google3/third_party/grte/v5_src/glibc-2.27/sysdeps/powerpc/powerpc64/power9/strncmp.S - GRTEv5 - Git at Google

 /* Optimized strncmp implementation for PowerPC64/POWER9.
    Copyright (C) 2016-2018 Free Software Foundation, Inc.
    This file is part of the GNU C Library.

    The GNU C Library is free software; you can redistribute it and/or
    modify it under the terms of the GNU Lesser General Public
    License as published by the Free Software Foundation; either
    version 2.1 of the License, or (at your option) any later version.

    The GNU C Library is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
    Lesser General Public License for more details.

    You should have received a copy of the GNU Lesser General Public
    License along with the GNU C Library; if not, see
    <http://www.gnu.org/licenses/>.  */
 #ifdef __LITTLE_ENDIAN__
 #include <sysdep.h>

 /* Implements the function

    int [r3] strncmp (const char *s1 [r3], const char *s2 [r4], size_t [r5] n)

    The implementation uses unaligned doubleword access to avoid specialized
    code paths depending of data alignment for first 32 bytes and uses
    vectorised loops after that.  */

 #ifndef STRNCMP
 # define STRNCMP strncmp
 #endif

 /* TODO: Change this to actual instructions when minimum binutils is upgraded
    to 2.27. Macros are defined below for these newer instructions in order
    to maintain compatibility.  */
 # define VCTZLSBB(r,v) .long (0x10010602 | ((r)<<(32-11)) | ((v)<<(32-21)))

 # define VEXTUBRX(t,a,b) .long (0x1000070d \
 				| ((t)<<(32-11))  \
 				| ((a)<<(32-16))  \
 				| ((b)<<(32-21)) )

 # define VCMPNEZB(t,a,b) .long (0x10000507 \
 				| ((t)<<(32-11))  \
 				| ((a)<<(32-16))  \
 				| ((b)<<(32-21)) )

 /* Get 16 bytes for unaligned case.
    reg1: Vector to hold next 16 bytes.
    reg2: Address to read from.
    reg3: Permute control vector.  */
 # define GET16BYTES(reg1, reg2, reg3) \
 	lvx	reg1, 0, reg2; \
 	vperm	v8, v2, reg1, reg3; \
 	vcmpequb.	v8, v0, v8; \
 	beq	cr6, 1f; \
 	vspltisb	v9, 0; \
 	b	2f; \
 	.align 4; \
 1: \
 	cmplw	cr6, r5, r11; \
 	ble	cr6, 2f; \
 	addi	r6, reg2, 16; \
 	lvx	v9, 0, r6; \
 2: \
 	vperm	reg1, v9, reg1, reg3;

 /* TODO: change this to .machine power9 when minimum binutils
    is upgraded to 2.27.  */
 	.machine  power7
 ENTRY_TOCLESS (STRNCMP, 4)
 	/* Check if size is 0.  */
 	cmpdi	cr0, r5, 0
 	beq	cr0, L(ret0)
 	li	r0, 0

 	/* Check if [s1]+32 or [s2]+32 will cross a 4K page boundary using
 	   the code:

 	    (((size_t) s1) % PAGE_SIZE > (PAGE_SIZE - ITER_SIZE))

 	   with PAGE_SIZE being 4096 and ITER_SIZE begin 32.  */
 	rldicl	r8, r3, 0, 52
 	cmpldi	cr7, r8, 4096-32
 	bgt	cr7, L(pagecross)
 	rldicl	r9, r4, 0, 52
 	cmpldi	cr7, r9, 4096-32
 	bgt	cr7, L(pagecross)

 	/* For short strings up to 32 bytes, load both s1 and s2 using
 	   unaligned dwords and compare.  */

 	ld	r7, 0(r3)
 	ld	r9, 0(r4)
 	li	r8, 0
 	cmpb	r8, r7, r8
 	cmpb	r6, r7, r9
 	orc.	r8, r8, r6
 	bne	cr0, L(different1)

