linux_dsm_epyc7002/arch/x86/lib/checksum_32.S
Ingo Molnar 131484c8da x86/debug: Remove perpetually broken, unmaintainable dwarf annotations
So the dwarf2 annotations in low level assembly code have
become an increasing hindrance: unreadable, messy macros
mixed into some of the most security sensitive code paths
of the Linux kernel.

These debug info annotations don't even buy the upstream
kernel anything: dwarf driven stack unwinding has caused
problems in the past so it's out of tree, and the upstream
kernel only uses the much more robust framepointers based
stack unwinding method.

In addition to that there's a steady, slow bitrot going
on with these annotations, requiring frequent fixups.
There's no tooling and no functionality upstream that
keeps it correct.

So burn down the sick forest, allowing new, healthier growth:

   27 files changed, 350 insertions(+), 1101 deletions(-)

Someone who has the willingness and time to do this
properly can attempt to reintroduce dwarf debuginfo in x86
assembly code plus dwarf unwinding from first principles,
with the following conditions:

 - it should be maximally readable, and maximally low-key to
   'ordinary' code reading and maintenance.

 - find a build time method to insert dwarf annotations
   automatically in the most common cases, for pop/push
   instructions that manipulate the stack pointer. This could
   be done for example via a preprocessing step that just
   looks for common patterns - plus special annotations for
   the few cases where we want to depart from the default.
   We have hundreds of CFI annotations, so automating most of
   that makes sense.

 - it should come with build tooling checks that ensure that
   CFI annotations are sensible. We've seen such efforts from
   the framepointer side, and there's no reason it couldn't be
   done on the dwarf side.

Cc: Andy Lutomirski <luto@amacapital.net>
Cc: Borislav Petkov <bp@alien8.de>
Cc: Brian Gerst <brgerst@gmail.com>
Cc: Denys Vlasenko <dvlasenk@redhat.com>
Cc: Frédéric Weisbecker <fweisbec@gmail.com
Cc: H. Peter Anvin <hpa@zytor.com>
Cc: Jan Beulich <JBeulich@suse.com>
Cc: Josh Poimboeuf <jpoimboe@redhat.com>
Cc: Linus Torvalds <torvalds@linux-foundation.org>
Cc: Peter Zijlstra <peterz@infradead.org>
Cc: Thomas Gleixner <tglx@linutronix.de>
Cc: linux-kernel@vger.kernel.org
Signed-off-by: Ingo Molnar <mingo@kernel.org>
2015-06-02 07:57:48 +02:00

