;; @file ; IPRT - Global YASM/NASM macros ; ; ; Copyright (C) 2006-2022 Oracle Corporation ; ; This file is part of VirtualBox Open Source Edition (OSE), as ; available from http://www.virtualbox.org. This file is free software; ; you can redistribute it and/or modify it under the terms of the GNU ; General Public License (GPL) as published by the Free Software ; Foundation, in version 2 as it comes in the "COPYING" file of the ; VirtualBox OSE distribution. VirtualBox OSE is distributed in the ; hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. ; ; The contents of this file may alternatively be used under the terms ; of the Common Development and Distribution License Version 1.0 ; (CDDL) only, as it comes in the "COPYING.CDDL" file of the ; VirtualBox OSE distribution, in which case the provisions of the ; CDDL are applicable instead of those of the GPL. ; ; You may elect to license modified versions of this file under the ; terms and conditions of either the GPL or the CDDL or both. ; ; Special hack for bs3kit. %ifdef RT_ASMDEFS_INC_FIRST_FILE %include "asmdefs-first.mac" %endif %ifndef ___iprt_asmdefs_mac %define ___iprt_asmdefs_mac ;; @defgroup grp_rt_cdefs_size Size Constants ; (Of course, these are binary computer terms, not SI.) ; @{ ;; 1 K (Kilo) (1 024). %define _1K 000000400h ;; 4 K (Kilo) (4 096). %define _4K 000001000h ;; 8 K (Kilo) (8 192). %define _8K 000002000h ;; 16 K (Kilo) (16 384). %define _16K 000004000h ;; 32 K (Kilo) (32 768). %define _32K 000008000h ;; 64 K (Kilo) (65 536). %define _64K 000010000h ;; 128 K (Kilo) (131 072). %define _128K 000020000h ;; 256 K (Kilo) (262 144). %define _256K 000040000h ;; 512 K (Kilo) (524 288). %define _512K 000080000h ;; 1 M (Mega) (1 048 576). %define _1M 000100000h ;; 2 M (Mega) (2 097 152). %define _2M 000200000h ;; 4 M (Mega) (4 194 304). %define _4M 000400000h ;; 1 G (Giga) (1 073 741 824). %define _1G 040000000h ;; 2 G (Giga) (2 147 483 648). %define _2G 00000000080000000h ;; 4 G (Giga) (4 294 967 296). %define _4G 00000000100000000h ;; 1 T (Tera) (1 099 511 627 776). %define _1T 00000010000000000h ;; 1 P (Peta) (1 125 899 906 842 624). %define _1P 00004000000000000h ;; 1 E (Exa) (1 152 921 504 606 846 976). %define _1E 01000000000000000h ;; 2 E (Exa) (2 305 843 009 213 693 952). %define _2E 02000000000000000h ;; @} ;; ; Make the mask for the given bit. %define RT_BIT(bit) (1 << bit) ;; ; Make the mask for the given bit. %define RT_BIT_32(bit) (1 << bit) ;; ; Make the mask for the given bit. %define RT_BIT_64(bit) (1 << bit) ;; ; Makes a 32-bit unsigned (not type safe, but whatever) out of four byte values. %define RT_MAKE_U32_FROM_U8(b0, b1, b2, b3) ( (b3 << 24) | (b2 << 16) | (b1 << 8) | b0 ) ;; Preprocessor concatenation macro. %define RT_CONCAT(a_1,a_2) a_1 %+ a_2 ;; Preprocessor concatenation macro, three arguments. %define RT_CONCAT3(a_1,a_2,a_3) a_1 %+ a_2 %+ a_3 ;; Preprocessor concatenation macro, four arguments. %define RT_CONCAT4(a_1,a_2,a_3,a_4) a_1 %+ a_2 %+ a_3 %+ a_4 ;; ; Trick for using RT_CONCAT and the like on %define names. ; @param 1 The name (expression. ; @param 2 The value. %macro RT_DEFINE_EX 2 %error 1=%1 2=%2 %define %1 %2 %endmacro ;; ; Trick for using RT_CONCAT and the like on %xdefine names. ; @param 1 The name (expression. ; @param 2 The value. %macro RT_XDEFINE_EX 2 %xdefine %1 %2 %endmacro ;; ; Trick for using RT_CONCAT and the like on %undef names. ; @param 1 The name (expression. %macro RT_UNDEF_EX 1 %error 1=%1 %undef %1 %endmacro ;; Define ASM_FORMAT_PE64 if applicable. %ifdef