/* Optimized 64-bit memset implementation for POWER6.
Copyright (C) 1997-2013 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
. */
#include
#include
#include
/* __ptr_t [r3] memset (__ptr_t s [r3], int c [r4], size_t n [r5]));
Returns 's'.
The memset is done in three sizes: byte (8 bits), word (32 bits),
cache line (256 bits). There is a special case for setting cache lines
to 0, to take advantage of the dcbz instruction. */
.machine power6
EALIGN (BP_SYM (memset), 7, 0)
CALL_MCOUNT 3
#define rTMP r0
#define rRTN r3 /* Initial value of 1st argument. */
#if __BOUNDED_POINTERS__
# define rMEMP0 r4 /* Original value of 1st arg. */
# define rCHR r5 /* Char to set in each byte. */
# define rLEN r6 /* Length of region to set. */
# define rMEMP r10 /* Address at which we are storing. */
#else
# define rMEMP0 r3 /* Original value of 1st arg. */
# define rCHR r4 /* Char to set in each byte. */
# define rLEN r5 /* Length of region to set. */
# define rMEMP r6 /* Address at which we are storing. */
#endif
#define rALIGN r7 /* Number of bytes we are setting now (when aligning). */
#define rMEMP2 r8
#define rMEMP3 r9 /* Alt mem pointer. */
L(_memset):
#if __BOUNDED_POINTERS__
cmpldi cr1, rRTN, 0
CHECK_BOUNDS_BOTH_WIDE (rMEMP0, rTMP, rTMP2, rLEN)
beq cr1, L(b0)
STORE_RETURN_VALUE (rMEMP0)
STORE_RETURN_BOUNDS (rTMP, rTMP2)
L(b0):
#endif
/* Take care of case for size <= 4. */
cmpldi cr1, rLEN, 8
andi. rALIGN, rMEMP0, 7
mr rMEMP, rMEMP0
ble cr1, L(small)
/* Align to doubleword boundary. */
cmpldi cr5, rLEN, 31
rlwimi rCHR, rCHR, 8, 16, 23 /* Replicate byte to halfword. */
beq+ L(aligned2)
mtcrf 0x01, rMEMP0
subfic rALIGN, rALIGN, 8
cror 28,30,31 /* Detect odd word aligned. */
add rMEMP, rMEMP, rALIGN
sub rLEN, rLEN, rALIGN
rlwimi rCHR, rCHR, 16, 0, 15 /* Replicate halfword to word. */
bt 29, L(g4)
/* Process the even word of doubleword. */
bf+ 31, L(g2)
stb rCHR, 0(rMEMP0)
bt 30, L(g4x)
L(g2):
sth rCHR, -6(rMEMP)
L(g4x):
stw rCHR, -4(rMEMP)
b L(aligned)
/* Process the odd word of doubleword. */
L(g4):
bf 28, L(g4x) /* If false, word aligned on odd word. */
bf+ 31, L(g0)
stb rCHR, 0(rMEMP0)
bt 30, L(aligned)
L(g0):
sth rCHR, -2(rMEMP)
/* Handle the case of size < 31. */
L(aligned2):
rlwimi rCHR, rCHR, 16, 0, 15 /* Replicate halfword to word. */
L(aligned):
mtcrf 0x01, rLEN
ble cr5, L(medium)
/* Align to 32-byte boundary. */
andi. rALIGN, rMEMP, 0x18
subfic rALIGN, rALIGN, 0x20
insrdi rCHR,rCHR,32,0 /* Replicate word to double word. */
beq L(caligned)
mtcrf 0x01, rALIGN
add rMEMP, rMEMP, rALIGN
sub rLEN, rLEN, rALIGN
cmplwi cr1, rALIGN, 0x10
mr rMEMP2, rMEMP
bf 28, L(a1)
stdu rCHR, -8(rMEMP2)
L(a1): blt cr1, L(a2)
std rCHR, -8(rMEMP2)
stdu rCHR, -16(rMEMP2)
L(a2):
/* Now aligned to a 32 byte boundary. */
.align 4
L(caligned):
cmpldi cr1, rCHR, 0
clrrdi. rALIGN, rLEN, 5
mtcrf 0x01, rLEN
beq cr1, L(zloopstart) /* Special case for clearing memory using dcbz. */
beq L(medium) /* We may not actually get to do a full line. */
.align 4
/* Storing a non-zero "c" value. We are aligned at a sector (32-byte)
boundary may not be at cache line (128-byte) boundary. */
L(nzloopstart):
/* memset in 32-byte chunks until we get to a cache line boundary.
