glibc/sysdeps/x86_64/dl-trampoline.h

647 lines
20 KiB
C

/* PLT trampolines. x86-64 version.
Copyright (C) 2009-2017 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/>. */
#undef REGISTER_SAVE_AREA_RAW
#ifdef __ILP32__
/* X32 saves RCX, RDX, RSI, RDI, R8 and R9 plus RAX as well as VEC0 to
VEC7. */
# define REGISTER_SAVE_AREA_RAW (8 * 7 + VEC_SIZE * 8)
#else
/* X86-64 saves RCX, RDX, RSI, RDI, R8 and R9 plus RAX as well as
BND0, BND1, BND2, BND3 and VEC0 to VEC7. */
# define REGISTER_SAVE_AREA_RAW (8 * 7 + 16 * 4 + VEC_SIZE * 8)
#endif
#undef REGISTER_SAVE_AREA
#undef LOCAL_STORAGE_AREA
#undef BASE
#if DL_RUNTIME_RESOLVE_REALIGN_STACK
# define REGISTER_SAVE_AREA (REGISTER_SAVE_AREA_RAW + 8)
/* Local stack area before jumping to function address: RBX. */
# define LOCAL_STORAGE_AREA 8
# define BASE rbx
# if (REGISTER_SAVE_AREA % VEC_SIZE) != 0
# error REGISTER_SAVE_AREA must be multples of VEC_SIZE
# endif
#else
# define REGISTER_SAVE_AREA REGISTER_SAVE_AREA_RAW
/* Local stack area before jumping to function address: All saved
registers. */
# define LOCAL_STORAGE_AREA REGISTER_SAVE_AREA
# define BASE rsp
# if (REGISTER_SAVE_AREA % 16) != 8
# error REGISTER_SAVE_AREA must be odd multples of 8
# endif
#endif
.text
#ifdef _dl_runtime_resolve_opt
/* Use the smallest vector registers to preserve the full YMM/ZMM
registers to avoid SSE transition penalty. */
# if VEC_SIZE == 32
/* Check if the upper 128 bits in %ymm0 - %ymm7 registers are non-zero
and preserve %xmm0 - %xmm7 registers with the zero upper bits. Since
there is no SSE transition penalty on AVX512 processors which don't
support XGETBV with ECX == 1, _dl_runtime_resolve_avx512_slow isn't
provided. */
.globl _dl_runtime_resolve_avx_slow
.hidden _dl_runtime_resolve_avx_slow
.type _dl_runtime_resolve_avx_slow, @function
.align 16
_dl_runtime_resolve_avx_slow:
cfi_startproc
cfi_adjust_cfa_offset(16) # Incorporate PLT
vorpd %ymm0, %ymm1, %ymm8
vorpd %ymm2, %ymm3, %ymm9
vorpd %ymm4, %ymm5, %ymm10
vorpd %ymm6, %ymm7, %ymm11
vorpd %ymm8, %ymm9, %ymm9
vorpd %ymm10, %ymm11, %ymm10
vpcmpeqd %xmm8, %xmm8, %xmm8
vorpd %ymm9, %ymm10, %ymm10
vptest %ymm10, %ymm8
# Preserve %ymm0 - %ymm7 registers if the upper 128 bits of any
# %ymm0 - %ymm7 registers aren't zero.
PRESERVE_BND_REGS_PREFIX
jnc _dl_runtime_resolve_avx
# Use vzeroupper to avoid SSE transition penalty.
vzeroupper
# Preserve %xmm0 - %xmm7 registers with the zero upper 128 bits
# when the upper 128 bits of %ymm0 - %ymm7 registers are zero.
PRESERVE_BND_REGS_PREFIX
jmp _dl_runtime_resolve_sse_vex
cfi_adjust_cfa_offset(-16) # Restore PLT adjustment
cfi_endproc
.size _dl_runtime_resolve_avx_slow, .-_dl_runtime_resolve_avx_slow
# endif
/* Use XGETBV with ECX == 1 to check which bits in vector registers are
non-zero and only preserve the non-zero lower bits with zero upper
bits. */
.globl _dl_runtime_resolve_opt
.hidden _dl_runtime_resolve_opt
.type _dl_runtime_resolve_opt, @function
.align 16
_dl_runtime_resolve_opt:
cfi_startproc
cfi_adjust_cfa_offset(16) # Incorporate PLT
pushq %rax
cfi_adjust_cfa_offset(8)
cfi_rel_offset(%rax, 0)
pushq %rcx
cfi_adjust_cfa_offset(8)
cfi_rel_offset(%rcx, 0)
pushq %rdx
cfi_adjust_cfa_offset(8)
cfi_rel_offset(%rdx, 0)
movl $1, %ecx
xgetbv
movl %eax, %r11d
popq %rdx
cfi_adjust_cfa_offset(-8)
cfi_restore (%rdx)
popq %rcx
cfi_adjust_cfa_offset(-8)
cfi_restore (%rcx)
popq %rax
cfi_adjust_cfa_offset(-8)
cfi_restore (%rax)
# if VEC_SIZE == 32
# For YMM registers, check if YMM state is in use.
andl $bit_YMM_state, %r11d
# Preserve %xmm0 - %xmm7 registers with the zero upper 128 bits if
# YMM state isn't in use.
PRESERVE_BND_REGS_PREFIX
jz _dl_runtime_resolve_sse_vex
# elif VEC_SIZE == 64
# For ZMM registers, check if YMM state and ZMM state are in
# use.
andl $(bit_YMM_state | bit_ZMM0_15_state), %r11d
cmpl $bit_YMM_state, %r11d
# Preserve %xmm0 - %xmm7 registers with the zero upper 384 bits if
# neither YMM state nor ZMM state are in use.
PRESERVE_BND_REGS_PREFIX
jl _dl_runtime_resolve_sse_vex
# Preserve %ymm0 - %ymm7 registers with the zero upper 256 bits if
# ZMM state isn't in use.
PRESERVE_BND_REGS_PREFIX
je _dl_runtime_resolve_avx
# else
# error Unsupported VEC_SIZE!
# endif
cfi_adjust_cfa_offset(-16) # Restore PLT adjustment
cfi_endproc
.size _dl_runtime_resolve_opt, .-_dl_runtime_resolve_opt
#endif
.globl _dl_runtime_resolve
.hidden _dl_runtime_resolve
.type _dl_runtime_resolve, @function
.align 16
cfi_startproc
_dl_runtime_resolve:
cfi_adjust_cfa_offset(16) # Incorporate PLT
#if DL_RUNTIME_RESOLVE_REALIGN_STACK
# if LOCAL_STORAGE_AREA != 8
# error LOCAL_STORAGE_AREA must be 8
# endif
pushq %rbx # push subtracts stack by 8.
cfi_adjust_cfa_offset(8)
cfi_rel_offset(%rbx, 0)
mov %RSP_LP, %RBX_LP
cfi_def_cfa_register(%rbx)
and $-VEC_SIZE, %RSP_LP
#endif
sub $REGISTER_SAVE_AREA, %RSP_LP
#if !DL_RUNTIME_RESOLVE_REALIGN_STACK
cfi_adjust_cfa_offset(REGISTER_SAVE_AREA)
#endif
# Preserve registers otherwise clobbered.
movq %rax, REGISTER_SAVE_RAX(%rsp)
movq %rcx, REGISTER_SAVE_RCX(%rsp)
movq %rdx, REGISTER_SAVE_RDX(%rsp)
movq %rsi, REGISTER_SAVE_RSI(%rsp)
movq %rdi, REGISTER_SAVE_RDI(%rsp)
movq %r8, REGISTER_SAVE_R8(%rsp)
movq %r9, REGISTER_SAVE_R9(%rsp)
VMOV %VEC(0), (REGISTER_SAVE_VEC_OFF)(%rsp)
VMOV %VEC(1), (REGISTER_SAVE_VEC_OFF + VEC_SIZE)(%rsp)
VMOV %VEC(2), (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 2)(%rsp)
VMOV %VEC(3), (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 3)(%rsp)
VMOV %VEC(4), (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 4)(%rsp)
VMOV %VEC(5), (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 5)(%rsp)
VMOV %VEC(6), (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 6)(%rsp)
VMOV %VEC(7), (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 7)(%rsp)