ASM_FORMAT_PE %ifdef RT_ARCH_AMD64 %define ASM_FORMAT_PE64 1 %endif %endif ;; ; SEH64 macros. %ifdef RT_ASM_WITH_SEH64 %ifndef ASM_FORMAT_PE64 %undef RT_ASM_WITH_SEH64 %endif %endif %ifdef RT_ASM_WITH_SEH64_ALT %ifdef ASM_FORMAT_PE64 ;; @name Register numbers. Used with RT_CONCAT to convert macro inputs to numbers. ;; @{ %define SEH64_PE_GREG_rax 0 %define SEH64_PE_GREG_xAX 0 %define SEH64_PE_GREG_rcx 1 %define SEH64_PE_GREG_xCX 1 %define SEH64_PE_GREG_rdx 2 %define SEH64_PE_GREG_xDX 2 %define SEH64_PE_GREG_rbx 3 %define SEH64_PE_GREG_xBX 3 %define SEH64_PE_GREG_rsp 4 %define SEH64_PE_GREG_xSP 4 %define SEH64_PE_GREG_rbp 5 %define SEH64_PE_GREG_xBP 5 %define SEH64_PE_GREG_rsi 6 %define SEH64_PE_GREG_xSI 6 %define SEH64_PE_GREG_rdi 7 %define SEH64_PE_GREG_xDI 7 %define SEH64_PE_GREG_r8 8 %define SEH64_PE_GREG_r9 9 %define SEH64_PE_GREG_r10 10 %define SEH64_PE_GREG_r11 11 %define SEH64_PE_GREG_r12 12 %define SEH64_PE_GREG_r13 13 %define SEH64_PE_GREG_r14 14 %define SEH64_PE_GREG_r15 15 ;; @} ;; @name PE unwind operations. ;; @{ %define SEH64_PE_PUSH_NONVOL 0 %define SEH64_PE_ALLOC_LARGE 1 %define SEH64_PE_ALLOC_SMALL 2 %define SEH64_PE_SET_FPREG 3 %define SEH64_PE_SAVE_NONVOL 4 %define SEH64_PE_SAVE_NONVOL_FAR 5 %define SEH64_PE_SAVE_XMM128 8 %define SEH64_PE_SAVE_XMM128_FAR 9 ;; @} ;; ; Starts the unwind info for the manual SEH64 info generation. ; @param 1 Function name. %macro SEH64_ALT_START_UNWIND_INFO 1 %assign seh64_idxOps 0 %assign seh64_FrameReg SEH64_PE_GREG_rsp %assign seh64_offFrame 0 %define asm_seh64_proc %1 %undef seh64_slot_bytes %endmacro ;; We keep the unwind bytes in the seh64_slot_bytes (x)define, in reverse order as per spec. %macro SEH64_APPEND_SLOT_PAIR 2 %ifdef seh64_slot_bytes %xdefine seh64_slot_bytes %1, %2, seh64_slot_bytes %else %xdefine seh64_slot_bytes %1, %2 %endif %endmacro ;; For multi-slot unwind info. %macro SEH64_APPEND_SLOT_BYTES 2+ %rep %0 %rotate -1 %ifdef seh64_slot_bytes %xdefine seh64_slot_bytes %1, seh64_slot_bytes %else %xdefine seh64_slot_bytes %1 %endif %endrep %endmacro %else %undef RT_ASM_WITH_SEH64_ALT %endif %endif ;; ; Records a xBP push. %macro SEH64_PUSH_xBP 0 %ifdef RT_ASM_WITH_SEH64 [pushreg rbp] %elifdef RT_ASM_WITH_SEH64_ALT RT_CONCAT(.seh64_op_label_,seh64_idxOps): %ifdef ASM_FORMAT_PE64 SEH64_APPEND_SLOT_PAIR RT_CONCAT(.seh64_op_label_,seh64_idxOps) - .start_of_prologue, \ SEH64_PE_PUSH_NONVOL | (SEH64_PE_GREG_rbp << 4) %endif %assign seh64_idxOps seh64_idxOps + 1 %endif %endmacro ;; ; Records a general register push. ; @param 1 Register name. %macro SEH64_PUSH_GREG 1 %ifdef RT_ASM_WITH_SEH64 [pushreg %1] %elifdef RT_ASM_WITH_SEH64_ALT RT_CONCAT(.seh64_op_label_,seh64_idxOps): %ifdef ASM_FORMAT_PE64 SEH64_APPEND_SLOT_PAIR RT_CONCAT(.seh64_op_label_,seh64_idxOps) - .start_of_prologue, \ SEH64_PE_PUSH_NONVOL | (RT_CONCAT(SEH64_PE_GREG_,%1) << 4) %endif %assign seh64_idxOps seh64_idxOps + 1 %endif %endmacro ;; ; Sets xBP as frame pointer that's pointing to a stack position %1 relative to xBP. %macro SEH64_SET_FRAME_xBP 1 %ifdef RT_ASM_WITH_SEH64 [setframe rbp, %1] %elifdef RT_ASM_WITH_SEH64_ALT RT_CONCAT(.seh64_op_label_,seh64_idxOps): %ifdef ASM_FORMAT_PE64 SEH64_APPEND_SLOT_PAIR RT_CONCAT(.seh64_op_label_,seh64_idxOps) - .start_of_prologue, \ SEH64_PE_SET_FPREG | 0 ; vs2019 seems to put the offset in the info field %assign seh64_FrameReg SEH64_PE_GREG_rbp %assign seh64_offFrame %1 %endif %assign seh64_idxOps seh64_idxOps + 1 %endif %endmacro ;; ; Records an ADD xSP, %1. %macro SEH64_ALLOCATE_STACK 1 %ifdef RT_ASM_WITH_SEH64 [allocstack %1] %elifdef RT_ASM_WITH_SEH64_ALT RT_CONCAT(.seh64_op_label_,seh64_idxOps): %ifdef ASM_FORMAT_PE64 %if (%1) & 7 %error "SEH64_ALLOCATE_STACK must be a multiple of 8" %endif %if (%1) < 8 %error "SEH64_ALLOCATE_STACK must have an argument that's 8 or higher." %elif (%1) <= 128 SEH64_APPEND_SLOT_PAIR RT_CONCAT(.seh64_op_label_,seh64_idxOps) - .start_of_prologue, \ SEH64_PE_ALLOC_SMALL | ((((%1) / 8) - 1) << 4) %elif (%1) < 512 SEH64_APPEND_SLOT_BYTES RT_CONCAT(.seh64_op_label_,seh64_idxOps) - .start_of_prologue, \ SEH64_PE_ALLOC_LARGE | 0, \ ((%1) / 8) & 0xff, ((%1) / 8) >> 8 %else SEH64_APPEND_SLOT_BYTES RT_CONCAT(.seh64_op_label_,seh64_idxOps) - .start_of_prologue, \ SEH64_PE_ALLOC_LARGE | 1, \ (%1) & 0xff, ((%1) >> 8) & 0xff, ((%1) >> 16) & 0xff, ((%1) >> 24) & 0xff %endif %endif %assign seh64_idxOps seh64_idxOps + 1 %endif %endmacro %macro SEH64_INFO_HELPER 1 %if defined(%1) dw %1 %endif %endmacro ;; ; Ends the prologue. %macro SEH64_END_PROLOGUE 0 .end_of_prologue: %ifdef RT_ASM_WITH_SEH64 [endprolog] %elifdef RT_ASM_WITH_SEH64_ALT %ifdef ASM_FORMAT_PE ; Emit the unwind info now. %ifndef ASM_DEFINED_XDATA_SECTION %define ASM_DEFINED_XDATA_SECTION section .xdata rdata align=4 %else section .xdata align 4, db 0 %endif .unwind_info: db 1 ; version 1 (3 bit), no flags (5 bits) db .end_of_prologue - .start_of_prologue db (.unwind_info_array_end - .unwind_info_array) / 2 db seh64_FrameReg | (seh64_offFrame & 0xf0) ; framereg and offset/16. .unwind_info_array: %ifdef seh64_slot_bytes db seh64_slot_bytes %undef seh64_slot_bytes %endif .unwind_info_array_end: ; Reset the segment BEGINCODE %endif %endif %endmacro ;; ; Align code, pad with INT3. %define ALIGNCODE(alignment) align alignment, db 0cch ;; ; Align data, pad with ZEROs. %define ALIGNDATA(alignment) align alignment, db 0 ;; ; Align BSS, pad with ZEROs. %define ALIGNBSS(alignment) align alignment, resb 1 ;; ; NAME_OVERLOAD can be defined by a .asm module to modify all the ; names created using the name macros in this files. ; This is handy when you've got some kind of template code. %ifndef NAME_OVERLOAD %ifdef RT_MANGLER_PREFIX %define NAME_OVERLOAD(name) RT_MANGLER_PREFIX %+ name %else %define NAME_OVERLOAD(name) name %endif %endif ;; ; Mangles the given name so it can be referenced using DECLASM() in the ; C/C++ world. %ifndef ASM_FORMAT_BIN %ifdef RT_ARCH_X86 %ifdef RT_OS_OS2 %define NAME(name) _ %+ NAME_OVERLOAD(name) %endif %ifdef RT_OS_WINDOWS %define NAME(name) _ %+ NAME_OVERLOAD(name) %endif %endif %ifdef RT_OS_DARWIN %define NAME(name) _ %+ NAME_OVERLOAD(name) %endif %endif %ifndef NAME %define NAME(name) NAME_OVERLOAD(name) %endif ;; ; Mangles the given C name so it will _import_ the right symbol. %ifdef ASM_FORMAT_PE %define IMPNAME(name) __imp_ %+ NAME(name) %else %define IMPNAME(name) NAME(name) %endif ;; ; Gets the pointer to an imported object. %ifdef ASM_FORMAT_PE %ifdef RT_ARCH_AMD64 %define IMP(name) qword [IMPNAME(name) wrt rip] %else %define IMP(name) dword [IMPNAME(name)] %endif %else %define IMP(name) IMPNAME(name) %endif ;; ; Gets the pointer to an imported object. %ifdef ASM_FORMAT_PE %ifdef RT_ARCH_AMD64 %define IMP_SEG(SegOverride, name) qword [SegOverride:IMPNAME(name) wrt rip] %else %define IMP_SEG(SegOverride, name) dword [SegOverride:IMPNAME(name)] %endif %else %define IMP_SEG(SegOverride, name) IMPNAME(name) %endif ;; ; Declares an imported object for use with IMP2. ; @note May change the current section! %macro EXTERN_IMP2 1 extern IMPNAME(%1) BEGINDATA %ifdef ASM_FORMAT_MACHO g_Imp2_ %+ %1: RTCCPTR_DEF