld rOFF8, rOFF8SAVE(r1)
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ld rOFF16, rOFF16SAVE(r1)
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ld rOFF24, rOFF24SAVE(r1)
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ld rOFF32, rOFF32SAVE(r1)
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li rRTN, 0
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blr
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.align 4
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L(dLcr7):
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ld rWORD8, rWORD8SAVE(r1)
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ld rWORD7, rWORD7SAVE(r1)
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L(dLcr7x):
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ld rOFF8, rOFF8SAVE(r1)
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ld rOFF16, rOFF16SAVE(r1)
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ld rOFF24, rOFF24SAVE(r1)
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ld rOFF32, rOFF32SAVE(r1)
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li rRTN, 1
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bgtlr cr7
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li rRTN, -1
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blr
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.align 4
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L(dLcr1):
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ld rWORD8, rWORD8SAVE(r1)
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ld rWORD7, rWORD7SAVE(r1)
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L(dLcr1x):
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ld rOFF8, rOFF8SAVE(r1)
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ld rOFF16, rOFF16SAVE(r1)
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ld rOFF24, rOFF24SAVE(r1)
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ld rOFF32, rOFF32SAVE(r1)
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li rRTN, 1
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bgtlr cr1
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li rRTN, -1
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blr
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.align 4
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L(dLcr6):
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ld rWORD8, rWORD8SAVE(r1)
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ld rWORD7, rWORD7SAVE(r1)
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L(dLcr6x):
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ld rOFF8, rOFF8SAVE(r1)
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ld rOFF16, rOFF16SAVE(r1)
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ld rOFF24, rOFF24SAVE(r1)
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ld rOFF32, rOFF32SAVE(r1)
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li rRTN, 1
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bgtlr cr6
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li rRTN, -1
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blr
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.align 4
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L(dLcr5):
|
|
ld rWORD8, rWORD8SAVE(r1)
|
|
ld rWORD7, rWORD7SAVE(r1)
|
|
L(dLcr5x):
|
|
ld rOFF8, rOFF8SAVE(r1)
|
|
ld rOFF16, rOFF16SAVE(r1)
|
|
ld rOFF24, rOFF24SAVE(r1)
|
|
ld rOFF32, rOFF32SAVE(r1)
|
|
li rRTN, 1
|
|
bgtlr cr5
|
|
li rRTN, -1
|
|
blr
|
|
|
|
.align 4
|
|
L(bytealigned):
|
|
mtctr rN
|
|
|
|
/* We need to prime this loop. This loop is swing modulo scheduled
|
|
to avoid pipe delays. The dependent instruction latencies (load to
|
|
compare to conditional branch) is 2 to 3 cycles. In this loop each
|
|
dispatch group ends in a branch and takes 1 cycle. Effectively
|
|
the first iteration of the loop only serves to load operands and
|
|
branches based on compares are delayed until the next loop.
