linux_dsm_epyc7002/arch/powerpc/lib/copy_32.S
LEROY Christophe 400c47d81c powerpc32: memset: only use dcbz once cache is enabled
memset() uses instruction dcbz to speed up clearing by not wasting time
loading cache line with data that will be overwritten.
Some platform like mpc52xx do no have cache active at startup and
can therefore not use memset(). Allthough no part of the code
explicitly uses memset(), GCC may make calls to it.

This patch modifies memset() such that at startup, memset()
unconditionally skip the optimised bloc that uses dcbz instruction.

Once the initial MMU is set up, in machine_init() we patch memset()
by replacing this inconditional jump by a NOP

Tested-by: Thomas Gleixner <tglx@linutronix.de>
Signed-off-by: Christophe Leroy <christophe.leroy@c-s.fr>
Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2015-09-17 10:36:53 +10:00

510 lines
9.5 KiB
ArmAsm

/*
* Memory copy functions for 32-bit PowerPC.
*
* Copyright (C) 1996-2005 Paul Mackerras.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*/
#include <asm/processor.h>
#include <asm/cache.h>
#include <asm/errno.h>
#include <asm/ppc_asm.h>
#define COPY_16_BYTES \
lwz r7,4(r4); \
lwz r8,8(r4); \
lwz r9,12(r4); \
lwzu r10,16(r4); \
stw r7,4(r6); \
stw r8,8(r6); \
stw r9,12(r6); \
stwu r10,16(r6)
#define COPY_16_BYTES_WITHEX(n) \
8 ## n ## 0: \
lwz r7,4(r4); \
8 ## n ## 1: \
lwz r8,8(r4); \
8 ## n ## 2: \
lwz r9,12(r4); \
8 ## n ## 3: \
lwzu r10,16(r4); \
8 ## n ## 4: \
stw r7,4(r6); \
8 ## n ## 5: \
stw r8,8(r6); \
8 ## n ## 6: \
stw r9,12(r6); \
8 ## n ## 7: \
stwu r10,16(r6)
#define COPY_16_BYTES_EXCODE(n) \
9 ## n ## 0: \
addi r5,r5,-(16 * n); \
b 104f; \
9 ## n ## 1: \
addi r5,r5,-(16 * n); \
b 105f; \
.section __ex_table,"a"; \
.align 2; \
.long 8 ## n ## 0b,9 ## n ## 0b; \
.long 8 ## n ## 1b,9 ## n ## 0b; \
.long 8 ## n ## 2b,9 ## n ## 0b; \
.long 8 ## n ## 3b,9 ## n ## 0b; \
.long 8 ## n ## 4b,9 ## n ## 1b; \
.long 8 ## n ## 5b,9 ## n ## 1b; \
.long 8 ## n ## 6b,9 ## n ## 1b; \
.long 8 ## n ## 7b,9 ## n ## 1b; \
.text
.text
.stabs "arch/powerpc/lib/",N_SO,0,0,0f
.stabs "copy_32.S",N_SO,0,0,0f
0:
CACHELINE_BYTES = L1_CACHE_BYTES
LG_CACHELINE_BYTES = L1_CACHE_SHIFT
CACHELINE_MASK = (L1_CACHE_BYTES-1)
/*
* Use dcbz on the complete cache lines in the destination
* to set them to zero. This requires that the destination
* area is cacheable. -- paulus
*
* During early init, cache might not be active yet, so dcbz cannot be used.
