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566 lines
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566 lines
22 KiB
Plaintext
@c Copyright (C) 1991, 92, 93, 94, 95, 97, 1998 Free Software Foundation, Inc.
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@c This is part of the GAS manual.
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@c For copying conditions, see the file as.texinfo.
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@ifset GENERIC
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@page
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@node i386-Dependent
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@chapter 80386 Dependent Features
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@end ifset
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@ifclear GENERIC
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@node Machine Dependencies
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@chapter 80386 Dependent Features
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@end ifclear
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@cindex i386 support
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@cindex i80306 support
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@menu
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* i386-Options:: Options
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* i386-Syntax:: AT&T Syntax versus Intel Syntax
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* i386-Mnemonics:: Instruction Naming
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* i386-Regs:: Register Naming
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* i386-Prefixes:: Instruction Prefixes
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* i386-Memory:: Memory References
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* i386-jumps:: Handling of Jump Instructions
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* i386-Float:: Floating Point
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* i386-SIMD:: Intel's MMX and AMD's 3DNow! SIMD Operations
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* i386-16bit:: Writing 16-bit Code
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* i386-Arch:: Specifying an x86 CPU architecture
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* i386-Bugs:: AT&T Syntax bugs
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* i386-Notes:: Notes
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@end menu
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@node i386-Options
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@section Options
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@cindex options for i386 (none)
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@cindex i386 options (none)
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The 80386 has no machine dependent options.
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@node i386-Syntax
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@section AT&T Syntax versus Intel Syntax
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@cindex i386 intel_syntax pseudo op
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@cindex intel_syntax pseudo op, i386
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@cindex i386 att_syntax pseudo op
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@cindex att_syntax pseudo op, i386
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@cindex i386 syntax compatibility
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@cindex syntax compatibility, i386
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@code{@value{AS}} now supports assembly using Intel assembler syntax.
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@code{.intel_syntax} selects Intel mode, and @code{.att_syntax} switches
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back to the usual AT&T mode for compatibility with the output of
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@code{@value{GCC}}. Either of these directives may have an optional
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argument, @code{prefix}, or @code{noprefix} specifying whether registers
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require a @samp{%} prefix. AT&T System V/386 assembler syntax is quite
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different from Intel syntax. We mention these differences because
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almost all 80386 documents use Intel syntax. Notable differences
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between the two syntaxes are:
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@cindex immediate operands, i386
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@cindex i386 immediate operands
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@cindex register operands, i386
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@cindex i386 register operands
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@cindex jump/call operands, i386
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@cindex i386 jump/call operands
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@cindex operand delimiters, i386
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@itemize @bullet
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@item
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AT&T immediate operands are preceded by @samp{$}; Intel immediate
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operands are undelimited (Intel @samp{push 4} is AT&T @samp{pushl $4}).
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AT&T register operands are preceded by @samp{%}; Intel register operands
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are undelimited. AT&T absolute (as opposed to PC relative) jump/call
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operands are prefixed by @samp{*}; they are undelimited in Intel syntax.
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@cindex i386 source, destination operands
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@cindex source, destination operands; i386
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@item
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AT&T and Intel syntax use the opposite order for source and destination
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operands. Intel @samp{add eax, 4} is @samp{addl $4, %eax}. The
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@samp{source, dest} convention is maintained for compatibility with
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previous Unix assemblers. Note that instructions with more than one
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source operand, such as the @samp{enter} instruction, do @emph{not} have
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reversed order. @ref{i386-Bugs}.
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@cindex mnemonic suffixes, i386
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@cindex sizes operands, i386
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@cindex i386 size suffixes
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@item
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In AT&T syntax the size of memory operands is determined from the last
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character of the instruction mnemonic. Mnemonic suffixes of @samp{b},
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@samp{w}, and @samp{l} specify byte (8-bit), word (16-bit), and long
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(32-bit) memory references. Intel syntax accomplishes this by prefixing
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memory operands (@emph{not} the instruction mnemonics) with @samp{byte
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ptr}, @samp{word ptr}, and @samp{dword ptr}. Thus, Intel @samp{mov al,
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byte ptr @var{foo}} is @samp{movb @var{foo}, %al} in AT&T syntax.