|
|
|
|
So we must precondition some registers and condition codes so that
|
|
we don't exit the loop early on the first iteration. */
|
|
|
|
lbz rWORD1, 0(rSTR1)
|
|
lbz rWORD2, 0(rSTR2)
|
|
bdz L(b11)
|
|
cmpld cr7, rWORD1, rWORD2
|
|
lbz rWORD3, 1(rSTR1)
|
|
lbz rWORD4, 1(rSTR2)
|
|
bdz L(b12)
|
|
cmpld cr1, rWORD3, rWORD4
|
|
lbzu rWORD5, 2(rSTR1)
|
|
lbzu rWORD6, 2(rSTR2)
|
|
bdz L(b13)
|
|
.align 4
|
|
L(bLoop):
|
|
lbzu rWORD1, 1(rSTR1)
|
|
lbzu rWORD2, 1(rSTR2)
|
|
bne cr7, L(bLcr7)
|
|
|
|
cmpld cr6, rWORD5, rWORD6
|
|
bdz L(b3i)
|
|
|
|
lbzu rWORD3, 1(rSTR1)
|
|
lbzu rWORD4, 1(rSTR2)
|
|
bne cr1, L(bLcr1)
|
|
|
|
cmpld cr7, rWORD1, rWORD2
|
|
bdz L(b2i)
|
|
|
|
lbzu rWORD5, 1(rSTR1)
|
|
lbzu rWORD6, 1(rSTR2)
|
|
bne cr6, L(bLcr6)
|
|
|
|
cmpld cr1, rWORD3, rWORD4
|
|
bdnz L(bLoop)
|
|
|
|
/* We speculatively loading bytes before we have tested the previous
|
|
bytes. But we must avoid overrunning the length (in the ctr) to
|
|
prevent these speculative loads from causing a segfault. In this
|
|
case the loop will exit early (before the all pending bytes are
|
|
tested. In this case we must complete the pending operations
|
|
before returning. */
|
|
L(b1i):
|
|
bne cr7, L(bLcr7)
|
|
bne cr1, L(bLcr1)
|
|
b L(bx56)
|
|
.align 4
|
|
L(b2i):
|
|
bne cr6, L(bLcr6)
|
|
bne cr7, L(bLcr7)
|
|
b L(bx34)
|
|
.align 4
|
|
L(b3i):
|
|
bne cr1, L(bLcr1)
|
|
bne cr6, L(bLcr6)
|
|
b L(bx12)
|
|
.align 4
|
|
L(bLcr7):
|
|
li rRTN, 1
|
|
bgtlr cr7
|
|
li rRTN, -1
|
|
blr
|
|
L(bLcr1):
|
|
li rRTN, 1
|
|
bgtlr cr1
|
|
li rRTN, -1
|
|
blr
|
|
L(bLcr6):
|
|
li rRTN, 1
|
|
bgtlr cr6
|
|
li rRTN, -1
|
|
blr
|
|
|
|
L(b13):
|
|
bne cr7, L(bx12)
|
|
bne cr1, L(bx34)
|
|
L(bx56):
|
|
sub rRTN, rWORD5, rWORD6
|
|
blr
|
|
nop
|
|
L(b12):
|
|
bne cr7, L(bx12)
|
|
L(bx34):
|
|
sub rRTN, rWORD3, rWORD4
|
|
blr
|
|
L(b11):
|
|
L(bx12):
|
|
sub rRTN, rWORD1, rWORD2
|
|
blr
|
|
|
|
.align 4
|
|
L(zeroLength):
|
|
li rRTN, 0
|
|
blr
|
|
|
|
.align 4
|
|
/* At this point we know the strings have different alignment and the
|
|
compare length is at least 8 bytes. r12 contains the low order
|
|
3 bits of rSTR1 and cr5 contains the result of the logical compare
|
|
of r12 to 0. If r12 == 0 then rStr1 is double word
|
|
aligned and can perform the DWunaligned loop.
|
|
|
|
Otherwise we know that rSTR1 is not already DW aligned yet.