 	/* If the strings compared are equal, but size is less or equal
 	   to 8, return 0.  */
 	cmpldi	cr7, r5, 8
 	li	r9, 0
 	ble	cr7, L(ret1)
 	addi	r5, r5, -8

 	ld	r7, 8(r3)
 	ld	r9, 8(r4)
 	cmpb	r8, r7, r8
 	cmpb	r6, r7, r9
 	orc.	r8, r8, r6
 	bne	cr0, L(different1)
 	cmpldi	cr7, r5, 8
 	mr	r9, r8
 	ble	cr7, L(ret1)
 	/* Update pointers and size.  */
 	addi	r5, r5, -8
 	addi	r3, r3, 16
 	addi	r4, r4, 16

 	ld	r7, 0(r3)
 	ld	r9, 0(r4)
 	li	r8, 0
 	cmpb	r8, r7, r8
 	cmpb	r6, r7, r9
 	orc.	r8, r8, r6
 	bne	cr0, L(different1)
 	cmpldi	cr7, r5, 8
 	li	r9, 0
 	ble	cr7, L(ret1)
 	addi	r5, r5, -8

 	ld	r7, 8(r3)
 	ld	r9, 8(r4)
 	cmpb	r8, r7, r8
 	cmpb	r6, r7, r9
 	orc.	r8, r8, r6
 	bne	cr0, L(different1)
 	cmpldi	cr7, r5, 8
 	mr	r9, r8
 	ble	cr7, L(ret1)

 	/* Update pointers and size.  */
 	addi	r5, r5, -8
 	addi	r3, r3, 16
 	addi	r4, r4, 16
 L(align):
 	/* Now it has checked for first 32 bytes, align source1 to doubleword
 	   and adjust source2 address.  */
 	vspltisb	v0, 0
 	vspltisb	v2, -1
 	or	r6, r4, r3
 	andi.	r6, r6, 0xF
 	beq	cr0, L(aligned)
 	lvsr	v6, 0, r4   /* Compute mask.  */
 	clrldi	r6, r4, 60
 	subfic	r11, r6, 16
 	andi.	r6, r3, 0xF
 	beq	cr0, L(s1_align)
 	/* Both s1 and s2 are unaligned.  */
 	GET16BYTES(v5, r4, v6)
 	lvsr	v10, 0, r3   /* Compute mask.  */
 	clrldi	r6, r3, 60
 	subfic	r11, r6, 16
 	GET16BYTES(v4, r3, v10)
 	VCMPNEZB(v7, v5, v4)
 	beq	cr6, L(match)
 	b	L(different)

 	/* Align s1 to qw and adjust s2 address.  */
 	.align  4
 L(match):
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	subf	r5, r11, r5
 	add	r3, r3, r11
 	add	r4, r4, r11
 	andi.	r11, r4, 0xF
 	beq	cr0, L(aligned)
 	lvsr	v6, 0, r4
 	clrldi	r6, r4, 60
 	subfic	r11, r6, 16
 	/* There are 2 loops depending on the input alignment.
 	   Each loop gets 16 bytes from s1 and s2, checks for null
 	   and compares them. Loops until a mismatch or  null occurs.  */
 L(s1_align):
 	lvx	v4, 0, r3
 	GET16BYTES(v5, r4, v6)
 	VCMPNEZB(v7, v5, v4)
 	bne	cr6, L(different)
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	addi	r5, r5, -16
 	addi	r3, r3, 16
 	addi	r4, r4, 16

 	lvx	v4, 0, r3
 	GET16BYTES(v5, r4, v6)
 	VCMPNEZB(v7, v5, v4)
 	bne	cr6, L(different)
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	addi	r5, r5, -16
 	addi	r3, r3, 16
 	addi	r4, r4, 16

 	lvx	v4, 0, r3
 	GET16BYTES(v5, r4, v6)
 	VCMPNEZB(v7, v5, v4)
 	bne	cr6, L(different)
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	addi	r5, r5, -16
 	addi	r3, r3, 16
 	addi	r4, r4, 16

 	lvx	v4, 0, r3
 	GET16BYTES(v5, r4, v6)
 	VCMPNEZB(v7, v5, v4)
 	bne	cr6, L(different)
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	addi	r5, r5, -16
 	addi	r3, r3, 16
 	addi	r4, r4, 16
 	b	L(s1_align)
 	.align  4
 L(aligned):
 	lvx	v4, 0, r3
 	lvx	v5, 0, r4
 	VCMPNEZB(v7, v5, v4)
 	bne	cr6, L(different)
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	addi	r5, r5, -16
 	addi	r3, r3, 16
 	addi	r4, r4, 16