If rLEN is less then the distance to the next cache-line boundary use
cacheAligned1 code to finish the tail. */
cmpldi cr1,rLEN,128
andi. rTMP,rMEMP,127
blt cr1,L(cacheAligned1)
addi rMEMP3,rMEMP,32
beq L(nzCacheAligned)
addi rLEN,rLEN,-32
std rCHR,0(rMEMP)
std rCHR,8(rMEMP)
std rCHR,16(rMEMP)
addi rMEMP,rMEMP,32
andi. rTMP,rMEMP3,127
std rCHR,-8(rMEMP3)
beq L(nzCacheAligned)
addi rLEN,rLEN,-32
std rCHR,0(rMEMP3)
addi rMEMP,rMEMP,32
std rCHR,8(rMEMP3)
andi. rTMP,rMEMP,127
std rCHR,16(rMEMP3)
std rCHR,24(rMEMP3)
beq L(nzCacheAligned)
addi rLEN,rLEN,-32
std rCHR,32(rMEMP3)
addi rMEMP,rMEMP,32
cmpldi cr1,rLEN,128
std rCHR,40(rMEMP3)
cmpldi cr6,rLEN,256
li rMEMP2,128
std rCHR,48(rMEMP3)
std rCHR,56(rMEMP3)
blt cr1,L(cacheAligned1)
b L(nzCacheAligned128)
/* Now we are aligned to the cache line and can use dcbtst. */
.align 4
L(nzCacheAligned):
cmpldi cr1,rLEN,128
blt cr1,L(cacheAligned1)
b L(nzCacheAligned128)
.align 5
L(nzCacheAligned128):
cmpldi cr1,rLEN,256
addi rMEMP3,rMEMP,64
std rCHR,0(rMEMP)
std rCHR,8(rMEMP)
std rCHR,16(rMEMP)
std rCHR,24(rMEMP)
std rCHR,32(rMEMP)
std rCHR,40(rMEMP)
std rCHR,48(rMEMP)
std rCHR,56(rMEMP)
addi rMEMP,rMEMP3,64
addi rLEN,rLEN,-128
std rCHR,0(rMEMP3)
std rCHR,8(rMEMP3)
std rCHR,16(rMEMP3)
std rCHR,24(rMEMP3)
std rCHR,32(rMEMP3)
std rCHR,40(rMEMP3)
std rCHR,48(rMEMP3)
std rCHR,56(rMEMP3)
bge cr1,L(nzCacheAligned128)
dcbtst 0,rMEMP
b L(cacheAligned1)
.align 5
/* Storing a zero "c" value. We are aligned at a sector (32-byte)
boundary but may not be at cache line (128-byte) boundary. If the
remaining length spans a full cache line we can use the Data cache
block zero instruction. */
L(zloopstart):
/* memset in 32-byte chunks until we get to a cache line boundary.
If rLEN is less then the distance to the next cache-line boundary use
cacheAligned1 code to finish the tail. */
cmpldi cr1,rLEN,128
beq L(medium)
L(getCacheAligned):
andi. rTMP,rMEMP,127
nop
blt cr1,L(cacheAligned1)
addi rMEMP3,rMEMP,32
beq L(cacheAligned)
addi rLEN,rLEN,-32
std rCHR,0(rMEMP)
std rCHR,8(rMEMP)
std rCHR,16(rMEMP)
addi rMEMP,rMEMP,32
andi. rTMP,rMEMP3,127
std rCHR,-8(rMEMP3)
L(getCacheAligned2):
beq L(cacheAligned)
addi rLEN,rLEN,-32
std rCHR,0(rMEMP3)
std rCHR,8(rMEMP3)
addi rMEMP,rMEMP,32
andi. rTMP,rMEMP,127
std rCHR,16(rMEMP3)
std rCHR,24(rMEMP3)
L(getCacheAligned3):
beq L(cacheAligned)
addi rLEN,rLEN,-32
std rCHR,32(rMEMP3)
addi rMEMP,rMEMP,32
cmpldi cr1,rLEN,128
std rCHR,40(rMEMP3)
cmpldi cr6,rLEN,256
li rMEMP2,128
std rCHR,48(rMEMP3)
std rCHR,56(rMEMP3)
blt cr1,L(cacheAligned1)
blt cr6,L(cacheAligned128)
b L(cacheAlignedx)
/* Now we are aligned to the cache line and can use dcbz. */
.align 5
L(cacheAligned):
cmpldi cr1,rLEN,128
cmpldi cr6,rLEN,256
blt cr1,L(cacheAligned1)
li rMEMP2,128
L(cacheAlignedx):
cmpldi cr5,rLEN,640
blt cr6,L(cacheAligned128)
bgt cr5,L(cacheAligned512)
cmpldi cr6,rLEN,512
dcbz 0,rMEMP
cmpldi cr1,rLEN,384
dcbz rMEMP2,rMEMP
addi rMEMP,rMEMP,256
addi rLEN,rLEN,-256