|
|
So we can force the string addresses to the next lower DW
|
|
boundary and special case this first DW using shift left to
|
|
eliminate bits preceding the first byte. Since we want to join the
|
|
normal (DWaligned) compare loop, starting at the second double word,
|
|
we need to adjust the length (rN) and special case the loop
|
|
versioning for the first DW. This ensures that the loop count is
|
|
correct and the first DW (shifted) is in the expected resister pair. */
|
|
L(unaligned):
|
|
std rSHL, rSHLSAVE(r1)
|
|
cfi_offset(rSHL, rSHLSAVE)
|
|
clrldi rSHL, rSTR2, 61
|
|
beq cr6, L(duzeroLength)
|
|
std rSHR, rSHRSAVE(r1)
|
|
cfi_offset(rSHR, rSHRSAVE)
|
|
beq cr5, L(DWunaligned)
|
|
std rWORD8_SHIFT, rWORD8SHIFTSAVE(r1)
|
|
cfi_offset(rWORD8_SHIFT, rWORD8SHIFTSAVE)
|
|
/* Adjust the logical start of rSTR2 to compensate for the extra bits
|
|
in the 1st rSTR1 DW. */
|
|
sub rWORD8_SHIFT, rSTR2, r12
|
|
/* But do not attempt to address the DW before that DW that contains
|
|
the actual start of rSTR2. */
|
|
clrrdi rSTR2, rSTR2, 3
|
|
std rWORD2_SHIFT, rWORD2SHIFTSAVE(r1)
|
|
/* Compute the left/right shift counts for the unaligned rSTR2,
|
|
compensating for the logical (DW aligned) start of rSTR1. */
|
|
clrldi rSHL, rWORD8_SHIFT, 61
|
|
clrrdi rSTR1, rSTR1, 3
|
|
std rWORD4_SHIFT, rWORD4SHIFTSAVE(r1)
|
|
sldi rSHL, rSHL, 3
|
|
cmpld cr5, rWORD8_SHIFT, rSTR2
|
|
add rN, rN, r12
|
|
sldi rWORD6, r12, 3
|
|
std rWORD6_SHIFT, rWORD6SHIFTSAVE(r1)
|
|
cfi_offset(rWORD2_SHIFT, rWORD2SHIFTSAVE)
|
|
cfi_offset(rWORD4_SHIFT, rWORD4SHIFTSAVE)
|
|
cfi_offset(rWORD6_SHIFT, rWORD6SHIFTSAVE)
|
|
subfic rSHR, rSHL, 64
|
|
srdi r0, rN, 5 /* Divide by 32 */
|
|
andi. r12, rN, 24 /* Get the DW remainder */
|
|
/* We normally need to load 2 DWs to start the unaligned rSTR2, but in
|
|
this special case those bits may be discarded anyway. Also we
|
|
must avoid loading a DW where none of the bits are part of rSTR2 as
|
|
this may cross a page boundary and cause a page fault. */
|
|
li rWORD8, 0
|
|
blt cr5, L(dus0)
|
|
LD rWORD8, 0, rSTR2
|
|
addi rSTR2, rSTR2, 8
|
|
sld rWORD8, rWORD8, rSHL
|
|
|
|
L(dus0):
|
|
LD rWORD1, 0, rSTR1
|
|
LD rWORD2, 0, rSTR2
|
|
cmpldi cr1, r12, 16
|
|
cmpldi cr7, rN, 32
|
|
