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This appendix provides a complete list of the machine instructions which NASM will assemble, and a short description of the function of each one.
It is not intended to be exhaustive documentation on the fine details of
the instructions' function, such as which exceptions they can trigger: for
such documentation, you should go to Intel's Web site,
.
Instead, this appendix is intended primarily to provide documentation on
the way the instructions may be used within NASM. For example, looking up
will tell you that NASM allows
or
to be
specified as an optional second argument to the
instruction, to enforce which of the two
possible counter registers should be used if the default is not the one
desired.
The instructions are not quite listed in alphabetical order, since groups of instructions with similar functions are lumped together in the same entry. Most of them don't move very far from their alphabetic position because of this.
The instruction descriptions in this appendix specify their operands using the following notation:
reg8
denotes an 8-bit general
purpose register, reg16
denotes a 16-bit general
purpose register, and reg32
a 32-bit one.
fpureg
denotes one of the eight FPU stack
registers, mmxreg
denotes one of the eight 64-bit
MMX registers, and segreg
denotes a segment
register. In addition, some registers (such as
AL
, DX
or
ECX
) may be specified explicitly.
imm
denotes a generic
immediate operand. imm8
,
imm16
and imm32
are
used when the operand is intended to be a specific size. For some of these
instructions, NASM needs an explicit specifier: for example,
ADD ESP,16
could be interpreted as either
ADD r/m32,imm32
or
ADD r/m32,imm8
. NASM chooses the former by
default, and so you must specify ADD ESP,BYTE 16
for the latter.
mem
denotes a generic
memory reference; mem8
,
mem16
, mem32
,
mem64
and mem80
are
used when the operand needs to be a specific size. Again, a specifier is
needed in some cases: DEC [address]
is ambiguous
and will be rejected by NASM. You must specify
DEC BYTE [address]
,
DEC WORD [address]
or
DEC DWORD [address]
instead.
MOV
instruction allows a memory address to be
specified without allowing the normal range of register
combinations and effective address processing. This is denoted by
memoffs8
, memoffs16
and
memoffs32
.
r/m8
is a shorthand for
reg8/mem8
; similarly
r/m16
and r/m32
.
r/m64
is MMX-related, and is a shorthand for
mmxreg/mem64
.
This appendix also provides the opcodes which NASM will generate for each form of each instruction. The opcodes are listed in the following way:
3F
, indicates a fixed
byte containing that number.
+r
, such as
C8+r
, indicates that one of the operands to the
instruction is a register, and the `register value' of that register should
be added to the hex number to produce the generated byte. For example, EDX
has register value 2, so the code C8+r
, when the
register operand is EDX, generates the hex byte
CA
. Register values for specific registers are
given in section B.2.1.
+cc
, such as
40+cc
, indicates that the instruction name has a
condition code suffix, and the numeric representation of the condition code
should be added to the hex number to produce the generated byte. For
example, the code 40+cc
, when the instruction
contains the NE
condition, generates the hex byte
45
. Condition codes and their numeric
representations are given in section B.2.2.
/2
,
indicates that one of the operands to the instruction is a memory address
or register (denoted mem
or
r/m
, with an optional size). This is to be
encoded as an effective address, with a ModR/M byte, an optional SIB byte,
and an optional displacement, and the spare (register) field of the ModR/M
byte should be the digit given (which will be from 0 to 7, so it fits in
three bits). The encoding of effective addresses is given in
section B.2.5.
/r
combines the above two: it
indicates that one of the operands is a memory address or
r/m
, and another is a register, and that an
effective address should be generated with the spare (register) field in
the ModR/M byte being equal to the `register value' of the register
operand. The encoding of effective addresses is given in
section B.2.5; register values are given in
section B.2.1.
ib
, iw
and id
indicate that one of the operands to the
instruction is an immediate value, and that this is to be encoded as a
byte, little-endian word or little-endian doubleword respectively.
rb
, rw
and rd
indicate that one of the operands to the
instruction is an immediate value, and that the difference between
this value and the address of the end of the instruction is to be encoded
as a byte, word or doubleword respectively. Where the form
rw/rd
appears, it indicates that either
rw
or rd
should be used
according to whether assembly is being performed in
BITS 16
or BITS 32
state respectively.
ow
and od
indicate that one of the operands to the instruction is a reference to the
contents of a memory address specified as an immediate value: this encoding
is used in some forms of the MOV
instruction in
place of the standard effective-address mechanism. The displacement is
encoded as a word or doubleword. Again, ow/od
denotes that ow
or od
should be chosen according to the BITS
setting.
o16
and
o32
indicate that the given form of the
instruction should be assembled with operand size 16 or 32 bits. In other
words, o16
indicates a
66
prefix in BITS 32
state, but generates no code in BITS 16
state;
and o32
indicates a 66
prefix in BITS 16
state but generates nothing in
BITS 32
.
a16
and
a32
, similarly to o16
and o32
, indicate the address size of the given
form of the instruction. Where this does not match the
BITS
setting, a 67
prefix is required.
Where an instruction requires a register value, it is already implicit in the encoding of the rest of the instruction what type of register is intended: an 8-bit general-purpose register, a segment register, a debug register, an MMX register, or whatever. Therefore there is no problem with registers of different types sharing an encoding value.
The encodings for the various classes of register are:
AL
is 0,
CL
is 1, DL
is 2,
BL
is 3, AH
is 4,
CH
is 5, DH
is 6, and
BH
is 7.
AX
is 0,
CX
is 1, DX
is 2,
BX
is 3, SP
is 4,
BP
is 5, SI
is 6, and
DI
is 7.
EAX
is 0,
ECX
is 1, EDX
is 2,
EBX
is 3, ESP
is 4,
EBP
is 5, ESI
is 6, and
EDI
is 7.
ES
is 0,
CS
is 1, SS
is 2,
DS
is 3, FS
is 4, and
GS
is 5.
ST0
is 0,
ST1
is 1, ST2
is 2,
ST3
is 3, ST4
is 4,
ST5
is 5, ST6
is 6, and
ST7
is 7.
MM0
is 0,
MM1
is 1, MM2
is 2,
MM3
is 3, MM4
is 4,
MM5
is 5, MM6
is 6, and
MM7
is 7.
CR0
is 0,
CR2
is 2, CR3
is 3, and
CR4
is 4.
DR0
is 0,
DR1
is 1, DR2
is 2,
DR3
is 3, DR6
is 6, and
DR7
is 7.
TR3
is 3,
TR4
is 4, TR5
is 5,
TR6
is 6, and TR7
is 7.
(Note that wherever a register name contains a number, that number is also the register value for that register.)
The available condition codes are given here, along with their numeric representations as part of opcodes. Many of these condition codes have synonyms, so several will be listed at a time.
In the following descriptions, the word `either', when applied to two possible trigger conditions, is used to mean `either or both'. If `either but not both' is meant, the phrase `exactly one of' is used.
O
is 0 (trigger if the overflow flag is set);
NO
is 1.
B
, C
and
NAE
are 2 (trigger if the carry flag is set);
AE
, NB
and
NC
are 3.
E
and Z
are 4
(trigger if the zero flag is set); NE
and
NZ
are 5.
BE
and NA
are 6
(trigger if either of the carry or zero flags is set);
A
and NBE
are 7.
S
is 8 (trigger if the sign flag is set);
NS
is 9.
P
and PE
are 10
(trigger if the parity flag is set); NP
and
PO
are 11.
L
and NGE
are 12
(trigger if exactly one of the sign and overflow flags is set);
GE
and NL
are 13.
LE
and NG
are 14
(trigger if either the zero flag is set, or exactly one of the sign and
overflow flags is set); G
and
NLE
are 15.
Note that in all cases, the sense of a condition code may be reversed by changing the low bit of the numeric representation.
For details of when an instruction sets each of the status flags, see the individual instruction, plus the Status Flags reference in section B.2.4
The condition predicates for SSE comparison instructions are the codes used as part of the opcode, to determine what form of comparison is being carried out. In each case, the imm8 value is the final byte of the opcode encoding, and the predicate is the code used as part of the mnemonic for the instruction (equivalent to the "cc" in an integer instruction that used a condition code). The instructions that use this will give details of what the various mnemonics are, this table is used to help you work out details of what is happening.
Predi- imm8 Description Relation where: Emula- Result QNaN cate Encod- A Is 1st Operand tion if NaN Signal ing B Is 2nd Operand Operand Invalid EQ 000B equal A = B False No LT 001B less-than A < B False Yes LE 010B less-than- A <= B False Yes or-equal --- ---- greater A > B Swap False Yes than Operands, Use LT --- ---- greater- A >= B Swap False Yes than-or-equal Operands, Use LE UNORD 011B unordered A, B = Unordered True No NEQ 100B not-equal A != B True No NLT 101B not-less- NOT(A < B) True Yes than NLE 110B not-less- NOT(A <= B) True Yes than-or- equal --- ---- not-greater NOT(A > B) Swap True Yes than Operands, Use NLT --- ---- not-greater NOT(A >= B) Swap True Yes than- Operands, or-equal Use NLE ORD 111B ordered A , B = Ordered False No
The unordered relationship is true when at least one of the two values being compared is a NaN or in an unsupported format.
