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# source:http://reocities.com/SiliconValley/heights/7052/opcode.txt | |
From: [email protected] (Mark Hopkins) | |
Newsgroups: alt.lang.asm | |
Subject: A Summary of the 80486 Opcodes and Instructions | |
(1) The 80x86 is an Octal Machine | |
This is a follow-up and revision of an article posted in alt.lang.asm on | |
7-5-92 concerning the 80x86 instruction encoding. | |
The only proper way to understand 80x86 coding is to realize that ALL 80x86 | |
OPCODES ARE CODED IN OCTAL. A byte has 3 octal digits, ranging from 000 to | |
377. In fact, each octal group (000-077, 100-177, etc.) tends to encode a | |
specific variety of operation. All of these are features inherited from the | |
8080/8085/Z80. | |
For some reason absolutely everybody misses all of this, even the Intel | |
people who wrote the reference on the 8086 (and even the 8080). The opcode | |
scheme outlined briefly below is expanded starting in the 80386, but | |
consistently with the overall scheme here. | |
As an example to see how this works, the mov instructions in octal are: | |
210 xrm mov Eb, Rb | |
211 xrm mov Ew, Rw | |
212 xrm mov Rb, Eb | |
213 xrm mov Rw, Ew | |
214 xsm mov Ew, SR | |
216 xsm mov SR, Ew | |
The meanings of the octal digits (x, m, r, s) and their correspondence to the | |
operands (Eb, Ew, Rb, Rw, SR) are the following: | |
The digit r (0-7) encodes the register operand as follows: | |
REGISTER (r): 0 1 2 3 4 5 6 7 | |
Rb = Byte-sized register AL CL DL BL AH CH DL BH | |
Rw = Word-sized register AX CX DX BX SP BP SI DI | |
The segment register digit s (0-7) encodes the segment register as follows: | |
SEGMENT REGISTER (s): 0 1 2 3 4 5 6 7 | |
SR = Segment register ES CS SS DS <Reserved> | |
The digits x (0-3), and m (0-7) encode the address mode according to | |
the following scheme. One or more bytes (labeled: Disp) may immediately | |
follow xrm as described below. | |
TABLE 1: 16-BIT ADDRESSING MODE (x, m): | |
Eb = Address of byte-sized object in memory or register | |
Ew = Address of word-sized object in memory or register | |
Dw = Unsigned word | |
Dc = Signed byte ("character"), range: -128 to +127 (decimal). | |
Db = Unsigned byte | |
x m Disp Eb Ew | |
------------------ | |
3 r Rb Rw | |
0 6 Dw DS:[Dw] | |
0 m Base:[0] (except for xm = 06). | |
1 m Dc Base:[Dc] | |
2 m Dw Base:[Dw] | |
x 0 Disp DS:[BX + SI + Disp] | |
x 1 Disp DS:[BX + DI + Disp] | |
x 2 Disp SS:[BP + SI + Disp] | |
x 3 Disp SS:[BP + DI + Disp] | |
x 4 Disp DS:[SI + Disp] | |
x 5 Disp SS:[DI + Disp] | |
x 6 Disp DS:[BP + Disp] (except for xm = 06) | |
x 7 Disp DS:[BX + Disp] | |
This expands into the following table: | |
TABLE 1a: 16-BIT ADDRESSING MODE (x, m) for the expansion impaired. :) | |
xm Eb/Ew xm Eb/Ew xm Eb/Ew xm Eb/Ew | |
00 DS:[BX + SI] 10 Dc DS:[BX + SI + Dc] 20 Dw DS:[BX + SI + Dw] 30 AL/AX | |
01 DS:[BX + DI] 11 Dc DS:[BX + BI + Dc] 21 Dw DS:[BX + DI + Dw] 31 CL/CX | |
02 SS:[BX + SI] 12 Dc SS:[BP + SI + Dc] 22 Dw SS:[BP + SI + Dw] 32 DL/DX | |
03 SS:[BX + DI] 13 Dc SS:[BP + DI + Dc] 23 Dw SS:[BP + DI + Dw] 33 BL/BX | |
04 DS:[SI] 14 Dc DS:[SI + Dc] 24 Dw DS:[SI + Dw] 34 AH/SP | |
05 DS:[DI] 15 Dc DS:[DI + Dc] 25 Dw DS:[DI + Dw] 35 CH/BP | |
06 Dw DS:[Dw] 16 Dc SS:[BP + Dc] 26 Dw SS:[BP + Dw] 36 DH/SI | |
07 DS:[BX] 17 Dc DS:[BX + Dc] 27 Dw DS:[BX + Dw] 37 BH/DI | |
Operands where x is 0, 1, or 2 are all pointers. If the instruction is a WORD | |
instruction (211, 213, 214, 216 are), then this pointer addresses a | |
word-sized object. The format of the object at the indicated address will | |
always be low-order byte first, and high-order byte second. Otherwise the | |
instruction is a BYTE instruction (210, 212) and the pointer addresses | |
byte-sized object at the indicated address. | |
The default segments (DS:, SS:) can be overridden with a segment prefix. In | |
all cases it's understood that everything has the default segment DS, except | |
for the two stack/frame pointers (BP and SP) whose default segment is SS. | |
That will be explained below. | |
Modes where x = 1, or 2 will require displacement bytes (Dc or Dw) to follow | |
the opcode as explained above. | |
When x = 3, WORD sized instructions address the word registers (AX, CX, ...) | |
and the BYTE size instructions the byte registers (AL, CL, ...). | |
EXAMPLE 1: The instruction opcode: 210 135 375 | |
Here, xm = 15, and r = 3, so the operands are: | |
mov Eb, Rb | |
=> | |
mov byte ptr DS:[DI + Dc], BL | |
The displacement, Dc, is 375 (or fd in hexadecimal), which is the signed byte | |
-3. So the instruction reads: | |
mov byte ptr DS:[DI - 3], BL | |
or just: | |
mov [DI - 3], BL | |
In C-like notation, the meaning of this operation would be: | |
((byte *)DS) [DI - 3] = BL; | |
EXAMPLE 2: The instruction opcode: 216 332 | |
Here, xm = 32, and s = 3, so the operands are: | |
mov SR, Ew | |
=> | |