#ifndef __ILP32__
# We also have to preserve bound registers. These are nops if
# Intel MPX isn't available or disabled.
# ifdef HAVE_MPX_SUPPORT
bndmov %bnd0, REGISTER_SAVE_BND0(%rsp)
bndmov %bnd1, REGISTER_SAVE_BND1(%rsp)
bndmov %bnd2, REGISTER_SAVE_BND2(%rsp)
bndmov %bnd3, REGISTER_SAVE_BND3(%rsp)
# else
# if REGISTER_SAVE_BND0 == 0
.byte 0x66,0x0f,0x1b,0x04,0x24
# else
.byte 0x66,0x0f,0x1b,0x44,0x24,REGISTER_SAVE_BND0
# endif
.byte 0x66,0x0f,0x1b,0x4c,0x24,REGISTER_SAVE_BND1
.byte 0x66,0x0f,0x1b,0x54,0x24,REGISTER_SAVE_BND2
.byte 0x66,0x0f,0x1b,0x5c,0x24,REGISTER_SAVE_BND3
# endif
#endif
# Copy args pushed by PLT in register.
# %rdi: link_map, %rsi: reloc_index
mov (LOCAL_STORAGE_AREA + 8)(%BASE), %RSI_LP
mov LOCAL_STORAGE_AREA(%BASE), %RDI_LP
call _dl_fixup # Call resolver.
mov %RAX_LP, %R11_LP # Save return value
#ifndef __ILP32__
# Restore bound registers. These are nops if Intel MPX isn't
# avaiable or disabled.
# ifdef HAVE_MPX_SUPPORT
bndmov REGISTER_SAVE_BND3(%rsp), %bnd3
bndmov REGISTER_SAVE_BND2(%rsp), %bnd2
bndmov REGISTER_SAVE_BND1(%rsp), %bnd1
bndmov REGISTER_SAVE_BND0(%rsp), %bnd0
# else
.byte 0x66,0x0f,0x1a,0x5c,0x24,REGISTER_SAVE_BND3
.byte 0x66,0x0f,0x1a,0x54,0x24,REGISTER_SAVE_BND2
.byte 0x66,0x0f,0x1a,0x4c,0x24,REGISTER_SAVE_BND1
# if REGISTER_SAVE_BND0 == 0
.byte 0x66,0x0f,0x1a,0x04,0x24
# else
.byte 0x66,0x0f,0x1a,0x44,0x24,REGISTER_SAVE_BND0
# endif
# endif
#endif
# Get register content back.
movq REGISTER_SAVE_R9(%rsp), %r9
movq REGISTER_SAVE_R8(%rsp), %r8
movq REGISTER_SAVE_RDI(%rsp), %rdi
movq REGISTER_SAVE_RSI(%rsp), %rsi
movq REGISTER_SAVE_RDX(%rsp), %rdx
movq REGISTER_SAVE_RCX(%rsp), %rcx
movq REGISTER_SAVE_RAX(%rsp), %rax
VMOV (REGISTER_SAVE_VEC_OFF)(%rsp), %VEC(0)
VMOV (REGISTER_SAVE_VEC_OFF + VEC_SIZE)(%rsp), %VEC(1)
VMOV (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 2)(%rsp), %VEC(2)
VMOV (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 3)(%rsp), %VEC(3)
VMOV (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 4)(%rsp), %VEC(4)
VMOV (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 5)(%rsp), %VEC(5)
VMOV (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 6)(%rsp), %VEC(6)
VMOV (REGISTER_SAVE_VEC_OFF + VEC_SIZE * 7)(%rsp), %VEC(7)
#if DL_RUNTIME_RESOLVE_REALIGN_STACK
mov %RBX_LP, %RSP_LP
cfi_def_cfa_register(%rsp)
movq (%rsp), %rbx
cfi_restore(%rbx)
#endif
# Adjust stack(PLT did 2 pushes)
add $(LOCAL_STORAGE_AREA + 16), %RSP_LP
cfi_adjust_cfa_offset(-(LOCAL_STORAGE_AREA + 16))
# Preserve bound registers.
PRESERVE_BND_REGS_PREFIX
jmp *%r11 # Jump to function address.