 	lvx	v4, 0, r3
 	lvx	v5, 0, r4
 	VCMPNEZB(v7, v5, v4)
 	bne	cr6, L(different)
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	addi	r5, r5, -16
 	addi	r3, r3, 16
 	addi	r4, r4, 16

 	lvx	v4, 0, r3
 	lvx	v5, 0, r4
 	VCMPNEZB(v7, v5, v4)
 	bne	cr6, L(different)
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	addi	r5, r5, -16
 	addi	r3, r3, 16
 	addi	r4, r4, 16

 	lvx	v4, 0, r3
 	lvx	v5, 0, r4
 	VCMPNEZB(v7, v5, v4)
 	bne	cr6, L(different)
 	cmpldi	cr7, r5, 16
 	ble	cr7, L(ret0)
 	addi	r5, r5, -16
 	addi	r3, r3, 16
 	addi	r4, r4, 16
 	b	L(aligned)
 	/* Calculate and return the difference.  */
 L(different):
 	VCTZLSBB(r6, v7)
 	cmplw	cr7, r5, r6
 	ble	cr7, L(ret0)
 	VEXTUBRX(r5, r6, v4)
 	VEXTUBRX(r4, r6, v5)
 	subf	r3, r4, r5
 	extsw	r3, r3
 	blr

 	.align 4
 L(ret0):
 	li	r9, 0
 L(ret1):
 	mr	r3, r9
 	blr

 	/* The code now checks if r8 and r5 are different by issuing a
 	   cmpb and shifts the result based on its output:

 	  leadzero = (__builtin_ffsl (z1) - 1);
 	  leadzero = leadzero > (n-1)*8 ? (n-1)*8 : leadzero;
 	  r1 = (r1 >> leadzero) & 0xFFUL;
 	  r2 = (r2 >> leadzero) & 0xFFUL;
 	  return r1 - r2;  */

 	.align 4
 L(different1):
 	neg	r11, r8
 	sldi	r5, r5, 3
 	and	r8, r11, r8
 	addi	r5, r5, -8
 	cntlzd	r8, r8
 	subfic	r8, r8, 63
 	extsw 	r8, r8
 	cmpld	cr7, r8, r5
 	ble	cr7, L(different2)
 	mr	r8, r5
 L(different2):
 	extsw	r8, r8
 	srd	r7, r7, r8
 	srd	r9, r9, r8
 	rldicl	r3, r7, 0, 56
 	rldicl	r9, r9, 0, 56
 	subf	r9, r9, 3
 	extsw	r9, r9
 	mr	r3, r9
 	blr

 	/* If unaligned 16 bytes reads across a 4K page boundary, it uses
 	   a simple byte a byte comparison until the page alignment for s1
 	   is reached.  */
 	.align 4
 L(pagecross):
 	lbz	r7, 0(r3)
 	lbz	r9, 0(r4)
 	subfic	r8, r8,4095
 	cmplw	cr7, r9, r7
 	bne	cr7, L(byte_ne_3)
 	cmpdi	cr7, r9, 0
 	beq	cr7, L(byte_ne_0)
 	addi	r5, r5, -1
 	subf	r7, r8, r5
 	subf	r9, r7, r5
 	addi	r9, r9, 1
 	mtctr	r9
 	b	L(pagecross_loop1)

 	.align 4
 L(pagecross_loop0):
 	beq	cr7, L(ret0)
 	lbz	r9, 0(r3)
 	lbz	r8, 0(r4)
 	addi	r5, r5, -1
 	cmplw	cr7, r9, r8
 	cmpdi	cr5, r9, 0
 	bne	cr7, L(byte_ne_2)
 	beq	cr5, L(byte_ne_0)
 L(pagecross_loop1):
 	cmpdi	cr7, r5, 0
 	addi	r3, r3, 1
 	addi	r4, r4, 1
 	bdnz	L(pagecross_loop0)
 	cmpdi	cr7, r7, 0
 	li	r9, 0
 	bne+	cr7, L(align)
 	b	L(ret1)