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@cindex return instructions, i386
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@cindex i386 jump, call, return
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@item
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Immediate form long jumps and calls are
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@samp{lcall/ljmp $@var{section}, $@var{offset}} in AT&T syntax; the
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Intel syntax is
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@samp{call/jmp far @var{section}:@var{offset}}. Also, the far return
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instruction
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is @samp{lret $@var{stack-adjust}} in AT&T syntax; Intel syntax is
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@samp{ret far @var{stack-adjust}}.
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@cindex sections, i386
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@cindex i386 sections
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@item
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The AT&T assembler does not provide support for multiple section
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programs. Unix style systems expect all programs to be single sections.
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@end itemize
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@node i386-Mnemonics
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@section Instruction Naming
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@cindex i386 instruction naming
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@cindex instruction naming, i386
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Instruction mnemonics are suffixed with one character modifiers which
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specify the size of operands. The letters @samp{b}, @samp{w}, and
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@samp{l} specify byte, word, and long operands. If no suffix is
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specified by an instruction then @code{@value{AS}} tries to fill in the
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missing suffix based on the destination register operand (the last one
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by convention). Thus, @samp{mov %ax, %bx} is equivalent to @samp{movw
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%ax, %bx}; also, @samp{mov $1, %bx} is equivalent to @samp{movw $1,
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%bx}. Note that this is incompatible with the AT&T Unix assembler which
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assumes that a missing mnemonic suffix implies long operand size. (This
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incompatibility does not affect compiler output since compilers always
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explicitly specify the mnemonic suffix.)
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Almost all instructions have the same names in AT&T and Intel format.
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There are a few exceptions. The sign extend and zero extend
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instructions need two sizes to specify them. They need a size to
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sign/zero extend @emph{from} and a size to zero extend @emph{to}. This
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is accomplished by using two instruction mnemonic suffixes in AT&T
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syntax. Base names for sign extend and zero extend are
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@samp{movs@dots{}} and @samp{movz@dots{}} in AT&T syntax (@samp{movsx}
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and @samp{movzx} in Intel syntax). The instruction mnemonic suffixes
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are tacked on to this base name, the @emph{from} suffix before the
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@emph{to} suffix. Thus, @samp{movsbl %al, %edx} is AT&T syntax for
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``move sign extend @emph{from} %al @emph{to} %edx.'' Possible suffixes,
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thus, are @samp{bl} (from byte to long), @samp{bw} (from byte to word),
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and @samp{wl} (from word to long).
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@cindex conversion instructions, i386
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@cindex i386 conversion instructions
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The Intel-syntax conversion instructions
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@itemize @bullet
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@item
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@samp{cbw} --- sign-extend byte in @samp{%al} to word in @samp{%ax},
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@item
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@samp{cwde} --- sign-extend word in @samp{%ax} to long in @samp{%eax},
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@item
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@samp{cwd} --- sign-extend word in @samp{%ax} to long in @samp{%dx:%ax},
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@item
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@samp{cdq} --- sign-extend dword in @samp{%eax} to quad in @samp{%edx:%eax},
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@end itemize
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@noindent
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are called @samp{cbtw}, @samp{cwtl}, @samp{cwtd}, and @samp{cltd} in
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AT&T naming. @code{@value{AS}} accepts either naming for these instructions.
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@cindex jump instructions, i386
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@cindex call instructions, i386
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Far call/jump instructions are @samp{lcall} and @samp{ljmp} in
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AT&T syntax, but are @samp{call far} and @samp{jump far} in Intel
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convention.
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@node i386-Regs
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@section Register Naming
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@cindex i386 registers
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@cindex registers, i386
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Register operands are always prefixed with @samp{%}. The 80386 registers
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consist of
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@itemize @bullet
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@item
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the 8 32-bit registers @samp{%eax} (the accumulator), @samp{%ebx},
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@samp{%ecx}, @samp{%edx}, @samp{%edi}, @samp{%esi}, @samp{%ebp} (the
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frame pointer), and @samp{%esp} (the stack pointer).