Note that the comparisons which are listed as not having a predicate or
encoding can only be achieved through software emulation, as described in
the "emulation" column. Note in particular that an instruction such as
is not the same as
, as, unlike with the
instruction, it has to take into account the
possibility of one operand containing a NaN or an unsupported numeric
format.
The status flags provide some information about the result of the
arithmetic instructions. This information can be used by conditional
instructions (such a
and
) as well as by some of the other
instructions (such as
and
).
There are 6 status flags:
CF - Carry flag.
Set if an arithmetic operation generates a carry or a borrow out of the most-significant bit of the result; cleared otherwise. This flag indicates an overflow condition for unsigned-integer arithmetic. It is also used in multiple-precision arithmetic.
PF - Parity flag.
Set if the least-significant byte of the result contains an even number of 1 bits; cleared otherwise.
AF - Adjust flag.
Set if an arithmetic operation generates a carry or a borrow out of bit 3 of the result; cleared otherwise. This flag is used in binary-coded decimal (BCD) arithmetic.
ZF - Zero flag.
Set if the result is zero; cleared otherwise.
SF - Sign flag.
Set equal to the most-significant bit of the result, which is the sign bit of a signed integer. (0 indicates a positive value and 1 indicates a negative value.)
OF - Overflow flag.
Set if the integer result is too large a positive number or too small a negative number (excluding the sign-bit) to fit in the destination operand; cleared otherwise. This flag indicates an overflow condition for signed-integer (two's complement) arithmetic.
An effective address is encoded in up to three parts: a ModR/M byte, an optional SIB byte, and an optional byte, word or doubleword displacement field.
The ModR/M byte consists of three fields: the
field, ranging from 0 to 3, in the upper two
bits of the byte, the
field, ranging from 0
to 7, in the lower three bits, and the spare (register) field in the middle
(bit 3 to bit 5). The spare field is not relevant to the effective address
being encoded, and either contains an extension to the instruction opcode
or the register value of another operand.
The ModR/M system can be used to encode a direct register reference
rather than a memory access. This is always done by setting the
field to 3 and the
field to the register value of the register
in question (it must be a general-purpose register, and the size of the
register must already be implicit in the encoding of the rest of the
instruction). In this case, the SIB byte and displacement field are both
absent.
In 16-bit addressing mode (either
with
no
prefix, or
with a
prefix), the SIB byte is never used. The general rules for
and
(there is
an exception, given below) are:
mod
field gives the length of the
displacement field: 0 means no displacement, 1 means one byte, and 2 means
two bytes.
r/m
field encodes the combination of
registers to be added to the displacement to give the accessed address: 0
means BX+SI
, 1 means
BX+DI
, 2 means BP+SI
, 3
means BP+DI
, 4 means SI
only, 5 means DI
only, 6 means
BP
only, and 7 means BX
only.
However, there is a special case:
mod
is 0 and r/m
is 6, the effective address encoded is not [BP]
as the above rules would suggest, but instead
[disp16]
: the displacement field is present and
is two bytes long, and no registers are added to the displacement.
Therefore the effective address
cannot be
encoded as efficiently as
; so if you code
in a program, NASM adds a notional 8-bit
zero displacement, and sets
to 1,
to 6, and the one-byte displacement field to
0.
In 32-bit addressing mode (either
with
a
prefix, or
with no
prefix) the general rules (again,
there are exceptions) for
and
are:
mod
field gives the length of the
displacement field: 0 means no displacement, 1 means one byte, and 2 means
four bytes.
ESP
, the r/m
field
gives its register value, and the SIB byte is absent. If the
r/m
field is 4 (which would encode
ESP
), the SIB byte is present and gives the
combination and scaling of registers to be added to the displacement.
If the SIB byte is present, it describes the combination of registers
(an optional base register, and an optional index register scaled by
multiplication by 1, 2, 4 or 8) to be added to the displacement. The SIB
byte is divided into the
field, in the top
two bits, the
field in the next three, and
the
field in the bottom three. The general
rules are:
base
field encodes the register value of
the base register.
index
field encodes the register value of
the index register, unless it is 4, in which case no index register is used
(so ESP
cannot be used as an index register).
scale
field encodes the multiplier by
which the index register is scaled before adding it to the base and
displacement: 0 encodes a multiplier of 1, 1 encodes 2, 2 encodes 4 and 3
encodes 8.
The exceptions to the 32-bit encoding rules are:
mod
is 0 and r/m
is 5, the effective address encoded is not [EBP]
as the above rules would suggest, but instead
[disp32]
: the displacement field is present and
is four bytes long, and no registers are added to the displacement.
mod
is 0, r/m
is
4 (meaning the SIB byte is present) and base
is
4, the effective address encoded is not
[EBP+index]
as the above rules would suggest, but
instead [disp32+index]
: the displacement field is
present and is four bytes long, and there is no base register (but the
index register is still processed in the normal way).
Given along with each instruction in this appendix is a set of flags, denoting the type of the instruction. The types are as follows:
8086
, 186
,
286
, 386
,
486
, PENT
and
P6
denote the lowest processor type that supports
the instruction. Most instructions run on all processors above the given
type; those that do not are documented. The Pentium II contains no
additional instructions beyond the P6 (Pentium Pro); from the point of view
of its instruction set, it can be thought of as a P6 with MMX capability.
3DNOW
indicates that the instruction is a
3DNow! one, and will run on the AMD K6-2 and later processors. ATHLON
extensions to the 3DNow! instruction set are documented as such.
CYRIX
indicates that the instruction is
specific to Cyrix processors, for example the extra MMX instructions in the
Cyrix extended MMX instruction set.
FPU
indicates that the instruction is a
floating-point one, and will only run on machines with a coprocessor
(automatically including 486DX, Pentium and above).
KATMAI
indicates that the instruction was
introduced as part of the Katmai New Instruction set. These instructions
are available on the Pentium III and later processors. Those which are not
specifically SSE instructions are also available on the AMD Athlon.
MMX
indicates that the instruction is an MMX
one, and will run on MMX-capable Pentium processors and the Pentium II.
PRIV
indicates that the instruction is a
protected-mode management instruction. Many of these may only be used in
protected mode, or only at privilege level zero.
SSE
and SSE2
indicate that the instruction is a Streaming SIMD Extension instruction.
These instructions operate on multiple values in a single operation. SSE
was introduced with the Pentium III and SSE2 was introduced with the
Pentium 4.
UNDOC
indicates that the instruction is an
undocumented one, and not part of the official Intel Architecture; it may
or may not be supported on any given machine.
WILLAMETTE
indicates that the instruction was
introduced as part of the new instruction set in the Pentium 4 and Intel
Xeon processors. These instructions are also known as SSE2 instructions.
AAA
, AAS
, AAM
, AAD
: ASCII AdjustmentsAAA ; 37 [8086]
AAS ; 3F [8086]
AAD ; D5 0A [8086] AAD imm ; D5 ib [8086]
AAM ; D4 0A [8086] AAM imm ; D4 ib [8086]
These instructions are used in conjunction with the add, subtract,
multiply and divide instructions to perform binary-coded decimal arithmetic
in unpacked (one BCD digit per byte - easy to translate to and
from
, hence the instruction names) form.
There are also packed BCD instructions
and
: see section
B.4.57.
AAA
(ASCII Adjust After Addition) should be
used after a one-byte ADD
instruction whose
destination was the AL
register: by means of
examining the value in the low nibble of AL
and
also the auxiliary carry flag AF
, it determines
whether the addition has overflowed, and adjusts it (and sets the carry
flag) if so. You can add long BCD strings together by doing
ADD
/AAA
on the low
digits, then doing
ADC
/AAA
on each
subsequent digit.
AAS
(ASCII Adjust AL After Subtraction) works
similarly to AAA
, but is for use after
SUB
instructions rather than
ADD
.
AAM
(ASCII Adjust AX After Multiply) is for
use after you have multiplied two decimal digits together and left the
result in AL
: it divides
AL
by ten and stores the quotient in
AH
, leaving the remainder in
AL
. The divisor 10 can be changed by specifying
an operand to the instruction: a particularly handy use of this is
AAM 16
, causing the two nibbles in
AL
to be separated into
AH
and AL
.
AAD
(ASCII Adjust AX Before Division)
performs the inverse operation to AAM
: it
multiplies AH
by ten, adds it to
AL
, and sets AH
to
zero. Again, the multiplier 10 can be changed.
ADC
: Add with CarryADC r/m8,reg8 ; 10 /r [8086] ADC r/m16,reg16 ; o16 11 /r [8086] ADC r/m32,reg32 ; o32 11 /r [386]
ADC reg8,r/m8 ; 12 /r [8086] ADC reg16,r/m16 ; o16 13 /r [8086] ADC reg32,r/m32 ; o32 13 /r [386]
ADC r/m8,imm8 ; 80 /2 ib [8086] ADC r/m16,imm16 ; o16 81 /2 iw [8086] ADC r/m32,imm32 ; o32 81 /2 id [386]
ADC r/m16,imm8 ; o16 83 /2 ib [8086] ADC r/m32,imm8 ; o32 83 /2 ib [386]
ADC AL,imm8 ; 14 ib [8086] ADC AX,imm16 ; o16 15 iw [8086] ADC EAX,imm32 ; o32 15 id [386]
performs integer addition: it adds its two
operands together, plus the value of the carry flag, and leaves the result
in its destination (first) operand. The destination operand can be a
register or a memory location. The source operand can be a register, a
memory location or an immediate value.