mov DS, DX | |
A move to CS is not possible (because the far jump instruction already does | |
that) so that the opcode sequence: | |
216 x2m | |
is free to be used for encoding something else. | |
EXAMPLE 3: As an illustration of why it's better to think in octal, just look | |
at the opcodes for the binary arithmetic instructions: | |
0P0 xrm Op Eb, Rb | |
0P1 xrm Op Ew, Rw | |
0P2 xrm Op Rb, Eb | |
0P3 xrm Op Rw, Ew | |
0P4 Db Op AL, Db | |
0P5 Dw Op AX, Dw | |
They all have the same form, with a single digit encoding the operator as | |
follows: | |
P Op P Op | |
0 add 1 or | |
2 adc 3 sbb | |
4 and 5 sub | |
6 xor 7 cmp | |
That's a good fraction of your reference table right there. | |
EXAMPLE 4: The same mapping is used in the immediate to memory/register form | |
of these operations: | |
200 xPm Db Op Eb, Db | |
201 xPm Dw Op Ew, Dw | |
203 xPm Dc Op Ew, Dc | |
(2) An Outline of 80x86 Instructions and Encoding | |
The authors of 8080 and 8086 references (including Intel's own references) | |
are apparently not aware of the octal nature of their own machines, and the | |
result is an almost grotesque complication and bungling up in the presentation | |
of something that is actually fairly simple. Thus, people claim that it's | |
almost impossible to know 8086 binary by heart, whereas in fact I know most of | |
it by memory. I'll straighten out the mess for you here. | |
As alluded to above, instructions are encoded as follows: | |
op xrm Const | |
where * op is a 1 or 2 byte opcode, | |
* xrm (if present) constitutes 3 octal digits whose normal uses are: | |
r = Register operand, xm = Memory or Register operand. | |
It may be followed immediately by a "displacement" byte or word, | |
depending solely on the digits x and m. | |
* Const (if present) denotes a byte or word value whose presence and | |
format depends solely on what op (and sometimes xrm) is. | |
In some cases, the opcode itself may be separated out into octal digits, e.g. | |
0s6 = push (Segment Register #s). | |
The one major exception to the coding scheme are all the conditional code | |
operations. Since there are 16 distinct conditional codes, they are | |
represented as a hexadecimal digit. The conditional jump in octal ranges | |
from 160 to 177, which is 7x in hexadecimal, where x is a hex digit encoding | |
the jump's condition. I'll represent them by the format: 160+CC. | |
The register and address encoding was described above. The '386 expands on | |
this a little with the addition of two segment registers: | |
SEGMENT REGISTER (s): 0 1 2 3 4 5 6 7 | |
SR = Segment register ES CS SS DS FS GS <Reserved> | |
In TABLE 1, note that the addresses encoded on modes 0m, 1m, 2m are the same | |
regardless of whether you're referring to Eb or Ew. What distinguishes them | |
is the size of the object being pointed to and this can be explicitly | |
indicated in traditional '86 assemblers like the following examples: | |
byte ptr [BP] | |
word ptr [BX + DI] | |
As explained before, all addresses, except those involving BP refer to the | |
data segment, DS. All the BP's refer to the stack segment, SS. This | |
is about to be explained. | |
(3) Segmentation and Registers | |
The 80x86 was designed with more or less specific uses for its registers. | |
In fact, the names are supposed to reflect their main uses: | |
AX (AH:AL) = Accumulator | |
BX (BH:BL) = Base Register | |
CX (CH:CL) = Counting Register | |
DX (DH:DL) = Data Register | |
CS = Code Segment -- where constants and programs lie. | |
DS = Data Segment -- where static variables lie. | |
SS = Stack Segment -- where auto variables and function parameters lie. | |
SP, BP = Stack and Frame Pointers, used to segment out the | |
local variables and function parameters. | |
ES = Extra Segment -- used in combination with the index registers for | |
string operations as follows: | |
DS:[SI] -- points to the Source of the string operation. | |
ES:[DI] -- points to the Destinction of the string operation. | |
The typical setup for the stack is as follows: | |
High Addresses FUNCTION DEFINITION: FUNCTION CALL: | |
... mov BP, SP push Parameters | |
Parameters push BP call Function | |
Return Address sub SP, Locals | |
BP -> Old BP ... function ... | |
Local Variables mov SP, BP | |
SP -> ... pop BP | |
Low Addresses ret Parameters | |
this dictates a certain protocol in calling functions with parameters and | |
returning from them, as shown above. In fact, this is so much so that the | |
opening and closing sequences above have all been defined as single operations | |
starting with the 80286 so that the function definition above can be rewritten | |
as: | |
FUNCTION DEFINITION: | |
enter Locals, 0 | |
... function ... | |
leave | |
ret Parameters | |
(4) Word and Address Size on the 80386 and Above | |
Starting with the 80386, operations can be done with not just 16-bit words | |