srd r12, rWORD2, rSHR
|
|
clrldi rN, rN, 61
|
|
beq L(duPs4)
|
|
mtctr r0
|
|
or rWORD8, r12, rWORD8
|
|
bgt cr1, L(duPs3)
|
|
beq cr1, L(duPs2)
|
|
|
|
/* Remainder is 8 */
|
|
.align 4
|
|
L(dusP1):
|
|
sld rWORD8_SHIFT, rWORD2, rSHL
|
|
sld rWORD7, rWORD1, rWORD6
|
|
sld rWORD8, rWORD8, rWORD6
|
|
bge cr7, L(duP1e)
|
|
/* At this point we exit early with the first double word compare
|
|
complete and remainder of 0 to 7 bytes. See L(du14) for details on
|
|
how we handle the remaining bytes. */
|
|
cmpld cr5, rWORD7, rWORD8
|
|
sldi. rN, rN, 3
|
|
bne cr5, L(duLcr5)
|
|
cmpld cr7, rN, rSHR
|
|
beq L(duZeroReturn)
|
|
li r0, 0
|
|
ble cr7, L(dutrim)
|
|
LD rWORD2, rOFF8, rSTR2
|
|
srd r0, rWORD2, rSHR
|
|
b L(dutrim)
|
|
/* Remainder is 16 */
|
|
.align 4
|
|
L(duPs2):
|
|
sld rWORD6_SHIFT, rWORD2, rSHL
|
|
sld rWORD5, rWORD1, rWORD6
|
|
sld rWORD6, rWORD8, rWORD6
|
|
b L(duP2e)
|
|
/* Remainder is 24 */
|
|
.align 4
|
|
L(duPs3):
|
|
sld rWORD4_SHIFT, rWORD2, rSHL
|
|
sld rWORD3, rWORD1, rWORD6
|
|
sld rWORD4, rWORD8, rWORD6
|
|
b L(duP3e)
|
|
/* Count is a multiple of 32, remainder is 0 */
|
|
.align 4
|
|
L(duPs4):
|
|
mtctr r0
|
|
or rWORD8, r12, rWORD8
|
|
sld rWORD2_SHIFT, rWORD2, rSHL
|
|
sld rWORD1, rWORD1, rWORD6
|
|
sld rWORD2, rWORD8, rWORD6
|
|
b L(duP4e)
|
|
|
|
/* At this point we know rSTR1 is double word aligned and the
|
|
compare length is at least 8 bytes. */
|
|
.align 4
|
|
L(DWunaligned):
|
|
std rWORD8_SHIFT, rWORD8SHIFTSAVE(r1)
|
|
clrrdi rSTR2, rSTR2, 3
|
|
std rWORD2_SHIFT, rWORD2SHIFTSAVE(r1)
|
|
srdi r0, rN, 5 /* Divide by 32 */
|
|
std rWORD4_SHIFT, rWORD4SHIFTSAVE(r1)
|
|
andi. r12, rN, 24 /* Get the DW remainder */
|
|
std rWORD6_SHIFT, rWORD6SHIFTSAVE(r1)
|
|
cfi_offset(rWORD8_SHIFT, rWORD8SHIFTSAVE)
|
|
cfi_offset(rWORD2_SHIFT, rWORD2SHIFTSAVE)
|
|
cfi_offset(rWORD4_SHIFT, rWORD4SHIFTSAVE)
|
|
cfi_offset(rWORD6_SHIFT, rWORD6SHIFTSAVE)
|
|
sldi rSHL, rSHL, 3
|
|
LD rWORD6, 0, rSTR2
|
|
LD rWORD8, rOFF8, rSTR2
|
|
addi rSTR2, rSTR2, 8
|
|
cmpldi cr1, r12, 16
|
|
cmpldi cr7, rN, 32
|
|
clrldi rN, rN, 61
|
|
subfic rSHR, rSHL, 64
|
|
sld rWORD6_SHIFT, rWORD6, rSHL
|
|
beq L(duP4)
|
|
mtctr r0
|
|
bgt cr1, L(duP3)
|
|
beq cr1, L(duP2)
|
|
|
|
/* Remainder is 8 */
|
|
.align 4
|
|