The flags are set according to the result of the operation: in
particular, the carry flag is affected and can be used by a subsequent
instruction.
In the forms with an 8-bit immediate second operand and a longer first
operand, the second operand is considered to be signed, and is
sign-extended to the length of the first operand. In these cases, the
qualifier is necessary to force NASM to
generate this form of the instruction.
To add two numbers without also adding the contents of the carry flag,
use
(section
B.4.3).
ADD
: Add IntegersADD r/m8,reg8 ; 00 /r [8086] ADD r/m16,reg16 ; o16 01 /r [8086] ADD r/m32,reg32 ; o32 01 /r [386]
ADD reg8,r/m8 ; 02 /r [8086] ADD reg16,r/m16 ; o16 03 /r [8086] ADD reg32,r/m32 ; o32 03 /r [386]
ADD r/m8,imm8 ; 80 /0 ib [8086] ADD r/m16,imm16 ; o16 81 /0 iw [8086] ADD r/m32,imm32 ; o32 81 /0 id [386]
ADD r/m16,imm8 ; o16 83 /0 ib [8086] ADD r/m32,imm8 ; o32 83 /0 ib [386]
ADD AL,imm8 ; 04 ib [8086] ADD AX,imm16 ; o16 05 iw [8086] ADD EAX,imm32 ; o32 05 id [386]
performs integer addition: it adds its two
operands together, and leaves the result in its destination (first)
operand. The destination operand can be a register or a memory location.
The source operand can be a register, a memory location or an immediate
value.
The flags are set according to the result of the operation: in
particular, the carry flag is affected and can be used by a subsequent
instruction.
In the forms with an 8-bit immediate second operand and a longer first
operand, the second operand is considered to be signed, and is
sign-extended to the length of the first operand. In these cases, the
qualifier is necessary to force NASM to
generate this form of the instruction.
ADDPD
: ADD Packed Double-Precision FP ValuesADDPD xmm1,xmm2/mem128 ; 66 0F 58 /r [WILLAMETTE,SSE2]
performs addition on each of two packed
double-precision FP value pairs.
dst[0-63] := dst[0-63] + src[0-63], dst[64-127] := dst[64-127] + src[64-127].
The destination is an
register. The source
operand can be either an
register or a
128-bit memory location.
ADDPS
: ADD Packed Single-Precision FP ValuesADDPS xmm1,xmm2/mem128 ; 0F 58 /r [KATMAI,SSE]
performs addition on each of four packed
single-precision FP value pairs
dst[0-31] := dst[0-31] + src[0-31], dst[32-63] := dst[32-63] + src[32-63], dst[64-95] := dst[64-95] + src[64-95], dst[96-127] := dst[96-127] + src[96-127].
The destination is an
register. The source
operand can be either an
register or a
128-bit memory location.
ADDSD
: ADD Scalar Double-Precision FP ValuesADDSD xmm1,xmm2/mem64 ; F2 0F 58 /r [KATMAI,SSE]
adds the low double-precision FP values
from the source and destination operands and stores the double-precision FP
result in the destination operand.
dst[0-63] := dst[0-63] + src[0-63], dst[64-127) remains unchanged.
The destination is an
register. The source
operand can be either an
register or a 64-bit
memory location.
ADDSS
: ADD Scalar Single-Precision FP ValuesADDSS xmm1,xmm2/mem32 ; F3 0F 58 /r [WILLAMETTE,SSE2]
adds the low single-precision FP values
from the source and destination operands and stores the single-precision FP
result in the destination operand.
dst[0-31] := dst[0-31] + src[0-31], dst[32-127] remains unchanged.
The destination is an
register. The source
operand can be either an
register or a 32-bit
memory location.
AND
: Bitwise ANDAND r/m8,reg8 ; 20 /r [8086] AND r/m16,reg16 ; o16 21 /r [8086] AND r/m32,reg32 ; o32 21 /r [386]
AND reg8,r/m8 ; 22 /r [8086] AND reg16,r/m16 ; o16 23 /r [8086] AND reg32,r/m32 ; o32 23 /r [386]
AND r/m8,imm8 ; 80 /4 ib [8086] AND r/m16,imm16 ; o16 81 /4 iw [8086] AND r/m32,imm32 ; o32 81 /4 id [386]
AND r/m16,imm8 ; o16 83 /4 ib [8086] AND r/m32,imm8 ; o32 83 /4 ib [386]
AND AL,imm8 ; 24 ib [8086] AND AX,imm16 ; o16 25 iw [8086] AND EAX,imm32 ; o32 25 id [386]
performs a bitwise AND operation between
its two operands (i.e. each bit of the result is 1 if and only if the
corresponding bits of the two inputs were both 1), and stores the result in
the destination (first) operand. The destination operand can be a register
or a memory location. The source operand can be a register, a memory
location or an immediate value.
In the forms with an 8-bit immediate second operand and a longer first
operand, the second operand is considered to be signed, and is
sign-extended to the length of the first operand. In these cases, the
qualifier is necessary to force NASM to
generate this form of the instruction.
The
instruction
(see section
B.4.202) performs the same operation on the 64-bit
registers.
ANDNPD
: Bitwise Logical AND NOT of Packed Double-Precision FP ValuesANDNPD xmm1,xmm2/mem128 ; 66 0F 55 /r [WILLAMETTE,SSE2]
inverts the bits of the two
double-precision floating-point values in the destination register, and
then performs a logical AND between the two double-precision floating-point
values in the source operand and the temporary inverted result, storing the
result in the destination register.
dst[0-63] := src[0-63] AND NOT dst[0-63], dst[64-127] := src[64-127] AND NOT dst[64-127].
The destination is an
register. The source
operand can be either an
register or a
128-bit memory location.
ANDNPS
: Bitwise Logical AND NOT of Packed Single-Precision FP ValuesANDNPS xmm1,xmm2/mem128 ; 0F 55 /r [KATMAI,SSE]
inverts the bits of the four
single-precision floating-point values in the destination register, and
then performs a logical AND between the four single-precision
floating-point values in the source operand and the temporary inverted
result, storing the result in the destination register.
dst[0-31] := src[0-31] AND NOT dst[0-31], dst[32-63] := src[32-63] AND NOT dst[32-63], dst[64-95] := src[64-95] AND NOT dst[64-95], dst[96-127] := src[96-127] AND NOT dst[96-127].
The destination is an
register. The source
operand can be either an
register or a
128-bit memory location.
ANDPD
: Bitwise Logical AND For Single FPANDPD xmm1,xmm2/mem128 ; 66 0F 54 /r [WILLAMETTE,SSE2]
performs a bitwise logical AND of the
two double-precision floating point values in the source and destination
operand, and stores the result in the destination register.
dst[0-63] := src[0-63] AND dst[0-63], dst[64-127] := src[64-127] AND dst[64-127].
The destination is an
register. The source
operand can be either an
register or a
128-bit memory location.
ANDPS
: Bitwise Logical AND For Single FPANDPS xmm1,xmm2/mem128 ; 0F 54 /r [KATMAI,SSE]
performs a bitwise logical AND of the
four single-precision floating point values in the source and destination
operand, and stores the result in the destination register.
dst[0-31] := src[0-31] AND dst[0-31], dst[32-63] := src[32-63] AND dst[32-63], dst[64-95] := src[64-95] AND dst[64-95], dst[96-127] := src[96-127] AND dst[96-127].
The destination is an
register. The source
operand can be either an
register or a
128-bit memory location.
ARPL
: Adjust RPL Field of SelectorARPL r/m16,reg16 ; 63 /r [286,PRIV]
expects its two word operands to be
segment selectors. It adjusts the
(requested
privilege level - stored in the bottom two bits of the selector) field of
the destination (first) operand to ensure that it is no less (i.e. no more
privileged than) the
field of the source
operand. The zero flag is set if and only if a change had to be made.
BOUND
: Check Array Index against BoundsBOUND reg16,mem ; o16 62 /r [186] BOUND reg32,mem ; o32 62 /r [386]
expects its second operand to point to
an area of memory containing two signed values of the same size as its
first operand (i.e. two words for the 16-bit form; two doublewords for the
32-bit form). It performs two signed comparisons: if the value in the
register passed as its first operand is less than the first of the
in-memory values, or is greater than or equal to the second, it throws a
exception. Otherwise, it does nothing.
BSF
, BSR
: Bit ScanBSF reg16,r/m16 ; o16 0F BC /r [386] BSF reg32,r/m32 ; o32 0F BC /r [386]
BSR reg16,r/m16 ; o16 0F BD /r [386] BSR reg32,r/m32 ; o32 0F BD /r [386]
BSF
searches for the least significant set
bit in its source (second) operand, and if it finds one, stores the index
in its destination (first) operand. If no set bit is found, the contents of
the destination operand are undefined. If the source operand is zero, the
zero flag is set.
BSR
performs the same function, but searches
from the top instead, so it finds the most significant set bit.
