google3/third_party/grte/v4_src/glibc-2.19/ports/sysdeps/aarch64/memset.S - GRTEv4 - Git at Google

 /* Copyright (C) 2012-2014 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/>.  */

 /* Assumptions:
  *
  * ARMv8-a, AArch64
  * Unaligned accesses
  *
  */

 #include <sysdep.h>

 /* By default we assume that the DC instruction can be used to zero
    data blocks more efficiently.  In some circumstances this might be
    unsafe, for example in an asymmetric multiprocessor environment with
    different DC clear lengths (neither the upper nor lower lengths are
    safe to use).  The feature can be disabled by defining DONT_USE_DC.

    If code may be run in a virtualized environment, then define
    MAYBE_VIRT.  This will cause the code to cache the system register
    values rather than re-reading them each call.  */

 #define dstin		x0
 #define val		w1
 #define count		x2
 #define tmp1		x3
 #define tmp1w		w3
 #define tmp2		x4
 #define tmp2w		w4
 #define zva_len_x	x5
 #define zva_len		w5
 #define zva_bits_x	x6

 #define A_l		x7
 #define A_lw		w7
 #define dst		x8
 #define tmp3w		w9

 ENTRY_ALIGN (__memset, 6)

 	mov	dst, dstin		/* Preserve return value.  */
 	ands	A_lw, val, #255
 #ifndef DONT_USE_DC
 	b.eq	L(zero_mem)
 #endif
 	orr	A_lw, A_lw, A_lw, lsl #8
 	orr	A_lw, A_lw, A_lw, lsl #16
 	orr	A_l, A_l, A_l, lsl #32
 L(tail_maybe_long):
 	cmp	count, #64
 	b.ge	L(not_short)
 L(tail_maybe_tiny):
 	cmp	count, #15
 	b.le	L(tail15tiny)
 L(tail63):
 	ands	tmp1, count, #0x30
 	b.eq	L(tail15)
 	add	dst, dst, tmp1
 	cmp	tmp1w, #0x20
 	b.eq	1f
 	b.lt	2f
 	stp	A_l, A_l, [dst, #-48]
 1:
 	stp	A_l, A_l, [dst, #-32]
 2:
 	stp	A_l, A_l, [dst, #-16]

 L(tail15):
 	and	count, count, #15
 	add	dst, dst, count
 	stp	A_l, A_l, [dst, #-16]	/* Repeat some/all of last store. */
 	RET

 L(tail15tiny):
 	/* Set up to 15 bytes.  Does not assume earlier memory
 	   being set.  */
 	tbz	count, #3, 1f
 	str	A_l, [dst], #8
 1:
 	tbz	count, #2, 1f
 	str	A_lw, [dst], #4
 1:
 	tbz	count, #1, 1f
 	strh	A_lw, [dst], #2
 1:
 	tbz	count, #0, 1f
 	strb	A_lw, [dst]
 1:
 	RET

 	/* Critical loop.  Start at a new cache line boundary.  Assuming
 	 * 64 bytes per line, this ensures the entire loop is in one line.  */
 	.p2align 6
 L(not_short):
 	neg	tmp2, dst
 	ands	tmp2, tmp2, #15
 	b.eq	2f
 	/* Bring DST to 128-bit (16-byte) alignment.  We know that there's
 	 * more than that to set, so we simply store 16 bytes and advance by
 	 * the amount required to reach alignment.  */
 	sub	count, count, tmp2
 	stp	A_l, A_l, [dst]
 	add	dst, dst, tmp2
 	/* There may be less than 63 bytes to go now.  */
 	cmp	count, #63
 	b.le	L(tail63)
 2:
 	sub	dst, dst, #16		/* Pre-bias.  */
 	sub	count, count, #64
 1:
 	stp	A_l, A_l, [dst, #16]
 	stp	A_l, A_l, [dst, #32]
 	stp	A_l, A_l, [dst, #48]
 	stp	A_l, A_l, [dst, #64]!
 	subs	count, count, #64
 	b.ge	1b
 	tst	count, #0x3f
 	add	dst, dst, #16
 	b.ne	L(tail63)
 	RET