* We therefore skip the optimised bloc that uses dcbz. This jump is
* replaced by a nop once cache is active. This is done in machine_init()
*/
_GLOBAL(memset)
rlwimi r4,r4,8,16,23
rlwimi r4,r4,16,0,15
addi r6,r3,-4
cmplwi 0,r5,4
blt 7f
stwu r4,4(r6)
beqlr
andi. r0,r6,3
add r5,r0,r5
subf r6,r0,r6
cmplwi 0,r4,0
bne 2f /* Use normal procedure if r4 is not zero */
_GLOBAL(memset_nocache_branch)
b 2f /* Skip optimised bloc until cache is enabled */
clrlwi r7,r6,32-LG_CACHELINE_BYTES
add r8,r7,r5
srwi r9,r8,LG_CACHELINE_BYTES
addic. r9,r9,-1 /* total number of complete cachelines */
ble 2f
xori r0,r7,CACHELINE_MASK & ~3
srwi. r0,r0,2
beq 3f
mtctr r0
4: stwu r4,4(r6)
bdnz 4b
3: mtctr r9
li r7,4
10: dcbz r7,r6
addi r6,r6,CACHELINE_BYTES
bdnz 10b
clrlwi r5,r8,32-LG_CACHELINE_BYTES
addi r5,r5,4
2: srwi r0,r5,2
mtctr r0
bdz 6f
1: stwu r4,4(r6)
bdnz 1b
6: andi. r5,r5,3
7: cmpwi 0,r5,0
beqlr
mtctr r5
addi r6,r6,3
8: stbu r4,1(r6)
bdnz 8b
blr
/*
* This version uses dcbz on the complete cache lines in the
* destination area to reduce memory traffic. This requires that
* the destination area is cacheable.
* We only use this version if the source and dest don't overlap.
* -- paulus.
*
* During early init, cache might not be active yet, so dcbz cannot be used.
* We therefore jump to generic_memcpy which doesn't use dcbz. This jump is
* replaced by a nop once cache is active. This is done in machine_init()
*/
_GLOBAL(memmove)
cmplw 0,r3,r4
bgt backwards_memcpy
/* fall through */
_GLOBAL(memcpy)
b generic_memcpy
add r7,r3,r5 /* test if the src & dst overlap */
add r8,r4,r5
cmplw 0,r4,r7
cmplw 1,r3,r8
crand 0,0,4 /* cr0.lt &= cr1.lt */
blt generic_memcpy /* if regions overlap */
addi r4,r4,-4
addi r6,r3,-4
neg r0,r3
andi. r0,r0,CACHELINE_MASK /* # bytes to start of cache line */
beq 58f
cmplw 0,r5,r0 /* is this more than total to do? */
blt 63f /* if not much to do */
andi. r8,r0,3 /* get it word-aligned first */
subf r5,r0,r5
mtctr r8
beq+ 61f
70: lbz r9,4(r4) /* do some bytes */
addi r4,r4,1
addi r6,r6,1
stb r9,3(r6)
bdnz 70b
61: srwi. r0,r0,2
mtctr r0
beq 58f
72: lwzu r9,4(r4) /* do some words */
stwu r9,4(r6)
bdnz 72b
58: srwi. r0,r5,LG_CACHELINE_BYTES /* # complete cachelines */
clrlwi r5,r5,32-LG_CACHELINE_BYTES
li r11,4
mtctr r0
beq 63f
53:
dcbz r11,r6
COPY_16_BYTES
#if L1_CACHE_BYTES >= 32
COPY_16_BYTES
#if L1_CACHE_BYTES >= 64
COPY_16_BYTES
COPY_16_BYTES
#if L1_CACHE_BYTES >= 128
COPY_16_BYTES
COPY_16_BYTES
COPY_16_BYTES
COPY_16_BYTES
#endif
#endif
#endif
bdnz 53b
63: srwi. r0,r5,2