cfi_endproc
.size _dl_runtime_resolve, .-_dl_runtime_resolve
/* To preserve %xmm0 - %xmm7 registers, dl-trampoline.h is included
twice, for _dl_runtime_resolve_sse and _dl_runtime_resolve_sse_vex.
But we don't need another _dl_runtime_profile for XMM registers. */
#if !defined PROF && defined _dl_runtime_profile
# if (LR_VECTOR_OFFSET % VEC_SIZE) != 0
# error LR_VECTOR_OFFSET must be multples of VEC_SIZE
# endif
.globl _dl_runtime_profile
.hidden _dl_runtime_profile
.type _dl_runtime_profile, @function
.align 16
_dl_runtime_profile:
cfi_startproc
cfi_adjust_cfa_offset(16) # Incorporate PLT
/* The La_x86_64_regs data structure pointed to by the
fourth paramater must be VEC_SIZE-byte aligned. This must
be explicitly enforced. We have the set up a dynamically
sized stack frame. %rbx points to the top half which
has a fixed size and preserves the original stack pointer. */
sub $32, %RSP_LP # Allocate the local storage.
cfi_adjust_cfa_offset(32)
movq %rbx, (%rsp)
cfi_rel_offset(%rbx, 0)
/* On the stack:
56(%rbx) parameter #1
48(%rbx) return address
40(%rbx) reloc index
32(%rbx) link_map
24(%rbx) La_x86_64_regs pointer
16(%rbx) framesize
8(%rbx) rax
(%rbx) rbx
*/
movq %rax, 8(%rsp)
mov %RSP_LP, %RBX_LP
cfi_def_cfa_register(%rbx)
/* Actively align the La_x86_64_regs structure. */
and $-VEC_SIZE, %RSP_LP
/* sizeof(La_x86_64_regs). Need extra space for 8 SSE registers
to detect if any xmm0-xmm7 registers are changed by audit
module. */
sub $(LR_SIZE + XMM_SIZE*8), %RSP_LP
movq %rsp, 24(%rbx)
/* Fill the La_x86_64_regs structure. */
movq %rdx, LR_RDX_OFFSET(%rsp)
movq %r8, LR_R8_OFFSET(%rsp)
movq %r9, LR_R9_OFFSET(%rsp)
movq %rcx, LR_RCX_OFFSET(%rsp)
movq %rsi, LR_RSI_OFFSET(%rsp)
movq %rdi, LR_RDI_OFFSET(%rsp)
movq %rbp, LR_RBP_OFFSET(%rsp)
lea 48(%rbx), %RAX_LP
movq %rax, LR_RSP_OFFSET(%rsp)
/* We always store the XMM registers even if AVX is available.
This is to provide backward binary compatibility for existing
audit modules. */
movaps %xmm0, (LR_XMM_OFFSET)(%rsp)
movaps %xmm1, (LR_XMM_OFFSET + XMM_SIZE)(%rsp)
movaps %xmm2, (LR_XMM_OFFSET + XMM_SIZE*2)(%rsp)
movaps %xmm3, (LR_XMM_OFFSET + XMM_SIZE*3)(%rsp)
movaps %xmm4, (LR_XMM_OFFSET + XMM_SIZE*4)(%rsp)
movaps %xmm5, (LR_XMM_OFFSET + XMM_SIZE*5)(%rsp)
movaps %xmm6, (LR_XMM_OFFSET + XMM_SIZE*6)(%rsp)
movaps %xmm7, (LR_XMM_OFFSET + XMM_SIZE*7)(%rsp)
# ifndef __ILP32__
# ifdef HAVE_MPX_SUPPORT
bndmov %bnd0, (LR_BND_OFFSET)(%rsp) # Preserve bound
bndmov %bnd1, (LR_BND_OFFSET + BND_SIZE)(%rsp) # registers. Nops if
bndmov %bnd2, (LR_BND_OFFSET + BND_SIZE*2)(%rsp) # MPX not available
bndmov %bnd3, (LR_BND_OFFSET + BND_SIZE*3)(%rsp) # or disabled.
