1 @c Copyright (C) 1991, 92, 93, 94, 95, 97, 1998 Free Software Foundation, Inc.
2 @c This is part of the GAS manual.
3 @c For copying conditions, see the file as.texinfo.
7 @chapter 80386 Dependent Features
10 @node Machine Dependencies
11 @chapter 80386 Dependent Features
15 @cindex i80306 support
17 * i386-Options:: Options
18 * i386-Syntax:: AT&T Syntax versus Intel Syntax
19 * i386-Mnemonics:: Instruction Naming
20 * i386-Regs:: Register Naming
21 * i386-Prefixes:: Instruction Prefixes
22 * i386-Memory:: Memory References
23 * i386-jumps:: Handling of Jump Instructions
24 * i386-Float:: Floating Point
25 * i386-SIMD:: Intel's MMX and AMD's 3DNow! SIMD Operations
26 * i386-16bit:: Writing 16-bit Code
27 * i386-Arch:: Specifying an x86 CPU architecture
28 * i386-Bugs:: AT&T Syntax bugs
35 @cindex options for i386 (none)
36 @cindex i386 options (none)
37 The 80386 has no machine dependent options.
41 @section AT&T Syntax versus Intel Syntax
43 @cindex i386 intel_syntax pseudo op
44 @cindex intel_syntax pseudo op, i386
45 @cindex i386 att_syntax pseudo op
46 @cindex att_syntax pseudo op, i386
47 @cindex i386 syntax compatibility
48 @cindex syntax compatibility, i386
50 @code{@value{AS}} now supports assembly using Intel assembler syntax.
51 @code{.intel_syntax} selects Intel mode, and @code{.att_syntax} switches
52 back to the usual AT&T mode for compatibility with the output of
53 @code{@value{GCC}}. Either of these directives may have an optional
54 argument, @code{prefix}, or @code{noprefix} specifying whether registers
55 require a @samp{%} prefix. AT&T System V/386 assembler syntax is quite
56 different from Intel syntax. We mention these differences because
57 almost all 80386 documents use Intel syntax. Notable differences
58 between the two syntaxes are:
60 @cindex immediate operands, i386
61 @cindex i386 immediate operands
62 @cindex register operands, i386
63 @cindex i386 register operands
64 @cindex jump/call operands, i386
65 @cindex i386 jump/call operands
66 @cindex operand delimiters, i386
69 AT&T immediate operands are preceded by @samp{$}; Intel immediate
70 operands are undelimited (Intel @samp{push 4} is AT&T @samp{pushl $4}).
71 AT&T register operands are preceded by @samp{%}; Intel register operands
72 are undelimited. AT&T absolute (as opposed to PC relative) jump/call
73 operands are prefixed by @samp{*}; they are undelimited in Intel syntax.
75 @cindex i386 source, destination operands
76 @cindex source, destination operands; i386
78 AT&T and Intel syntax use the opposite order for source and destination
79 operands. Intel @samp{add eax, 4} is @samp{addl $4, %eax}. The
80 @samp{source, dest} convention is maintained for compatibility with
81 previous Unix assemblers. Note that instructions with more than one
82 source operand, such as the @samp{enter} instruction, do @emph{not} have
83 reversed order. @ref{i386-Bugs}.
85 @cindex mnemonic suffixes, i386
86 @cindex sizes operands, i386
87 @cindex i386 size suffixes
89 In AT&T syntax the size of memory operands is determined from the last
90 character of the instruction mnemonic. Mnemonic suffixes of @samp{b},
91 @samp{w}, and @samp{l} specify byte (8-bit), word (16-bit), and long
92 (32-bit) memory references. Intel syntax accomplishes this by prefixing
93 memory operands (@emph{not} the instruction mnemonics) with @samp{byte
94 ptr}, @samp{word ptr}, and @samp{dword ptr}. Thus, Intel @samp{mov al,
95 byte ptr @var{foo}} is @samp{movb @var{foo}, %al} in AT&T syntax.