Bit indices are from 0 (least significant) to 15 or 31 (most significant). The destination operand can only be a register. The source operand can be a register or a memory location.
BSWAP
: Byte SwapBSWAP reg32 ; o32 0F C8+r [486]
swaps the order of the four bytes of a
32-bit register: bits 0-7 exchange places with bits 24-31, and bits 8-15
swap with bits 16-23. There is no explicit 16-bit equivalent: to byte-swap
,
,
or
,
can be used. When
is used with a 16-bit register, the result
is undefined.
BT
, BTC
, BTR
, BTS
: Bit TestBT r/m16,reg16 ; o16 0F A3 /r [386] BT r/m32,reg32 ; o32 0F A3 /r [386] BT r/m16,imm8 ; o16 0F BA /4 ib [386] BT r/m32,imm8 ; o32 0F BA /4 ib [386]
BTC r/m16,reg16 ; o16 0F BB /r [386] BTC r/m32,reg32 ; o32 0F BB /r [386] BTC r/m16,imm8 ; o16 0F BA /7 ib [386] BTC r/m32,imm8 ; o32 0F BA /7 ib [386]
BTR r/m16,reg16 ; o16 0F B3 /r [386] BTR r/m32,reg32 ; o32 0F B3 /r [386] BTR r/m16,imm8 ; o16 0F BA /6 ib [386] BTR r/m32,imm8 ; o32 0F BA /6 ib [386]
BTS r/m16,reg16 ; o16 0F AB /r [386] BTS r/m32,reg32 ; o32 0F AB /r [386] BTS r/m16,imm ; o16 0F BA /5 ib [386] BTS r/m32,imm ; o32 0F BA /5 ib [386]
These instructions all test one bit of their first operand, whose index is given by the second operand, and store the value of that bit into the carry flag. Bit indices are from 0 (least significant) to 15 or 31 (most significant).
In addition to storing the original value of the bit into the carry
flag,
also resets (clears) the bit in the
operand itself.
sets the bit, and
complements the bit.
does not modify its operands.
The destination can be a register or a memory location. The source can be a register or an immediate value.
If the destination operand is a register, the bit offset should be in the range 0-15 (for 16-bit operands) or 0-31 (for 32-bit operands). An immediate value outside these ranges will be taken modulo 16/32 by the processor.
If the destination operand is a memory location, then an immediate bit offset follows the same rules as for a register. If the bit offset is in a register, then it can be anything within the signed range of the register used (ie, for a 32-bit operand, it can be (-2^31) to (2^31 - 1)
CALL
: Call SubroutineCALL imm ; E8 rw/rd [8086] CALL imm:imm16 ; o16 9A iw iw [8086] CALL imm:imm32 ; o32 9A id iw [386] CALL FAR mem16 ; o16 FF /3 [8086] CALL FAR mem32 ; o32 FF /3 [386] CALL r/m16 ; o16 FF /2 [8086] CALL r/m32 ; o32 FF /2 [386]
calls a subroutine, by means of pushing
the current instruction pointer (
) and
optionally
as well on the stack, and then
jumping to a given address.
is pushed as well as
if and only if the call is a far call, i.e. a
destination segment address is specified in the instruction. The forms
involving two colon-separated arguments are far calls; so are the
forms.
The immediate near call takes one of two forms
(
, determined by the current
segment size limit. For 16-bit operands, you would use
, and for 32-bit operands you would
use
. The value passed as an
operand is a relative offset.
You can choose between the two immediate far call forms
(
) by the use of the
and
keywords:
) or
.
The
forms execute a far call by
loading the destination address out of memory. The address loaded consists
of 16 or 32 bits of offset (depending on the operand size), and 16 bits of
segment. The operand size may be overridden using
or
.
The
forms execute a near call (within
the same segment), loading the destination address out of memory or out of
a register. The keyword
may be specified,
for clarity, in these forms, but is not necessary. Again, operand size can
be overridden using
or
.
As a convenience, NASM does not require you to call a far procedure
symbol by coding the cumbersome
, but instead allows the
easier synonym
.
The
forms given above are near calls;
NASM will accept the
keyword (e.g.
), even though it is not
strictly necessary.
CBW
, CWD
, CDQ
, CWDE
: Sign ExtensionsCBW ; o16 98 [8086] CWDE ; o32 98 [386]
CWD ; o16 99 [8086] CDQ ; o32 99 [386]
All these instructions sign-extend a short value into a longer one, by replicating the top bit of the original value to fill the extended one.
extends
into
by repeating the top bit of
in every bit of
.
extends
into
.
extends
into
by
repeating the top bit of
throughout
, and
extends
into
.
CLC
, CLD
, CLI
, CLTS
: Clear FlagsCLC ; F8 [8086] CLD ; FC [8086] CLI ; FA [8086] CLTS ; 0F 06 [286,PRIV]
These instructions clear various flags.
clears the carry flag;
clears the direction
flag;
clears the interrupt flag (thus
disabling interrupts); and
clears the
task-switched (
) flag in
.
To set the carry, direction, or interrupt flags, use the
,
and
instructions
(section B.4.301). To invert the carry flag,
use
(section
B.4.22).
CLFLUSH
: Flush Cache LineCLFLUSH mem ; 0F AE /7 [WILLAMETTE,SSE2]
invalidates the cache line that
contains the linear address specified by the source operand from all levels
of the processor cache hierarchy (data and instruction). If, at any level
of the cache hierarchy, the line is inconsistent with memory (dirty) it is
written to memory before invalidation. The source operand points to a
byte-sized memory location.
Although
is flagged
and above, it may not be present on all
processors which have
support, and it may be
supported on other processors; the
instruction (section B.4.34) will return a
bit which indicates support for the
instruction.
CMC
: Complement Carry FlagCMC ; F5 [8086]
changes the value of the carry flag: if it
was 0, it sets it to 1, and vice versa.
CMOVcc
: Conditional MoveCMOVcc reg16,r/m16 ; o16 0F 40+cc /r [P6] CMOVcc reg32,r/m32 ; o32 0F 40+cc /r [P6]
moves its source (second) operand into
its destination (first) operand if the given condition code is satisfied;
otherwise it does nothing.
For a list of condition codes, see section B.2.2.
Although the
instructions are flagged
and above, they may not be supported by all
Pentium Pro processors; the
instruction
(section B.4.34) will return a bit which
indicates whether conditional moves are supported.
CMP
: Compare IntegersCMP r/m8,reg8 ; 38 /r [8086] CMP r/m16,reg16 ; o16 39 /r [8086] CMP r/m32,reg32 ; o32 39 /r [386]
CMP reg8,r/m8 ; 3A /r [8086] CMP reg16,r/m16 ; o16 3B /r [8086] CMP reg32,r/m32 ; o32 3B /r [386]
CMP r/m8,imm8 ; 80 /0 ib [8086] CMP r/m16,imm16 ; o16 81 /0 iw [8086] CMP r/m32,imm32 ; o32 81 /0 id [386]
CMP r/m16,imm8 ; o16 83 /0 ib [8086] CMP r/m32,imm8 ; o32 83 /0 ib [386]
CMP AL,imm8 ; 3C ib [8086] CMP AX,imm16 ; o16 3D iw [8086] CMP EAX,imm32 ; o32 3D id [386]
performs a `mental' subtraction of its
second operand from its first operand, and affects the flags as if the
subtraction had taken place, but does not store the result of the
subtraction anywhere.
In the forms with an 8-bit immediate second operand and a longer first
operand, the second operand is considered to be signed, and is
sign-extended to the length of the first operand. In these cases, the
qualifier is necessary to force NASM to
generate this form of the instruction.
The destination operand can be a register or a memory location. The source can be a register, memory location or an immediate value of the same size as the destination.
CMPccPD
: Packed Double-Precision FP Compare CMPPD xmm1,xmm2/mem128,imm8 ; 66 0F C2 /r ib [WILLAMETTE,SSE2]
CMPEQPD xmm1,xmm2/mem128 ; 66 0F C2 /r 00 [WILLAMETTE,SSE2] CMPLTPD xmm1,xmm2/mem128 ; 66 0F C2 /r 01 [WILLAMETTE,SSE2] CMPLEPD xmm1,xmm2/mem128 ; 66 0F C2 /r 02 [WILLAMETTE,SSE2] CMPUNORDPD xmm1,xmm2/mem128 ; 66 0F C2 /r 03 [WILLAMETTE,SSE2] CMPNEQPD xmm1,xmm2/mem128 ; 66 0F C2 /r 04 [WILLAMETTE,SSE2] CMPNLTPD xmm1,xmm2/mem128 ; 66 0F C2 /r 05 [WILLAMETTE,SSE2] CMPNLEPD xmm1,xmm2/mem128 ; 66 0F C2 /r 06 [WILLAMETTE,SSE2] CMPORDPD xmm1,xmm2/mem128 ; 66 0F C2 /r 07 [WILLAMETTE,SSE2]
The
instructions compare the two
packed double-precision FP values in the source and destination operands,
and returns the result of the comparison in the destination register. The
result of each comparison is a quadword mask of all 1s (comparison true) or
all 0s (comparison false).
The destination is an
register. The source
can be either an
register or a 128-bit memory
location.