# else
.byte 0x66,0x0f,0x1b,0x84,0x24;.long (LR_BND_OFFSET)
.byte 0x66,0x0f,0x1b,0x8c,0x24;.long (LR_BND_OFFSET + BND_SIZE)
.byte 0x66,0x0f,0x1b,0x94,0x24;.long (LR_BND_OFFSET + BND_SIZE*2)
.byte 0x66,0x0f,0x1b,0x9c,0x24;.long (LR_BND_OFFSET + BND_SIZE*3)
# endif
# endif
# ifdef RESTORE_AVX
/* This is to support AVX audit modules. */
VMOVA %VEC(0), (LR_VECTOR_OFFSET)(%rsp)
VMOVA %VEC(1), (LR_VECTOR_OFFSET + VECTOR_SIZE)(%rsp)
VMOVA %VEC(2), (LR_VECTOR_OFFSET + VECTOR_SIZE*2)(%rsp)
VMOVA %VEC(3), (LR_VECTOR_OFFSET + VECTOR_SIZE*3)(%rsp)
VMOVA %VEC(4), (LR_VECTOR_OFFSET + VECTOR_SIZE*4)(%rsp)
VMOVA %VEC(5), (LR_VECTOR_OFFSET + VECTOR_SIZE*5)(%rsp)
VMOVA %VEC(6), (LR_VECTOR_OFFSET + VECTOR_SIZE*6)(%rsp)
VMOVA %VEC(7), (LR_VECTOR_OFFSET + VECTOR_SIZE*7)(%rsp)
/* Save xmm0-xmm7 registers to detect if any of them are
changed by audit module. */
vmovdqa %xmm0, (LR_SIZE)(%rsp)
vmovdqa %xmm1, (LR_SIZE + XMM_SIZE)(%rsp)
vmovdqa %xmm2, (LR_SIZE + XMM_SIZE*2)(%rsp)
vmovdqa %xmm3, (LR_SIZE + XMM_SIZE*3)(%rsp)
vmovdqa %xmm4, (LR_SIZE + XMM_SIZE*4)(%rsp)
vmovdqa %xmm5, (LR_SIZE + XMM_SIZE*5)(%rsp)
vmovdqa %xmm6, (LR_SIZE + XMM_SIZE*6)(%rsp)
vmovdqa %xmm7, (LR_SIZE + XMM_SIZE*7)(%rsp)
# endif
mov %RSP_LP, %RCX_LP # La_x86_64_regs pointer to %rcx.
mov 48(%rbx), %RDX_LP # Load return address if needed.
mov 40(%rbx), %RSI_LP # Copy args pushed by PLT in register.
mov 32(%rbx), %RDI_LP # %rdi: link_map, %rsi: reloc_index
lea 16(%rbx), %R8_LP # Address of framesize
call _dl_profile_fixup # Call resolver.
mov %RAX_LP, %R11_LP # Save return value.
movq 8(%rbx), %rax # Get back register content.