IMPNAME(%1) %endif %endmacro ;; ; Gets the pointer to an imported object, version 2. %ifdef ASM_FORMAT_PE %ifdef RT_ARCH_AMD64 %define IMP2(name) qword [IMPNAME(name) wrt rip] %else %define IMP2(name) dword [IMPNAME(name)] %endif %elifdef ASM_FORMAT_ELF %ifdef PIC %ifdef RT_ARCH_AMD64 %define IMP2(name) qword [rel IMPNAME(name) wrt ..got] %else %define IMP2(name) IMPNAME(name) wrt ..plt %endif %endif %elifdef ASM_FORMAT_MACHO %define IMP2(name) RTCCPTR_PRE [g_Imp2_ %+ name xWrtRIP] %endif %ifndef IMP2 %define IMP2(name) IMPNAME(name) %endif ;; ; Global marker which is DECLASM() compatible. %macro GLOBALNAME 1 %ifndef ASM_FORMAT_BIN global NAME(%1) %endif NAME(%1): %endmacro ;; ; Global exported marker which is DECLASM() compatible. %macro EXPORTEDNAME 1 %ifdef ASM_FORMAT_PE export %1=NAME(%1) %endif %ifdef __NASM__ %ifdef ASM_FORMAT_OMF export NAME(%1) NAME(%1) %endif %endif GLOBALNAME %1 %endmacro ;; ; Global marker which is DECLASM() compatible. %macro GLOBALNAME_EX 2 %ifndef ASM_FORMAT_BIN %ifdef ASM_FORMAT_ELF global NAME(%1):%2 %else global NAME(%1) %endif %endif NAME(%1): %endmacro ;; ; Global exported marker which is DECLASM() compatible. %macro EXPORTEDNAME_EX 2 %ifdef ASM_FORMAT_PE export %1=NAME(%1) %endif %ifdef __NASM__ %ifdef ASM_FORMAT_OMF export NAME(%1) NAME(%1) %endif %endif GLOBALNAME_EX %1, %2 %endmacro ;; ; Begins a C callable procedure. %macro BEGINPROC 1 %ifdef RT_ASM_WITH_SEH64_ALT SEH64_ALT_START_UNWIND_INFO %1 %endif %ifdef RT_ASM_WITH_SEH64 global NAME(%1):function proc_frame NAME(%1) %else GLOBALNAME_EX %1, function hidden %endif .start_of_prologue: %endmacro ;; ; Begins a C callable exported procedure. %macro BEGINPROC_EXPORTED 1 %ifdef RT_ASM_WITH_SEH64_ALT SEH64_ALT_START_UNWIND_INFO %1 %endif %ifdef RT_ASM_WITH_SEH64 %ifdef ASM_FORMAT_PE export %1=NAME(%1) %endif global NAME(%1):function proc_frame NAME(%1) %else EXPORTEDNAME_EX %1, function %endif .start_of_prologue: %endmacro ;; ; Ends a C callable procedure. %macro ENDPROC 1 %ifdef RT_ASM_WITH_SEH64 endproc_frame %endif GLOBALNAME_EX %1 %+ _EndProc, function hidden %ifdef ASM_FORMAT_ELF %ifndef __NASM__ ; nasm does this in the global directive. size NAME(%1) NAME(%1 %+ _EndProc) - NAME(%1) size NAME(%1 %+ _EndProc) 4 ; make it non-zero to shut up warnigns from Linux's objtool. %endif %endif db 0xCC, 0xCC, 0xCC, 0xCC %ifdef RT_ASM_WITH_SEH64_ALT %ifdef ASM_FORMAT_PE ; Emit the RUNTIME_FUNCTION entry. The linker is picky here, no label. %ifndef ASM_DEFINED_PDATA_SECTION %define ASM_DEFINED_PDATA_SECTION section .pdata rdata align=4 %else section .pdata %endif dd NAME(%1) wrt ..imagebase dd NAME(%1 %+ _EndProc) wrt ..imagebase dd NAME(%1 %+ .unwind_info) wrt ..imagebase ; Restore code section. BEGINCODE %endif %endif %endmacro ; ; Do OMF and Mach-O/Yasm segment definitions ; ; Both format requires this to get the segment order right, in the Mach-O/Yasm case ; it's only to make sure the .bss section ends up last (it's not declared here). ; %ifdef ASM_FORMAT_OMF %ifndef RT_NOINC_SEGMENTS ; 16-bit segments first (OMF / OS/2 specific). %ifdef RT_INCL_16BIT_SEGMENTS segment DATA16 public CLASS=FAR_DATA align=16 use16 segment DATA16_INIT public CLASS=FAR_DATA align=16 use16 group DGROUP16 DATA16 DATA16_INIT ;; ; Begins 16-bit data %macro BEGINDATA16 0 segment DATA16 %endmacro ;; ; Begins 16-bit init data %macro BEGINDATA16INIT 0 segment DATA16_INIT %endmacro segment CODE16 public CLASS=FAR_CODE align=16 use16 segment CODE16_INIT public CLASS=FAR_CODE align=16 use16 group CGROUP16 CODE16 CODE16_INIT ;; ; Begins 