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@item
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the 8 16-bit low-ends of these: @samp{%ax}, @samp{%bx}, @samp{%cx},
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@samp{%dx}, @samp{%di}, @samp{%si}, @samp{%bp}, and @samp{%sp}.
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@item
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the 8 8-bit registers: @samp{%ah}, @samp{%al}, @samp{%bh},
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@samp{%bl}, @samp{%ch}, @samp{%cl}, @samp{%dh}, and @samp{%dl} (These
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are the high-bytes and low-bytes of @samp{%ax}, @samp{%bx},
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@samp{%cx}, and @samp{%dx})
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@item
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the 6 section registers @samp{%cs} (code section), @samp{%ds}
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(data section), @samp{%ss} (stack section), @samp{%es}, @samp{%fs},
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and @samp{%gs}.
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@item
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the 3 processor control registers @samp{%cr0}, @samp{%cr2}, and
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@samp{%cr3}.
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@item
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the 6 debug registers @samp{%db0}, @samp{%db1}, @samp{%db2},
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@samp{%db3}, @samp{%db6}, and @samp{%db7}.
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@item
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the 2 test registers @samp{%tr6} and @samp{%tr7}.
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@item
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the 8 floating point register stack @samp{%st} or equivalently
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@samp{%st(0)}, @samp{%st(1)}, @samp{%st(2)}, @samp{%st(3)},
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@samp{%st(4)}, @samp{%st(5)}, @samp{%st(6)}, and @samp{%st(7)}.
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@end itemize
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@node i386-Prefixes
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@section Instruction Prefixes
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@cindex i386 instruction prefixes
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@cindex instruction prefixes, i386
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@cindex prefixes, i386
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Instruction prefixes are used to modify the following instruction. They
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are used to repeat string instructions, to provide section overrides, to
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perform bus lock operations, and to change operand and address sizes.
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(Most instructions that normally operate on 32-bit operands will use
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16-bit operands if the instruction has an ``operand size'' prefix.)
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Instruction prefixes are best written on the same line as the instruction
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they act upon. For example, the @samp{scas} (scan string) instruction is
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repeated with:
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@smallexample
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repne scas %es:(%edi),%al
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@end smallexample
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You may also place prefixes on the lines immediately preceding the
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instruction, but this circumvents checks that @code{@value{AS}} does
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with prefixes, and will not work with all prefixes.
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Here is a list of instruction prefixes:
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@cindex section override prefixes, i386
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@itemize @bullet
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@item
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Section override prefixes @samp{cs}, @samp{ds}, @samp{ss}, @samp{es},
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@samp{fs}, @samp{gs}. These are automatically added by specifying
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using the @var{section}:@var{memory-operand} form for memory references.
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@cindex size prefixes, i386
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@item
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Operand/Address size prefixes @samp{data16} and @samp{addr16}
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change 32-bit operands/addresses into 16-bit operands/addresses,
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while @samp{data32} and @samp{addr32} change 16-bit ones (in a
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@code{.code16} section) into 32-bit operands/addresses. These prefixes
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@emph{must} appear on the same line of code as the instruction they
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modify. For example, in a 16-bit @code{.code16} section, you might
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write:
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@smallexample
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addr32 jmpl *(%ebx)
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@end smallexample
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@cindex bus lock prefixes, i386
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@cindex inhibiting interrupts, i386
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@item
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The bus lock prefix @samp{lock} inhibits interrupts during execution of
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the instruction it precedes. (This is only valid with certain
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instructions; see a 80386 manual for details).
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@cindex coprocessor wait, i386
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@item
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The wait for coprocessor prefix @samp{wait} waits for the coprocessor to
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complete the current instruction. This should never be needed for the
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80386/80387 combination.
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@cindex repeat prefixes, i386
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@item
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The @samp{rep}, @samp{repe}, and @samp{repne} prefixes are added
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to string instructions to make them repeat @samp{%ecx} times (@samp{%cx}
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times if the current address size is 16-bits).