movq LR_RDX_OFFSET(%rsp), %rdx
movq LR_R8_OFFSET(%rsp), %r8
movq LR_R9_OFFSET(%rsp), %r9
movaps (LR_XMM_OFFSET)(%rsp), %xmm0
movaps (LR_XMM_OFFSET + XMM_SIZE)(%rsp), %xmm1
movaps (LR_XMM_OFFSET + XMM_SIZE*2)(%rsp), %xmm2
movaps (LR_XMM_OFFSET + XMM_SIZE*3)(%rsp), %xmm3
movaps (LR_XMM_OFFSET + XMM_SIZE*4)(%rsp), %xmm4
movaps (LR_XMM_OFFSET + XMM_SIZE*5)(%rsp), %xmm5
movaps (LR_XMM_OFFSET + XMM_SIZE*6)(%rsp), %xmm6
movaps (LR_XMM_OFFSET + XMM_SIZE*7)(%rsp), %xmm7
# ifdef RESTORE_AVX
/* Check if any xmm0-xmm7 registers are changed by audit
module. */
vpcmpeqq (LR_SIZE)(%rsp), %xmm0, %xmm8
vpmovmskb %xmm8, %esi
cmpl $0xffff, %esi
je 2f
vmovdqa %xmm0, (LR_VECTOR_OFFSET)(%rsp)
jmp 1f
2: VMOVA (LR_VECTOR_OFFSET)(%rsp), %VEC(0)
vmovdqa %xmm0, (LR_XMM_OFFSET)(%rsp)
1: vpcmpeqq (LR_SIZE + XMM_SIZE)(%rsp), %xmm1, %xmm8
vpmovmskb %xmm8, %esi
cmpl $0xffff, %esi
je 2f
vmovdqa %xmm1, (LR_VECTOR_OFFSET + VECTOR_SIZE)(%rsp)
jmp 1f
2: VMOVA (LR_VECTOR_OFFSET + VECTOR_SIZE)(%rsp), %VEC(1)
vmovdqa %xmm1, (LR_XMM_OFFSET + XMM_SIZE)(%rsp)
1: vpcmpeqq (LR_SIZE + XMM_SIZE*2)(%rsp), %xmm2, %xmm8
vpmovmskb %xmm8, %esi
cmpl $0xffff, %esi
je 2f
vmovdqa %xmm2, (LR_VECTOR_OFFSET + VECTOR_SIZE*2)(%rsp)
jmp 1f
2: VMOVA (LR_VECTOR_OFFSET + VECTOR_SIZE*2)(%rsp), %VEC(2)
vmovdqa %xmm2, (LR_XMM_OFFSET + XMM_SIZE*2)(%rsp)
1: vpcmpeqq (LR_SIZE + XMM_SIZE*3)(%rsp), %xmm3, %xmm8
vpmovmskb %xmm8, %esi
cmpl $0xffff, %esi
je 2f
vmovdqa %xmm3, (LR_VECTOR_OFFSET + VECTOR_SIZE*3)(%rsp)
jmp 1f
2: VMOVA (LR_VECTOR_OFFSET + VECTOR_SIZE*3)(%rsp), %VEC(3)
vmovdqa %xmm3, (LR_XMM_OFFSET + XMM_SIZE*3)(%rsp)
1: vpcmpeqq (LR_SIZE + XMM_SIZE*4)(%rsp), %xmm4, %xmm8
vpmovmskb %xmm8, %esi
cmpl $0xffff, %esi
je 2f
vmovdqa %xmm4, (LR_VECTOR_OFFSET + VECTOR_SIZE*4)(%rsp)
jmp 1f
2: VMOVA (LR_VECTOR_OFFSET + VECTOR_SIZE*4)(%rsp), %VEC(4)
vmovdqa %xmm4, (LR_XMM_OFFSET + XMM_SIZE*4)(%rsp)
1: vpcmpeqq (LR_SIZE + XMM_SIZE*5)(%rsp), %xmm5, %xmm8
vpmovmskb %xmm8, %esi
cmpl $0xffff, %esi
je 2f
vmovdqa %xmm5, (LR_VECTOR_OFFSET + VECTOR_SIZE*5)(%rsp)
jmp 1f
2: VMOVA (LR_VECTOR_OFFSET + VECTOR_SIZE*5)(%rsp), %VEC(5)
vmovdqa %xmm5, (LR_XMM_OFFSET + XMM_SIZE*5)(%rsp)
1: vpcmpeqq (LR_SIZE + XMM_SIZE*6)(%rsp), %xmm6, %xmm8
vpmovmskb %xmm8, %esi
cmpl $0xffff, %esi
je 2f
vmovdqa %xmm6, (LR_VECTOR_OFFSET + VECTOR_SIZE*6)(%rsp)
jmp 1f
2: VMOVA (LR_VECTOR_OFFSET + VECTOR_SIZE*6)(%rsp), %VEC(6)
vmovdqa %xmm6, (LR_XMM_OFFSET + XMM_SIZE*6)(%rsp)
1: vpcmpeqq (LR_SIZE + XMM_SIZE*7)(%rsp), %xmm7, %xmm8
vpmovmskb %xmm8, %esi
cmpl $0xffff, %esi
je 2f
vmovdqa %xmm7, (LR_VECTOR_OFFSET + VECTOR_SIZE*7)(%rsp)
jmp 1f
2: VMOVA (LR_VECTOR_OFFSET + VECTOR_SIZE*7)(%rsp), %VEC(7)
vmovdqa %xmm7, (LR_XMM_OFFSET + XMM_SIZE*7)(%rsp)
1:
# endif
# ifndef __ILP32__
# ifdef HAVE_MPX_SUPPORT
bndmov (LR_BND_OFFSET)(%rsp), %bnd0 # Restore bound
bndmov (LR_BND_OFFSET + BND_SIZE)(%rsp), %bnd1 # registers.