493 lines
10 KiB
ArmAsm

/*
* INET An implementation of the TCP/IP protocol suite for the LINUX
* operating system. INET is implemented using the BSD Socket
* interface as the means of communication with the user level.
*
* IP/TCP/UDP checksumming routines
*
* Authors: Jorge Cwik, <jorge@laser.satlink.net>
* Arnt Gulbrandsen, <agulbra@nvg.unit.no>
* Tom May, <ftom@netcom.com>
* Pentium Pro/II routines:
* Alexander Kjeldaas <astor@guardian.no>
* Finn Arne Gangstad <finnag@guardian.no>
* Lots of code moved from tcp.c and ip.c; see those files
* for more names.
*
* Changes: Ingo Molnar, converted csum_partial_copy() to 2.1 exception
* handling.
* Andi Kleen, add zeroing on error
* converted to pure assembler
*
* 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 <linux/linkage.h>
#include <asm/errno.h>
#include <asm/asm.h>
/*
* computes a partial checksum, e.g. for TCP/UDP fragments
*/
/*
unsigned int csum_partial(const unsigned char * buff, int len, unsigned int sum)
*/
.text
#ifndef CONFIG_X86_USE_PPRO_CHECKSUM
/*
* Experiments with Ethernet and SLIP connections show that buff
* is aligned on either a 2-byte or 4-byte boundary. We get at
* least a twofold speedup on 486 and Pentium if it is 4-byte aligned.
* Fortunately, it is easy to convert 2-byte alignment to 4-byte
* alignment for the unrolled loop.
*/
ENTRY(csum_partial)
pushl %esi
pushl %ebx
movl 20(%esp),%eax # Function arg: unsigned int sum
movl 16(%esp),%ecx # Function arg: int len
movl 12(%esp),%esi # Function arg: unsigned char *buff
testl $3, %esi # Check alignment.
jz 2f # Jump if alignment is ok.
testl $1, %esi # Check alignment.
jz 10f # Jump if alignment is boundary of 2 bytes.
# buf is odd
dec %ecx
jl 8f
movzbl (%esi), %ebx
adcl %ebx, %eax
roll $8, %eax
inc %esi
testl $2, %esi
jz 2f
10:
subl $2, %ecx # Alignment uses up two bytes.
jae 1f # Jump if we had at least two bytes.
addl $2, %ecx # ecx was < 2. Deal with it.
jmp 4f
1: movw (%esi), %bx
addl $2, %esi
addw %bx, %ax
adcl $0, %eax
2:
movl %ecx, %edx
shrl $5, %ecx
jz 2f
testl %esi, %esi
1: movl (%esi), %ebx
adcl %ebx, %eax
movl 4(%esi), %ebx
adcl %ebx, %eax
movl 8(%esi), %ebx
adcl %ebx, %eax
movl 12(%esi), %ebx
adcl %ebx, %eax
movl 16(%esi), %ebx
adcl %ebx, %eax
movl 20(%esi), %ebx
adcl %ebx, %eax
movl 24(%esi), %ebx
adcl %ebx, %eax
movl 28(%esi), %ebx
adcl %ebx, %eax
lea 32(%esi), %esi
dec %ecx
jne 1b
adcl $0, %eax
2: movl %edx, %ecx
andl $0x1c, %edx
je 4f
shrl $2, %edx # This clears CF
3: adcl (%esi), %eax
lea 4(%esi), %esi
dec %edx
jne 3b
adcl $0, %eax
4: andl $3, %ecx
jz 7f
cmpl $2, %ecx
jb 5f
movw (%esi),%cx
leal 2(%esi),%esi
je 6f
shll $16,%ecx
5: movb (%esi),%cl
6: addl %ecx,%eax
adcl $0, %eax
7:
testb $1, 12(%esp)
jz 8f
roll $8, %eax
8:
popl %ebx
popl %esi
ret
ENDPROC(csum_partial)
#else
/* Version for PentiumII/PPro */
ENTRY(csum_partial)
pushl %esi
pushl %ebx
movl 20(%esp),%eax # Function arg: unsigned int sum
movl 16(%esp),%ecx # Function arg: int len
movl 12(%esp),%esi # Function arg: const unsigned char *buf
testl $3, %esi
jnz 25f
10:
movl %ecx, %edx
movl %ecx, %ebx
andl $0x7c, %ebx
shrl $7, %ecx
addl %ebx,%esi