16-bit code %macro BEGINCODE16 0 segment CODE16 %endmacro ;; ; Begins 16-bit init code %macro BEGINCODE16INIT 0 segment CODE16_INIT %endmacro %endif ; 32-bit segments. segment TEXT32 public CLASS=CODE align=16 use32 flat segment DATA32 public CLASS=DATA align=16 use32 flat segment BSS32 public CLASS=BSS align=16 use32 flat ; Make the TEXT32 segment default. segment TEXT32 %endif ; RT_NOINC_SEGMENTS %endif %ifdef ASM_FORMAT_MACHO %ifdef __YASM__ section .text section .data %endif %endif ;; ; Begins code %ifdef ASM_FORMAT_OMF %macro BEGINCODE 0 segment TEXT32 %endmacro %else %macro BEGINCODE 0 section .text %endmacro %endif ;; ; Begins constant (read-only) data ; ; @remarks This is mapped to the CODE section/segment when there isn't ; any dedicated const section/segment. (There is code that ; assumes this, so don't try change it.) %ifdef ASM_FORMAT_OMF %macro BEGINCONST 0 segment TEXT32 %endmacro %else %macro BEGINCONST 0 %ifdef ASM_FORMAT_MACHO ;; @todo check the other guys too. section .rodata %else section .text %endif %endmacro %endif ;; ; Begins initialized data %ifdef ASM_FORMAT_OMF %macro BEGINDATA 0 segment DATA32 %endmacro %else %macro BEGINDATA 0 section .data %endmacro %endif ;; ; Begins uninitialized data %ifdef ASM_FORMAT_OMF %macro BEGINBSS 0 segment BSS32 %endmacro %else %macro BEGINBSS 0 section .bss %endmacro %endif ;; @def ARCH_BITS ; Defines the bit count of the current context. %ifndef ARCH_BITS %ifdef RT_ARCH_AMD64 %define ARCH_BITS 64 %else %define ARCH_BITS 32 %endif %endif ;; @def HC_ARCH_BITS ; Defines the host architechture bit count. %ifndef HC_ARCH_BITS %ifndef IN_RC %define HC_ARCH_BITS ARCH_BITS %else %define HC_ARCH_BITS 32 %endif %endif ;; @def R3_ARCH_BITS ; Defines the host ring-3 architechture bit count. %ifndef R3_ARCH_BITS %ifdef IN_RING3 %define R3_ARCH_BITS ARCH_BITS %else %define R3_ARCH_BITS HC_ARCH_BITS %endif %endif ;; @def R0_ARCH_BITS ; Defines the host ring-0 architechture bit count. %ifndef R0_ARCH_BITS %ifdef IN_RING0 %define R0_ARCH_BITS ARCH_BITS %else %define R0_ARCH_BITS HC_ARCH_BITS %endif %endif ;; @def GC_ARCH_BITS ; Defines the guest architechture bit count. %ifndef GC_ARCH_BITS %ifdef IN_RC %define GC_ARCH_BITS ARCH_BITS %else %define GC_ARCH_BITS 32 %endif %endif ;; @def RTHCPTR_DEF ; The pesudo-instruction used to declare an initialized pointer variable in the host context. %if HC_ARCH_BITS == 64 %define RTHCPTR_DEF dq %else %define RTHCPTR_DEF dd %endif ;; @def RTHCPTR_RES ; The pesudo-instruction used to declare (=reserve space for) an uninitialized pointer ; variable of the host context. %if HC_ARCH_BITS == 64 %define RTHCPTR_RES resq %else %define RTHCPTR_RES resd %endif ;; @def RTHCPTR_PRE ; The memory operand prefix used for a pointer in the host context. %if HC_ARCH_BITS == 64 %define RTHCPTR_PRE qword %else %define RTHCPTR_PRE dword %endif ;; @def RTHCPTR_CB ; The size in bytes of a pointer in the host context. %if HC_ARCH_BITS == 64 %define RTHCPTR_CB 8 %else %define RTHCPTR_CB 4 %endif ;; @def RTR0PTR_DEF ; The pesudo-instruction used to declare an initialized pointer variable in the ring-0 host context. %if R0_ARCH_BITS == 64 %define RTR0PTR_DEF dq %else %define RTR0PTR_DEF dd %endif ;; @def RTR0PTR_RES ; The pesudo-instruction used to declare (=reserve space for) an uninitialized pointer ; variable of the ring-0 host context. %if R0_ARCH_BITS == 64 %define RTR0PTR_RES resq %else %define RTR0PTR_RES resd %endif ;; @def RTR0PTR_PRE ; The memory operand prefix used for a pointer in the ring-0 host context. %if R0_ARCH_BITS == 64 %define RTR0PTR_PRE qword %else %define RTR0PTR_PRE dword %endif ;; @def RTR0PTR_CB ; The size in bytes of a pointer in the ring-0 host context. %if R0_ARCH_BITS == 64 %define RTR0PTR_CB 8 %else %define RTR0PTR_CB 4 %endif ;; @def RTR3PTR_DEF ; The pesudo-instruction used to declare an initialized pointer variable in the ring-3 host context. %if R3_ARCH_BITS == 64 %define RTR3PTR_DEF dq %else %define RTR3PTR_DEF dd %endif ;; @def RTR3PTR_RES ; The pesudo-instruction used to declare (=reserve space for) an uninitialized pointer ; variable of the ring-3 host context. %if R3_ARCH_BITS == 64 %define RTR3PTR_RES resq %else %define RTR3PTR_RES resd %endif ;; @def RTR3PTR_PRE ; The memory operand prefix used for a pointer in the ring-3 host context. %if R3_ARCH_BITS == 64 %define RTR3PTR_PRE qword %else %define RTR3PTR_PRE dword %endif ;; @def RTR3PTR_CB ; The size in bytes of a pointer in the ring-3 host context. %if R3_ARCH_BITS == 64 %define RTR3PTR_CB 8 %else %define RTR3PTR_CB 4 %endif ;; @def RTGCPTR_DEF ; The pesudo-instruction used to declare an initialized pointer variable in the guest context. %if GC_ARCH_BITS == 64 %define RTGCPTR_DEF dq %else %define RTGCPTR_DEF dd %endif ;; @def RTGCPTR_RES ; The pesudo-instruction used to declare (=reserve space for) an uninitialized pointer ; variable of the guest context. %if GC_ARCH_BITS == 64 %define RTGCPTR_RES resq %else %define RTGCPTR_RES resd %endif %define RTGCPTR32_RES resd %define RTGCPTR64_RES resq ;; @def RTGCPTR_PRE ; The memory operand prefix used for a pointer in the guest context. %if GC_ARCH_BITS == 64 %define RTGCPTR_PRE qword %else %define RTGCPTR_PRE dword %endif ;; @def RTGCPTR_CB ; The size in bytes of a pointer in the guest context. %if GC_ARCH_BITS == 64 %define RTGCPTR_CB 8 %else %define RTGCPTR_CB 4 %endif ;; @def RTRCPTR_DEF ; The pesudo-instruction used to declare an initialized pointer variable in the raw mode context. %define RTRCPTR_DEF dd ;; @def RTRCPTR_RES ; The pesudo-instruction used to declare (=reserve space for) an uninitialized pointer ; variable of the raw mode context. %define RTRCPTR_RES resd ;; @def RTRCPTR_PRE ; The memory operand prefix used for a pointer in the raw mode context. %define RTRCPTR_PRE dword ;; @def RTRCPTR_CB ; The size in bytes of a pointer in the raw mode context. %define RTRCPTR_CB 4 ;; @def RT_CCPTR_DEF ; The pesudo-instruction used to declare an initialized pointer variable in the current context. ;; @def RT_CCPTR_RES ; The pesudo-instruction used to declare (=reserve space for) an uninitialized pointer ; variable of the current context. ;; @def RT_CCPTR_PRE ; The memory operand prefix used for a pointer in the current context. ;; @def RT_CCPTR_CB ; The size in bytes of a pointer in the current context. %ifdef IN_RC %define RTCCPTR_DEF RTRCPTR_DEF %define RTCCPTR_RES RTRCPTR_RES %define RTCCPTR_PRE RTRCPTR_PRE %define RTCCPTR_CB RTRCPTR_CB %else %ifdef IN_RING0 %define RTCCPTR_DEF RTR0PTR_DEF %define RTCCPTR_RES RTR0PTR_RES %define RTCCPTR_PRE RTR0PTR_PRE %define RTCCPTR_CB RTR0PTR_CB %else %define RTCCPTR_DEF RTR3PTR_DEF %define RTCCPTR_RES RTR3PTR_RES %define RTCCPTR_PRE RTR3PTR_PRE %define RTCCPTR_CB RTR3PTR_CB %endif %endif ;; @def RTHCPHYS_DEF ; The pesudo-instruction used to declare an initialized host physical address. %define RTHCPHYS_DEF dq ;; @def RTHCPTR_RES ; The pesudo-instruction used to declare (=reserve space for) an uninitialized ; host physical address variable %define RTHCPHYS_RES resq ;; @def RTHCPTR_PRE ; The memory operand prefix used for a host