The third operand is an 8-bit immediate value, of which the low 3 bits
define the type of comparison. For ease of programming, the 8 two-operand
pseudo-instructions are provided, with the third operand already filled in.
The
are:
EQ 0 Equal LT 1 Less-than LE 2 Less-than-or-equal UNORD 3 Unordered NE 4 Not-equal NLT 5 Not-less-than NLE 6 Not-less-than-or-equal ORD 7 Ordered
For more details of the comparison predicates, and details of how to emulate the "greater-than" equivalents, see section B.2.3
CMPccPS
: Packed Single-Precision FP Compare CMPPS xmm1,xmm2/mem128,imm8 ; 0F C2 /r ib [KATMAI,SSE]
CMPEQPS xmm1,xmm2/mem128 ; 0F C2 /r 00 [KATMAI,SSE] CMPLTPS xmm1,xmm2/mem128 ; 0F C2 /r 01 [KATMAI,SSE] CMPLEPS xmm1,xmm2/mem128 ; 0F C2 /r 02 [KATMAI,SSE] CMPUNORDPS xmm1,xmm2/mem128 ; 0F C2 /r 03 [KATMAI,SSE] CMPNEQPS xmm1,xmm2/mem128 ; 0F C2 /r 04 [KATMAI,SSE] CMPNLTPS xmm1,xmm2/mem128 ; 0F C2 /r 05 [KATMAI,SSE] CMPNLEPS xmm1,xmm2/mem128 ; 0F C2 /r 06 [KATMAI,SSE] CMPORDPS xmm1,xmm2/mem128 ; 0F C2 /r 07 [KATMAI,SSE]
The
instructions compare the two
packed single-precision FP values in the source and destination operands,
and returns the result of the comparison in the destination register. The
result of each comparison is a doubleword mask of all 1s (comparison true)
or all 0s (comparison false).
The destination is an
register. The source
can be either an
register or a 128-bit memory
location.
The third operand is an 8-bit immediate value, of which the low 3 bits
define the type of comparison. For ease of programming, the 8 two-operand
pseudo-instructions are provided, with the third operand already filled in.
The
are:
EQ 0 Equal LT 1 Less-than LE 2 Less-than-or-equal UNORD 3 Unordered NE 4 Not-equal NLT 5 Not-less-than NLE 6 Not-less-than-or-equal ORD 7 Ordered
For more details of the comparison predicates, and details of how to emulate the "greater-than" equivalents, see section B.2.3
CMPSB
, CMPSW
, CMPSD
: Compare StringsCMPSB ; A6 [8086] CMPSW ; o16 A7 [8086] CMPSD ; o32 A7 [386]
compares the byte at
or
with the byte at
or
, and sets the flags accordingly. It then
increments or decrements (depending on the direction flag: increments if
the flag is clear, decrements if it is set)
and
(or
and
).
The registers used are
and
if the address size is 16 bits, and
and
if it is 32
bits. If you need to use an address size not equal to the current
setting, you can use an explicit
or
prefix.
The segment register used to load from
or
can be overridden by using a segment
register name as a prefix (for example,
). The use of
for the load from
or
cannot be
overridden.
and
work
in the same way, but they compare a word or a doubleword instead of a byte,
and increment or decrement the addressing registers by 2 or 4 instead of 1.
The
and
prefixes (equivalently,
and
) may be used to repeat the instruction up
to
(or
- again,
the address size chooses which) times until the first unequal or equal byte
is found.
CMPccSD
: Scalar Double-Precision FP Compare CMPSD xmm1,xmm2/mem64,imm8 ; F2 0F C2 /r ib [WILLAMETTE,SSE2]
CMPEQSD xmm1,xmm2/mem64 ; F2 0F C2 /r 00 [WILLAMETTE,SSE2] CMPLTSD xmm1,xmm2/mem64 ; F2 0F C2 /r 01 [WILLAMETTE,SSE2] CMPLESD xmm1,xmm2/mem64 ; F2 0F C2 /r 02 [WILLAMETTE,SSE2] CMPUNORDSD xmm1,xmm2/mem64 ; F2 0F C2 /r 03 [WILLAMETTE,SSE2] CMPNEQSD xmm1,xmm2/mem64 ; F2 0F C2 /r 04 [WILLAMETTE,SSE2] CMPNLTSD xmm1,xmm2/mem64 ; F2 0F C2 /r 05 [WILLAMETTE,SSE2] CMPNLESD xmm1,xmm2/mem64 ; F2 0F C2 /r 06 [WILLAMETTE,SSE2] CMPORDSD xmm1,xmm2/mem64 ; F2 0F C2 /r 07 [WILLAMETTE,SSE2]
The
instructions compare the low-order
double-precision FP values in the source and destination operands, and
returns the result of the comparison in the destination register. The
result of each comparison is a quadword mask of all 1s (comparison true) or
all 0s (comparison false).
The destination is an
register. The source
can be either an
register or a 128-bit memory
location.
The third operand is an 8-bit immediate value, of which the low 3 bits
define the type of comparison. For ease of programming, the 8 two-operand
pseudo-instructions are provided, with the third operand already filled in.
The
are:
EQ 0 Equal LT 1 Less-than LE 2 Less-than-or-equal UNORD 3 Unordered NE 4 Not-equal NLT 5 Not-less-than NLE 6 Not-less-than-or-equal ORD 7 Ordered
For more details of the comparison predicates, and details of how to emulate the "greater-than" equivalents, see section B.2.3
CMPccSS
: Scalar Single-Precision FP Compare CMPSS xmm1,xmm2/mem32,imm8 ; F3 0F C2 /r ib [KATMAI,SSE]
CMPEQSS xmm1,xmm2/mem32 ; F3 0F C2 /r 00 [KATMAI,SSE] CMPLTSS xmm1,xmm2/mem32 ; F3 0F C2 /r 01 [KATMAI,SSE] CMPLESS xmm1,xmm2/mem32 ; F3 0F C2 /r 02 [KATMAI,SSE] CMPUNORDSS xmm1,xmm2/mem32 ; F3 0F C2 /r 03 [KATMAI,SSE] CMPNEQSS xmm1,xmm2/mem32 ; F3 0F C2 /r 04 [KATMAI,SSE] CMPNLTSS xmm1,xmm2/mem32 ; F3 0F C2 /r 05 [KATMAI,SSE] CMPNLESS xmm1,xmm2/mem32 ; F3 0F C2 /r 06 [KATMAI,SSE] CMPORDSS xmm1,xmm2/mem32 ; F3 0F C2 /r 07 [KATMAI,SSE]
The
instructions compare the low-order
single-precision FP values in the source and destination operands, and
returns the result of the comparison in the destination register. The
result of each comparison is a doubleword mask of all 1s (comparison true)
or all 0s (comparison false).
The destination is an
register. The source
can be either an
register or a 128-bit memory
location.
The third operand is an 8-bit immediate value, of which the low 3 bits
define the type of comparison. For ease of programming, the 8 two-operand
pseudo-instructions are provided, with the third operand already filled in.
The
are:
EQ 0 Equal LT 1 Less-than LE 2 Less-than-or-equal UNORD 3 Unordered NE 4 Not-equal NLT 5 Not-less-than NLE 6 Not-less-than-or-equal ORD 7 Ordered
For more details of the comparison predicates, and details of how to emulate the "greater-than" equivalents, see section B.2.3
CMPXCHG
, CMPXCHG486
: Compare and ExchangeCMPXCHG r/m8,reg8 ; 0F B0 /r [PENT] CMPXCHG r/m16,reg16 ; o16 0F B1 /r [PENT] CMPXCHG r/m32,reg32 ; o32 0F B1 /r [PENT]
CMPXCHG486 r/m8,reg8 ; 0F A6 /r [486,UNDOC] CMPXCHG486 r/m16,reg16 ; o16 0F A7 /r [486,UNDOC] CMPXCHG486 r/m32,reg32 ; o32 0F A7 /r [486,UNDOC]
These two instructions perform exactly the same operation; however,
apparently some (not all) 486 processors support it under a non-standard
opcode, so NASM provides the undocumented
form to generate the non-standard
opcode.
compares its destination (first)
operand to the value in
,
or
(depending on
the operand size of the instruction). If they are equal, it copies its
source (second) operand into the destination and sets the zero flag.
Otherwise, it clears the zero flag and copies the destination register to
AL, AX or EAX.
The destination can be either a register or a memory location. The source is a register.
is intended to be used for atomic
operations in multitasking or multiprocessor environments. To safely update
a value in shared memory, for example, you might load the value into
, load the updated value into
, and then execute the instruction
. If
has not changed since being loaded, it is
updated with your desired new value, and the zero flag is set to let you
know it has worked. (The
prefix prevents
another processor doing anything in the middle of this operation: it
guarantees atomicity.) However, if another processor has modified the value
in between your load and your attempted store, the store does not happen,
and you are notified of the failure by a cleared zero flag, so you can go
round and try again.
CMPXCHG8B
: Compare and Exchange Eight BytesCMPXCHG8B mem ; 0F C7 /1 [PENT]
This is a larger and more unwieldy version of
: it compares the 64-bit (eight-byte)
value stored at
with the value in
. If they are equal, it sets the zero flag
and stores
into the memory area. If they
are unequal, it clears the zero flag and stores the memory contents into
.
can be used with the
prefix, to allow atomic execution. This is
useful in multi-processor and multi-tasking environments.