but also 32 bit words. Generally the same operation is defined for both sets | |
and context is used to determine which is which in the following two ways: | |
* Which mode the machine is running in | |
Protected mode -- both word sizes and address sizes are 32-bits | |
Real & Virtual modes -- 16-bits. | |
* The presence of certain prefixes to override either the default | |
word size, address size or both on an instruction-by-instruction | |
basis. | |
(a) Word Size | |
When the word size for the current operation is 32-bits, everything listed | |
above as "word" is interpreted as 32-bits, including registers. The register | |
numbering corresponding to this word size is: | |
REGISTER (r): 0 1 2 3 4 5 6 7 | |
Rb = Byte-sized register AL CL DL BL AH CH DL BH | |
Rd = Dword-sized register EAX ECX EDX EBX ESP EBP ESI EDI | |
(b) Address Size | |
When the address size is switched to 32-bits, the address scheme listed in | |
TABLE 1 is altered in its entirety. | |
TABLE 2: 32-BIT ADDRESSING MODE (x, m): Encoding of scaled index SI: | |
x m Disp Eb Ew si SI | |
-------------------- --------------- | |
0 6 Dw DS:[Dw] s0 EAX * 2^s | |
0 4 sir [Rd + SI + 0] s1 ECX * 2^s | |
1 4 sir Dc [Rd + SI + Dc] s2 EDX * 2^s | |
2 4 sir Dw [Rd + SI + Dw] s3 EBX * 2^s | |
0 r [Rd + 0] (except r = 4, 6) 04 0 | |
1 r Dc [Rd + Dc] (except r = 4) s5 EBP * 2^s | |
2 r Dw [Rd + Dw] (except r = 4) s6 ESI * 2^s | |
3 r Rb Rw s7 EDI * 2^s | |
The encodings si = 14, 24 and 34 remain undefined. | |
This alteration is INDEPENDENT of the word size setting. That means that | |
even the "Dw"'s, "Rw"'s in the chart above will vary in interpretation as | |
16-bit or 32-bit objects depending on the word size setting. That leads to | |
4 possible combinations, not just 2. | |
EXAMPLE 5: The opcode sequence 211 135 375 | |
This is the operation | |
mov Ew, Rw | |
where xm = 15, r = 3 and Disp = -3. The 4 combinations are: | |
Addr-Size Word-Size Operation | |
16 16 mov word ptr [DI - 3], BX | |
16 32 mov dword ptr [DI - 3], EBX | |
32 16 mov word ptr [EBP - 3], BX | |
32 32 mov dword ptr [EBP - 3], EBX | |
EXAMPLE 6: The opcode sequence 211 134 302 375 with 32-bit addressing. | |
This is the move instruction where xm = 14 and r = 3. | |
mov Ew, [E]BX ([E]BX since r = 3) | |
It uses the indexed register addressing. The address, Ew, may be derived | |
as follows: | |
x m sir Disp Ew Comments | |
1 4 sir Dc [EDX + SI + Dc] | |
1 4 si2 375 [EDX + SI - 3] (Rd = EDX for r = 2) | |
1 4 302 375 [EDX + 8*EAX - 3] (SI = 8*EAX for si = 30) | |
Therefore, this instruction represents one of the following: | |
Word-Size Operation: 211 134 302 375 | |
16 mov word ptr [EDX + 8*EAX - 3], BX | |
32 mov dword ptr [EDX + 8*EAX - 3], EBX | |
(5) The Opcode Summary | |
The chart below summarises all the machine instructions. The following | |
abbreviations are used: | |
Registers: Immediate Data Constant: | |
Rb (byte sized) Db (byte sized) | |
Rw (word sized) Dw (word sized) | |
Rd (dword sized) Dc (signed byte) | |
Register/Memory Address: Relative Code Address: | |
Eb (byte sized) Cb (byte sized) | |
Ew (word sized) Cw (word sized) | |
Memory Address: Code Address: | |
Es (16 bit selector) Af (32/48 bit absolute far code address) | |
En (near 16/32 bit pointer) | |
Ef (far i32/48 bit pointer) | |
Ep (pointer to 6-byte object) | |
Ea (generic address) | |
Processor Extensions: | |
* = 80186 extension | |
$ = 80286 extension | |
# = 80386 extension | |
@ = 80486 extension | |
The switch between 16 and 32 bit word size affects all operands labeled | |
Rw, Ew, Dw, Cw, En and even Af and Ef. The latter two objects refer to | |
far code addresses which are 4 bytes when the word size is 16 bits, and | |
6 bytes else. | |
The only such operands not actually affected by the word-size switch are | |
those whose size a consequence of the operation's meaning. These include | |
the following: RET, BOUND, ARPL, SMSW, LMSW, LAR and LSL. | |
The switch between 16 and 32 bit address size affects all the operands | |
labeled Eb, Ew, Es, En, Ef, Ep, and Ea. Each of these is interpreted | |
according to the xm digts in the opcode according to either the 16-bit | |
addres table described near the start of the article or the 32-bit address | |
table just described above. | |
NOTE: In the following presentation everything is in octal. | |
ARITHMETIC & LOGIC | |
------------------ | |
Comments: | |
* All of these operations affect all 6 arithmetic flags, except NOT (which | |
affects no flags), and INC and DEC (which don't affect CF). | |
* IMUL and MUL only affect CF and OF predictably. | |
* IDIV and DIV affect no flags predictably. | |
* AND, OR, XOR, and TEST all set CF and OF to 0 and alter AF unpredictably. | |
* CMP and TEST have no affect on any operands. They're used for setting | |
flags. CMP is used for doing relational operators (< > <= >= == !=), and | |
TEST for doing bit-testing. | |