L(duP1):
|
|
srd r12, rWORD8, rSHR
|
|
LD rWORD7, 0, rSTR1
|
|
sld rWORD8_SHIFT, rWORD8, rSHL
|
|
or rWORD8, r12, rWORD6_SHIFT
|
|
blt cr7, L(duP1x)
|
|
L(duP1e):
|
|
LD rWORD1, rOFF8, rSTR1
|
|
LD rWORD2, rOFF8, rSTR2
|
|
cmpld cr5, rWORD7, rWORD8
|
|
srd r0, rWORD2, rSHR
|
|
sld rWORD2_SHIFT, rWORD2, rSHL
|
|
or rWORD2, r0, rWORD8_SHIFT
|
|
LD rWORD3, rOFF16, rSTR1
|
|
LD rWORD4, rOFF16, rSTR2
|
|
cmpld cr7, rWORD1, rWORD2
|
|
srd r12, rWORD4, rSHR
|
|
sld rWORD4_SHIFT, rWORD4, rSHL
|
|
bne cr5, L(duLcr5)
|
|
or rWORD4, r12, rWORD2_SHIFT
|
|
LD rWORD5, rOFF24, rSTR1
|
|
LD rWORD6, rOFF24, rSTR2
|
|
cmpld cr1, rWORD3, rWORD4
|
|
srd r0, rWORD6, rSHR
|
|
sld rWORD6_SHIFT, rWORD6, rSHL
|
|
bne cr7, L(duLcr7)
|
|
or rWORD6, r0, rWORD4_SHIFT
|
|
cmpld cr6, rWORD5, rWORD6
|
|
b L(duLoop3)
|
|
.align 4
|
|
/* At this point we exit early with the first double word compare
|
|
complete and remainder of 0 to 7 bytes. See L(du14) for details on
|
|
how we handle the remaining bytes. */
|
|
L(duP1x):
|
|
cmpld cr5, rWORD7, rWORD8
|
|
sldi. rN, rN, 3
|
|
bne cr5, L(duLcr5)
|
|
cmpld cr7, rN, rSHR
|
|
beq L(duZeroReturn)
|
|
li r0, 0
|
|
ble cr7, L(dutrim)
|
|
LD rWORD2, rOFF8, rSTR2
|
|
srd r0, rWORD2, rSHR
|
|
b L(dutrim)
|
|
/* Remainder is 16 */
|
|
.align 4
|
|
L(duP2):
|
|
srd r0, rWORD8, rSHR
|
|
LD rWORD5, 0, rSTR1
|
|
or rWORD6, r0, rWORD6_SHIFT
|
|
sld rWORD6_SHIFT, rWORD8, rSHL
|
|
L(duP2e):
|
|
LD rWORD7, rOFF8, rSTR1
|
|
LD rWORD8, rOFF8, rSTR2
|
|
cmpld cr6, rWORD5, rWORD6
|
|
srd r12, rWORD8, rSHR
|
|
sld rWORD8_SHIFT, rWORD8, rSHL
|
|
or rWORD8, r12, rWORD6_SHIFT
|
|
blt cr7, L(duP2x)
|
|
LD rWORD1, rOFF16, rSTR1
|
|
LD rWORD2, rOFF16, rSTR2
|
|
cmpld cr5, rWORD7, rWORD8
|
|
bne cr6, L(duLcr6)
|
|
srd r0, rWORD2, rSHR
|
|
sld rWORD2_SHIFT, rWORD2, rSHL
|
|
or rWORD2, r0, rWORD8_SHIFT
|
|
LD rWORD3, rOFF24, rSTR1
|
|
LD rWORD4, rOFF24, rSTR2
|
|
cmpld cr7, rWORD1, rWORD2
|
|
bne cr5, L(duLcr5)
|
|
srd r12, rWORD4, rSHR
|
|
sld rWORD4_SHIFT, rWORD4, rSHL
|
|
or rWORD4, r12, rWORD2_SHIFT
|
|
addi rSTR1, rSTR1, 8
|
|
addi rSTR2, rSTR2, 8
|
|
cmpld cr1, rWORD3, rWORD4
|
|
b L(duLoop2)
|
|
.align 4
|
|
L(duP2x):
|
|
cmpld cr5, rWORD7, rWORD8
|
|
addi rSTR1, rSTR1, 8
|
|
addi rSTR2, rSTR2, 8
|
|
bne cr6, L(duLcr6)
