📄 unix64.s

📁 Mac OS X 10.4.9 for x86 Source Code gcc 实现源代码
💻 S
字号:
/* -----------------------------------------------------------------------   unix64.S - Copyright (c) 2002  Bo Thorsen <bo@suse.de>   x86-64 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 CYGNUS SOLUTIONS 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 __x86_64__#define LIBFFI_ASM	#include <fficonfig.h>#include <ffi.h>.text/* ffi_call_unix64 (void *args, unsigned long bytes, unsigned flags,                    void *raddr, void (*fnaddr)());   Bit o trickiness here -- ARGS+BYTES is the base of the stack frame   for this function.  This has been allocated by ffi_call.  We also   deallocate some of the stack that has been alloca'd.  */	.align	2	.globl	ffi_call_unix64        .type	ffi_call_unix64,@functionffi_call_unix64:.LUW0:	movq	(%rsp), %r10		/* Load return address.  */	leaq	(%rdi, %rsi), %rax	/* Find local stack base.  */	movq	%rdx, (%rax)		/* Save flags.  */	movq	%rcx, 8(%rax)		/* Save raddr.  */	movq	%rbp, 16(%rax)		/* Save old frame pointer.  */	movq	%r10, 24(%rax)		/* Relocate return address.  */	movq	%rax, %rbp		/* Finalize local stack frame.  */.LUW1:	movq	%rdi, %r10		/* Save a copy of the register area. */	movq	%r8, %r11		/* Save a copy of the target fn.  */	/* Load up all argument registers.  */	movq	(%r10), %rdi	movq	8(%r10), %rsi	movq	16(%r10), %rdx	movq	24(%r10), %rcx	movq	32(%r10), %r8	movq	40(%r10), %r9	movdqa	48(%r10), %xmm0	movdqa	64(%r10), %xmm1	movdqa	80(%r10), %xmm2	movdqa	96(%r10), %xmm3	movdqa	112(%r10), %xmm4	movdqa	128(%r10), %xmm5	movdqa	144(%r10), %xmm6	movdqa	160(%r10), %xmm7	/* Deallocate the reg arg area.  */	leaq	176(%r10), %rsp	/* Call the user function.  */	call	*%r11	/* Deallocate stack arg area; local stack frame in redzone.  */	leaq	24(%rbp), %rsp	movq	0(%rbp), %rcx		/* Reload flags.  */	movq	8(%rbp), %rdi		/* Reload raddr.  */	movq	16(%rbp), %rbp		/* Reload old frame pointer.  */.LUW2:	/* The first byte of the flags contains the FFI_TYPE.  */	movzbl	%cl, %r10d	leaq	.Lstore_table(%rip), %r11	movslq	(%r11, %r10, 4), %r10	addq	%r11, %r10	jmp	*%r10	.section .rodata.Lstore_table:	.long	.Lst_void-.Lstore_table		/* FFI_TYPE_VOID */	.long	.Lst_sint32-.Lstore_table	/* FFI_TYPE_INT */	.long	.Lst_float-.Lstore_table	/* FFI_TYPE_FLOAT */	.long	.Lst_double-.Lstore_table	/* FFI_TYPE_DOUBLE */	.long	.Lst_ldouble-.Lstore_table	/* FFI_TYPE_LONGDOUBLE */	.long	.Lst_uint8-.Lstore_table	/* FFI_TYPE_UINT8 */	.long	.Lst_sint8-.Lstore_table	/* FFI_TYPE_SINT8 */	.long	.Lst_uint16-.Lstore_table	/* FFI_TYPE_UINT16 */	.long	.Lst_sint16-.Lstore_table	/* FFI_TYPE_SINT16 */	.long	.Lst_uint32-.Lstore_table	/* FFI_TYPE_UINT32 */	.long	.Lst_sint32-.Lstore_table	/* FFI_TYPE_SINT32 */	.long	.Lst_int64-.Lstore_table	/* FFI_TYPE_UINT64 */	.long	.Lst_int64-.Lstore_table	/* FFI_TYPE_SINT64 */	.long	.Lst_struct-.Lstore_table	/* FFI_TYPE_STRUCT */	.long	.Lst_int64-.Lstore_table	/* FFI_TYPE_POINTER */	.text	.align 2.Lst_void:	ret	.align 2.Lst_uint8:	movzbq	%al, %rax	movq	%rax, (%rdi)	ret	