* CMP and TEST can have their operands listed in either order. | |
P Op Description | |
0 ADD L, E L += E | |
2 ADC L, E L += E + CF | |
5 SUB L, E L -= E | |
3 SBB L, E L -= E + CF | |
7 CMP L, E (void)(L - E) | |
1 OR L, E L |= E | |
4 AND L, E L &= E | |
6 XOR L, E L ^= E | |
0P0 xrm Op Eb, Rb | |
0P1 xrm Op Ew, Rw | |
0P2 xrm Op Rb, Eb | |
0P3 xrm Op Rw, Ew | |
0P4 Db Op AL, Db | |
0P5 Dw Op AX, Dw | |
200 xPm Db Op Eb, Db | |
201 xPm Dw Op Ew, Dw | |
203 xPm Dc Op Ew, Dc | |
NOT L L = ~L | |
366 x2m not Eb | |
367 x2m not Ew | |
NEG L L = -L | |
366 x3m neg Eb | |
367 x3m neg Ew | |
INC L L++ | |
10r inc Rw | |
376 x0m inc Eb | |
377 x0m inc Ew | |
DEC L L-- | |
11r dec Rw | |
376 x1m dec Eb | |
377 x1m dec Ew | |
TEST L, E (void)(L&E) | |
204 xrm test Rb, Eb | |
205 xrm test Rw, Ew | |
250 Db test AL, Db | |
251 Dw test AX, Dw | |
366 x0m Db test Eb, Db | |
367 x0m Dw test Ew, Dw | |
IMUL L, E, D L = (signed)E*D | |
IMUL L, E L = (signed)L*E | |
# 017 257 xrm Dw imul Rw, Ew | |
* 151 xrm Dw imul Rw, Ew, Dw | |
* 153 xrm Db imul Rw, Ew, Dc | |
In the following operations: | |
Operand Size ACC' ACC | |
1 AX AL | |
2 DX:AX AX | |
4 EDX:EAX EAX | |
P Op Description | |
4 MUL E ACC' = (unsigned) ACC*E | |
5 IMUL E ACC' = (signed) ACC*E | |
6 DIV E ACC' = (unsigned) ACC%E : ACC/E | |
7 IDIV E ACC' = (signed) ACC%E : ACC/E | |
366 xPm Op Eb | |
367 xPm Op Ew | |
SHIFTS & ROTATIONS | |
------------------ | |
Comments: | |
* Where applicable, N is masked off by 0x1f. | |
* For Rxx and Sxx, OF is predictably affected only when N is 1. | |
* SHLD and SHRD affect all 6 arithmetic flags, but OF and AF unpredictably. | |
* RxL: OF = (CF != high order bit of L) before shift | |
* RxR: OF = (high order bit of L != next high order bit of L) before shift | |
* SxL: OF = (CF != sign bit of L) after shift | |
* SxR: OF = (sign bit of L) after shift | |
P Op Description | |
0 ROL CF <- [<-<-<-] <- high order bit Rotate | |
1 ROR low order bit -> [->->->] -> CF | |
2 RCL CF <- [<-<-<-] <- CF Rotate Through CF | |
3 RCR CF -> [->->->] -> CF | |
4 SHL CF <- [<-<-<-] <- 0 Shift (unsigned) | |
5 SHR 0 -> [->->->] -> CF | |
4 SAL CF <- [<-<-<-] <- 0 Shift (signed) | |
7 SAR sign bit -> [->->->] -> CF | |
* 300 xPm Db Op Eb, Db | |
* 301 xPm Db Op Ew, Db | |
320 xPm Op Eb, 1 | |
321 xPm Op Ew, 1 | |
322 xPm Op Eb, CL | |
323 xPm Op Ew, CL | |
SHLD L, E, N CF:L = L:E << N | |
SHRD L, E, N L:CF = E:L >> N | |
# 017 244 Db shld Ew, Rw, Db | |
# 017 245 shld Ew, Rw, CL | |
# 017 254 Db shrd Ew, Rw, Db | |
# 017 255 shrd Ew, Rw, CL | |
TYPE CONVERSIONS | |
---------------- | |
[] Decimal Conversions | |
Comments: | |
* DAA and DAS are used for adjusting the results of addition and subtraction | |
respectively back to packed BCD format. They will alter all 6 of the | |
arithmetic flags, OF unpredictably. | |
* AAA, AAS, AAD, and AAM are used for adjusting the results of the four | |
basic arithmetic operations back to unpacked BCD format or ASCII format. | |
However, AAD is used *before* a divide operation. They too affect all | |
6 of the arithmetic flags, but only AF and CF predictably (for AAA and | |
AAS) or SF, ZF and PF (for AAD and AAM). | |
* In the following, A0 stands for the lower 4 bits of AL and A1 the upper | |
4 bits of AL. | |
* The binary codes for AAM and AAD each consist of an opcode followed by | |
a constant 10 (012 in octal). It has been said that this "10" is | |
actually a hidden parameter to a more general AAD and AAM operator, | |
which can actually be used for any base other than 10. Some processors | |
will not allow AAD to be generalized in this way, however. The reason it | |
was left out in the open like this was supposedly because the original | |
8086 design literally ran out of space to pack in the opcode. | |
DAA if (A0 > 9) AF = 1; if (AF) AL += (0x10 - 10); | |
if (A1 > 9) CF = 1; if (CF) AL += (0x10 - 10)*0x10; | |
DAS if (A0 > 9) AF = 1; if (AF) AL -= (0x10 - 10); | |
if (A1 > 9) CF = 1; if (CF) AL += (0x10 - 10)*0x10; | |
AAA if (A0 > 9) AF = 1; CF = AF; if (CF) A0 += (0x10 - 10), AH++; | |
AAS if (A0 > 9) AF = 1; CF = AF; if (CF) A0 -= (0x10 - 10), AH--; | |
AAM AX = AL/10 : AL%10 | |
AAD AX = (10*AH + AL)%0x10 | |
047 daa | |
057 das | |
067 aaa | |
077 aas | |
324 012 aam | |
325 012 aad | |
[] Sign Conversions | |
Comments: | |
* In converting from a shorter to longer operand size, sign conversion | |
involves either taking the leading (sign) bit and replicating it leftward | |
(conversion to signed), or placing zero's on the left (for conversion | |
to unsigned). | |
MOVSX L, E L = (signed)E | |
MOVZX L, E L = (unsigned)E | |
# 017 266 xrm movsx Rw, Eb | |
# 017 267 xrm movsx Rw, Ew | |
# 017 266 xrm movzx Ew, Rb | |
# 017 277 xrm movzx Ew, Rw | |
CBW AX = (signed)AL | |
CWDE EAX = (signed)AX | |
CWD DX:AX = (signed)AX | |
CDQ EDX:EAX = (signed)EAX | |
230 cbw / (#) cwde | |