physical address. %define RTHCPHYS_PRE qword ;; @def RTHCPHYS_CB ; The size in bytes of a host physical address. %define RTHCPHYS_CB 8 ;; @def RTGCPHYS_DEF ; The pesudo-instruction used to declare an initialized guest physical address. %define RTGCPHYS_DEF dq ;; @def RTGCPHYS_RES ; The pesudo-instruction used to declare (=reserve space for) an uninitialized ; guest physical address variable %define RTGCPHYS_RES resq ;; @def RTGCPTR_PRE ; The memory operand prefix used for a guest physical address. %define RTGCPHYS_PRE qword ;; @def RTGCPHYS_CB ; The size in bytes of a guest physical address. %define RTGCPHYS_CB 8 ;; ; The size of the long double C/C++ type. ; On 32-bit Darwin this is 16 bytes, on L4, Linux, OS/2 and Windows ; it's 12 bytes. ; @todo figure out what 64-bit Windows does (I don't recall right now). %ifdef RT_ARCH_X86 %ifdef RT_OS_DARWIN %define RTLRD_CB 16 %else %define RTLRD_CB 12 %endif %else %define RTLRD_CB 16 %endif ;; @def ASM_CALL64_GCC ; Indicates that we're using the GCC 64-bit calling convention. ; @see @ref sec_vboxrem_amd64_compare (in VBoxREMWrapper.cpp) for an ABI description. ;; @def ASM_CALL64_MSC ; Indicates that we're using the Microsoft 64-bit calling convention (fastcall on steroids). ; @see @ref sec_vboxrem_amd64_compare (in VBoxREMWrapper.cpp) for an ABI description. ; Note: On X86 we're using cdecl unconditionally. There is not yet any common ; calling convention on AMD64, that's why we need to support two different ones.) %ifdef RT_ARCH_AMD64 %ifndef ASM_CALL64_GCC %ifndef ASM_CALL64_MSC ; define it based on the object format. %ifdef ASM_FORMAT_PE %define ASM_CALL64_MSC %else %define ASM_CALL64_GCC %endif %endif %else ; sanity check. %ifdef ASM_CALL64_MSC %error "Only one of the ASM_CALL64_* defines should be defined!" %endif %endif %else ;later; %ifdef ASM_CALL64_GCC ;later; %error "ASM_CALL64_GCC is defined without RT_ARCH_AMD64!" ASM_CALL64_GCC ;later; %endif ;later; %ifdef ASM_CALL64_MSC ;later; %error "ASM_CALL64_MSC is defined without RT_ARCH_AMD64!" ASM_CALL64_MSC ;later; %endif %endif ;; @def RT_BEGINPROC ; Starts an IPRT procedure that should be exported unless IN_RT_STATIC is defined. ; ; @param 1 The function name. Will apply NAME macro to it. %macro RT_BEGINPROC 1 %ifdef IN_RT_STATIC BEGINPROC %1 %else BEGINPROC_EXPORTED %1 %endif %endmacro ; RT_BEGINPROC ;; @def RT_NOCRT ; Symbol name wrapper for the No-CRT bits. ; ; In order to coexist in the same process as other CRTs, we need to ; decorate the symbols such that they don't conflict the ones in the ; other CRTs. The result of such conflicts / duplicate symbols can ; confuse the dynamic loader on unix like systems. ; ; @remark Always feed the name to this macro first and then pass the result ; on to the next *NAME* macro. ; %ifndef RT_WITHOUT_NOCRT_WRAPPERS %define RT_NOCRT(name) nocrt_ %+ name %else %define RT_NOCRT(name) name %endif ;; @def RT_NOCRT_BEGINPROC ; Starts a NOCRT procedure, taking care of name wrapping and aliasing. ; ; Aliasing (weak ones, if supported) will be created when RT_WITH_NOCRT_ALIASES ; is defined and RT_WITHOUT_NOCRT_WRAPPERS isn't. ; %macro RT_NOCRT_BEGINPROC 1 %ifdef RT_WITH_NOCRT_ALIASES BEGINPROC_EXPORTED RT_NOCRT(%1) %ifdef ASM_FORMAT_ELF global NAME(%1) weak NAME(%1) NAME(%1): %else GLOBALNAME %1 %endif %else ; !RT_WITH_NOCRT_ALIASES BEGINPROC_EXPORTED RT_NOCRT(%1) %endif ; !RT_WITH_NOCRT_ALIASES %endmacro ; RT_NOCRT_BEGINPROC %ifdef RT_WITH_NOCRT_ALIASES %ifdef RT_WITHOUT_NOCRT_WRAPPERS %error "RT_WITH_NOCRT_ALIASES and RT_WITHOUT_NOCRT_WRAPPERS doesn't