.align 2.Lst_sint8:	movsbq	%al, %rax	movq	%rax, (%rdi)	ret	.align 2.Lst_uint16:	movzwq	%ax, %rax	movq	%rax, (%rdi)	.align 2.Lst_sint16:	movswq	%ax, %rax	movq	%rax, (%rdi)	ret	.align 2.Lst_uint32:	movl	%eax, %eax	movq	%rax, (%rdi)	.align 2.Lst_sint32:	cltq	movq	%rax, (%rdi)	ret	.align 2.Lst_int64:	movq	%rax, (%rdi)	ret	.align 2.Lst_float:	movss	%xmm0, (%rdi)	ret	.align 2.Lst_double:	movsd	%xmm0, (%rdi)	ret.Lst_ldouble:	fstpt	(%rdi)	ret	.align 2.Lst_struct:	leaq	-20(%rsp), %rsi		/* Scratch area in redzone.  */	/* We have to locate the values now, and since we don't want to	   write too much data into the user's return value, we spill the	   value to a 16 byte scratch area first.  Bits 8, 9, and 10	   control where the values are located.  Only one of the three	   bits will be set; see ffi_prep_cif_machdep for the pattern.  */	movd	%xmm0, %r10	movd	%xmm1, %r11	testl	$0x100, %ecx	cmovnz	%rax, %rdx	cmovnz	%r10, %rax	testl	$0x200, %ecx	cmovnz	%r10, %rdx	testl	$0x400, %ecx	cmovnz	%r10, %rax	cmovnz	%r11, %rdx	movq	%rax, (%rsi)	movq	%rdx, 8(%rsi)	/* Bits 11-31 contain the true size of the structure.  Copy from	   the scratch area to the true destination.  */	shrl	$11, %ecx	rep movsb	ret.LUW3:	.size    ffi_call_unix64,.-ffi_call_unix64	.align	2	.globl ffi_closure_unix64        .type	ffi_closure_unix64,@functionffi_closure_unix64:.LUW4:	subq	$200, %rsp.LUW5:	movq	%rdi, (%rsp)        movq    %rsi, 8(%rsp)        movq    %rdx, 16(%rsp)        movq    %rcx, 24(%rsp)        movq    %r8, 32(%rsp)        movq    %r9, 40(%rsp)	movdqa	%xmm0, 48(%rsp)	movdqa	%xmm1, 64(%rsp)	movdqa	%xmm2, 80(%rsp)	movdqa	%xmm3, 96(%rsp)	movdqa	%xmm4, 112(%rsp)	movdqa	%xmm5, 128(%rsp)	movdqa	%xmm6, 144(%rsp)	movdqa	%xmm7, 160(%rsp)	movq	%r10, %rdi	leaq	176(%rsp), %rsi	movq	%rsp, %rdx	leaq	208(%rsp), %rcx	call	ffi_closure_unix64_inner@PLT	/* Deallocate stack frame early; return value is now in redzone.  */	addq	$200, %rsp.LUW6:	/* The first byte of the return value contains the FFI_TYPE.  */	movzbl	%al, %r10d	leaq	.Lload_table(%rip), %r11	movslq	(%r11, %r10, 4), %r10	addq	%r11, %r10	jmp	*%r10	.section .rodata.Lload_table:	.long	.Lld_void-.Lload_table		/* FFI_TYPE_VOID */	.long	.Lld_int32-.Lload_table		/* FFI_TYPE_INT */	.long	.Lld_float-.Lload_table		/* FFI_TYPE_FLOAT */	.long	.Lld_double-.Lload_table	/* FFI_TYPE_DOUBLE */	.long	.Lld_ldouble-.Lload_table	/* FFI_TYPE_LONGDOUBLE */	.long	.Lld_int8-.Lload_table		/* FFI_TYPE_UINT8 */	.long	.Lld_int8-.Lload_table		/* FFI_TYPE_SINT8 */	.long	.Lld_int16-.Lload_table		/* FFI_TYPE_UINT16 */	.long	.Lld_int16-.Lload_table		/* FFI_TYPE_SINT16 */	.long	.Lld_int32-.Lload_table		/* FFI_TYPE_UINT32 */	.long	.Lld_int32-.Lload_table		/* FFI_TYPE_SINT32 */	.long	.Lld_int64-.Lload_table		/* FFI_TYPE_UINT64 */	.long	.Lld_int64-.Lload_table		/* FFI_TYPE_SINT64 */	.long	.Lld_struct-.Lload_table	/* FFI_TYPE_STRUCT */	.long	.Lld_int64-.Lload_table		/* FFI_TYPE_POINTER */	.text	.align 2.Lld_void:	ret	.align 2.Lld_int8:	movzbl	-24(%rsp), %eax	ret	.align 2.Lld_int16:	movzwl	-24(%rsp), %eax	ret	.align 2.Lld_int32:	movl	-24(%rsp), %eax	ret	.align 2.Lld_int64:	movq	-24(%rsp), %rax	ret	.align 2.Lld_float:	movss	-24(%rsp), %xmm0	ret	.align 2.Lld_double:	movsd	-24(%rsp), %xmm0	ret	.align 2.Lld_ldouble:	fldt	-24(%rsp)	ret	.align 2.Lld_struct:	/* There are four possibilities here, %rax/%rdx, %xmm0/%rax,	   %rax/%xmm0, %xmm0/%xmm1.  