bndmov (LR_BND_OFFSET + BND_SIZE*2)(%rsp), %bnd2
bndmov (LR_BND_OFFSET + BND_SIZE*3)(%rsp), %bnd3
# else
.byte 0x66,0x0f,0x1a,0x84,0x24;.long (LR_BND_OFFSET)
.byte 0x66,0x0f,0x1a,0x8c,0x24;.long (LR_BND_OFFSET + BND_SIZE)
.byte 0x66,0x0f,0x1a,0x94,0x24;.long (LR_BND_OFFSET + BND_SIZE*2)
.byte 0x66,0x0f,0x1a,0x9c,0x24;.long (LR_BND_OFFSET + BND_SIZE*3)
# endif
# endif
mov 16(%rbx), %R10_LP # Anything in framesize?
test %R10_LP, %R10_LP
PRESERVE_BND_REGS_PREFIX
jns 3f
/* There's nothing in the frame size, so there
will be no call to the _dl_call_pltexit. */
/* Get back registers content. */
movq LR_RCX_OFFSET(%rsp), %rcx
movq LR_RSI_OFFSET(%rsp), %rsi
movq LR_RDI_OFFSET(%rsp), %rdi
mov %RBX_LP, %RSP_LP
movq (%rsp), %rbx
cfi_restore(%rbx)
cfi_def_cfa_register(%rsp)
add $48, %RSP_LP # Adjust the stack to the return value
# (eats the reloc index and link_map)
cfi_adjust_cfa_offset(-48)
PRESERVE_BND_REGS_PREFIX
jmp *%r11 # Jump to function address.
3:
cfi_adjust_cfa_offset(48)
cfi_rel_offset(%rbx, 0)
cfi_def_cfa_register(%rbx)
/* At this point we need to prepare new stack for the function
which has to be called. We copy the original stack to a
temporary buffer of the size specified by the 'framesize'
returned from _dl_profile_fixup */
lea LR_RSP_OFFSET(%rbx), %RSI_LP # stack
add $8, %R10_LP
and $-16, %R10_LP
mov %R10_LP, %RCX_LP
sub %R10_LP, %RSP_LP
mov %RSP_LP, %RDI_LP
shr $3, %RCX_LP
rep
movsq
movq 24(%rdi), %rcx # Get back register content.
movq 32(%rdi), %rsi
movq 40(%rdi), %rdi
PRESERVE_BND_REGS_PREFIX
call *%r11
mov 24(%rbx), %RSP_LP # Drop the copied stack content
/* Now we have to prepare the La_x86_64_retval structure for the
_dl_call_pltexit. The La_x86_64_regs is being pointed by rsp now,
so we just need to allocate the sizeof(La_x86_64_retval) space on
the stack, since the alignment has already been taken care of. */
# ifdef RESTORE_AVX
/* sizeof(La_x86_64_retval). Need extra space for 2 SSE
registers to detect if xmm0/xmm1 registers are changed
by audit module. */
sub $(LRV_SIZE + XMM_SIZE*2), %RSP_LP
# else
sub $LRV_SIZE, %RSP_LP # sizeof(La_x86_64_retval)
# endif
mov %RSP_LP, %RCX_LP # La_x86_64_retval argument to %rcx.