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@end itemize
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@node i386-Memory
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@section Memory References
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@cindex i386 memory references
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@cindex memory references, i386
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An Intel syntax indirect memory reference of the form
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@smallexample
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@var{section}:[@var{base} + @var{index}*@var{scale} + @var{disp}]
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@end smallexample
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@noindent
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is translated into the AT&T syntax
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@smallexample
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@var{section}:@var{disp}(@var{base}, @var{index}, @var{scale})
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@end smallexample
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@noindent
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where @var{base} and @var{index} are the optional 32-bit base and
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index registers, @var{disp} is the optional displacement, and
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@var{scale}, taking the values 1, 2, 4, and 8, multiplies @var{index}
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to calculate the address of the operand. If no @var{scale} is
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specified, @var{scale} is taken to be 1. @var{section} specifies the
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optional section register for the memory operand, and may override the
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default section register (see a 80386 manual for section register
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defaults). Note that section overrides in AT&T syntax @emph{must}
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be preceded by a @samp{%}. If you specify a section override which
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coincides with the default section register, @code{@value{AS}} does @emph{not}
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output any section register override prefixes to assemble the given
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instruction. Thus, section overrides can be specified to emphasize which
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section register is used for a given memory operand.
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Here are some examples of Intel and AT&T style memory references:
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@table @asis
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@item AT&T: @samp{-4(%ebp)}, Intel: @samp{[ebp - 4]}
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@var{base} is @samp{%ebp}; @var{disp} is @samp{-4}. @var{section} is
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missing, and the default section is used (@samp{%ss} for addressing with
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@samp{%ebp} as the base register). @var{index}, @var{scale} are both missing.
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@item AT&T: @samp{foo(,%eax,4)}, Intel: @samp{[foo + eax*4]}
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@var{index} is @samp{%eax} (scaled by a @var{scale} 4); @var{disp} is
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@samp{foo}. All other fields are missing. The section register here
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defaults to @samp{%ds}.
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@item AT&T: @samp{foo(,1)}; Intel @samp{[foo]}
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This uses the value pointed to by @samp{foo} as a memory operand.
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Note that @var{base} and @var{index} are both missing, but there is only
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@emph{one} @samp{,}. This is a syntactic exception.
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@item AT&T: @samp{%gs:foo}; Intel @samp{gs:foo}
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This selects the contents of the variable @samp{foo} with section
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register @var{section} being @samp{%gs}.
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@end table
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Absolute (as opposed to PC relative) call and jump operands must be
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prefixed with @samp{*}. If no @samp{*} is specified, @code{@value{AS}}
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always chooses PC relative addressing for jump/call labels.
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Any instruction that has a memory operand, but no register operand,
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@emph{must} specify its size (byte, word, or long) with an instruction
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mnemonic suffix (@samp{b}, @samp{w}, or @samp{l}, respectively).
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@node i386-jumps
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@section Handling of Jump Instructions
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@cindex jump optimization, i386
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@cindex i386 jump optimization
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Jump instructions are always optimized to use the smallest possible
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displacements. This is accomplished by using byte (8-bit) displacement
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jumps whenever the target is sufficiently close. If a byte displacement
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is insufficient a long (32-bit) displacement is used. We do not support
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word (16-bit) displacement jumps in 32-bit mode (i.e. prefixing the jump
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instruction with the @samp{data16} instruction prefix), since the 80386
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insists upon masking @samp{%eip} to 16 bits after the word displacement
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is added.
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Note that the @samp{jcxz}, @samp{jecxz}, @samp{loop}, @samp{loopz},
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@samp{loope}, @samp{loopnz} and @samp{loopne} instructions only come in byte
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displacements, so that if you use these instructions (@code{@value{GCC}} does
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not use them) you may get an error message (and incorrect code). The AT&T
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80386 assembler tries to get around this problem by expanding @samp{jcxz foo}
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to
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@smallexample
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jcxz cx_zero
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jmp cx_nonzero
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cx_zero: jmp foo
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cx_nonzero:
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@end smallexample
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@node i386-Float
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@section Floating Point
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@cindex i386 floating point
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@cindex floating point, i386
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All 80387 floating point types except packed BCD are supported.
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(BCD support may be added without much difficulty). These data
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types are 16-, 32-, and 64- bit integers, and single (32-bit),
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double (64-bit), and extended (80-bit) precision floating point.
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Each supported type has an instruction mnemonic suffix and a constructor
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associated with it. Instruction mnemonic suffixes specify the operand's
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data type. Constructors build these data types into memory.
