/* -----------------------------------------------------------------------
sysv.S - Copyright (c) 1998, 2008, 2011 Red Hat, Inc.
Copyright (c) 2011 Plausible Labs Cooperative, Inc.
ARM Foreign Function Interface
Permission is hereby granted, free of charge, to any person obtaining
a copy of this software and associated documentation files (the
``Software''), to deal in the Software without restriction, including
without limitation the rights to use, copy, modify, merge, publish,
distribute, sublicense, and/or sell copies of the Software, and to
permit persons to whom the Software is furnished to do so, subject to
the following conditions:
The above copyright notice and this permission notice shall be included
in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED ``AS IS'', WITHOUT WARRANTY OF ANY KIND,
EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
DEALINGS IN THE SOFTWARE.
----------------------------------------------------------------------- */
#ifdef __arm__
#define LIBFFI_ASM
#include <fficonfig.h>
#include <ffi.h>
#include <ffi_cfi.h>
#include "internal.h"
/* GCC 4.8 provides __ARM_ARCH; construct it otherwise. */
#ifndef __ARM_ARCH
# if defined(__ARM_ARCH_7__) || defined(__ARM_ARCH_7A__) \
|| defined(__ARM_ARCH_7R__) || defined(__ARM_ARCH_7M__) \
|| defined(__ARM_ARCH_7EM__)
# define __ARM_ARCH 7
# elif defined(__ARM_ARCH_6__) || defined(__ARM_ARCH_6J__) \
|| defined(__ARM_ARCH_6K__) || defined(__ARM_ARCH_6Z__) \
|| defined(__ARM_ARCH_6ZK__) || defined(__ARM_ARCH_6T2__) \
|| defined(__ARM_ARCH_6M__)
# define __ARM_ARCH 6
# elif defined(__ARM_ARCH_5__) || defined(__ARM_ARCH_5T__) \
|| defined(__ARM_ARCH_5E__) || defined(__ARM_ARCH_5TE__) \
|| defined(__ARM_ARCH_5TEJ__)
# define __ARM_ARCH 5
# else
# define __ARM_ARCH 4
# endif
#endif
/* Conditionally compile unwinder directives. */
#ifdef __ARM_EABI__
# define UNWIND(...) __VA_ARGS__
#else
# define UNWIND(...)
#endif
#if defined(HAVE_AS_CFI_PSEUDO_OP) && defined(__ARM_EABI__)
.cfi_sections .debug_frame
#endif
#define CONCAT(a, b) CONCAT2(a, b)
#define CONCAT2(a, b) a ## b
#ifdef __USER_LABEL_PREFIX__
# define CNAME(X) CONCAT (__USER_LABEL_PREFIX__, X)
#else
# define CNAME(X) X
#endif
#ifdef __ELF__
# define SIZE(X) .size CNAME(X), . - CNAME(X)
# define TYPE(X, Y) .type CNAME(X), Y
#else
# define SIZE(X)
# define TYPE(X, Y)
#endif
#define ARM_FUNC_START_LOCAL(name) \
.align 3; \
TYPE(CNAME(name), %function); \
CNAME(name):
#define ARM_FUNC_START(name) \
.globl CNAME(name); \
FFI_HIDDEN(CNAME(name)); \
ARM_FUNC_START_LOCAL(name)
#define ARM_FUNC_END(name) \
SIZE(name)
.text
.syntax unified
#if defined(_WIN32)
/* Windows on ARM is thumb-only */
.thumb
#else
/* Keep the assembly in ARM mode in other cases, for simplicity
* (to avoid interworking issues). */
#undef __thumb__
.arm
#endif
/* Aid in defining a jump table with 8 bytes between entries. */
#ifdef __thumb__
/* In thumb mode, instructions can be shorter than expected in arm mode, so
* we need to align the start of each case. */
# define E(index) .align 3
#elif defined(__clang__)
/* ??? The clang assembler doesn't handle .if with symbolic expressions. */
# define E(index)
#else
# define E(index) \
.if . - 0b - 8*index; \
.error "type table out of sync"; \
.endif
#endif
#ifndef __clang__
/* We require interworking on LDM, which implies ARMv5T,
which implies the existance of BLX. */
.arch armv5t
#endif
/* Note that we use STC and LDC to encode VFP instructions,
so that we do not need ".fpu vfp", nor get that added to
the object file attributes. These will not be executed
unless the FFI_VFP abi is used. */
@ r0: stack
@ r1: frame
@ r2: fn
@ r3: vfp_used
ARM_FUNC_START(ffi_call_VFP)
UNWIND(.fnstart)
cfi_startproc
cmp r3, #3 @ load only d0 if possible
ite le
#ifdef __clang__
vldrle d0, [r0]
vldmgt r0, {d0-d7}
#else
ldcle p11, cr0, [r0] @ vldrle d0, [r0]
ldcgt p11, cr0, [r0], {16} @ vldmgt r0, {d0-d7}
#endif
add r0, r0, #64 @ discard the vfp register args
/* FALLTHRU */
ARM_FUNC_END(ffi_call_VFP)
ARM_FUNC_START(ffi_call_SYSV)
stm r1, {fp, lr}
mov fp, r1
@ This is a bit of a lie wrt the origin of the unwind info, but
@ now we've got the usual frame pointer and two saved registers.