/* Fill in the La_x86_64_retval structure. */
movq %rax, LRV_RAX_OFFSET(%rcx)
movq %rdx, LRV_RDX_OFFSET(%rcx)
movaps %xmm0, LRV_XMM0_OFFSET(%rcx)
movaps %xmm1, LRV_XMM1_OFFSET(%rcx)
# ifdef RESTORE_AVX
/* This is to support AVX audit modules. */
VMOVA %VEC(0), LRV_VECTOR0_OFFSET(%rcx)
VMOVA %VEC(1), LRV_VECTOR1_OFFSET(%rcx)
/* Save xmm0/xmm1 registers to detect if they are changed
by audit module. */
vmovdqa %xmm0, (LRV_SIZE)(%rcx)
vmovdqa %xmm1, (LRV_SIZE + XMM_SIZE)(%rcx)
# endif
# ifndef __ILP32__
# ifdef HAVE_MPX_SUPPORT
bndmov %bnd0, LRV_BND0_OFFSET(%rcx) # Preserve returned bounds.
bndmov %bnd1, LRV_BND1_OFFSET(%rcx)
# else
.byte 0x66,0x0f,0x1b,0x81;.long (LRV_BND0_OFFSET)
.byte 0x66,0x0f,0x1b,0x89;.long (LRV_BND1_OFFSET)
# endif
# endif
fstpt LRV_ST0_OFFSET(%rcx)
fstpt LRV_ST1_OFFSET(%rcx)
movq 24(%rbx), %rdx # La_x86_64_regs argument to %rdx.
movq 40(%rbx), %rsi # Copy args pushed by PLT in register.
movq 32(%rbx), %rdi # %rdi: link_map, %rsi: reloc_index
call _dl_call_pltexit
/* Restore return registers. */
movq LRV_RAX_OFFSET(%rsp), %rax
movq LRV_RDX_OFFSET(%rsp), %rdx
movaps LRV_XMM0_OFFSET(%rsp), %xmm0
movaps LRV_XMM1_OFFSET(%rsp), %xmm1
# ifdef RESTORE_AVX
/* Check if xmm0/xmm1 registers are changed by audit module. */
vpcmpeqq (LRV_SIZE)(%rsp), %xmm0, %xmm2
vpmovmskb %xmm2, %esi
cmpl $0xffff, %esi
jne 1f
VMOVA LRV_VECTOR0_OFFSET(%rsp), %VEC(0)
1: vpcmpeqq (LRV_SIZE + XMM_SIZE)(%rsp), %xmm1, %xmm2
vpmovmskb %xmm2, %esi
cmpl $0xffff, %esi
jne 1f
VMOVA LRV_VECTOR1_OFFSET(%rsp), %VEC(1)
1:
# endif
# ifndef __ILP32__
# ifdef HAVE_MPX_SUPPORT
bndmov LRV_BND0_OFFSET(%rsp), %bnd0 # Restore bound registers.
bndmov LRV_BND1_OFFSET(%rsp), %bnd1
# else
.byte 0x66,0x0f,0x1a,0x84,0x24;.long (LRV_BND0_OFFSET)
.byte 0x66,0x0f,0x1a,0x8c,0x24;.long (LRV_BND1_OFFSET)
# endif
# endif
fldt LRV_ST1_OFFSET(%rsp)
fldt LRV_ST0_OFFSET(%rsp)
mov %RBX_LP, %RSP_LP
movq (%rsp), %rbx
cfi_restore(%rbx)
cfi_def_cfa_register(%rsp)
add $48, %RSP_LP # Adjust the stack to the return value
# (eats the reloc index and link_map)
cfi_adjust_cfa_offset(-48)
PRESERVE_BND_REGS_PREFIX
retq
cfi_endproc
.size _dl_runtime_profile, .-_dl_runtime_profile
#endif