COMISD
: Scalar Ordered Double-Precision FP Compare and Set EFLAGSCOMISD xmm1,xmm2/mem64 ; 66 0F 2F /r [WILLAMETTE,SSE2]
compares the low-order double-precision
FP value in the two source operands. ZF, PF and CF are set according to the
result. OF, AF and AF are cleared. The unordered result is returned if
either source is a NaN (QNaN or SNaN).
The destination operand is an
register.
The source can be either an
register or a
memory location.
The flags are set according to the following rules:
Result Flags Values
UNORDERED: ZF,PF,CF <-- 111; GREATER_THAN: ZF,PF,CF <-- 000; LESS_THAN: ZF,PF,CF <-- 001; EQUAL: ZF,PF,CF <-- 100;
COMISS
: Scalar Ordered Single-Precision FP Compare and Set EFLAGSCOMISS xmm1,xmm2/mem32 ; 66 0F 2F /r [KATMAI,SSE]
compares the low-order single-precision
FP value in the two source operands. ZF, PF and CF are set according to the
result. OF, AF and AF are cleared. The unordered result is returned if
either source is a NaN (QNaN or SNaN).
The destination operand is an
register.
The source can be either an
register or a
memory location.
The flags are set according to the following rules:
Result Flags Values
UNORDERED: ZF,PF,CF <-- 111; GREATER_THAN: ZF,PF,CF <-- 000; LESS_THAN: ZF,PF,CF <-- 001; EQUAL: ZF,PF,CF <-- 100;
CPUID
: Get CPU Identification CodeCPUID ; 0F A2 [PENT]
returns various information about the
processor it is being executed on. It fills the four registers
,
,
and
with
information, which varies depending on the input contents of
.
also acts as a barrier to serialise
instruction execution: executing the
instruction guarantees that all the effects (memory modification, flag
modification, register modification) of previous instructions have been
completed before the next instruction gets fetched.
The information returned is as follows:
EAX
is zero on input,
EAX
on output holds the maximum acceptable input
value of EAX
, and
EBX:EDX:ECX
contain the string
"GenuineIntel"
(or not, if you have a clone
processor). That is to say, EBX
contains
"Genu"
(in NASM's own sense of character
constants, described in section
3.4.2), EDX
contains
"ineI"
and ECX
contains
"ntel"
.
EAX
is one on input,
EAX
on output contains version information about
the processor, and EDX
contains a set of feature
flags, showing the presence and absence of various features. For example,
bit 8 is set if the CMPXCHG8B
instruction
(section B.4.31) is supported, bit 15 is set
if the conditional move instructions (section
B.4.23 and section B.4.72) are supported,
and bit 23 is set if MMX
instructions are
supported.
EAX
is two on input,
EAX
, EBX
,
ECX
and EDX
all contain
information about caches and TLBs (Translation Lookahead Buffers).
For more information on the data returned from
, see the documentation from Intel and other
processor manufacturers.
CVTDQ2PD
: Packed Signed INT32 to Packed Double-Precision FP ConversionCVTDQ2PD xmm1,xmm2/mem64 ; F3 0F E6 /r [WILLAMETTE,SSE2]
converts two packed signed
doublewords from the source operand to two packed double-precision FP
values in the destination operand.
The destination operand is an
register.
The source can be either an
register or a
64-bit memory location. If the source is a register, the packed integers
are in the low quadword.
CVTDQ2PS
: Packed Signed INT32 to Packed Single-Precision FP ConversionCVTDQ2PS xmm1,xmm2/mem128 ; 0F 5B /r [WILLAMETTE,SSE2]
converts four packed signed
doublewords from the source operand to four packed single-precision FP
values in the destination operand.
The destination operand is an
register.
The source can be either an
register or a
128-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTPD2DQ
: Packed Double-Precision FP to Packed Signed INT32 ConversionCVTPD2DQ xmm1,xmm2/mem128 ; F2 0F E6 /r [WILLAMETTE,SSE2]
converts two packed double-precision
FP values from the source operand to two packed signed doublewords in the
low quadword of the destination operand. The high quadword of the
destination is set to all 0s.
The destination operand is an
register.
The source can be either an
register or a
128-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTPD2PI
: Packed Double-Precision FP to Packed Signed INT32 ConversionCVTPD2PI mm,xmm/mem128 ; 66 0F 2D /r [WILLAMETTE,SSE2]
converts two packed double-precision
FP values from the source operand to two packed signed doublewords in the
destination operand.
The destination operand is an
register.
The source can be either an
register or a
128-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTPD2PS
: Packed Double-Precision FP to Packed Single-Precision FP ConversionCVTPD2PS xmm1,xmm2/mem128 ; 66 0F 5A /r [WILLAMETTE,SSE2]
converts two packed double-precision
FP values from the source operand to two packed single-precision FP values
in the low quadword of the destination operand. The high quadword of the
destination is set to all 0s.
The destination operand is an
register.
The source can be either an
register or a
128-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTPI2PD
: Packed Signed INT32 to Packed Double-Precision FP ConversionCVTPI2PD xmm,mm/mem64 ; 66 0F 2A /r [WILLAMETTE,SSE2]
converts two packed signed
doublewords from the source operand to two packed double-precision FP
values in the destination operand.
The destination operand is an
register.
The source can be either an
register or a
64-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTPI2PS
: Packed Signed INT32 to Packed Single-FP ConversionCVTPI2PS xmm,mm/mem64 ; 0F 2A /r [KATMAI,SSE]
converts two packed signed
doublewords from the source operand to two packed single-precision FP
values in the low quadword of the destination operand. The high quadword of
the destination remains unchanged.
The destination operand is an
register.
The source can be either an
register or a
64-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTPS2DQ
: Packed Single-Precision FP to Packed Signed INT32 ConversionCVTPS2DQ xmm1,xmm2/mem128 ; 66 0F 5B /r [WILLAMETTE,SSE2]
converts four packed single-precision
FP values from the source operand to four packed signed doublewords in the
destination operand.
The destination operand is an
register.
The source can be either an
register or a
128-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTPS2PD
: Packed Single-Precision FP to Packed Double-Precision FP ConversionCVTPS2PD xmm1,xmm2/mem64 ; 0F 5A /r [WILLAMETTE,SSE2]
converts two packed single-precision
FP values from the source operand to two packed double-precision FP values
in the destination operand.
The destination operand is an
register.
The source can be either an
register or a
64-bit memory location. If the source is a register, the input values are
in the low quadword.
For more details of this instruction, see the Intel Processor manuals.
CVTPS2PI
: Packed Single-Precision FP to Packed Signed INT32 ConversionCVTPS2PI mm,xmm/mem64 ; 0F 2D /r [KATMAI,SSE]
converts two packed single-precision
FP values from the source operand to two packed signed doublewords in the
destination operand.
The destination operand is an
register.
The source can be either an
register or a
64-bit memory location. If the source is a register, the input values are
in the low quadword.
For more details of this instruction, see the Intel Processor manuals.
CVTSD2SI
: Scalar Double-Precision FP to Signed INT32 ConversionCVTSD2SI reg32,xmm/mem64 ; F2 0F 2D /r [WILLAMETTE,SSE2]
converts a double-precision FP value
from the source operand to a signed doubleword in the destination operand.
The destination operand is a general purpose register. The source can be
either an
register or a 64-bit memory
location. If the source is a register, the input value is in the low
quadword.
For more details of this instruction, see the Intel Processor manuals.
CVTSD2SS
: Scalar Double-Precision FP to Scalar Single-Precision FP ConversionCVTSD2SS xmm1,xmm2/mem64 ; F2 0F 5A /r [KATMAI,SSE]
converts a double-precision FP value
from the source operand to a single-precision FP value in the low
doubleword of the destination operand. The upper 3 doublewords are left
unchanged.
The destination operand is an
register.
The source can be either an
register or a
64-bit memory location. If the source is a register, the input value is in
the low quadword.
For more details of this instruction, see the Intel Processor manuals.
CVTSI2SD
: Signed INT32 to Scalar Double-Precision FP ConversionCVTSI2SD xmm,r/m32 ; F2 0F 2A /r [WILLAMETTE,SSE2]
converts a signed doubleword from the
source operand to a double-precision FP value in the low quadword of the
destination operand. The high quadword is left unchanged.
The destination operand is an
register.
The source can be either a general purpose register or a 32-bit memory
location.
For more details of this instruction, see the Intel Processor manuals.
CVTSI2SS
: Signed INT32 to Scalar Single-Precision FP ConversionCVTSI2SS xmm,r/m32 ; F3 0F 2A /r [KATMAI,SSE]
converts a signed doubleword from the
source operand to a single-precision FP value in the low doubleword of the
destination operand. The upper 3 doublewords are left unchanged.
The destination operand is an
register.
The source can be either a general purpose register or a 32-bit memory
location.
For more details of this instruction, see the Intel Processor manuals.
CVTSS2SD
: Scalar Single-Precision FP to Scalar Double-Precision FP ConversionCVTSS2SD xmm1,xmm2/mem32 ; F3 0F 5A /r [WILLAMETTE,SSE2]
converts a single-precision FP value
from the source operand to a double-precision FP value in the low quadword
of the destination operand. The upper quadword is left unchanged.