|
|
sldi. rN, rN, 3
|
|
bne cr5, L(duLcr5)
|
|
cmpld cr7, rN, rSHR
|
|
beq L(duZeroReturn)
|
|
li r0, 0
|
|
ble cr7, L(dutrim)
|
|
LD rWORD2, rOFF8, rSTR2
|
|
srd r0, rWORD2, rSHR
|
|
b L(dutrim)
|
|
|
|
/* Remainder is 24 */
|
|
.align 4
|
|
L(duP3):
|
|
srd r12, rWORD8, rSHR
|
|
LD rWORD3, 0, rSTR1
|
|
sld rWORD4_SHIFT, rWORD8, rSHL
|
|
or rWORD4, r12, rWORD6_SHIFT
|
|
L(duP3e):
|
|
LD rWORD5, rOFF8, rSTR1
|
|
LD rWORD6, rOFF8, rSTR2
|
|
cmpld cr1, rWORD3, rWORD4
|
|
srd r0, rWORD6, rSHR
|
|
sld rWORD6_SHIFT, rWORD6, rSHL
|
|
or rWORD6, r0, rWORD4_SHIFT
|
|
LD rWORD7, rOFF16, rSTR1
|
|
LD rWORD8, rOFF16, rSTR2
|
|
cmpld cr6, rWORD5, rWORD6
|
|
bne cr1, L(duLcr1)
|
|
srd r12, rWORD8, rSHR
|
|
sld rWORD8_SHIFT, rWORD8, rSHL
|
|
or rWORD8, r12, rWORD6_SHIFT
|
|
blt cr7, L(duP3x)
|
|
LD rWORD1, rOFF24, rSTR1
|
|
LD rWORD2, rOFF24, rSTR2
|
|
cmpld cr5, rWORD7, rWORD8
|
|
bne cr6, L(duLcr6)
|
|
srd r0, rWORD2, rSHR
|
|
sld rWORD2_SHIFT, rWORD2, rSHL
|
|
or rWORD2, r0, rWORD8_SHIFT
|
|
addi rSTR1, rSTR1, 16
|
|
addi rSTR2, rSTR2, 16
|
|
cmpld cr7, rWORD1, rWORD2
|
|
b L(duLoop1)
|
|
.align 4
|
|
L(duP3x):
|
|
addi rSTR1, rSTR1, 16
|
|
addi rSTR2, rSTR2, 16
|
|
cmpld cr5, rWORD7, rWORD8
|
|
bne cr6, L(duLcr6)
|
|
sldi. rN, rN, 3
|
|
bne cr5, L(duLcr5)
|
|
cmpld cr7, rN, rSHR
|
|
beq L(duZeroReturn)
|
|
li r0, 0
|
|
ble cr7, L(dutrim)
|
|
LD rWORD2, rOFF8, rSTR2
|
|
srd r0, rWORD2, rSHR
|
|
b L(dutrim)
|
|
|
|
/* Count is a multiple of 32, remainder is 0 */
|
|
.align 4
|
|
L(duP4):
|
|
mtctr r0
|
|
srd r0, rWORD8, rSHR
|
|
LD rWORD1, 0, rSTR1
|
|
sld rWORD2_SHIFT, rWORD8, rSHL
|
|
or rWORD2, r0, rWORD6_SHIFT
|
|
L(duP4e):
|
|
LD rWORD3, rOFF8, rSTR1
|
|
LD rWORD4, rOFF8, rSTR2
|
|
cmpld cr7, rWORD1, rWORD2
|
|
srd r12, rWORD4, rSHR
|
|
sld rWORD4_SHIFT, rWORD4, rSHL
|
|
or rWORD4, r12, rWORD2_SHIFT
|
|
LD rWORD5, rOFF16, rSTR1
|
|
LD rWORD6, rOFF16, rSTR2
|
|
cmpld cr1, rWORD3, rWORD4
|
|
bne cr7, L(duLcr7)
|
|
srd r0, rWORD6, rSHR
|
|
sld rWORD6_SHIFT, rWORD6, rSHL
|
|
or rWORD6, r0, rWORD4_SHIFT
|
|
LD rWORD7, rOFF24, rSTR1
|
|
LD rWORD8, rOFF24, rSTR2
|
|
addi rSTR1, rSTR1, 24
|
|
addi rSTR2, rSTR2, 24
|
|
cmpld cr6, rWORD5, rWORD6
|
|
bne cr1, L(duLcr1)
|
|
srd r12, rWORD8, rSHR
|
|