UNWIND(.save {fp,lr})
UNWIND(.setfp fp, sp)
cfi_def_cfa(fp, 8)
cfi_rel_offset(fp, 0)
cfi_rel_offset(lr, 4)
mov sp, r0 @ install the stack pointer
mov lr, r2 @ move the fn pointer out of the way
ldr ip, [fp, #16] @ install the static chain
ldmia sp!, {r0-r3} @ move first 4 parameters in registers.
blx lr @ call fn
@ Load r2 with the pointer to storage for the return value
@ Load r3 with the return type code
ldr r2, [fp, #8]
ldr r3, [fp, #12]
@ Deallocate the stack with the arguments.
mov sp, fp
cfi_def_cfa_register(sp)
@ Store values stored in registers.
#ifndef __thumb__
.align 3
add pc, pc, r3, lsl #3
nop
#else
adr ip, 0f
add ip, ip, r3, lsl #3
mov pc, ip
.align 3
#endif
0:
E(ARM_TYPE_VFP_S)
#ifdef __clang__
vstr s0, [r2]
#else
stc p10, cr0, [r2] @ vstr s0, [r2]
#endif
pop {fp,pc}
E(ARM_TYPE_VFP_D)
#ifdef __clang__
vstr d0, [r2]
#else
stc p11, cr0, [r2] @ vstr d0, [r2]
#endif
pop {fp,pc}
E(ARM_TYPE_VFP_N)
#ifdef __clang__
vstm r2, {d0-d3}
#else
stc p11, cr0, [r2], {8} @ vstm r2, {d0-d3}
#endif
pop {fp,pc}
E(ARM_TYPE_INT64)
str r1, [r2, #4]
nop
E(ARM_TYPE_INT)
str r0, [r2]
pop {fp,pc}
E(ARM_TYPE_VOID)
pop {fp,pc}
nop
E(ARM_TYPE_STRUCT)
pop {fp,pc}
cfi_endproc
UNWIND(.fnend)
ARM_FUNC_END(ffi_call_SYSV)
#if FFI_CLOSURES
/*
int ffi_closure_inner_* (cif, fun, user_data, frame)
*/
ARM_FUNC_START(ffi_go_closure_SYSV)
cfi_startproc
stmdb sp!, {r0-r3} @ save argument regs
cfi_adjust_cfa_offset(16)
ldr r0, [ip, #4] @ load cif
ldr r1, [ip, #8] @ load fun
mov r2, ip @ load user_data
b 0f
cfi_endproc
ARM_FUNC_END(ffi_go_closure_SYSV)
ARM_FUNC_START(ffi_closure_SYSV)
UNWIND(.fnstart)
cfi_startproc
#ifdef _WIN32
ldmfd sp!, {r0, ip} @ restore fp (r0 is used for stack alignment)
#endif
stmdb sp!, {r0-r3} @ save argument regs
cfi_adjust_cfa_offset(16)
#if FFI_EXEC_TRAMPOLINE_TABLE
ldr ip, [ip] @ ip points to the config page, dereference to get the ffi_closure*
#endif
ldr r0, [ip, #FFI_TRAMPOLINE_CLOSURE_OFFSET] @ load cif
ldr r1, [ip, #FFI_TRAMPOLINE_CLOSURE_OFFSET+4] @ load fun
ldr r2, [ip, #FFI_TRAMPOLINE_CLOSURE_OFFSET+8] @ load user_data
0:
add ip, sp, #16 @ compute entry sp
sub sp, sp, #64+32 @ allocate frame
cfi_adjust_cfa_offset(64+32)
stmdb sp!, {ip,lr}
/* Remember that EABI unwind info only applies at call sites.