97 @cindex return instructions, i386
98 @cindex i386 jump, call, return
100 Immediate form long jumps and calls are
101 @samp{lcall/ljmp $@var{section}, $@var{offset}} in AT&T syntax; the
103 @samp{call/jmp far @var{section}:@var{offset}}. Also, the far return
105 is @samp{lret $@var{stack-adjust}} in AT&T syntax; Intel syntax is
106 @samp{ret far @var{stack-adjust}}.
108 @cindex sections, i386
109 @cindex i386 sections
111 The AT&T assembler does not provide support for multiple section
112 programs. Unix style systems expect all programs to be single sections.
116 @section Instruction Naming
118 @cindex i386 instruction naming
119 @cindex instruction naming, i386
120 Instruction mnemonics are suffixed with one character modifiers which
121 specify the size of operands. The letters @samp{b}, @samp{w}, and
122 @samp{l} specify byte, word, and long operands. If no suffix is
123 specified by an instruction then @code{@value{AS}} tries to fill in the
124 missing suffix based on the destination register operand (the last one
125 by convention). Thus, @samp{mov %ax, %bx} is equivalent to @samp{movw
126 %ax, %bx}; also, @samp{mov $1, %bx} is equivalent to @samp{movw $1,
127 %bx}. Note that this is incompatible with the AT&T Unix assembler which
128 assumes that a missing mnemonic suffix implies long operand size. (This
129 incompatibility does not affect compiler output since compilers always
130 explicitly specify the mnemonic suffix.)
132 Almost all instructions have the same names in AT&T and Intel format.
133 There are a few exceptions. The sign extend and zero extend
134 instructions need two sizes to specify them. They need a size to
135 sign/zero extend @emph{from} and a size to zero extend @emph{to}. This
136 is accomplished by using two instruction mnemonic suffixes in AT&T
137 syntax. Base names for sign extend and zero extend are
138 @samp{movs@dots{}} and @samp{movz@dots{}} in AT&T syntax (@samp{movsx}
139 and @samp{movzx} in Intel syntax). The instruction mnemonic suffixes
140 are tacked on to this base name, the @emph{from} suffix before the
141 @emph{to} suffix. Thus, @samp{movsbl %al, %edx} is AT&T syntax for
142 ``move sign extend @emph{from} %al @emph{to} %edx.'' Possible suffixes,
143 thus, are @samp{bl} (from byte to long), @samp{bw} (from byte to word),
144 and @samp{wl} (from word to long).
146 @cindex conversion instructions, i386
147 @cindex i386 conversion instructions
148 The Intel-syntax conversion instructions
152 @samp{cbw} --- sign-extend byte in @samp{%al} to word in @samp{%ax},
155 @samp{cwde} --- sign-extend word in @samp{%ax} to long in @samp{%eax},
158 @samp{cwd} --- sign-extend word in @samp{%ax} to long in @samp{%dx:%ax},
161 @samp{cdq} --- sign-extend dword in @samp{%eax} to quad in @samp{%edx:%eax},
165 are called @samp{cbtw}, @samp{cwtl}, @samp{cwtd}, and @samp{cltd} in
166 AT&T naming. @code{@value{AS}} accepts either naming for these instructions.
168 @cindex jump instructions, i386
169 @cindex call instructions, i386
170 Far call/jump instructions are @samp{lcall} and @samp{ljmp} in
171 AT&T syntax, but are @samp{call far} and @samp{jump far} in Intel
175 @section Register Naming
177 @cindex i386 registers
178 @cindex registers, i386
179 Register operands are always prefixed with @samp{%}. The 80386 registers
184 the 8 32-bit registers @samp{%eax} (the accumulator), @samp{%ebx},
185 @samp{%ecx}, @samp{%edx}, @samp{%edi}, @samp{%esi}, @samp{%ebp} (the
186 frame pointer), and @samp{%esp} (the stack pointer).