mix." %endif %endif ;; @def xCB ; The stack unit size / The register unit size. ;; @def xSP ; The stack pointer register (RSP or ESP). ;; @def xBP ; The base pointer register (RBP or ESP). ;; @def xAX ; RAX or EAX depending on context. ;; @def xBX ; RBX or EBX depending on context. ;; @def xCX ; RCX or ECX depending on context. ;; @def xDX ; RDX or EDX depending on context. ;; @def xDI ; RDI or EDI depending on context. ;; @def xSI ; RSI or ESI depending on context. ;; @def xWrtRIP ; 'wrt rip' for AMD64 targets, nothing for x86 ones. %ifdef RT_ARCH_AMD64 %define xCB 8 %define xSP rsp %define xBP rbp %define xAX rax %define xBX rbx %define xCX rcx %define xDX rdx %define xDI rdi %define xSI rsi %define xWrtRIP wrt rip %else %define xCB 4 %define xSP esp %define xBP ebp %define xAX eax %define xBX ebx %define xCX ecx %define xDX edx %define xDI edi %define xSI esi %define xWrtRIP %endif ; ; NASM sets __PASS__ to 0 in preprocess-only mode, and to 3 when only generating dependencies. ; YASM has no such setting which is why we must rely on kBuild to tell us what we're doing. ; For simplicity, we'll set the kBuild macro when using NASM. ; %ifndef KBUILD_GENERATING_MAKEFILE_DEPENDENCIES %ifdef __NASM__ %if __PASS__ == 0 || __PASS__ == 3 %define KBUILD_GENERATING_MAKEFILE_DEPENDENCIES %endif %endif %endif ; ; Some simple compile time assertions. ; ; Note! Requires new kBuild to work with YASM (see above). ; ;; ; Structure size assertion macro. %define AssertCompileSize(a_Type, a_Size) AssertCompileSizeML a_Type, a_Size %macro AssertCompileSizeML 2 %ifndef KBUILD_GENERATING_MAKEFILE_DEPENDENCIES %assign AssertVar_cbActual %1 %+ _size %assign AssertVar_cbExpected %2 %if AssertVar_cbActual != AssertVar_cbExpected %error %1 is AssertVar_cbActual bytes instead of AssertVar_cbExpected %endif %endif %endmacro ;; ; Structure size alignment assertion macro. %define AssertCompileSizeAlignment(a_Type, a_Align) AssertCompileSizeAlignmentML a_Type, a_Align %macro AssertCompileSizeAlignmentML 2 %ifndef KBUILD_GENERATING_MAKEFILE_DEPENDENCIES %assign AssertVar_cbActual %1 %+ _size %assign AssertVar_cbAlignment %2 %if (AssertVar_cbActual & (AssertVar_cbAlignment - 1)) != 0 %error %1 is AssertVar_cbActual bytes, expected size with AssertVar_cbAlignment bytes alignment. %endif %endif %endmacro ;; ; Structure member offset assertion macro. %define AssertCompileMemberOffset(a_Type, a_Member, a_off) AssertCompileMemberOffsetML a_Type, a_Member, a_off %macro AssertCompileMemberOffsetML 3 %ifndef KBUILD_GENERATING_MAKEFILE_DEPENDENCIES %assign AssertVar_offActual %1 %+ . %+ %2 %assign AssertVar_offExpected %3 %if AssertVar_offActual != AssertVar_offExpected %error %1 %+ . %+ %2 is at AssertVar_offActual instead of AssertVar_offExpected %endif %endif %endmacro ;; ; Structure member alignment assertion macro. %define AssertCompileMemberAlignment(a_Type, a_Member, a_cbAlign) AssertCompileMemberAlignmentML a_Type, a_Member, a_cbAlign %macro AssertCompileMemberAlignmentML 3 %ifndef KBUILD_GENERATING_MAKEFILE_DEPENDENCIES %assign AssertVar_offActual %1 %+ . %+ %2 %assign AssertVar_cbAlign %3 %if AssertVar_offActual & (AssertVar_cbAlign - 1) %error %1 %+ . %+ %2 is at AssertVar_offActual, expected AssertVar_cbAlign alignment %endif %endif %endmacro ;; ; Generic compile time expression assertion. %define AssertCompile(a_Expr) AssertCompileML { a_Expr } %macro AssertCompileML 1 %ifndef KBUILD_GENERATING_MAKEFILE_DEPENDENCIES %if (%1) != 1 %assign AssertVar_uResult %1 %error %1 => AssertVar_uResult %endif %endif %endmacro %endif