We need do nothing except note the save of the stack pointer
and the link registers. */
UNWIND(.save {sp,lr})
cfi_adjust_cfa_offset(8)
cfi_rel_offset(lr, 4)
add r3, sp, #8 @ load frame
bl CNAME(ffi_closure_inner_SYSV)
@ Load values returned in registers.
add r2, sp, #8+64 @ load result
adr r3, CNAME(ffi_closure_ret)
#ifndef __thumb__
add pc, r3, r0, lsl #3
#else
add r3, r3, r0, lsl #3
mov pc, r3
#endif
cfi_endproc
UNWIND(.fnend)
ARM_FUNC_END(ffi_closure_SYSV)
ARM_FUNC_START(ffi_go_closure_VFP)
cfi_startproc
stmdb sp!, {r0-r3} @ save argument regs
cfi_adjust_cfa_offset(16)
ldr r0, [ip, #4] @ load cif
ldr r1, [ip, #8] @ load fun
mov r2, ip @ load user_data
b 0f
cfi_endproc
ARM_FUNC_END(ffi_go_closure_VFP)
ARM_FUNC_START(ffi_closure_VFP)
UNWIND(.fnstart)
cfi_startproc
#ifdef _WIN32
ldmfd sp!, {r0, ip} @ restore fp (r0 is used for stack alignment)
#endif
stmdb sp!, {r0-r3} @ save argument regs
cfi_adjust_cfa_offset(16)
#if FFI_EXEC_TRAMPOLINE_TABLE
ldr ip, [ip] @ ip points to the config page, dereference to get the ffi_closure*
#endif
ldr r0, [ip, #FFI_TRAMPOLINE_CLOSURE_OFFSET] @ load cif
ldr r1, [ip, #FFI_TRAMPOLINE_CLOSURE_OFFSET+4] @ load fun
ldr r2, [ip, #FFI_TRAMPOLINE_CLOSURE_OFFSET+8] @ load user_data
0:
add ip, sp, #16
sub sp, sp, #64+32 @ allocate frame
cfi_adjust_cfa_offset(64+32)
#ifdef __clang__
vstm sp, {d0-d7}
#else
stc p11, cr0, [sp], {16} @ vstm sp, {d0-d7}
#endif
stmdb sp!, {ip,lr}
/* See above. */
UNWIND(.save {sp,lr})
cfi_adjust_cfa_offset(8)
cfi_rel_offset(lr, 4)
add r3, sp, #8 @ load frame
bl CNAME(ffi_closure_inner_VFP)
@ Load values returned in registers.
add r2, sp, #8+64 @ load result
adr r3, CNAME(ffi_closure_ret)
#ifndef __thumb__
add pc, r3, r0, lsl #3
#else
add r3, r3, r0, lsl #3
mov pc, r3
#endif
cfi_endproc
UNWIND(.fnend)
ARM_FUNC_END(ffi_closure_VFP)
/* Load values returned in registers for both closure entry points.