231 cwd / (#) cdq | |
[] Byte Ordering | |
* Used to convert between "little Endian" (Intel byte ordering) and "big | |
Endian" (Motorola byte ordering). Typical use: networking applications. | |
BSWAP L L[0]:L[1]:L[2]:L[3] = L[3]:L[2]:L[1]:L[0] | |
@ 017 31r bswap Rd | |
[] Table Lookup | |
XLATB AL = [BX + AL] | |
327 xlatb | |
SEMAPHORES & SYNCHRONIZATION | |
---------------------------- | |
Comments: | |
* All these operations affect all 6 arithmetic flags. BT, BTS, BTR, BTC | |
affect only CF predictably; and BSF and BSR affect only ZF predictably. | |
* ACC is either AL, AX or EAX in CMPXCHG, depending on the operand size. | |
* WAIT is used in the '486 to force a pending unmasked interrupt from the | |
internal floating point processing unit. | |
* LOCK is a prefix used in multi-CPU contexts to assure exclusive access to | |
memory for the following two-step read & modify operations: | |
(INC, DEC, NEG, NOT) Mem (ADD, ADC, SUB, SBB) Mem, Src | |
(BT, BTS, BTR, BTC) Mem, Src (AND, XOR, OR) Mem, Src | |
XCHG Reg, Mem XCHG Mem, Reg | |
But XCHG automatically does its own LOCK so does not need to be prefixed. | |
P Op Description | |
4 BT L, N CF = L.N; | |
5 BTS L, N CF = L.N; L.N = 1; | |
6 BTR L, N CF = L.N; L.N = 0; | |
7 BTC L, N CF = L.N; L.N = !L.N; | |
# 017 2P3 xrm Op Ew, Rw | |
# 017 272 xPm Db Op Ew, Db | |
BSF L, E ZF = !E; if (ZF) L = First 1-bit position in E; else L = ??? | |
BSR L, E ZF = !E; if (ZF) L = Last 1-bit position in E; else L = ??? | |
# 017 274 xrm bsf Rw, Ew | |
# 017 275 xrm bsr Rw, Ew | |
CMPXCHG L, E ZF = (ACC == L); if (ZF) L = E; else ACC = L; | |
@ 017 246 xrm cmpxchg Eb, Rb | |
@ 017 247 xrm cmpxchg Ew, Rw | |
XADD L, L' <L, L'> = <L + L', L> | |
@ 017 300 xrm xadd Eb, Rb | |
@ 017 301 xrm xadd Ew, Rw | |
NOP Delay 1 cycle. | |
WAIT Wait for coprocessor unit. | |
LOCK Hardware memory bus semaphore. | |
HLT Wait for a reset or interrupt. | |
220 nop | |
233 wait | |
360 lock | |
364 hlt | |
INT N push [E]FLAGS, CS, [E]IP; TF = 0; | |
if (the Nth entry in the IDT is a Interrupt Gate) IF = 0; | |
jmp to the far address listed under the Nth entry in the IDT | |
INTO if (OF) INT 4 | |
IRET if (NT) return to task listed under TSS.BackLink; | |
else pop [E]IP, CS, [E]FLAGS; | |
314 int 3 | |
315 Db int Db | |
316 into | |
317 iret | |
FLAGS | |
----- | |
Comments: | |
* No flags are affected except the explicit moves to the FLAGS register: | |
POPF[D] and SAHF, but SAHF only sets the arithmetic flags (except OF). | |
POPF pop FLAGS | |
POPFD pop EFLAGS | |
PUSHF push FLAGS | |
PUSHFD push EFLAGS | |
SAHF FLAGS |= (AH & 0xd5) | |
LAHF AH = FLAGS; | |
234 pushf / (#) pushfd | |
235 popf / (#) popfd | |
236 sahf | |
237 lahf | |
CMC CF = !CF | |
CLC CF = 0 | |
STC CF = 1 | |
CLI IF = 0 (Interrupts off) | |
STI IF = 1 (Interrupts on) | |
CLD DF = 0 (Set string ops to increment) | |
STD DF = 1 (Set string ops to decrement) | |
365 cmc | |
370 clc | |
371 stc | |
372 cli | |
373 sti | |
374 cld | |
375 std | |
CONDITIONAL OPERATIONS | |
---------------------- | |
(NOTE: The values listed for CC are in octal). | |
CC Condition(s) Definition Descriptions | |
07 A NBE !CF && !ZF x > y x > 0 (unsigned) | |
03 AE NB !CF x >= y x >= 0 (unsigned) | |
02 B NAE CF x < y x < 0 (unsigned) | |
06 BE NA CF || ZF x <= y x <= 0 (unsigned) | |
17 G NLE SF == OF && !ZF x > y x > 0 (signed) | |
15 GE NL SF == OF x >= y x >= 0 (signed) | |
14 L NGE SF != OF x < y x < 0 (signed) | |
16 LE NG SF != OF || ZF x <= y x <= 0 (signed) | |
04 E Z ZF x == y x == 0 | |
05 NE NZ !ZF x != y x != 0 | |
00 O OF Overflow (signed overflow) | |
01 NO !OF No overflow (signed overflow) | |
02 C CF Carry (unsigned overflow) | |
03 NC !CF No carry (unsigned overflow) | |
10 S SF (Negative) sign | |
11 NS !SF No (negative) sign | |
12 P PE PF Parity [even] | |
13 NP PO !PF No parity (parity odd) | |
CC cc Cond. | |
Jcc Rel if (Cond) EIP += Rel; | |
SETcc L L = (Cond)? 1: 0; | |
# 017 200+CC Cw jcc Cw '=&h80+cc | |
# 017 220+CC x0m setcc Rb '=&h90+cc | |
160+CC jcc Cb '=&h70+cc | |
STACK OPERATIONS | |
---------------- | |
Comments: | |
* PUSHA[D] uses the value SP had before the operation started. | |
* POPA[D] doesn't actually affect [E]SP, which is why it's bracketed out. | |
* POP CS is not allowed because it's already subsumed by the RET (far) | |
operation. Instead, 017 is used as a 2-byte operation prefix. | |
* POP SS inhibits interrupts in order to allow [E]SP to be altered in the | |
following operation -- for what should be obvious reasons. | |
PUSH E SP -= sizeof E; SS:[SP] = E; | |
PUSHA push AX, CX, DX, BX, SP, BP, SI, DI | |
PUSHAD push EAX, ECX, EDX, EBX, ESP, EBP, ESI, EDI | |
# 017 240 push FS | |
# 017 250 push GS | |
0s6 push SR (s = 0-3) | |
12r push Rw | |
* 140 pusha / (#) pushad | |
150 Dw push Dw | |
152 Dc push Dc | |
377 x6m push Ew | |
POP L L = SS:[SP]; SP += sizeof L; | |
POPA pop DI, SI, BP, (SP), BX, DX, CX, AX | |