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@cindex @code{float} directive, i386
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@cindex @code{single} directive, i386
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@cindex @code{double} directive, i386
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@cindex @code{tfloat} directive, i386
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@itemize @bullet
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@item
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Floating point constructors are @samp{.float} or @samp{.single},
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@samp{.double}, and @samp{.tfloat} for 32-, 64-, and 80-bit formats.
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These correspond to instruction mnemonic suffixes @samp{s}, @samp{l},
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and @samp{t}. @samp{t} stands for 80-bit (ten byte) real. The 80387
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only supports this format via the @samp{fldt} (load 80-bit real to stack
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top) and @samp{fstpt} (store 80-bit real and pop stack) instructions.
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@cindex @code{word} directive, i386
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@cindex @code{long} directive, i386
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@cindex @code{int} directive, i386
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@cindex @code{quad} directive, i386
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@item
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Integer constructors are @samp{.word}, @samp{.long} or @samp{.int}, and
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@samp{.quad} for the 16-, 32-, and 64-bit integer formats. The
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corresponding instruction mnemonic suffixes are @samp{s} (single),
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@samp{l} (long), and @samp{q} (quad). As with the 80-bit real format,
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the 64-bit @samp{q} format is only present in the @samp{fildq} (load
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quad integer to stack top) and @samp{fistpq} (store quad integer and pop
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stack) instructions.
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@end itemize
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Register to register operations should not use instruction mnemonic suffixes.
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@samp{fstl %st, %st(1)} will give a warning, and be assembled as if you
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wrote @samp{fst %st, %st(1)}, since all register to register operations
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use 80-bit floating point operands. (Contrast this with @samp{fstl %st, mem},
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which converts @samp{%st} from 80-bit to 64-bit floating point format,
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then stores the result in the 4 byte location @samp{mem})
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@node i386-SIMD
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@section Intel's MMX and AMD's 3DNow! SIMD Operations
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@cindex MMX, i386
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@cindex 3DNow!, i386
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@cindex SIMD, i386
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@code{@value{AS}} supports Intel's MMX instruction set (SIMD
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instructions for integer data), available on Intel's Pentium MMX
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processors and Pentium II processors, AMD's K6 and K6-2 processors,
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Cyrix' M2 processor, and probably others. It also supports AMD's 3DNow!
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instruction set (SIMD instructions for 32-bit floating point data)
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available on AMD's K6-2 processor and possibly others in the future.
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Currently, @code{@value{AS}} does not support Intel's floating point
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SIMD, Katmai (KNI).
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The eight 64-bit MMX operands, also used by 3DNow!, are called @samp{%mm0},
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@samp{%mm1}, ... @samp{%mm7}. They contain eight 8-bit integers, four
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16-bit integers, two 32-bit integers, one 64-bit integer, or two 32-bit
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floating point values. The MMX registers cannot be used at the same time
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as the floating point stack.
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See Intel and AMD documentation, keeping in mind that the operand order in
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instructions is reversed from the Intel syntax.
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@node i386-16bit
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@section Writing 16-bit Code
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@cindex i386 16-bit code
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@cindex 16-bit code, i386
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@cindex real-mode code, i386
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@cindex @code{code16gcc} directive, i386
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@cindex @code{code16} directive, i386
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@cindex @code{code32} directive, i386
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While @code{@value{AS}} normally writes only ``pure'' 32-bit i386 code,
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it also supports writing code to run in real mode or in 16-bit protected
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mode code segments. To do this, put a @samp{.code16} or
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@samp{.code16gcc} directive before the assembly language instructions to
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be run in 16-bit mode. You can switch @code{@value{AS}} back to writing
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normal 32-bit code with the @samp{.code32} directive.
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@samp{.code16gcc} provides experimental support for generating 16-bit
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code from gcc, and differs from @samp{.code16} in that @samp{call},
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@samp{ret}, @samp{enter}, @samp{leave}, @samp{push}, @samp{pop},
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@samp{pusha}, @samp{popa}, @samp{pushf}, and @samp{popf} instructions
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default to 32-bit size. This is so that the stack pointer is
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manipulated in the same way over function calls, allowing access to
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function parameters at the same stack offsets as in 32-bit mode.