189 the 8 16-bit low-ends of these: @samp{%ax}, @samp{%bx}, @samp{%cx},
190 @samp{%dx}, @samp{%di}, @samp{%si}, @samp{%bp}, and @samp{%sp}.
193 the 8 8-bit registers: @samp{%ah}, @samp{%al}, @samp{%bh},
194 @samp{%bl}, @samp{%ch}, @samp{%cl}, @samp{%dh}, and @samp{%dl} (These
195 are the high-bytes and low-bytes of @samp{%ax}, @samp{%bx},
196 @samp{%cx}, and @samp{%dx})
199 the 6 section registers @samp{%cs} (code section), @samp{%ds}
200 (data section), @samp{%ss} (stack section), @samp{%es}, @samp{%fs},
204 the 3 processor control registers @samp{%cr0}, @samp{%cr2}, and
208 the 6 debug registers @samp{%db0}, @samp{%db1}, @samp{%db2},
209 @samp{%db3}, @samp{%db6}, and @samp{%db7}.
212 the 2 test registers @samp{%tr6} and @samp{%tr7}.
215 the 8 floating point register stack @samp{%st} or equivalently
216 @samp{%st(0)}, @samp{%st(1)}, @samp{%st(2)}, @samp{%st(3)},
217 @samp{%st(4)}, @samp{%st(5)}, @samp{%st(6)}, and @samp{%st(7)}.
221 @section Instruction Prefixes
223 @cindex i386 instruction prefixes
224 @cindex instruction prefixes, i386
225 @cindex prefixes, i386
226 Instruction prefixes are used to modify the following instruction. They
227 are used to repeat string instructions, to provide section overrides, to
228 perform bus lock operations, and to change operand and address sizes.
229 (Most instructions that normally operate on 32-bit operands will use
230 16-bit operands if the instruction has an ``operand size'' prefix.)
231 Instruction prefixes are best written on the same line as the instruction
232 they act upon. For example, the @samp{scas} (scan string) instruction is
236 repne scas %es:(%edi),%al
239 You may also place prefixes on the lines immediately preceding the
240 instruction, but this circumvents checks that @code{@value{AS}} does
241 with prefixes, and will not work with all prefixes.
243 Here is a list of instruction prefixes:
245 @cindex section override prefixes, i386
248 Section override prefixes @samp{cs}, @samp{ds}, @samp{ss}, @samp{es},
249 @samp{fs}, @samp{gs}. These are automatically added by specifying
250 using the @var{section}:@var{memory-operand} form for memory references.
252 @cindex size prefixes, i386
254 Operand/Address size prefixes @samp{data16} and @samp{addr16}
255 change 32-bit operands/addresses into 16-bit operands/addresses,
256 while @samp{data32} and @samp{addr32} change 16-bit ones (in a
257 @code{.code16} section) into 32-bit operands/addresses. These prefixes
258 @emph{must} appear on the same line of code as the instruction they
259 modify. For example, in a 16-bit @code{.code16} section, you might
266 @cindex bus lock prefixes, i386
267 @cindex inhibiting interrupts, i386
269 The bus lock prefix @samp{lock} inhibits interrupts during execution of
270 the instruction it precedes. (This is only valid with certain
271 instructions; see a 80386 manual for details).
273 @cindex coprocessor wait, i386
275 The wait for coprocessor prefix @samp{wait} waits for the coprocessor to
276 complete the current instruction. This should never be needed for the
277 80386/80387 combination.
279 @cindex repeat prefixes, i386
281 The @samp{rep}, @samp{repe}, and @samp{repne} prefixes are added
282 to string instructions to make them repeat @samp{%ecx} times (@samp{%cx}
283 times if the current address size is 16-bits).