 	.align 4
 L(byte_ne_0):
 	li	r7, 0
 L(byte_ne_1):
 	subf	r9, r9, r7
 	extsw	r9, r9
 	b	L(ret1)

 	.align 4
 L(byte_ne_2):
 	extsw	r7, r9
 	mr	r9, r8
 	b	L(byte_ne_1)
 L(byte_ne_3):
 	extsw	r7, r7
 	b	L(byte_ne_1)
 END(STRNCMP)
 libc_hidden_builtin_def(strncmp)
 #else
 #include <sysdeps/powerpc/powerpc64/power8/strncmp.S>
 #endif
	/* Optimized strncmp implementation for PowerPC64/POWER9.
	Copyright (C) 2016-2018 Free Software Foundation, Inc.
	This file is part of the GNU C Library.

	The GNU C Library is free software; you can redistribute it and/or
	modify it under the terms of the GNU Lesser General Public
	License as published by the Free Software Foundation; either
	version 2.1 of the License, or (at your option) any later version.

	The GNU C Library is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	Lesser General Public License for more details.

	You should have received a copy of the GNU Lesser General Public
	License along with the GNU C Library; if not, see
	<http://www.gnu.org/licenses/>. */
	#ifdef __LITTLE_ENDIAN__
	#include <sysdep.h>

	/* Implements the function

	int [r3] strncmp (const char s1 [r3], const char s2 [r4], size_t [r5] n)

	The implementation uses unaligned doubleword access to avoid specialized
	code paths depending of data alignment for first 32 bytes and uses
	vectorised loops after that. */

	#ifndef STRNCMP
	# define STRNCMP strncmp
	#endif

	/* TODO: Change this to actual instructions when minimum binutils is upgraded
	to 2.27. Macros are defined below for these newer instructions in order
	to maintain compatibility. */
	# define VCTZLSBB(r,v) .long (0x10010602 \| ((r)<<(32-11)) \| ((v)<<(32-21)))

	# define VEXTUBRX(t,a,b) .long (0x1000070d \
	\| ((t)<<(32-11)) \
	\| ((a)<<(32-16)) \
	\| ((b)<<(32-21)) )

	# define VCMPNEZB(t,a,b) .long (0x10000507 \
	\| ((t)<<(32-11)) \
	\| ((a)<<(32-16)) \
	\| ((b)<<(32-21)) )

	/* Get 16 bytes for unaligned case.
	reg1: Vector to hold next 16 bytes.
	reg2: Address to read from.
	reg3: Permute control vector. */
	# define GET16BYTES(reg1, reg2, reg3) \
	lvx reg1, 0, reg2; \
	vperm v8, v2, reg1, reg3; \
	vcmpequb. v8, v0, v8; \
	beq cr6, 1f; \
	vspltisb v9, 0; \
	b 2f; \
	.align 4; \
	1: \
	cmplw cr6, r5, r11; \
	ble cr6, 2f; \
	addi r6, reg2, 16; \
	lvx v9, 0, r6; \
	2: \
	vperm reg1, v9, reg1, reg3;

	/* TODO: change this to .machine power9 when minimum binutils
	is upgraded to 2.27. */
	.machine power7
	ENTRY_TOCLESS (STRNCMP, 4)
	/* Check if size is 0. */
	cmpdi cr0, r5, 0
	beq cr0, L(ret0)
	li r0, 0

	/* Check if [s1]+32 or [s2]+32 will cross a 4K page boundary using
	the code:

	(((size_t) s1) % PAGE_SIZE > (PAGE_SIZE - ITER_SIZE))

	with PAGE_SIZE being 4096 and ITER_SIZE begin 32. */
	rldicl r8, r3, 0, 52
	cmpldi cr7, r8, 4096-32
	bgt cr7, L(pagecross)
	rldicl r9, r4, 0, 52
	cmpldi cr7, r9, 4096-32
	bgt cr7, L(pagecross)

	/* For short strings up to 32 bytes, load both s1 and s2 using
	unaligned dwords and compare. */

	ld r7, 0(r3)
	ld r9, 0(r4)
	li r8, 0
	cmpb r8, r7, r8
	cmpb r6, r7, r9
	orc. r8, r8, r6
	bne cr0, L(different1)