mtctr r0
beq 64f
30: lwzu r0,4(r4)
stwu r0,4(r6)
bdnz 30b
64: andi. r0,r5,3
mtctr r0
beq+ 65f
addi r4,r4,3
addi r6,r6,3
40: lbzu r0,1(r4)
stbu r0,1(r6)
bdnz 40b
65: blr
_GLOBAL(generic_memcpy)
srwi. r7,r5,3
addi r6,r3,-4
addi r4,r4,-4
beq 2f /* if less than 8 bytes to do */
andi. r0,r6,3 /* get dest word aligned */
mtctr r7
bne 5f
1: lwz r7,4(r4)
lwzu r8,8(r4)
stw r7,4(r6)
stwu r8,8(r6)
bdnz 1b
andi. r5,r5,7
2: cmplwi 0,r5,4
blt 3f
lwzu r0,4(r4)
addi r5,r5,-4
stwu r0,4(r6)
3: cmpwi 0,r5,0
beqlr
mtctr r5
addi r4,r4,3
addi r6,r6,3
4: lbzu r0,1(r4)
stbu r0,1(r6)
bdnz 4b
blr
5: subfic r0,r0,4
mtctr r0
6: lbz r7,4(r4)
addi r4,r4,1
stb r7,4(r6)
addi r6,r6,1
bdnz 6b
subf r5,r0,r5
rlwinm. r7,r5,32-3,3,31
beq 2b
mtctr r7
b 1b
_GLOBAL(backwards_memcpy)
rlwinm. r7,r5,32-3,3,31 /* r0 = r5 >> 3 */
add r6,r3,r5
add r4,r4,r5
beq 2f
andi. r0,r6,3
mtctr r7
bne 5f
1: lwz r7,-4(r4)
lwzu r8,-8(r4)
stw r7,-4(r6)
stwu r8,-8(r6)
bdnz 1b
andi. r5,r5,7
2: cmplwi 0,r5,4
blt 3f
lwzu r0,-4(r4)
subi r5,r5,4
stwu r0,-4(r6)
3: cmpwi 0,r5,0
beqlr
mtctr r5
4: lbzu r0,-1(r4)
stbu r0,-1(r6)
bdnz 4b
blr
5: mtctr r0
6: lbzu r7,-1(r4)
stbu r7,-1(r6)
bdnz 6b
subf r5,r0,r5
rlwinm. r7,r5,32-3,3,31
beq 2b
mtctr r7
b 1b
_GLOBAL(__copy_tofrom_user)
addi r4,r4,-4
addi r6,r3,-4
neg r0,r3
andi. r0,r0,CACHELINE_MASK /* # bytes to start of cache line */
beq 58f
cmplw 0,r5,r0 /* is this more than total to do? */
blt 63f /* if not much to do */
andi. r8,r0,3 /* get it word-aligned first */
mtctr r8
beq+ 61f
70: lbz r9,4(r4) /* do some bytes */
71: stb r9,4(r6)
addi r4,r4,1
addi r6,r6,1
bdnz 70b
61: subf r5,r0,r5
srwi. r0,r0,2
mtctr r0
beq 58f
72: lwzu r9,4(r4) /* do some words */
73: stwu r9,4(r6)
bdnz 72b
.section __ex_table,"a"
.align 2
.long 70b,100f
.long 71b,101f
.long 72b,102f
.long 73b,103f
.text
58: srwi. r0,r5,LG_CACHELINE_BYTES /* # complete cachelines */
clrlwi r5,r5,32-LG_CACHELINE_BYTES
li r11,4
beq 63f
/* Here we decide how far ahead to prefetch the source */
li r3,4
cmpwi r0,1
li r7,0
ble 114f
li r7,1
#if MAX_COPY_PREFETCH > 1
/* Heuristically, for large transfers we prefetch
MAX_COPY_PREFETCH cachelines ahead. For small transfers
we prefetch 1 cacheline ahead. */
cmpwi r0,MAX_COPY_PREFETCH
ble 112f
li r7,MAX_COPY_PREFETCH
112: mtctr r7
111: dcbt r3,r4
addi r3,r3,CACHELINE_BYTES
bdnz 111b
#else
dcbt r3,r4
addi r3,r3,CACHELINE_BYTES
#endif /* MAX_COPY_PREFETCH > 1 */
114: subf r8,r7,r0
mr r0,r7
mtctr r8
53: dcbt r3,r4
54: dcbz r11,r6
.section __ex_table,"a"
.align 2
.long 54b,105f
.text