 #ifndef DONT_USE_DC
 	/* For zeroing memory, check to see if we can use the ZVA feature to
 	 * zero entire 'cache' lines.  */
 L(zero_mem):
 	mov	A_l, #0
 	cmp	count, #63
 	b.le	L(tail_maybe_tiny)
 	neg	tmp2, dst
 	ands	tmp2, tmp2, #15
 	b.eq	1f
 	sub	count, count, tmp2
 	stp	A_l, A_l, [dst]
 	add	dst, dst, tmp2
 	cmp	count, #63
 	b.le	L(tail63)
 1:
 	/* For zeroing small amounts of memory, it's not worth setting up
 	 * the line-clear code.  */
 	cmp	count, #128
 	b.lt	L(not_short)
 #ifdef MAYBE_VIRT
 	/* For efficiency when virtualized, we cache the ZVA capability.  */
 	adrp	tmp2, L(cache_clear)
 	ldr	zva_len, [tmp2, #:lo12:L(cache_clear)]
 	tbnz	zva_len, #31, L(not_short)
 	cbnz	zva_len, L(zero_by_line)
 	mrs	tmp1, dczid_el0
 	tbz	tmp1, #4, 1f
 	/* ZVA not available.  Remember this for next time.  */
 	mov	zva_len, #~0
 	str	zva_len, [tmp2, #:lo12:L(cache_clear)]
 	b	L(not_short)
 1:
 	mov	tmp3w, #4
 	and	zva_len, tmp1w, #15	/* Safety: other bits reserved.  */
 	lsl	zva_len, tmp3w, zva_len
 	str	zva_len, [tmp2, #:lo12:L(cache_clear)]
 #else
 	mrs	tmp1, dczid_el0
 	tbnz	tmp1, #4, L(not_short)
 	mov	tmp3w, #4
 	and	zva_len, tmp1w, #15	/* Safety: other bits reserved.  */
 	lsl	zva_len, tmp3w, zva_len
 #endif

 L(zero_by_line):
 	/* Compute how far we need to go to become suitably aligned.  We're
 	 * already at quad-word alignment.  */
 	cmp	count, zva_len_x
 	b.lt	L(not_short)		/* Not enough to reach alignment.  */
 	sub	zva_bits_x, zva_len_x, #1
 	neg	tmp2, dst
 	ands	tmp2, tmp2, zva_bits_x
 	b.eq	1f			/* Already aligned.  */
 	/* Not aligned, check that there's enough to copy after alignment.  */
 	sub	tmp1, count, tmp2
 	cmp	tmp1, #64
 	ccmp	tmp1, zva_len_x, #8, ge	/* NZCV=0b1000 */
 	b.lt	L(not_short)
 	/* We know that there's at least 64 bytes to zero and that it's safe
 	 * to overrun by 64 bytes.  */
 	mov	count, tmp1
 2:
 	stp	A_l, A_l, [dst]
 	stp	A_l, A_l, [dst, #16]
 	stp	A_l, A_l, [dst, #32]
 	subs	tmp2, tmp2, #64
 	stp	A_l, A_l, [dst, #48]
 	add	dst, dst, #64
 	b.ge	2b
 	/* We've overrun a bit, so adjust dst downwards.  */
 	add	dst, dst, tmp2
 1:
 	sub	count, count, zva_len_x
 3:
 	dc	zva, dst
 	add	dst, dst, zva_len_x
 	subs	count, count, zva_len_x
 	b.ge	3b
 	ands	count, count, zva_bits_x
 	b.ne	L(tail_maybe_long)
 	RET
 #ifdef MAYBE_VIRT
 	.bss
 	.p2align 2
 L(cache_clear):
 	.space 4
 #endif
 #endif /* DONT_USE_DC */

 END (__memset)
 weak_alias (__memset, memset)
 libc_hidden_builtin_def (memset)
	/* Copyright (C) 2012-2014 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/>. */

	/* Assumptions:
	*
	* ARMv8-a, AArch64
	* Unaligned accesses
	*
	*/

	#include <sysdep.h>

	/* By default we assume that the DC instruction can be used to zero
	data blocks more efficiently. In some circumstances this might be
	unsafe, for example in an asymmetric multiprocessor environment with
	different DC clear lengths (neither the upper nor lower lengths are
	safe to use). The feature can be disabled by defining DONT_USE_DC.

	If code may be run in a virtualized environment, then define
	MAYBE_VIRT. This will cause the code to cache the system register
	values rather than re-reading them each call. */

	#define dstin x0
	#define val w1
	#define count x2
	#define tmp1 x3
	#define tmp1w w3
	#define tmp2 x4
	#define tmp2w w4
	#define zva_len_x x5
	#define zva_len w5
	#define zva_bits_x x6

	#define A_l x7
	#define A_lw w7
	#define dst x8
	#define tmp3w w9

	ENTRY_ALIGN (__memset, 6)

	mov dst, dstin /* Preserve return value. */
	ands A_lw, val, #255
	#ifndef DONT_USE_DC
	b.eq L(zero_mem)
	#endif
	orr A_lw, A_lw, A_lw, lsl #8
	orr A_lw, A_lw, A_lw, lsl #16
	orr A_l, A_l, A_l, lsl #32
	L(tail_maybe_long):
	cmp count, #64
	b.ge L(not_short)
	L(tail_maybe_tiny):
	cmp count, #15
	b.le L(tail15tiny)
	L(tail63):
	ands tmp1, count, #0x30
	b.eq L(tail15)
	add dst, dst, tmp1
	cmp tmp1w, #0x20
	b.eq 1f
	b.lt 2f
	stp A_l, A_l, [dst, #-48]
	1:
	stp A_l, A_l, [dst, #-32]
	2:
	stp A_l, A_l, [dst, #-16]

	L(tail15):
	and count, count, #15
	add dst, dst, count
	stp A_l, A_l, [dst, #-16] /* Repeat some/all of last store. */
	RET