sld rWORD8_SHIFT, rWORD8, rSHL
|
|
or rWORD8, r12, rWORD6_SHIFT
|
|
cmpld cr5, rWORD7, rWORD8
|
|
bdz L(du24) /* Adjust CTR as we start with +4 */
|
|
/* This is the primary loop */
|
|
.align 4
|
|
L(duLoop):
|
|
LD rWORD1, rOFF8, rSTR1
|
|
LD rWORD2, rOFF8, rSTR2
|
|
cmpld cr1, rWORD3, rWORD4
|
|
bne cr6, L(duLcr6)
|
|
srd r0, rWORD2, rSHR
|
|
sld rWORD2_SHIFT, rWORD2, rSHL
|
|
or rWORD2, r0, rWORD8_SHIFT
|
|
L(duLoop1):
|
|
LD rWORD3, rOFF16, rSTR1
|
|
LD rWORD4, rOFF16, rSTR2
|
|
cmpld cr6, rWORD5, rWORD6
|
|
bne cr5, L(duLcr5)
|
|
srd r12, rWORD4, rSHR
|
|
sld rWORD4_SHIFT, rWORD4, rSHL
|
|
or rWORD4, r12, rWORD2_SHIFT
|
|
L(duLoop2):
|
|
LD rWORD5, rOFF24, rSTR1
|
|
LD rWORD6, rOFF24, rSTR2
|
|
cmpld cr5, rWORD7, rWORD8
|
|
bne cr7, L(duLcr7)
|
|
srd r0, rWORD6, rSHR
|
|
sld rWORD6_SHIFT, rWORD6, rSHL
|
|
or rWORD6, r0, rWORD4_SHIFT
|
|
L(duLoop3):
|
|
LD rWORD7, rOFF32, rSTR1
|
|
LD rWORD8, rOFF32, rSTR2
|
|
addi rSTR1, rSTR1, 32
|
|
addi rSTR2, rSTR2, 32
|
|
cmpld cr7, rWORD1, rWORD2
|
|
bne cr1, L(duLcr1)
|
|
srd r12, rWORD8, rSHR
|
|
sld rWORD8_SHIFT, rWORD8, rSHL
|
|
or rWORD8, r12, rWORD6_SHIFT
|
|
bdnz L(duLoop)
|
|
|
|
L(duL4):
|
|
cmpld cr1, rWORD3, rWORD4
|
|
bne cr6, L(duLcr6)
|
|
cmpld cr6, rWORD5, rWORD6
|
|
bne cr5, L(duLcr5)
|
|
cmpld cr5, rWORD7, rWORD8
|
|
L(du44):
|
|
bne cr7, L(duLcr7)
|
|
L(du34):
|
|
bne cr1, L(duLcr1)
|
|
L(du24):
|
|
bne cr6, L(duLcr6)
|
|
L(du14):
|
|
sldi. rN, rN, 3
|
|
bne cr5, L(duLcr5)
|
|
/* At this point we have a remainder of 1 to 7 bytes to compare. We use
|
|
shift right double to eliminate bits beyond the compare length.
|
|
|
|
However it may not be safe to load rWORD2 which may be beyond the
|
|
string length. So we compare the bit length of the remainder to
|
|
the right shift count (rSHR). If the bit count is less than or equal
|
|
we do not need to load rWORD2 (all significant bits are already in
|
|
rWORD8_SHIFT). */
|
|
cmpld cr7, rN, rSHR
|
|
beq L(duZeroReturn)
|
|
li r0, 0
|
|
ble cr7, L(dutrim)
|
|
LD rWORD2, rOFF8, rSTR2
|
|
srd r0, rWORD2, rSHR
|
|
.align 4
|
|
L(dutrim):
|
|
LD rWORD1, rOFF8, rSTR1
|
|
ld rWORD8, -8(r1)
|
|
subfic rN, rN, 64 /* Shift count is 64 - (rN * 8). */
|
|
or rWORD2, r0, rWORD8_SHIFT
|
|
ld rWORD7, rWORD7SAVE(r1)
|
|