POPAD pop EDI, ESI, EBP, (ESP), EBX, EDX, ECX, EAX | |
# 017 241 pop FS | |
# 017 251 pop GS | |
0s7 pop SR (s = 0, 2-3) | |
13r pop Rw | |
* 141 popa / (#) popad | |
217 x0m pop Ew | |
TRANSFER OPERATIONS | |
------------------- | |
Comments: | |
* XCHG can have its operands listed in either order. | |
* MOV CS, ... is not allowed, since this is already subsumed by JMPs. | |
* LCS ... is not allowed either for the same reason. | |
* XCHG AX, AX is one and the same as NOP. | |
XCHG L, E <L, E> = <E, L> | |
206 xrm xchg Rb, Eb | |
207 xrm xchg Rw, Ew | |
22r xchg AX, Rw (r != 0) | |
MOV L, E L = E; | |
210 xrm mov Eb, Rb | |
211 xrm mov Ew, Rw | |
212 xrm mov Rb, Eb | |
213 xrm mov Rw, Ew | |
214 xsm mov Es, SR (s = 0-3, (#) 4-5) | |
216 xsm mov SR, Es (s = 0,2-3, (#) 4-5) | |
240 Dw mov AL, [Dw] | |
241 Dw mov AX, [Dw] | |
242 Dw mov [Dw], AL | |
243 Dw mov [Dw], AX | |
26r Db mov Rb, Db | |
27r Dw mov Rw, Dw | |
306 x0m Db mov Eb, Db | |
307 x0m Dw mov Ew, Dw | |
LEA L, An L = &An; | |
215 xrm lea Rw, En (x != 3) | |
LSeg L, Af Seg:L = &Af; | |
# 017 262 xrm lss Rw, Ef (x != 3) | |
# 017 264 xrm lfs Rw, Ef (x != 3) | |
# 017 265 xrm lgs Rw, Ef (x != 3) | |
304 xrm les Rw, Ef (x != 3) | |
305 xrm lds Rw, Ef (x != 3) | |
ADDRESSING | |
---------- | |
Comments: | |
* The current mode of the machine determines its default mode (16 or 32 | |
bits). | |
* RAND: and ADDR: (not an standard name, since Intel has none) are | |
prefixes that alter the default for the next instruction only. | |
* RAND: changes the word size between 16 and 32 bits. | |
* ADDR: changes the address size between 16 and 32 bits. | |
* seg: cannot override the implied ES:[DI] operand in any string op, | |
but can override the DS in the implied DS:[SI] operands there. | |
seg: Segment override prefix | |
ADDR: Address size toggle | |
RAND: Operand size toggle | |
305 xrm lds Rw, Ef (x != 3) | |
046 ES: | |
056 CS: | |
066 SS: | |
076 DS: | |
# 144 FS: | |
# 145 GS: | |
# 146 RAND: | |
# 147 ADDR: | |
PORT I/O | |
-------- | |
Comments: | |
* In protected mode the user of these operations must pass the I/O | |
Privilege Level (IOPL) else they are blocked by an interrupt. | |
This allows the Operating System to spool I/O devices in a | |
multitasking system (since the OS handles interrupts) to avoid having | |
processes all trying to use the same device at once. | |
IN ACC, Port ACC = IO[Port] | |
344 Db in AL, Db | |
345 Db in AX, Db | |
354 in AL, DX | |
355 in AX, DX | |
OUT Port, ACC IO[Port] = ACC | |
346 Db out Db, AL | |
347 Db out Db, AX | |
356 out DX, AL | |
357 out DX, AX | |
STRING OPERATIONS | |
----------------- | |
Comments: | |
* In all these operations below, Src denotes DS;[ESI] and Dest ES:[EDI]. | |
* Dest cannot be overridden by a segment prefix, only Src. | |
* The pointes (ESI, EDI) are bumped up (DF = 0) or down (DF = 1) after | |
the operation by sizeof Operand. | |
* ACC is either AL, AX or EAX depending on the operand size. | |
* The flags altered are exactly those altered by the corresponding | |
MOV, IN, OUT, or CMP operation (namely: only SCAS and CMPS alter the | |
flags and in the same way as CMP) and these are therefore the only ones | |
that can be prefixed by REP[N]E/REP[N]Z. | |
* REP with all string ops, but REP LODS doesn't do anything sensible. | |
INS in Dest, DX | |
OUTS out DX, Src | |
MOVS mov Dest, Src | |
CMPS cmp Dest, Src | |
STOS mov Dest, ACC | |
LODS mov ACC, Src | |
SCAS cmp ACC, Dest | |
* 154 insb | |
* 155 insw / (#) insd | |
* 156 outsb | |
* 157 outsw / (#) outsd | |
244 movsb | |
245 movsw / (#) movsd | |
246 cmpsb | |
247 cmpsw / (#) cmpsd | |
252 stosb | |
253 stosw / (#) stosd | |
254 lodsb | |
255 lodsw / (#) lodsd | |
256 scasb | |
257 scasw / (#) scasd | |
REP Op while (CX-- > 0) Op | |
REPE /REPZ Op while (CX-- > 0 && ZF) Op | |
REPNE/REPNZ Op while (CX-- > 0 && !ZF) Op | |
362 repne / repnz / rep | |
363 repe / repz | |
CONTROL FLOW | |
------------ | |
Comments: | |
* The distinction between near and far jumps/calls/returns is built right | |
into the 8086 language, which pretty much forces you to explicitly | |
declare a routine as "near" or "far" and be consistent about it. The | |
intended usage runs pretty much like C's static vs. global functions, | |
with each C file being analogous to an 8086 segment. | |
* The 8086 was specifically designed to be a Pascal (and PL/I) machine, | |
though. Intel wrongly assumed that one of these languages would become | |
like C is now. So the ENTER and LEAVE operators were added (and BOUND | |
to do array bounds-checking). The segmentation structure was intended | |
to support these types of languages. | |
JCXZ Rel if (!CX) IP += Rel; | |
JECXZ Rel if (!ECX) IP += Rel; | |
LOOPcc Rel if (!--CX && cc) IP += Rel; | |
340 Cb loopnz Cb / loopne Cb | |
341 Cb loopz Cb / loope Cb | |
342 Cb loop Cb | |
343 Cb jcxz Cb / (#) jecxz Cb | |