287 @section Memory References
289 @cindex i386 memory references
290 @cindex memory references, i386
291 An Intel syntax indirect memory reference of the form
294 @var{section}:[@var{base} + @var{index}*@var{scale} + @var{disp}]
298 is translated into the AT&T syntax
301 @var{section}:@var{disp}(@var{base}, @var{index}, @var{scale})
305 where @var{base} and @var{index} are the optional 32-bit base and
306 index registers, @var{disp} is the optional displacement, and
307 @var{scale}, taking the values 1, 2, 4, and 8, multiplies @var{index}
308 to calculate the address of the operand. If no @var{scale} is
309 specified, @var{scale} is taken to be 1. @var{section} specifies the
310 optional section register for the memory operand, and may override the
311 default section register (see a 80386 manual for section register
312 defaults). Note that section overrides in AT&T syntax @emph{must}
313 be preceded by a @samp{%}. If you specify a section override which
314 coincides with the default section register, @code{@value{AS}} does @emph{not}
315 output any section register override prefixes to assemble the given
316 instruction. Thus, section overrides can be specified to emphasize which
317 section register is used for a given memory operand.
319 Here are some examples of Intel and AT&T style memory references:
322 @item AT&T: @samp{-4(%ebp)}, Intel: @samp{[ebp - 4]}
323 @var{base} is @samp{%ebp}; @var{disp} is @samp{-4}. @var{section} is
324 missing, and the default section is used (@samp{%ss} for addressing with
325 @samp{%ebp} as the base register). @var{index}, @var{scale} are both missing.
327 @item AT&T: @samp{foo(,%eax,4)}, Intel: @samp{[foo + eax*4]}
328 @var{index} is @samp{%eax} (scaled by a @var{scale} 4); @var{disp} is
329 @samp{foo}. All other fields are missing. The section register here
330 defaults to @samp{%ds}.
332 @item AT&T: @samp{foo(,1)}; Intel @samp{[foo]}
333 This uses the value pointed to by @samp{foo} as a memory operand.
334 Note that @var{base} and @var{index} are both missing, but there is only
335 @emph{one} @samp{,}. This is a syntactic exception.
337 @item AT&T: @samp{%gs:foo}; Intel @samp{gs:foo}
338 This selects the contents of the variable @samp{foo} with section
339 register @var{section} being @samp{%gs}.
342 Absolute (as opposed to PC relative) call and jump operands must be
343 prefixed with @samp{*}. If no @samp{*} is specified, @code{@value{AS}}
344 always chooses PC relative addressing for jump/call labels.
346 Any instruction that has a memory operand, but no register operand,
347 @emph{must} specify its size (byte, word, or long) with an instruction
348 mnemonic suffix (@samp{b}, @samp{w}, or @samp{l}, respectively).
351 @section Handling of Jump Instructions
353 @cindex jump optimization, i386
354 @cindex i386 jump optimization
355 Jump instructions are always optimized to use the smallest possible
356 displacements. This is accomplished by using byte (8-bit) displacement
357 jumps whenever the target is sufficiently close. If a byte displacement
358 is insufficient a long (32-bit) displacement is used. We do not support
359 word (16-bit) displacement jumps in 32-bit mode (i.e. prefixing the jump
360 instruction with the @samp{data16} instruction prefix), since the 80386
361 insists upon masking @samp{%eip} to 16 bits after the word displacement
364 Note that the @samp{jcxz}, @samp{jecxz}, @samp{loop}, @samp{loopz},
365 @samp{loope}, @samp{loopnz} and @samp{loopne} instructions only come in byte
366 displacements, so that if you use these instructions (@code{@value{GCC}} does
367 not use them) you may get an error message (and incorrect code). The AT&T
368 80386 assembler tries to get around this problem by expanding @samp{jcxz foo}
379 @section Floating Point
381 @cindex i386 floating point
382 @cindex floating point, i386
383 All 80387 floating point types except packed BCD are supported.
384 (BCD support may be added without much difficulty). These data
385 types are 16-, 32-, and 64- bit integers, and single (32-bit),
386 double (64-bit), and extended (80-bit) precision floating point.
387 Each supported type has an instruction mnemonic suffix and a constructor
388 associated with it. Instruction mnemonic suffixes specify the operand's
389 data type. Constructors build these data types into memory.