We collapse two by always loading	   both rdx and xmm1 with the second word.  For the remaining,	   bit 8 set means xmm0 gets the second word, and bit 9 means	   that rax gets the second word.  */	movq	-24(%rsp), %rcx	movq	-16(%rsp), %rdx	movq	-16(%rsp), %xmm1	testl	$0x100, %eax	cmovnz	%rdx, %rcx	movd	%rcx, %xmm0	testl	$0x200, %eax	movq	-24(%rsp), %rax	cmovnz	%rdx, %rax	ret.LUW7:	.size	ffi_closure_unix64,.-ffi_closure_unix64	.section	.eh_frame,"a",@progbits.Lframe1:	.long	.LECIE1-.LSCIE1		/* CIE Length */.LSCIE1:	.long	0			/* CIE Identifier Tag */	.byte	1			/* CIE Version */	.ascii "zR\0"			/* CIE Augmentation */	.uleb128 1			/* CIE Code Alignment Factor */	.sleb128 -8			/* CIE Data Alignment Factor */	.byte	0x10			/* CIE RA Column */	.uleb128 1			/* Augmentation size */	.byte	0x1b			/* FDE Encoding (pcrel sdata4) */	.byte	0xc			/* DW_CFA_def_cfa, %rsp offset 8 */	.uleb128 7	.uleb128 8	.byte	0x80+16			/* DW_CFA_offset, %rip offset 1*-8 */	.uleb128 1	.align 8.LECIE1:.LSFDE1:	.long	.LEFDE1-.LASFDE1	/* FDE Length */.LASFDE1:	.long	.LASFDE1-.Lframe1	/* FDE CIE offset */	.long	.LUW0-.			/* FDE initial location */	.long	.LUW3-.LUW0		/* FDE address range */	.uleb128 0x0			/* Augmentation size */	.byte	0x4			/* DW_CFA_advance_loc4 */	.long	.LUW1-.LUW0        /* New stack frame based off rbp.  This is a itty bit of unwind           trickery in that the CFA *has* changed.  There is no easy way           to describe it correctly on entry to the function.  Fortunately,           it doesn't matter too much since at all points we can correctly           unwind back to ffi_call.  Note that the location to which we           moved the return address is (the new) CFA-8, so from the           perspective of the unwind info, it hasn't moved.  */	.byte	0xc			/* DW_CFA_def_cfa, %rbp offset 32 */	.uleb128 6	.uleb128 32	.byte	0x80+6			/* DW_CFA_offset, %rbp offset 2*-8 */	.uleb128 2	.byte	0x4			/* DW_CFA_advance_loc4 */	.long	.LUW2-.LUW1	.byte	0xc			/* DW_CFA_def_cfa, %rsp offset 8 */	.uleb128 7	.uleb128 8	.byte	0xc0+6			/* DW_CFA_restore, %rbp */	.align 8.LEFDE1:.LSFDE3:	.long	.LEFDE3-.LASFDE3	/* FDE Length */.LASFDE3:	.long	.LASFDE3-.Lframe1	/* FDE CIE offset */	.long	.LUW4-.			/* FDE initial location */	.long	.LUW7-.LUW4		/* FDE address range */	.uleb128 0x0			/* Augmentation size */	.byte	0x4			/* DW_CFA_advance_loc4 */	.long	.LUW5-.LUW4	.byte	0xe			/* DW_CFA_def_cfa_offset */	.uleb128 208	.byte	0x4			/* DW_CFA_advance_loc4 */	.long	.LUW6-.LUW5	.byte	0xe			/* DW_CFA_def_cfa_offset */	.uleb128 8	.align 8.LEFDE3:#endif /* __x86_64__ */
⌨️ 快捷键说明

复制代码 Ctrl + C
搜索代码 Ctrl + F
全屏模式 F11
切换主题 Ctrl + Shift + D
显示快捷键 ?
增大字号 Ctrl + =
减小字号 Ctrl + -