blt cr1,L(cacheAligned1)
blt cr6,L(cacheAligned128)
b L(cacheAligned256)
.align 5
/* A simple loop for the longer (>640 bytes) lengths. This form limits
the branch miss-predicted to exactly 1 at loop exit.*/
L(cacheAligned512):
cmpli cr1,rLEN,128
blt cr1,L(cacheAligned1)
dcbz 0,rMEMP
addi rLEN,rLEN,-128
addi rMEMP,rMEMP,128
b L(cacheAligned512)
.align 5
L(cacheAligned256):
cmpldi cr6,rLEN,512
dcbz 0,rMEMP
cmpldi cr1,rLEN,384
dcbz rMEMP2,rMEMP
addi rMEMP,rMEMP,256
addi rLEN,rLEN,-256
bge cr6,L(cacheAligned256)
blt cr1,L(cacheAligned1)
.align 4
L(cacheAligned128):
dcbz 0,rMEMP
addi rMEMP,rMEMP,128
addi rLEN,rLEN,-128
nop
L(cacheAligned1):
cmpldi cr1,rLEN,32
blt cr1,L(handletail32)
addi rMEMP3,rMEMP,32
addi rLEN,rLEN,-32
std rCHR,0(rMEMP)
std rCHR,8(rMEMP)
std rCHR,16(rMEMP)
addi rMEMP,rMEMP,32
cmpldi cr1,rLEN,32
std rCHR,-8(rMEMP3)
L(cacheAligned2):
blt cr1,L(handletail32)
addi rLEN,rLEN,-32
std rCHR,0(rMEMP3)
std rCHR,8(rMEMP3)
addi rMEMP,rMEMP,32
cmpldi cr1,rLEN,32
std rCHR,16(rMEMP3)
std rCHR,24(rMEMP3)
nop
L(cacheAligned3):
blt cr1,L(handletail32)
addi rMEMP,rMEMP,32
addi rLEN,rLEN,-32
std rCHR,32(rMEMP3)
std rCHR,40(rMEMP3)
std rCHR,48(rMEMP3)
std rCHR,56(rMEMP3)
/* We are here because the length or remainder (rLEN) is less than the
cache line/sector size and does not justify aggressive loop unrolling.
So set up the preconditions for L(medium) and go there. */
.align 3
L(handletail32):
cmpldi cr1,rLEN,0
beqlr cr1
b L(medium)
.align 5
L(small):
/* Memset of 8 bytes or less. */
cmpldi cr6, rLEN, 4
cmpldi cr5, rLEN, 1
ble cr6,L(le4)
subi rLEN, rLEN, 4
stb rCHR,0(rMEMP)
stb rCHR,1(rMEMP)
stb rCHR,2(rMEMP)
stb rCHR,3(rMEMP)
addi rMEMP,rMEMP, 4
cmpldi cr5, rLEN, 1
L(le4):
cmpldi cr1, rLEN, 3
bltlr cr5
stb rCHR, 0(rMEMP)
beqlr cr5
stb rCHR, 1(rMEMP)
bltlr cr1
stb rCHR, 2(rMEMP)
beqlr cr1
stb rCHR, 3(rMEMP)
blr
/* Memset of 0-31 bytes. */
.align 5
L(medium):
insrdi rCHR,rCHR,32,0 /* Replicate word to double word. */
cmpldi cr1, rLEN, 16
L(medium_tail2):
add rMEMP, rMEMP, rLEN
L(medium_tail):
bt- 31, L(medium_31t)
bt- 30, L(medium_30t)
L(medium_30f):
bt 29, L(medium_29t)
L(medium_29f):
bge cr1, L(medium_27t)
bflr 28
std rCHR, -8(rMEMP)
blr
L(medium_31t):
stbu rCHR, -1(rMEMP)
bf- 30, L(medium_30f)
L(medium_30t):
sthu rCHR, -2(rMEMP)
bf- 29, L(medium_29f)
L(medium_29t):
stwu rCHR, -4(rMEMP)
blt cr1, L(medium_27f)
L(medium_27t):
std rCHR, -8(rMEMP)
stdu rCHR, -16(rMEMP)
L(medium_27f):
bflr 28
L(medium_28t):
std rCHR, -8(rMEMP)
blr
END_GEN_TB (BP_SYM (memset),TB_TOCLESS)
libc_hidden_builtin_def (memset)
/* Copied from bzero.S to prevent the linker from inserting a stub
between bzero and memset. */
ENTRY (BP_SYM (__bzero))
CALL_MCOUNT 3
#if __BOUNDED_POINTERS__
mr r6,r4
li r5,0
mr r4,r3
/* Tell memset that we don't want a return value. */
li r3,0
b L(_memset)
#else
mr r5,r4
li r4,0
b L(_memset)
#endif
END_GEN_TB (BP_SYM (__bzero),TB_TOCLESS)
weak_alias (BP_SYM (__bzero), BP_SYM (bzero))