391 @cindex @code{float} directive, i386
392 @cindex @code{single} directive, i386
393 @cindex @code{double} directive, i386
394 @cindex @code{tfloat} directive, i386
397 Floating point constructors are @samp{.float} or @samp{.single},
398 @samp{.double}, and @samp{.tfloat} for 32-, 64-, and 80-bit formats.
399 These correspond to instruction mnemonic suffixes @samp{s}, @samp{l},
400 and @samp{t}. @samp{t} stands for 80-bit (ten byte) real. The 80387
401 only supports this format via the @samp{fldt} (load 80-bit real to stack
402 top) and @samp{fstpt} (store 80-bit real and pop stack) instructions.
404 @cindex @code{word} directive, i386
405 @cindex @code{long} directive, i386
406 @cindex @code{int} directive, i386
407 @cindex @code{quad} directive, i386
409 Integer constructors are @samp{.word}, @samp{.long} or @samp{.int}, and
410 @samp{.quad} for the 16-, 32-, and 64-bit integer formats. The
411 corresponding instruction mnemonic suffixes are @samp{s} (single),
412 @samp{l} (long), and @samp{q} (quad). As with the 80-bit real format,
413 the 64-bit @samp{q} format is only present in the @samp{fildq} (load
414 quad integer to stack top) and @samp{fistpq} (store quad integer and pop
418 Register to register operations should not use instruction mnemonic suffixes.
419 @samp{fstl %st, %st(1)} will give a warning, and be assembled as if you
420 wrote @samp{fst %st, %st(1)}, since all register to register operations
421 use 80-bit floating point operands. (Contrast this with @samp{fstl %st, mem},
422 which converts @samp{%st} from 80-bit to 64-bit floating point format,
423 then stores the result in the 4 byte location @samp{mem})
426 @section Intel's MMX and AMD's 3DNow! SIMD Operations
432 @code{@value{AS}} supports Intel's MMX instruction set (SIMD
433 instructions for integer data), available on Intel's Pentium MMX
434 processors and Pentium II processors, AMD's K6 and K6-2 processors,
435 Cyrix' M2 processor, and probably others. It also supports AMD's 3DNow!
436 instruction set (SIMD instructions for 32-bit floating point data)
437 available on AMD's K6-2 processor and possibly others in the future.
439 Currently, @code{@value{AS}} does not support Intel's floating point
442 The eight 64-bit MMX operands, also used by 3DNow!, are called @samp{%mm0},
443 @samp{%mm1}, ... @samp{%mm7}. They contain eight 8-bit integers, four
444 16-bit integers, two 32-bit integers, one 64-bit integer, or two 32-bit
445 floating point values. The MMX registers cannot be used at the same time
446 as the floating point stack.
448 See Intel and AMD documentation, keeping in mind that the operand order in
449 instructions is reversed from the Intel syntax.
452 @section Writing 16-bit Code
454 @cindex i386 16-bit code
455 @cindex 16-bit code, i386
456 @cindex real-mode code, i386
457 @cindex @code{code16gcc} directive, i386
458 @cindex @code{code16} directive, i386
459 @cindex @code{code32} directive, i386
460 While @code{@value{AS}} normally writes only ``pure'' 32-bit i386 code,
461 it also supports writing code to run in real mode or in 16-bit protected
462 mode code segments. To do this, put a @samp{.code16} or
463 @samp{.code16gcc} directive before the assembly language instructions to
464 be run in 16-bit mode. You can switch @code{@value{AS}} back to writing
465 normal 32-bit code with the @samp{.code32} directive.
467 @samp{.code16gcc} provides experimental support for generating 16-bit
468 code from gcc, and differs from @samp{.code16} in that @samp{call},
469 @samp{ret}, @samp{enter}, @samp{leave}, @samp{push}, @samp{pop},
470 @samp{pusha}, @samp{popa}, @samp{pushf}, and @samp{popf} instructions
471 default to 32-bit size. This is so that the stack pointer is
472 manipulated in the same way over function calls, allowing access to
473 function parameters at the same stack offsets as in 32-bit mode.