	L(tail15tiny):
	/* Set up to 15 bytes. Does not assume earlier memory
	being set. */
	tbz count, #3, 1f
	str A_l, [dst], #8
	1:
	tbz count, #2, 1f
	str A_lw, [dst], #4
	1:
	tbz count, #1, 1f
	strh A_lw, [dst], #2
	1:
	tbz count, #0, 1f
	strb A_lw, [dst]
	1:
	RET

	/* Critical loop. Start at a new cache line boundary. Assuming
	* 64 bytes per line, this ensures the entire loop is in one line. */
	.p2align 6
	L(not_short):
	neg tmp2, dst
	ands tmp2, tmp2, #15
	b.eq 2f
	/* Bring DST to 128-bit (16-byte) alignment. We know that there's
	* more than that to set, so we simply store 16 bytes and advance by
	* the amount required to reach alignment. */
	sub count, count, tmp2
	stp A_l, A_l, [dst]
	add dst, dst, tmp2
	/* There may be less than 63 bytes to go now. */
	cmp count, #63
	b.le L(tail63)
	2:
	sub dst, dst, #16 /* Pre-bias. */
	sub count, count, #64
	1:
	stp A_l, A_l, [dst, #16]
	stp A_l, A_l, [dst, #32]
	stp A_l, A_l, [dst, #48]
	stp A_l, A_l, [dst, #64]!
	subs count, count, #64
	b.ge 1b
	tst count, #0x3f
	add dst, dst, #16
	b.ne L(tail63)
	RET

	#ifndef DONT_USE_DC
	/* For zeroing memory, check to see if we can use the ZVA feature to
	* zero entire 'cache' lines. */
	L(zero_mem):
	mov A_l, #0
	cmp count, #63
	b.le L(tail_maybe_tiny)
	neg tmp2, dst
	ands tmp2, tmp2, #15
	b.eq 1f
	sub count, count, tmp2
	stp A_l, A_l, [dst]
	add dst, dst, tmp2
	cmp count, #63
	b.le L(tail63)
	1:
	/* For zeroing small amounts of memory, it's not worth setting up
	* the line-clear code. */
	cmp count, #128
	b.lt L(not_short)
	#ifdef MAYBE_VIRT
	/* For efficiency when virtualized, we cache the ZVA capability. */
	adrp tmp2, L(cache_clear)
	ldr zva_len, [tmp2, #:lo12:L(cache_clear)]
	tbnz zva_len, #31, L(not_short)
	cbnz zva_len, L(zero_by_line)
	mrs tmp1, dczid_el0
	tbz tmp1, #4, 1f
	/* ZVA not available. Remember this for next time. */
	mov zva_len, #~0
	str zva_len, [tmp2, #:lo12:L(cache_clear)]
	b L(not_short)
	1:
	mov tmp3w, #4
	and zva_len, tmp1w, #15 /* Safety: other bits reserved. */
	lsl zva_len, tmp3w, zva_len
	str zva_len, [tmp2, #:lo12:L(cache_clear)]
	#else
	mrs tmp1, dczid_el0
	tbnz tmp1, #4, L(not_short)
	mov tmp3w, #4
	and zva_len, tmp1w, #15 /* Safety: other bits reserved. */
	lsl zva_len, tmp3w, zva_len
	#endif

	L(zero_by_line):
	/* Compute how far we need to go to become suitably aligned. We're
	* already at quad-word alignment. */
	cmp count, zva_len_x
	b.lt L(not_short) /* Not enough to reach alignment. */
	sub zva_bits_x, zva_len_x, #1
	neg tmp2, dst
	ands tmp2, tmp2, zva_bits_x
	b.eq 1f /* Already aligned. */
	/* Not aligned, check that there's enough to copy after alignment. */
	sub tmp1, count, tmp2
	cmp tmp1, #64
	ccmp tmp1, zva_len_x, #8, ge /* NZCV=0b1000 */
	b.lt L(not_short)
	/* We know that there's at least 64 bytes to zero and that it's safe
	* to overrun by 64 bytes. */
	mov count, tmp1
	2:
	stp A_l, A_l, [dst]
	stp A_l, A_l, [dst, #16]
	stp A_l, A_l, [dst, #32]
	subs tmp2, tmp2, #64
	stp A_l, A_l, [dst, #48]
	add dst, dst, #64
	b.ge 2b
	/* We've overrun a bit, so adjust dst downwards. */
	add dst, dst, tmp2
	1:
	sub count, count, zva_len_x
	3:
	dc zva, dst
	add dst, dst, zva_len_x
	subs count, count, zva_len_x
	b.ge 3b
	ands count, count, zva_bits_x
	b.ne L(tail_maybe_long)
	RET
	#ifdef MAYBE_VIRT
	.bss
	.p2align 2
	L(cache_clear):
	.space 4
	#endif
	#endif /* DONT_USE_DC */

	END (__memset)
	weak_alias (__memset, memset)
	libc_hidden_builtin_def (memset)