JMP Rel IP += Rel; | |
JMP FAR Af CS:IP = Af; | |
CALL Rel push IP; IP += Rel; | |
CALL FAR Af push CS, IP; IP = Af; | |
232 Af call Af | |
350 Cw call Cw | |
351 Cw jmp Cw | |
352 Af jmp far Af | |
353 Cb jmp Cb | |
377 x2m call En | |
377 x3m call far Ef | |
377 x4m jmp En | |
377 x5m jmp far Ef | |
RET Params pop IP; SP += Params (default: Params = 0) | |
RET FAR Params pop IP, CS; SP += Params (default: Params = 0) | |
302 Dw ret Dw | |
303 ret | |
312 Dw ret far Dw | |
313 ret far | |
ENTER Locs, N push EBP; | |
(sub EBP, 4; push [EBP]) N-1 times, if N > 0 | |
mov EBP, ESP | |
(add EBP, 4*(N-1); push EBP), if N > 0 | |
sub ESP, Locs | |
LEAVE mov ESP, EBP; pop EBP | |
* 310 Dw Db enter Dw, Db | |
* 311 leave | |
SYSTEM CONTROL & MEMORY PROTECTION | |
---------------------------------- | |
BOUND A, AA if (A not in range AA[0]..AA[1]) INT 5 | |
ARPL L, E ZF = (L.RPL < E.RPL); | |
if (ZF) L.RPL = E.RPL; | |
* 142 xrm bound Rw, Ed | |
$ 143 xrm arpl Es, Rw | |
SLDT Sel Sel = LDTR | |
STR Sel Sel = TR | |
LLDT Sel LDTR = Sel | |
LTR Sel TR = Sel | |
VERR Sel ZF = (Sel is accessible and has read-access) | |
VERW Sel ZF = (Sel is accessible and has write-access) | |
LAR L, Sel ZF = (Sel is accessible); | |
if (ZF) L = the access rights of Sel's descriptor. | |
LSL L, Sel ZF = (Sel is accessible); | |
if (ZF) L = the segment limit of Sel's descriptor. | |
$ 017 000 x0m sldt Ew | |
$ 017 000 x1m str Ew | |
$ 017 000 x2m lldt Ew | |
$ 017 000 x3m ltr Ew | |
$ 017 000 x4m verr Ew | |
$ 017 000 x5m verw Ew | |
$ 017 002 xrm lar Rw, Ew | |
$ 017 003 xrm lsl Rw, Ew | |
SGDT Desc Desc = GDTR | |
SIDT Desc Desc = IDTR | |
LGDT Desc GDTR = Desc | |
LIDT Desc IDTR = Desc | |
$ 017 001 x0m sgdt Ep | |
$ 017 001 x1m sidt Ep | |
$ 017 001 x2m lgdt Ep | |
$ 017 001 x3m lidt Ep | |
SMSW L L = MSW ... note that MSW is CR0 bits 0-15. | |
LMSW E MSW = E | |
CLTS MSW.3 = 0 ... clears the Task Switched flag. | |
$ 017 001 x4m smsw Ew | |
$ 017 001 x6m lmsw Ew | |
$ 017 006 clts | |
INVD Invalidate internal cache. | |
WBINVD Invalidate internal cache, after writing it back. | |
INVLPD Ea Invalidate Ea's page. | |
@ 017 010 invd | |
@ 017 011 wbinvd | |
@ 017 020 x7m invlpg Ea | |
MOV Reg, SysReg | |
MOV SysReg, Reg | |
# 017 040 3nr mov Rd, CRn (n = 0-3) | |
# 017 041 3nr mov Rd, DRn (n = 0-3, 6-7) | |
# 017 042 3nr mov CRn, Rd (n = 0, 2-3) | |
# 017 043 3nr mov DRn, Rd (n = 0-3, 6-7) | |
# 017 044 3nr mov Rd, TRn (n = 6-7) | |
# 017 046 3nr mov TRn, Rd (n = 6-7) | |
CO-PROCESSOR ESCAPE SEQUENCE | |
---------------------------- | |
Comments: | |
* This escape sequence is intended to be used with an external co-processor | |
with the most common application being the 80x87 floating point unit. | |
* Starting in the 80486, the floating point unit was made internal to the | |
processor. | |
ESC TL, Ea Escape, operation TL, address mode Ea. | |
33T xLm esc TL Ea | |
(6) Floating Point Operations | |
The Floating Point unit consists of 8 internal registers arranged in a | |
circular stack, and the Control Word (CW), Status Word (SW) and Tag Word (TW) | |
registers. The floating point stack registers all store data in Real80 | |
format (described below). | |
Operations are carried out on data in the following formats (low-order bits | |
on right): | |
INTEGER: 16/32/64 bits (Int16, Int32, Int64) | |
BCD: (BCD80) | |
S 0000000 D D D D D D D D D D D D D D D D D D | |
S = 1-bit sign (1 = negative, 0 = positive) | |
D = 4-bit digit (encodes digits 0-9). | |
FLOATING POINT: 32/64/80 bits (Real32, Real64, Real80) | |
S Exponent Mantissa | |
S = 1-bit sign (1 = negative, 0 = positive) | |
Exponent = 8/11/15 bit biased exponent | |
Mantissa = 23/52/64 bit decimal fraction. | |
The values of floating point numbers in each format are as follows: | |
Real32: (-1)^S (1 + Mantissa)/2^23 x 2^(Exponent - 127) | |
Real64: (-1)^S (1 + Mantissa)/2^52 x 2^(Exponent - 1023) | |
Real80: (-1)^S Mantissa/2^63 x 2^(Exponent - 16383) | |
The floatng point formats do not cover all the logical combination of binary | |
0's and 1's, and the remaining combinations are defined for special purposes: | |
Sign Exponent Mantissa Meaning | |
S 0 0 0 ... 0 0 0 0 ... 0 0 | |
S 0 0 0 ... 0 ... 1 ... DENORMAL (Infinitesimal) | |
S 1 1 1 ... 1 0 0 0 ... 0 INFINITY | |
S 1 1 1 ... 1 0 ... 1 ... Signalling NaN (Not a Number) | |
S 1 1 1 ... 1 1 ... Quiet NaN | |
This is all IEEE standard format. Quiet NaN's are set by the FP Unit to | |
indicate invalid operations. | |
Notation: | |
ST(n) -- the nth item below the stack top. | |
ST ----- ST(0), the stack top. | |
Int*, BCD*, Real* -- described above. | |
All Int*, BCD*, and Real* operands are stored in memory and are encoded in | |
the 80x86's current addressing mode (16 or 32 bit). All opcodes are | |
listed in the format: | |
T L xm for 8086 escape code 33T xLm | |
Since only memory addresses are used in the operations, that frees up all | |