474 @samp{.code16gcc} also automatically adds address size prefixes where
475 necessary to use the 32-bit addressing modes that gcc generates.
477 The code which @code{@value{AS}} generates in 16-bit mode will not
478 necessarily run on a 16-bit pre-80386 processor. To write code that
479 runs on such a processor, you must refrain from using @emph{any} 32-bit
480 constructs which require @code{@value{AS}} to output address or operand
483 Note that writing 16-bit code instructions by explicitly specifying a
484 prefix or an instruction mnemonic suffix within a 32-bit code section
485 generates different machine instructions than those generated for a
486 16-bit code segment. In a 32-bit code section, the following code
487 generates the machine opcode bytes @samp{66 6a 04}, which pushes the
488 value @samp{4} onto the stack, decrementing @samp{%esp} by 2.
494 The same code in a 16-bit code section would generate the machine
495 opcode bytes @samp{6a 04} (ie. without the operand size prefix), which
496 is correct since the processor default operand size is assumed to be 16
497 bits in a 16-bit code section.
500 @section AT&T Syntax bugs
502 The UnixWare assembler, and probably other AT&T derived ix86 Unix
503 assemblers, generate floating point instructions with reversed source
504 and destination registers in certain cases. Unfortunately, gcc and
505 possibly many other programs use this reversed syntax, so we're stuck
514 results in @samp{%st(3)} being updated to @samp{%st - %st(3)} rather
515 than the expected @samp{%st(3) - %st}. This happens with all the
516 non-commutative arithmetic floating point operations with two register
517 operands where the source register is @samp{%st} and the destination
518 register is @samp{%st(i)}.
521 @section Specifying CPU Architecture
523 @cindex arch directive, i386
524 @cindex i386 arch directive
526 @code{@value{AS}} may be told to assemble for a particular CPU
527 architecture with the @code{.arch @var{cpu_type}} directive. This
528 directive enables a warning when gas detects an instruction that is not
529 supported on the CPU specified. The choices for @var{cpu_type} are:
531 @multitable @columnfractions .20 .20 .20 .20
532 @item @samp{i8086} @tab @samp{i186} @tab @samp{i286} @tab @samp{i386}
533 @item @samp{i486} @tab @samp{i586} @tab @samp{i686} @tab @samp{pentium}
534 @item @samp{pentiumpro} @tab @samp{k6} @tab @samp{athlon}
537 Apart from the warning, there is only one other effect on
538 @code{@value{AS}} operation; If you specify a CPU other than
539 @samp{i486}, then shift by one instructions such as @samp{sarl $1, %eax}
540 will automatically use a two byte opcode sequence. The larger three
541 byte opcode sequence is used on the 486 (and when no architecture is
542 specified) because it executes faster on the 486. Note that you can
543 explicitly request the two byte opcode by writing @samp{sarl %eax}.
548 @cindex i386 @code{mul}, @code{imul} instructions
549 @cindex @code{mul} instruction, i386
550 @cindex @code{imul} instruction, i386
551 There is some trickery concerning the @samp{mul} and @samp{imul}
552 instructions that deserves mention. The 16-, 32-, and 64-bit expanding
553 multiplies (base opcode @samp{0xf6}; extension 4 for @samp{mul} and 5
554 for @samp{imul}) can be output only in the one operand form. Thus,
555 @samp{imul %ebx, %eax} does @emph{not} select the expanding multiply;
556 the expanding multiply would clobber the @samp{%edx} register, and this
557 would confuse @code{@value{GCC}} output. Use @samp{imul %ebx} to get the
558 64-bit product in @samp{%edx:%eax}.
560 We have added a two operand form of @samp{imul} when the first operand
561 is an immediate mode expression and the second operand is a register.
562 This is just a shorthand, so that, multiplying @samp{%eax} by 69, for
563 example, can be done with @samp{imul $69, %eax} rather than @samp{imul