	/* If the strings compared are equal, but size is less or equal
	to 8, return 0. */
	cmpldi cr7, r5, 8
	li r9, 0
	ble cr7, L(ret1)
	addi r5, r5, -8

	ld r7, 8(r3)
	ld r9, 8(r4)
	cmpb r8, r7, r8
	cmpb r6, r7, r9
	orc. r8, r8, r6
	bne cr0, L(different1)
	cmpldi cr7, r5, 8
	mr r9, r8
	ble cr7, L(ret1)
	/* Update pointers and size. */
	addi r5, r5, -8
	addi r3, r3, 16
	addi r4, r4, 16

	ld r7, 0(r3)
	ld r9, 0(r4)
	li r8, 0
	cmpb r8, r7, r8
	cmpb r6, r7, r9
	orc. r8, r8, r6
	bne cr0, L(different1)
	cmpldi cr7, r5, 8
	li r9, 0
	ble cr7, L(ret1)
	addi r5, r5, -8

	ld r7, 8(r3)
	ld r9, 8(r4)
	cmpb r8, r7, r8
	cmpb r6, r7, r9
	orc. r8, r8, r6
	bne cr0, L(different1)
	cmpldi cr7, r5, 8
	mr r9, r8
	ble cr7, L(ret1)

	/* Update pointers and size. */
	addi r5, r5, -8
	addi r3, r3, 16
	addi r4, r4, 16
	L(align):
	/* Now it has checked for first 32 bytes, align source1 to doubleword
	and adjust source2 address. */
	vspltisb v0, 0
	vspltisb v2, -1
	or r6, r4, r3
	andi. r6, r6, 0xF
	beq cr0, L(aligned)
	lvsr v6, 0, r4 /* Compute mask. */
	clrldi r6, r4, 60
	subfic r11, r6, 16
	andi. r6, r3, 0xF
	beq cr0, L(s1_align)
	/* Both s1 and s2 are unaligned. */
	GET16BYTES(v5, r4, v6)
	lvsr v10, 0, r3 /* Compute mask. */
	clrldi r6, r3, 60
	subfic r11, r6, 16
	GET16BYTES(v4, r3, v10)
	VCMPNEZB(v7, v5, v4)
	beq cr6, L(match)
	b L(different)

	/* Align s1 to qw and adjust s2 address. */
	.align 4
	L(match):
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	subf r5, r11, r5
	add r3, r3, r11
	add r4, r4, r11
	andi. r11, r4, 0xF
	beq cr0, L(aligned)
	lvsr v6, 0, r4
	clrldi r6, r4, 60
	subfic r11, r6, 16
	/* There are 2 loops depending on the input alignment.
	Each loop gets 16 bytes from s1 and s2, checks for null
	and compares them. Loops until a mismatch or null occurs. */
	L(s1_align):
	lvx v4, 0, r3
	GET16BYTES(v5, r4, v6)
	VCMPNEZB(v7, v5, v4)
	bne cr6, L(different)
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	addi r5, r5, -16
	addi r3, r3, 16
	addi r4, r4, 16

	lvx v4, 0, r3
	GET16BYTES(v5, r4, v6)
	VCMPNEZB(v7, v5, v4)
	bne cr6, L(different)
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	addi r5, r5, -16
	addi r3, r3, 16
	addi r4, r4, 16

	lvx v4, 0, r3
	GET16BYTES(v5, r4, v6)
	VCMPNEZB(v7, v5, v4)
	bne cr6, L(different)
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	addi r5, r5, -16
	addi r3, r3, 16
	addi r4, r4, 16

	lvx v4, 0, r3
	GET16BYTES(v5, r4, v6)
	VCMPNEZB(v7, v5, v4)
	bne cr6, L(different)
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	addi r5, r5, -16
	addi r3, r3, 16
	addi r4, r4, 16
	b L(s1_align)
	.align 4
	L(aligned):
	lvx v4, 0, r3
	lvx v5, 0, r4
	VCMPNEZB(v7, v5, v4)
	bne cr6, L(different)
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	addi r5, r5, -16
	addi r3, r3, 16
	addi r4, r4, 16