/* the main body of the cacheline loop */
COPY_16_BYTES_WITHEX(0)
#if L1_CACHE_BYTES >= 32
COPY_16_BYTES_WITHEX(1)
#if L1_CACHE_BYTES >= 64
COPY_16_BYTES_WITHEX(2)
COPY_16_BYTES_WITHEX(3)
#if L1_CACHE_BYTES >= 128
COPY_16_BYTES_WITHEX(4)
COPY_16_BYTES_WITHEX(5)
COPY_16_BYTES_WITHEX(6)
COPY_16_BYTES_WITHEX(7)
#endif
#endif
#endif
bdnz 53b
cmpwi r0,0
li r3,4
li r7,0
bne 114b
63: srwi. r0,r5,2
mtctr r0
beq 64f
30: lwzu r0,4(r4)
31: stwu r0,4(r6)
bdnz 30b
64: andi. r0,r5,3
mtctr r0
beq+ 65f
40: lbz r0,4(r4)
41: stb r0,4(r6)
addi r4,r4,1
addi r6,r6,1
bdnz 40b
65: li r3,0
blr
/* read fault, initial single-byte copy */
100: li r9,0
b 90f
/* write fault, initial single-byte copy */
101: li r9,1
90: subf r5,r8,r5
li r3,0
b 99f
/* read fault, initial word copy */
102: li r9,0
b 91f
/* write fault, initial word copy */
103: li r9,1
91: li r3,2
b 99f
/*
* this stuff handles faults in the cacheline loop and branches to either
* 104f (if in read part) or 105f (if in write part), after updating r5
*/
COPY_16_BYTES_EXCODE(0)
#if L1_CACHE_BYTES >= 32
COPY_16_BYTES_EXCODE(1)
#if L1_CACHE_BYTES >= 64
COPY_16_BYTES_EXCODE(2)
COPY_16_BYTES_EXCODE(3)
#if L1_CACHE_BYTES >= 128
COPY_16_BYTES_EXCODE(4)
COPY_16_BYTES_EXCODE(5)
COPY_16_BYTES_EXCODE(6)
COPY_16_BYTES_EXCODE(7)
#endif
#endif
#endif
/* read fault in cacheline loop */
104: li r9,0
b 92f
/* fault on dcbz (effectively a write fault) */
/* or write fault in cacheline loop */
105: li r9,1
92: li r3,LG_CACHELINE_BYTES
mfctr r8
add r0,r0,r8
b 106f
/* read fault in final word loop */
108: li r9,0
b 93f
/* write fault in final word loop */
109: li r9,1
93: andi. r5,r5,3
li r3,2
b 99f
/* read fault in final byte loop */
110: li r9,0
b 94f
/* write fault in final byte loop */
111: li r9,1
94: li r5,0
li r3,0
/*
* At this stage the number of bytes not copied is
* r5 + (ctr << r3), and r9 is 0 for read or 1 for write.
*/
99: mfctr r0
106: slw r3,r0,r3
add. r3,r3,r5
beq 120f /* shouldn't happen */
cmpwi 0,r9,0
bne 120f
/* for a read fault, first try to continue the copy one byte at a time */
mtctr r3
130: lbz r0,4(r4)
131: stb r0,4(r6)
addi r4,r4,1
addi r6,r6,1
bdnz 130b
/* then clear out the destination: r3 bytes starting at 4(r6) */
132: mfctr r3
srwi. r0,r3,2
li r9,0
mtctr r0
beq 113f
112: stwu r9,4(r6)
bdnz 112b
113: andi. r0,r3,3
mtctr r0
beq 120f
114: stb r9,4(r6)
addi r6,r6,1
bdnz 114b
120: blr
.section __ex_table,"a"
.align 2
.long 30b,108b
.long 31b,109b
.long 40b,110b
.long 41b,111b
.long 130b,132b
.long 131b,120b
.long 112b,120b
.long 114b,120b
.text