The destination operand is an
register.
The source can be either an
register or a
32-bit memory location. If the source is a register, the input value is
contained in the low doubleword.
For more details of this instruction, see the Intel Processor manuals.
CVTSS2SI
: Scalar Single-Precision FP to Signed INT32 ConversionCVTSS2SI reg32,xmm/mem32 ; F3 0F 2D /r [KATMAI,SSE]
converts a single-precision FP value
from the source operand to a signed doubleword in the destination operand.
The destination operand is a general purpose register. The source can be
either an
register or a 32-bit memory
location. If the source is a register, the input value is in the low
doubleword.
For more details of this instruction, see the Intel Processor manuals.
CVTTPD2DQ
: Packed Double-Precision FP to Packed Signed INT32 Conversion with TruncationCVTTPD2DQ xmm1,xmm2/mem128 ; 66 0F E6 /r [WILLAMETTE,SSE2]
converts two packed double-precision
FP values in the source operand to two packed single-precision FP values in
the destination operand. If the result is inexact, it is truncated (rounded
toward zero). The high quadword is set to all 0s.
The destination operand is an
register.
The source can be either an
register or a
128-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTTPD2PI
: Packed Double-Precision FP to Packed Signed INT32 Conversion with TruncationCVTTPD2PI mm,xmm/mem128 ; 66 0F 2C /r [WILLAMETTE,SSE2]
converts two packed double-precision
FP values in the source operand to two packed single-precision FP values in
the destination operand. If the result is inexact, it is truncated (rounded
toward zero).
The destination operand is an
register.
The source can be either an
register or a
128-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTTPS2DQ
: Packed Single-Precision FP to Packed Signed INT32 Conversion with TruncationCVTTPS2DQ xmm1,xmm2/mem128 ; F3 0F 5B /r [WILLAMETTE,SSE2]
converts four packed
single-precision FP values in the source operand to four packed signed
doublewords in the destination operand. If the result is inexact, it is
truncated (rounded toward zero).
The destination operand is an
register.
The source can be either an
register or a
128-bit memory location.
For more details of this instruction, see the Intel Processor manuals.
CVTTPS2PI
: Packed Single-Precision FP to Packed Signed INT32 Conversion with TruncationCVTTPS2PI mm,xmm/mem64 ; 0F 2C /r [KATMAI,SSE]
converts two packed single-precision
FP values in the source operand to two packed signed doublewords in the
destination operand. If the result is inexact, it is truncated (rounded
toward zero). If the source is a register, the input values are in the low
quadword.
The destination operand is an
register.
The source can be either an
register or a
64-bit memory location. If the source is a register, the input value is in
the low quadword.
For more details of this instruction, see the Intel Processor manuals.
CVTTSD2SI
: Scalar Double-Precision FP to Signed INT32 Conversion with TruncationCVTTSD2SI reg32,xmm/mem64 ; F2 0F 2C /r [WILLAMETTE,SSE2]
converts a double-precision FP value
in the source operand to a signed doubleword in the destination operand. If
the result is inexact, it is truncated (rounded toward zero).
The destination operand is a general purpose register. The source can be
either an
register or a 64-bit memory
location. If the source is a register, the input value is in the low
quadword.
For more details of this instruction, see the Intel Processor manuals.
CVTTSS2SI
: Scalar Single-Precision FP to Signed INT32 Conversion with TruncationCVTTSD2SI reg32,xmm/mem32 ; F3 0F 2C /r [KATMAI,SSE]
converts a single-precision FP value
in the source operand to a signed doubleword in the destination operand. If
the result is inexact, it is truncated (rounded toward zero).
The destination operand is a general purpose register. The source can be
either an
register or a 32-bit memory
location. If the source is a register, the input value is in the low
doubleword.
For more details of this instruction, see the Intel Processor manuals.
DAA
, DAS
: Decimal AdjustmentsDAA ; 27 [8086] DAS ; 2F [8086]
These instructions are used in conjunction with the add and subtract instructions to perform binary-coded decimal arithmetic in packed (one BCD digit per nibble) form. For the unpacked equivalents, see section B.4.1.
should be used after a one-byte
instruction whose destination was the
register: by means of examining the value in
the
and also the auxiliary carry flag
, it determines whether either digit of the
addition has overflowed, and adjusts it (and sets the carry and
auxiliary-carry flags) if so. You can add long BCD strings together by
doing
/
on the
low two digits, then doing
/
on each
subsequent pair of digits.
works similarly to
, but is for use after
instructions rather than
.
DEC
: Decrement IntegerDEC reg16 ; o16 48+r [8086] DEC reg32 ; o32 48+r [386] DEC r/m8 ; FE /1 [8086] DEC r/m16 ; o16 FF /1 [8086] DEC r/m32 ; o32 FF /1 [386]
subtracts 1 from its operand. It does
not affect the carry flag: to affect the carry flag, use
(see
section B.4.305).
affects all the other flags according to the
result.
This instruction can be used with a
prefix to allow atomic execution.
See also
(section B.4.120).
DIV
: Unsigned Integer DivideDIV r/m8 ; F6 /6 [8086] DIV r/m16 ; o16 F7 /6 [8086] DIV r/m32 ; o32 F7 /6 [386]
performs unsigned integer division. The
explicit operand provided is the divisor; the dividend and destination
operands are implicit, in the following way:
DIV r/m8
, AX
is
divided by the given operand; the quotient is stored in
AL
and the remainder in
AH
.
DIV r/m16
,
DX:AX
is divided by the given operand; the
quotient is stored in AX
and the remainder in
DX
.
DIV r/m32
,
EDX:EAX
is divided by the given operand; the
quotient is stored in EAX
and the remainder in
EDX
.
Signed integer division is performed by the
instruction: see
section B.4.117.
DIVPD
: Packed Double-Precision FP DivideDIVPD xmm1,xmm2/mem128 ; 66 0F 5E /r [WILLAMETTE,SSE2]
divides the two packed double-precision
FP values in the destination operand by the two packed double-precision FP
values in the source operand, and stores the packed double-precision
results in the destination register.
The destination is an
register. The source
operand can be either an
register or a
128-bit memory location.
dst[0-63] := dst[0-63] / src[0-63], dst[64-127] := dst[64-127] / src[64-127].
DIVPS
: Packed Single-Precision FP DivideDIVPS xmm1,xmm2/mem128 ; 0F 5E /r [KATMAI,SSE]
divides the four packed single-precision
FP values in the destination operand by the four packed single-precision FP
values in the source operand, and stores the packed single-precision
results in the destination register.
The destination is an
register. The source
operand can be either an
register or a
128-bit memory location.
dst[0-31] := dst[0-31] / src[0-31], dst[32-63] := dst[32-63] / src[32-63], dst[64-95] := dst[64-95] / src[64-95], dst[96-127] := dst[96-127] / src[96-127].
DIVSD
: Scalar Double-Precision FP DivideDIVSD xmm1,xmm2/mem64 ; F2 0F 5E /r [WILLAMETTE,SSE2]
divides the low-order double-precision
FP value in the destination operand by the low-order double-precision FP
value in the source operand, and stores the double-precision result in the
destination register.
The destination is an
register. The source
operand can be either an
register or a 64-bit
memory location.
dst[0-63] := dst[0-63] / src[0-63], dst[64-127] remains unchanged.
DIVSS
: Scalar Single-Precision FP DivideDIVSS xmm1,xmm2/mem32 ; F3 0F 5E /r [KATMAI,SSE]
divides the low-order single-precision
FP value in the destination operand by the low-order single-precision FP
value in the source operand, and stores the single-precision result in the
destination register.
The destination is an
register. The source
operand can be either an
register or a 32-bit
memory location.
dst[0-31] := dst[0-31] / src[0-31], dst[32-127] remains unchanged.
EMMS
: Empty MMX StateEMMS ; 0F 77 [PENT,MMX]
sets the FPU tag word (marking which
floating-point registers are available) to all ones, meaning all registers
are available for the FPU to use. It should be used after executing
instructions and before executing any
subsequent floating-point operations.
ENTER
: Create Stack FrameENTER imm,imm ; C8 iw ib [186]
constructs a
for a high-level language procedure
call. The first operand (the
in the opcode
definition above refers to the first operand) gives the amount of stack
space to allocate for local variables; the second (the
above) gives the nesting level of the
procedure (for languages like Pascal, with nested procedures).
The function of
, with a nesting level of
zero, is equivalent to
PUSH EBP ; or PUSH BP in 16 bits MOV EBP,ESP ; or MOV BP,SP in 16 bits SUB ESP,operand1 ; or SUB SP,operand1 in 16 bits
This creates a stack frame with the procedure parameters accessible
upwards from
, and local variables accessible
downwards from
.
With a nesting level of one, the stack frame created is 4 (or 2) bytes
bigger, and the value of the final frame pointer
is accessible in memory at
.
This allows
, when called with a nesting
level of two, to look at the stack frame described by the previous
value of
, find the frame pointer at offset -4
from that, and push it along with its new frame pointer, so that when a
level-two procedure is called from within a level-one procedure,
holds the frame pointer of the most
recent level-one procedure call and
holds
that of the most recent level-two call. And so on, for nesting levels up to
31.