shrl $2, %ebx
negl %ebx
lea 45f(%ebx,%ebx,2), %ebx
testl %esi, %esi
jmp *%ebx
# Handle 2-byte-aligned regions
20: addw (%esi), %ax
lea 2(%esi), %esi
adcl $0, %eax
jmp 10b
25:
testl $1, %esi
jz 30f
# buf is odd
dec %ecx
jl 90f
movzbl (%esi), %ebx
addl %ebx, %eax
adcl $0, %eax
roll $8, %eax
inc %esi
testl $2, %esi
jz 10b
30: subl $2, %ecx
ja 20b
je 32f
addl $2, %ecx
jz 80f
movzbl (%esi),%ebx # csumming 1 byte, 2-aligned
addl %ebx, %eax
adcl $0, %eax
jmp 80f
32:
addw (%esi), %ax # csumming 2 bytes, 2-aligned
adcl $0, %eax
jmp 80f
40:
addl -128(%esi), %eax
adcl -124(%esi), %eax
adcl -120(%esi), %eax
adcl -116(%esi), %eax
adcl -112(%esi), %eax
adcl -108(%esi), %eax
adcl -104(%esi), %eax
adcl -100(%esi), %eax
adcl -96(%esi), %eax
adcl -92(%esi), %eax
adcl -88(%esi), %eax
adcl -84(%esi), %eax
adcl -80(%esi), %eax
adcl -76(%esi), %eax
adcl -72(%esi), %eax
adcl -68(%esi), %eax
adcl -64(%esi), %eax
adcl -60(%esi), %eax
adcl -56(%esi), %eax
adcl -52(%esi), %eax
adcl -48(%esi), %eax
adcl -44(%esi), %eax
adcl -40(%esi), %eax
adcl -36(%esi), %eax
adcl -32(%esi), %eax
adcl -28(%esi), %eax
adcl -24(%esi), %eax
adcl -20(%esi), %eax
adcl -16(%esi), %eax
adcl -12(%esi), %eax
adcl -8(%esi), %eax
adcl -4(%esi), %eax
45:
lea 128(%esi), %esi
adcl $0, %eax
dec %ecx
jge 40b
movl %edx, %ecx
50: andl $3, %ecx
jz 80f
# Handle the last 1-3 bytes without jumping
notl %ecx # 1->2, 2->1, 3->0, higher bits are masked
movl $0xffffff,%ebx # by the shll and shrl instructions
shll $3,%ecx
shrl %cl,%ebx
andl -128(%esi),%ebx # esi is 4-aligned so should be ok
addl %ebx,%eax
adcl $0,%eax
80:
testb $1, 12(%esp)
jz 90f
roll $8, %eax
90:
popl %ebx
popl %esi
ret
ENDPROC(csum_partial)
#endif
/*
unsigned int csum_partial_copy_generic (const char *src, char *dst,
int len, int sum, int *src_err_ptr, int *dst_err_ptr)
*/
/*
* Copy from ds while checksumming, otherwise like csum_partial
*
* The macros SRC and DST specify the type of access for the instruction.
* thus we can call a custom exception handler for all access types.
*
* FIXME: could someone double-check whether I haven't mixed up some SRC and
* DST definitions? It's damn hard to trigger all cases. I hope I got
* them all but there's no guarantee.
*/
#define SRC(y...) \
9999: y; \
_ASM_EXTABLE(9999b, 6001f)
#define DST(y...) \
9999: y; \
_ASM_EXTABLE(9999b, 6002f)
#ifndef CONFIG_X86_USE_PPRO_CHECKSUM
#define ARGBASE 16
#define FP 12
ENTRY(csum_partial_copy_generic)
subl $4,%esp
pushl %edi
pushl %esi
pushl %ebx
movl ARGBASE+16(%esp),%eax # sum
movl ARGBASE+12(%esp),%ecx # len
movl ARGBASE+4(%esp),%esi # src
movl ARGBASE+8(%esp),%edi # dst
testl $2, %edi # Check alignment.
jz 2f # Jump if alignment is ok.
subl $2, %ecx # Alignment uses up two bytes.
jae 1f # Jump if we had at least two bytes.
addl $2, %ecx # ecx was < 2. Deal with it.
jmp 4f
SRC(1: movw (%esi), %bx )
addl $2, %esi
DST( movw %bx, (%edi) )
addl $2, %edi
addw %bx, %ax
adcl $0, %eax
2:
movl %ecx, FP(%esp)
shrl $5, %ecx
jz 2f
testl %esi, %esi
SRC(1: movl (%esi), %ebx )
SRC( movl 4(%esi), %edx )
adcl %ebx, %eax
DST( movl %ebx, (%edi) )
adcl %edx, %eax
DST( movl %edx, 4(%edi) )