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@samp{.code16gcc} also automatically adds address size prefixes where
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necessary to use the 32-bit addressing modes that gcc generates.
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The code which @code{@value{AS}} generates in 16-bit mode will not
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necessarily run on a 16-bit pre-80386 processor. To write code that
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runs on such a processor, you must refrain from using @emph{any} 32-bit
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constructs which require @code{@value{AS}} to output address or operand
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size prefixes.
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Note that writing 16-bit code instructions by explicitly specifying a
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prefix or an instruction mnemonic suffix within a 32-bit code section
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generates different machine instructions than those generated for a
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16-bit code segment. In a 32-bit code section, the following code
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generates the machine opcode bytes @samp{66 6a 04}, which pushes the
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value @samp{4} onto the stack, decrementing @samp{%esp} by 2.
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@smallexample
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pushw $4
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@end smallexample
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The same code in a 16-bit code section would generate the machine
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opcode bytes @samp{6a 04} (ie. without the operand size prefix), which
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is correct since the processor default operand size is assumed to be 16
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bits in a 16-bit code section.
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@node i386-Bugs
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@section AT&T Syntax bugs
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The UnixWare assembler, and probably other AT&T derived ix86 Unix
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assemblers, generate floating point instructions with reversed source
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and destination registers in certain cases. Unfortunately, gcc and
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possibly many other programs use this reversed syntax, so we're stuck
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with it.
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For example
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@smallexample
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fsub %st,%st(3)
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@end smallexample
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@noindent
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results in @samp{%st(3)} being updated to @samp{%st - %st(3)} rather
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than the expected @samp{%st(3) - %st}. This happens with all the
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non-commutative arithmetic floating point operations with two register
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operands where the source register is @samp{%st} and the destination
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register is @samp{%st(i)}.
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@node i386-Arch
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@section Specifying CPU Architecture
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@cindex arch directive, i386
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@cindex i386 arch directive
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@code{@value{AS}} may be told to assemble for a particular CPU
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architecture with the @code{.arch @var{cpu_type}} directive. This
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directive enables a warning when gas detects an instruction that is not
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supported on the CPU specified. The choices for @var{cpu_type} are:
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@multitable @columnfractions .20 .20 .20 .20
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@item @samp{i8086} @tab @samp{i186} @tab @samp{i286} @tab @samp{i386}
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@item @samp{i486} @tab @samp{i586} @tab @samp{i686} @tab @samp{pentium}
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@item @samp{pentiumpro} @tab @samp{k6} @tab @samp{athlon}
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@end multitable
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Apart from the warning, there is only one other effect on
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@code{@value{AS}} operation; If you specify a CPU other than
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@samp{i486}, then shift by one instructions such as @samp{sarl $1, %eax}
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will automatically use a two byte opcode sequence. The larger three
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byte opcode sequence is used on the 486 (and when no architecture is
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specified) because it executes faster on the 486. Note that you can
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explicitly request the two byte opcode by writing @samp{sarl %eax}.
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@node i386-Notes
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@section Notes
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@cindex i386 @code{mul}, @code{imul} instructions
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@cindex @code{mul} instruction, i386
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@cindex @code{imul} instruction, i386
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There is some trickery concerning the @samp{mul} and @samp{imul}
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instructions that deserves mention. The 16-, 32-, and 64-bit expanding
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multiplies (base opcode @samp{0xf6}; extension 4 for @samp{mul} and 5
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for @samp{imul}) can be output only in the one operand form. Thus,
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@samp{imul %ebx, %eax} does @emph{not} select the expanding multiply;
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the expanding multiply would clobber the @samp{%edx} register, and this
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would confuse @code{@value{GCC}} output. Use @samp{imul %ebx} to get the
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64-bit product in @samp{%edx:%eax}.
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We have added a two operand form of @samp{imul} when the first operand
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is an immediate mode expression and the second operand is a register.
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This is just a shorthand, so that, multiplying @samp{%eax} by 69, for
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example, can be done with @samp{imul $69, %eax} rather than @samp{imul
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$69, %eax, %eax}.
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