	lvx v4, 0, r3
	lvx v5, 0, r4
	VCMPNEZB(v7, v5, v4)
	bne cr6, L(different)
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	addi r5, r5, -16
	addi r3, r3, 16
	addi r4, r4, 16

	lvx v4, 0, r3
	lvx v5, 0, r4
	VCMPNEZB(v7, v5, v4)
	bne cr6, L(different)
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	addi r5, r5, -16
	addi r3, r3, 16
	addi r4, r4, 16

	lvx v4, 0, r3
	lvx v5, 0, r4
	VCMPNEZB(v7, v5, v4)
	bne cr6, L(different)
	cmpldi cr7, r5, 16
	ble cr7, L(ret0)
	addi r5, r5, -16
	addi r3, r3, 16
	addi r4, r4, 16
	b L(aligned)
	/* Calculate and return the difference. */
	L(different):
	VCTZLSBB(r6, v7)
	cmplw cr7, r5, r6
	ble cr7, L(ret0)
	VEXTUBRX(r5, r6, v4)
	VEXTUBRX(r4, r6, v5)
	subf r3, r4, r5
	extsw r3, r3
	blr

	.align 4
	L(ret0):
	li r9, 0
	L(ret1):
	mr r3, r9
	blr

	/* The code now checks if r8 and r5 are different by issuing a
	cmpb and shifts the result based on its output:

	leadzero = (__builtin_ffsl (z1) - 1);
	leadzero = leadzero > (n-1)8 ? (n-1)8 : leadzero;
	r1 = (r1 >> leadzero) & 0xFFUL;
	r2 = (r2 >> leadzero) & 0xFFUL;
	return r1 - r2; */

	.align 4
	L(different1):
	neg r11, r8
	sldi r5, r5, 3
	and r8, r11, r8
	addi r5, r5, -8
	cntlzd r8, r8
	subfic r8, r8, 63
	extsw r8, r8
	cmpld cr7, r8, r5
	ble cr7, L(different2)
	mr r8, r5
	L(different2):
	extsw r8, r8
	srd r7, r7, r8
	srd r9, r9, r8
	rldicl r3, r7, 0, 56
	rldicl r9, r9, 0, 56
	subf r9, r9, 3
	extsw r9, r9
	mr r3, r9
	blr

	/* If unaligned 16 bytes reads across a 4K page boundary, it uses
	a simple byte a byte comparison until the page alignment for s1
	is reached. */
	.align 4
	L(pagecross):
	lbz r7, 0(r3)
	lbz r9, 0(r4)
	subfic r8, r8,4095
	cmplw cr7, r9, r7
	bne cr7, L(byte_ne_3)
	cmpdi cr7, r9, 0
	beq cr7, L(byte_ne_0)
	addi r5, r5, -1
	subf r7, r8, r5
	subf r9, r7, r5
	addi r9, r9, 1
	mtctr r9
	b L(pagecross_loop1)

	.align 4
	L(pagecross_loop0):
	beq cr7, L(ret0)
	lbz r9, 0(r3)
	lbz r8, 0(r4)
	addi r5, r5, -1
	cmplw cr7, r9, r8
	cmpdi cr5, r9, 0
	bne cr7, L(byte_ne_2)
	beq cr5, L(byte_ne_0)
	L(pagecross_loop1):
	cmpdi cr7, r5, 0
	addi r3, r3, 1
	addi r4, r4, 1
	bdnz L(pagecross_loop0)
	cmpdi cr7, r7, 0
	li r9, 0
	bne+ cr7, L(align)
	b L(ret1)

	.align 4
	L(byte_ne_0):
	li r7, 0
	L(byte_ne_1):
	subf r9, r9, r7
	extsw r9, r9
	b L(ret1)

	.align 4
	L(byte_ne_2):
	extsw r7, r9
	mr r9, r8
	b L(byte_ne_1)
	L(byte_ne_3):
	extsw r7, r7
	b L(byte_ne_1)
	END(STRNCMP)
	libc_hidden_builtin_def(strncmp)
	#else
	#include <sysdeps/powerpc/powerpc64/power8/strncmp.S>
	#endif