SRC( movl 8(%esi), %ebx )
SRC( movl 12(%esi), %edx )
adcl %ebx, %eax
DST( movl %ebx, 8(%edi) )
adcl %edx, %eax
DST( movl %edx, 12(%edi) )
SRC( movl 16(%esi), %ebx )
SRC( movl 20(%esi), %edx )
adcl %ebx, %eax
DST( movl %ebx, 16(%edi) )
adcl %edx, %eax
DST( movl %edx, 20(%edi) )
SRC( movl 24(%esi), %ebx )
SRC( movl 28(%esi), %edx )
adcl %ebx, %eax
DST( movl %ebx, 24(%edi) )
adcl %edx, %eax
DST( movl %edx, 28(%edi) )
lea 32(%esi), %esi
lea 32(%edi), %edi
dec %ecx
jne 1b
adcl $0, %eax
2: movl FP(%esp), %edx
movl %edx, %ecx
andl $0x1c, %edx
je 4f
shrl $2, %edx # This clears CF
SRC(3: movl (%esi), %ebx )
adcl %ebx, %eax
DST( movl %ebx, (%edi) )
lea 4(%esi), %esi
lea 4(%edi), %edi
dec %edx
jne 3b
adcl $0, %eax
4: andl $3, %ecx
jz 7f
cmpl $2, %ecx
jb 5f
SRC( movw (%esi), %cx )
leal 2(%esi), %esi
DST( movw %cx, (%edi) )
leal 2(%edi), %edi
je 6f
shll $16,%ecx
SRC(5: movb (%esi), %cl )
DST( movb %cl, (%edi) )
6: addl %ecx, %eax
adcl $0, %eax
7:
5000:
# Exception handler:
.section .fixup, "ax"
6001:
movl ARGBASE+20(%esp), %ebx # src_err_ptr
movl $-EFAULT, (%ebx)
# zero the complete destination - computing the rest
# is too much work
movl ARGBASE+8(%esp), %edi # dst
movl ARGBASE+12(%esp), %ecx # len
xorl %eax,%eax
rep ; stosb
jmp 5000b
6002:
movl ARGBASE+24(%esp), %ebx # dst_err_ptr
movl $-EFAULT,(%ebx)
jmp 5000b
.previous
popl %ebx
popl %esi
popl %edi
popl %ecx # equivalent to addl $4,%esp
ret
ENDPROC(csum_partial_copy_generic)
#else
/* Version for PentiumII/PPro */
#define ROUND1(x) \
SRC(movl x(%esi), %ebx ) ; \
addl %ebx, %eax ; \
DST(movl %ebx, x(%edi) ) ;
#define ROUND(x) \
SRC(movl x(%esi), %ebx ) ; \
adcl %ebx, %eax ; \
DST(movl %ebx, x(%edi) ) ;
#define ARGBASE 12
ENTRY(csum_partial_copy_generic)
pushl %ebx
pushl %edi
pushl %esi
movl ARGBASE+4(%esp),%esi #src
movl ARGBASE+8(%esp),%edi #dst
movl ARGBASE+12(%esp),%ecx #len
movl ARGBASE+16(%esp),%eax #sum
# movl %ecx, %edx
movl %ecx, %ebx
movl %esi, %edx
shrl $6, %ecx
andl $0x3c, %ebx
negl %ebx
subl %ebx, %esi
subl %ebx, %edi
lea -1(%esi),%edx
andl $-32,%edx
lea 3f(%ebx,%ebx), %ebx
testl %esi, %esi
jmp *%ebx
1: addl $64,%esi
addl $64,%edi
SRC(movb -32(%edx),%bl) ; SRC(movb (%edx),%bl)
ROUND1(-64) ROUND(-60) ROUND(-56) ROUND(-52)
ROUND (-48) ROUND(-44) ROUND(-40) ROUND(-36)
ROUND (-32) ROUND(-28) ROUND(-24) ROUND(-20)
ROUND (-16) ROUND(-12) ROUND(-8) ROUND(-4)
3: adcl $0,%eax
addl $64, %edx
dec %ecx
jge 1b
4: movl ARGBASE+12(%esp),%edx #len
andl $3, %edx
jz 7f
cmpl $2, %edx
jb 5f
SRC( movw (%esi), %dx )
leal 2(%esi), %esi
DST( movw %dx, (%edi) )
leal 2(%edi), %edi
je 6f
shll $16,%edx
5:
SRC( movb (%esi), %dl )
DST( movb %dl, (%edi) )
6: addl %edx, %eax
adcl $0, %eax
7:
.section .fixup, "ax"
6001: movl ARGBASE+20(%esp), %ebx # src_err_ptr
movl $-EFAULT, (%ebx)
# zero the complete destination (computing the rest is too much work)
movl ARGBASE+8(%esp),%edi # dst
movl ARGBASE+12(%esp),%ecx # len
xorl %eax,%eax
rep; stosb
jmp 7b
6002: movl ARGBASE+24(%esp), %ebx # dst_err_ptr
movl $-EFAULT, (%ebx)
jmp 7b
.previous
popl %esi
popl %edi
popl %ebx
ret
ENDPROC(csum_partial_copy_generic)
#undef ROUND
#undef ROUND1
#endif