ld rSHL, rSHLSAVE(r1)
|
|
srd rWORD1, rWORD1, rN
|
|
srd rWORD2, rWORD2, rN
|
|
ld rSHR, rSHRSAVE(r1)
|
|
ld rWORD8_SHIFT, rWORD8SHIFTSAVE(r1)
|
|
li rRTN, 0
|
|
cmpld cr7, rWORD1, rWORD2
|
|
ld rWORD2_SHIFT, rWORD2SHIFTSAVE(r1)
|
|
ld rWORD4_SHIFT, rWORD4SHIFTSAVE(r1)
|
|
beq cr7, L(dureturn24)
|
|
li rRTN, 1
|
|
ld rWORD6_SHIFT, rWORD6SHIFTSAVE(r1)
|
|
ld rOFF8, rOFF8SAVE(r1)
|
|
ld rOFF16, rOFF16SAVE(r1)
|
|
ld rOFF24, rOFF24SAVE(r1)
|
|
ld rOFF32, rOFF32SAVE(r1)
|
|
bgtlr cr7
|
|
li rRTN, -1
|
|
blr
|
|
.align 4
|
|
L(duLcr7):
|
|
ld rWORD8, rWORD8SAVE(r1)
|
|
ld rWORD7, rWORD7SAVE(r1)
|
|
li rRTN, 1
|
|
bgt cr7, L(dureturn29)
|
|
ld rSHL, rSHLSAVE(r1)
|
|
ld rSHR, rSHRSAVE(r1)
|
|
li rRTN, -1
|
|
b L(dureturn27)
|
|
.align 4
|
|
L(duLcr1):
|
|
ld rWORD8, rWORD8SAVE(r1)
|
|
ld rWORD7, rWORD7SAVE(r1)
|
|
li rRTN, 1
|
|
bgt cr1, L(dureturn29)
|
|
ld rSHL, rSHLSAVE(r1)
|
|
ld rSHR, rSHRSAVE(r1)
|
|
li rRTN, -1
|
|
b L(dureturn27)
|
|
.align 4
|
|
L(duLcr6):
|
|
ld rWORD8, rWORD8SAVE(r1)
|
|
ld rWORD7, rWORD7SAVE(r1)
|
|
li rRTN, 1
|
|
bgt cr6, L(dureturn29)
|
|
ld rSHL, rSHLSAVE(r1)
|
|
ld rSHR, rSHRSAVE(r1)
|
|
li rRTN, -1
|
|
b L(dureturn27)
|
|
.align 4
|
|
L(duLcr5):
|
|
ld rWORD8, rWORD8SAVE(r1)
|
|
ld rWORD7, rWORD7SAVE(r1)
|
|
li rRTN, 1
|
|
bgt cr5, L(dureturn29)
|
|
ld rSHL, rSHLSAVE(r1)
|
|
ld rSHR, rSHRSAVE(r1)
|
|
li rRTN, -1
|
|
b L(dureturn27)
|
|
|
|
.align 3
|
|
L(duZeroReturn):
|
|
li rRTN, 0
|
|
.align 4
|
|
L(dureturn):
|
|
ld rWORD8, rWORD8SAVE(r1)
|
|
ld rWORD7, rWORD7SAVE(r1)
|
|
L(dureturn29):
|
|
ld rSHL, rSHLSAVE(r1)
|
|
ld rSHR, rSHRSAVE(r1)
|
|
L(dureturn27):
|
|
ld rWORD8_SHIFT, rWORD8SHIFTSAVE(r1)
|
|
ld rWORD2_SHIFT, rWORD2SHIFTSAVE(r1)
|
|
ld rWORD4_SHIFT, rWORD4SHIFTSAVE(r1)
|
|
L(dureturn24):
|
|
ld rWORD6_SHIFT, rWORD6SHIFTSAVE(r1)
|
|
ld rOFF8, rOFF8SAVE(r1)
|
|
ld rOFF16, rOFF16SAVE(r1)
|
|
ld rOFF24, rOFF24SAVE(r1)
|
|
ld rOFF32, rOFF32SAVE(r1)
|
|
blr
|
|
|
|
L(duzeroLength):
|
|
ld rOFF8, rOFF8SAVE(r1)
|
|
ld rOFF16, rOFF16SAVE(r1)
|
|
ld rOFF24, rOFF24SAVE(r1)
|
|
ld rOFF32, rOFF32SAVE(r1)
|
|
li rRTN, 0
|
|
blr
|
|
|
|
END (MEMCMP)
|
|
libc_hidden_builtin_def (memcmp)
|
|
weak_alias (memcmp, bcmp)
|
|
strong_alias (memcmp, __memcmpeq)
|
|
libc_hidden_def (__memcmpeq)
|