the combinations xm where x = 3. These are generally used to encode the | |
operations that do not involve memory addresses. In the following | |
presentation where "xm" is listed generally, it is understood that x is not 3. | |
The operations FENI, FDISI are specific to the 8887; FSETPM to the 80287 | |
and FUCOM*, FPREM1, and the trig. operations FSIN, FCOS, FSINCOS are all | |
present only in the 80387 and after. | |
DATA TRANSFER | |
------------- | |
Comments: | |
* The followng table is used: | |
P 0 2 3 | |
F-OP fld fst fstp | |
I-OP fild fist fistp | |
FLD Arg ST = (Real80)Arg | |
FST Arg Arg = (typeof Arg)ST | |
FSTP Arg Arg = (typeof Arg)ST; pop(); | |
FXCH Arg Arg <--> ST, with appropriate type conversions. | |
1 P xm F-OP Real32 | |
3 P xm I-OP Int32 | |
5 P xm F-OP Real64 | |
7 P xm I-OP Int16 | |
3 5 xm fld Real80 | |
3 7 xm fstp Real80 | |
7 4 xm fbld BCD80 | |
7 5 xm fild Int64 | |
7 6 xm fbstp BCD80 | |
7 7 xm fistp Int64 | |
1 0 3m fld ST(m) | |
1 1 3m fxch ST(m) | |
5 2 3m fst ST(m) | |
5 3 3m fstp ST(m) | |
COMPARISON | |
---------- | |
Comments: | |
* The followng table is used: | |
P 2 3 | |
F-OP fcom fcomp | |
I-OP ficom ficomp | |
FCOM Arg cmp ST, Arg | |
FCOMP Arg cmp ST, Arg; pop(); | |
0 P xm F-OP Real32 | |
2 P xm I-OP Int32 | |
4 P xm F-OP Real64 | |
6 P xm I-OP Int16 | |
0 P 3m F-OP ST(m) | |
FCOMPP cmp ST, ST(1); pop(); pop(); | |
6 3 31 fcompp | |
FTST cmp ST, 0.0 | |
1 4 34 ftst | |
FXAM examine ST | |
1 4 35 fxam | |
FUCOM Arg unordered compare ST, Arg | |
FUCOMP Arg unordered compare ST, Arg; pop(); | |
FUCOMPP Arg unordered compare ST, ST(1); pop(); pop(); | |
5 4 3m fucom ST(m) | |
5 5 3m fucomp ST(m) | |
2 5 31 fucompp | |
ARITHMETIC OPERATIONS | |
--------------------- | |
Comments: | |
* The followng table is used: | |
P 0 1 4 5 6 7 | |
F-OP fadd fmul fsub fsubr fdiv fdivr | |
I-OP fiadd fimul fisub fisubr fidiv fidivr | |
P-OP faddp fmulp fsubp fsubrp fdivp fdivrp | |
* Dest is ST and Src the listed operand except where noted below. | |
FADD Arg Dest += Src | |
FSUB Arg Dest += Src | |
FSUBR Arg Dest = Src - Dest | |
FMUL Arg Dest *= Src | |
FDIV Arg Dest /= Src | |
FDIVR Arg Dest = Src/Dest | |
0 P xm F-OP Real32 | |
2 P xm I-OP Int32 | |
4 P xm F-OP Real64 | |
6 P xm I-OP Int16 | |
0 P 3m F-OP ST(m) | |
4 P 3m F-OP ST(m) (Dest = ST(m), Src = ST) | |
6 P 3m P-OP ST(m) (Dest = ST(m), Src = ST) | |
CONSTANTS | |
--------- | |
FLD1 ST = 1.0 | |
FLDL2T ST = log_2(10) | |
FLDL2E ST = log_2(e) | |
FLDPI ST = pi | |
FLDLG2 ST = log_10(2) | |
FLDLN2 ST = ln(2) | |
FLDZ ST = 0.0 | |
1 5 30 fld1 | |
1 5 31 fldl2t | |
1 5 32 fldl2e | |
1 5 33 fldpi | |
1 5 34 fldlg2 | |
1 5 35 fldln2 | |
1 5 36 fldz | |
BUILT-IN FUNCTIONS | |
------------------ | |
Comments: | |
* The stack replacements entail pop()'s. | |
FCHS ST = -ST | |
FABS ST = |ST| | |
F2XM1 ST = 2^ST - 1 | |
FYL2X Replace the stack: ST(1), ST -> ST(1)*log_2(ST) | |
FPTAN Replace the stack: ST -> tan(ST), 1.0 | |
FPATAN Replace the stack: ST(1), ST -> atan(ST(1)/ST) | |
FXTRACT Replace the stack: ST -> exponent(ST), mantissa(ST) | |
FPREM1 ST = remainder(ST/ST(1)), IEEE consistent | |
FPREM ST = remainder(ST/ST(1)) | |
FYL2XPI Replace the stack: ST(1), ST -> ST(1)*log_2(ST + 1) | |
FSQRT ST = sqrt(ST) | |
FSINCOS Replace the stack: ST -> sin(ST), cos(ST) | |
FRNDINT ST = round(ST) | |
FSCALE ST *= 2^(int)ST(1) | |
FSIN ST = sin(ST) | |
FCOS ST = cos(ST) | |
1 4 30 fchs | |
1 4 31 fabs | |
1 6 30 f2xm1 | |
1 6 31 fyl2x | |
1 6 32 fptan | |
1 6 33 fpatan | |
1 6 34 fxtract | |
1 6 35 fprem1 | |
1 7 30 fprem | |
1 7 31 fyl2xpi | |
1 7 32 fsqrt | |
1 7 33 fsincos | |
1 7 34 frndint | |
1 7 35 fscale | |
1 7 36 fsin | |
1 7 37 fcos | |
CONTROL | |
------- | |
Comments: | |
* The save and load operations for the environment and state are used | |
primarily for multitasking applications where 2 or more processes are | |
using the FP unit concurrently. | |
FNOP Delay 1 cycle. | |
FLDENV Arg Load FP environment from [Arg] | |
FLDCW Arg CW = Arg | |
FSTENV Arg Save FP environment to [Arg] | |
FSTCW Arg Arg = CW | |
FDECSTP TOP = (TOP - 1) mod 8 | |
FINCSTP TOP = (TOP + 1) mod 8 | |
FENI Enable interrupts (8087 only) | |
FDISI Disable interrupts (8087 only) | |
FCLEX Clear out FP exception flags | |
FINIT Initialize FP registers | |
FSETPM Enter Protected Mode (80287 only) | |
FFREE ST(m) Mark register m as unused. | |
FRSTOR Arg Restore FP state from [Arg] | |
FSAVE Arg Save FP state to [Arg] | |
FSTSW Arg Arg = SW | |
1 2 30 fnop | |
1 4 xm fldenv Ea | |
1 5 xm fldcw Ea | |
1 6 xm fstenv Ea | |
1 7 xm fstcw Ea | |
1 6 36 fdecstp | |
1 6 37 fincstp | |
3 4 30 feni | |
3 4 31 fdisi | |
3 4 32 fclex | |
3 4 33 finit | |
3 4 34 fsetpm | |
5 0 3m ffree ST(m) | |
5 4 xm frstor Ea | |
5 6 xm fsave Ea | |
5 7 xm fstsw Ea | |
7 4 30 fstsw AX |
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