Note that we use LDM with SP in the register set. This is deprecated
by ARM, but not yet unpredictable. */
ARM_FUNC_START_LOCAL(ffi_closure_ret)
cfi_startproc
cfi_rel_offset(sp, 0)
cfi_rel_offset(lr, 4)
0:
E(ARM_TYPE_VFP_S)
#ifdef __clang__
vldr s0, [r2]
#else
ldc p10, cr0, [r2] @ vldr s0, [r2]
#endif
b call_epilogue
E(ARM_TYPE_VFP_D)
#ifdef __clang__
vldr d0, [r2]
#else
ldc p11, cr0, [r2] @ vldr d0, [r2]
#endif
b call_epilogue
E(ARM_TYPE_VFP_N)
#ifdef __clang__
vldm r2, {d0-d3}
#else
ldc p11, cr0, [r2], {8} @ vldm r2, {d0-d3}
#endif
b call_epilogue
E(ARM_TYPE_INT64)
ldr r1, [r2, #4]
nop
E(ARM_TYPE_INT)
ldr r0, [r2]
b call_epilogue
E(ARM_TYPE_VOID)
b call_epilogue
nop
E(ARM_TYPE_STRUCT)
b call_epilogue
call_epilogue:
#ifndef __thumb__
ldm sp, {sp,pc}
#else
ldm sp, {ip,lr}
mov sp, ip
bx lr
#endif
cfi_endproc
ARM_FUNC_END(ffi_closure_ret)
#if defined(FFI_EXEC_STATIC_TRAMP)
ARM_FUNC_START(ffi_closure_SYSV_alt)
/* See the comments above trampoline_code_table. */
ldr ip, [sp, #4] /* Load closure in ip */
add sp, sp, 8 /* Restore the stack */
b CNAME(ffi_closure_SYSV)
ARM_FUNC_END(ffi_closure_SYSV_alt)
ARM_FUNC_START(ffi_closure_VFP_alt)
/* See the comments above trampoline_code_table. */
ldr ip, [sp, #4] /* Load closure in ip */
add sp, sp, 8 /* Restore the stack */
b CNAME(ffi_closure_VFP)
ARM_FUNC_END(ffi_closure_VFP_alt)
/*
* Below is the definition of the trampoline code table. Each element in
* the code table is a trampoline.
*/
/*
* The trampoline uses register ip (r12). It saves the original value of ip
* on the stack.
*
* The trampoline has two parameters - target code to jump to and data for
* the target code. The trampoline extracts the parameters from its parameter
* block (see tramp_table_map()). The trampoline saves the data address on
* the stack. Finally, it jumps to the target code.
*
* The target code can choose to:
*
* - restore the value of ip
* - load the data address in a register
* - restore the stack pointer to what it was when the trampoline was invoked.
*/
.align ARM_TRAMP_MAP_SHIFT
ARM_FUNC_START(trampoline_code_table)
.rept ARM_TRAMP_MAP_SIZE / ARM_TRAMP_SIZE
sub sp, sp, #8 /* Make space on the stack */
str ip, [sp] /* Save ip on stack */
ldr ip, [pc, #4080] /* Copy data into ip */
str ip, [sp, #4] /* Save data on stack */
ldr pc, [pc, #4076] /* Copy code into PC */
.endr
ARM_FUNC_END(trampoline_code_table)
.align ARM_TRAMP_MAP_SHIFT
#endif /* FFI_EXEC_STATIC_TRAMP */
#endif /* FFI_CLOSURES */
#if FFI_EXEC_TRAMPOLINE_TABLE
#ifdef __MACH__
#include <mach/machine/vm_param.h>
.align PAGE_MAX_SHIFT
ARM_FUNC_START(ffi_closure_trampoline_table_page)
.rept PAGE_MAX_SIZE / FFI_TRAMPOLINE_SIZE
adr ip, #-PAGE_MAX_SIZE @ the config page is PAGE_MAX_SIZE behind the trampoline page
sub ip, #8 @ account for pc bias
ldr pc, [ip, #4] @ jump to ffi_closure_SYSV or ffi_closure_VFP
.endr
ARM_FUNC_END(ffi_closure_trampoline_table_page)
#endif
#elif defined(_WIN32)
ARM_FUNC_START(ffi_arm_trampoline)
0: adr ip, 0b
stmdb sp!, {r0, ip}
ldr pc, 1f
1: .long 0
ARM_FUNC_END(ffi_arm_trampoline)
#else
ARM_FUNC_START(ffi_arm_trampoline)
0: adr ip, 0b
ldr pc, 1f
1: .long 0
ARM_FUNC_END(ffi_arm_trampoline)
#endif /* FFI_EXEC_TRAMPOLINE_TABLE */
#endif /* __arm__ */
#if defined __ELF__ && defined __linux__
.section .note.GNU-stack,"",%progbits
#endif