Stack frames created by
can be destroyed
by the
instruction: see
section B.4.136.
F2XM1
: Calculate 2**X-1F2XM1 ; D9 F0 [8086,FPU]
raises 2 to the power of
, subtracts one, and stores the result back
into
. The initial contents of
must be a number in the range -1.0 to +1.0.
FABS
: Floating-Point Absolute ValueFABS ; D9 E1 [8086,FPU]
computes the absolute value of
,by clearing the sign bit, and stores the
result back in
.
FADD
, FADDP
: Floating-Point AdditionFADD mem32 ; D8 /0 [8086,FPU] FADD mem64 ; DC /0 [8086,FPU]
FADD fpureg ; D8 C0+r [8086,FPU] FADD ST0,fpureg ; D8 C0+r [8086,FPU]
FADD TO fpureg ; DC C0+r [8086,FPU] FADD fpureg,ST0 ; DC C0+r [8086,FPU]
FADDP fpureg ; DE C0+r [8086,FPU] FADDP fpureg,ST0 ; DE C0+r [8086,FPU]
FADD
, given one operand, adds the operand to
ST0
and stores the result back in
ST0
. If the operand has the
TO
modifier, the result is stored in the register
given rather than in ST0
.
FADDP
performs the same function as
FADD TO
, but pops the register stack after
storing the result.
The given two-operand forms are synonyms for the one-operand forms.
To add an integer value to
, use the
c{FIADD} instruction (section B.4.80)
FBLD
, FBSTP
: BCD Floating-Point Load and StoreFBLD mem80 ; DF /4 [8086,FPU] FBSTP mem80 ; DF /6 [8086,FPU]
loads an 80-bit (ten-byte) packed
binary-coded decimal number from the given memory address, converts it to a
real, and pushes it on the register stack.
stores the value of
, in packed BCD, at the
given address and then pops the register stack.
FCHS
: Floating-Point Change SignFCHS ; D9 E0 [8086,FPU]
negates the number in
, by inverting the sign bit: negative numbers
become positive, and vice versa.
FCLEX
, FNCLEX
: Clear Floating-Point ExceptionsFCLEX ; 9B DB E2 [8086,FPU] FNCLEX ; DB E2 [8086,FPU]
clears any floating-point exceptions
which may be pending.
does the same thing
but doesn't wait for previous floating-point operations (including the
handling of pending exceptions) to finish first.
FCMOVcc
: Floating-Point Conditional MoveFCMOVB fpureg ; DA C0+r [P6,FPU] FCMOVB ST0,fpureg ; DA C0+r [P6,FPU]
FCMOVE fpureg ; DA C8+r [P6,FPU] FCMOVE ST0,fpureg ; DA C8+r [P6,FPU]
FCMOVBE fpureg ; DA D0+r [P6,FPU] FCMOVBE ST0,fpureg ; DA D0+r [P6,FPU]
FCMOVU fpureg ; DA D8+r [P6,FPU] FCMOVU ST0,fpureg ; DA D8+r [P6,FPU]
FCMOVNB fpureg ; DB C0+r [P6,FPU] FCMOVNB ST0,fpureg ; DB C0+r [P6,FPU]
FCMOVNE fpureg ; DB C8+r [P6,FPU] FCMOVNE ST0,fpureg ; DB C8+r [P6,FPU]
FCMOVNBE fpureg ; DB D0+r [P6,FPU] FCMOVNBE ST0,fpureg ; DB D0+r [P6,FPU]
FCMOVNU fpureg ; DB D8+r [P6,FPU] FCMOVNU ST0,fpureg ; DB D8+r [P6,FPU]
The
instructions perform conditional
move operations: each of them moves the contents of the given register into
if its condition is satisfied, and does
nothing if not.
The conditions are not the same as the standard condition codes used
with conditional jump instructions. The conditions
,
,
,
,
and
are exactly as
normal, but none of the other standard ones are supported. Instead, the
condition
and its counterpart
are provided; the
condition is satisfied if the last two floating-point numbers compared were
unordered, i.e. they were not equal but neither one could be said
to be greater than the other, for example if they were NaNs. (The flag
state which signals this is the setting of the parity flag: so the
condition is notionally equivalent to
, and
is
equivalent to
.)
The
conditions test the main processor's
status flags, not the FPU status flags, so using
directly after
will not work. Instead, you should either
use
which writes directly to the main CPU
flags word, or use
to extract the FPU
flags.
Although the
instructions are flagged
above, they may not be supported by all
Pentium Pro processors; the
instruction
(section B.4.34) will return a bit which
indicates whether conditional moves are supported.
FCOM
, FCOMP
, FCOMPP
, FCOMI
, FCOMIP
: Floating-Point CompareFCOM mem32 ; D8 /2 [8086,FPU] FCOM mem64 ; DC /2 [8086,FPU] FCOM fpureg ; D8 D0+r [8086,FPU] FCOM ST0,fpureg ; D8 D0+r [8086,FPU]
FCOMP mem32 ; D8 /3 [8086,FPU] FCOMP mem64 ; DC /3 [8086,FPU] FCOMP fpureg ; D8 D8+r [8086,FPU] FCOMP ST0,fpureg ; D8 D8+r [8086,FPU]
FCOMPP ; DE D9 [8086,FPU]
FCOMI fpureg ; DB F0+r [P6,FPU] FCOMI ST0,fpureg ; DB F0+r [P6,FPU]
FCOMIP fpureg ; DF F0+r [P6,FPU] FCOMIP ST0,fpureg ; DF F0+r [P6,FPU]
compares
with the given operand, and sets the FPU flags accordingly.
is treated as the left-hand side of the
comparison, so that the carry flag is set (for a `less-than' result) if
is less than the given operand.
does the same as
, but pops the register stack afterwards.
compares
with
and then pops the register stack twice.
and
work like the corresponding forms of
and
, but write their results directly to the
CPU flags register rather than the FPU status word, so they can be
immediately followed by conditional jump or conditional move instructions.
The
instructions differ from the
instructions
(section B.4.108) only in the way they
handle quiet NaNs:
will handle them
silently and set the condition code flags to an `unordered' result, whereas
will generate an exception.
FCOS
: CosineFCOS ; D9 FF [386,FPU]
computes the cosine of
(in radians), and stores the result in
. The absolute value of
must be less than 2**63.
See also
(section B.4.100).
FDECSTP
: Decrement Floating-Point Stack PointerFDECSTP ; D9 F6 [8086,FPU]
decrements the `top' field in the
floating-point status word. This has the effect of rotating the FPU
register stack by one, as if the contents of
had been pushed on the stack. See also
(section B.4.85).
FxDISI
, FxENI
: Disable and Enable Floating-Point InterruptsFDISI ; 9B DB E1 [8086,FPU] FNDISI ; DB E1 [8086,FPU]
FENI ; 9B DB E0 [8086,FPU] FNENI ; DB E0 [8086,FPU]
and
disable and enable floating-point interrupts. These instructions are only
meaningful on original 8087 processors: the 287 and above treat them as
no-operation instructions.
and
do
the same thing as
and
respectively, but without waiting for the
floating-point processor to finish what it was doing first.
FDIV
, FDIVP
, FDIVR
, FDIVRP
: Floating-Point DivisionFDIV mem32 ; D8 /6 [8086,FPU] FDIV mem64 ; DC /6 [8086,FPU]
FDIV fpureg ; D8 F0+r [8086,FPU] FDIV ST0,fpureg ; D8 F0+r [8086,FPU]
FDIV TO fpureg ; DC F8+r [8086,FPU] FDIV fpureg,ST0 ; DC F8+r [8086,FPU]
FDIVR mem32 ; D8 /0 [8086,FPU] FDIVR mem64 ; DC /0 [8086,FPU]
FDIVR fpureg ; D8 F8+r [8086,FPU] FDIVR ST0,fpureg ; D8 F8+r [8086,FPU]
FDIVR TO fpureg ; DC F0+r [8086,FPU] FDIVR fpureg,ST0 ; DC F0+r [8086,FPU]
FDIVP fpureg ; DE F8+r [8086,FPU] FDIVP fpureg,ST0 ; DE F8+r [8086,FPU]
FDIVRP fpureg ; DE F0+r [8086,FPU] FDIVRP fpureg,ST0 ; DE F0+r [8086,FPU]
FDIV
divides ST0
by
the given operand and stores the result back in
ST0
, unless the TO
qualifier is given, in which case it divides the given operand by
ST0
and stores the result in the operand.
FDIVR
does the same thing, but does the
division the other way up: so if TO
is not given,
it divides the given operand by ST0
and stores
the result in ST0
, whereas if
TO
is given it divides
ST0
by its operand and stores the result in the
operand.
FDIVP
operates like
FDIV TO
, but pops the register stack once it has
finished.
FDIVRP
operates like
FDIVR TO
, but pops the register stack once it has
finished.
For FP/Integer divisions, see
(section B.4.82).
FEMMS
: Faster Enter/Exit of the MMX or floating-point stateFEMMS ; 0F 0E [PENT,3DNOW]
can be used in place of the
instruction on processors which support the
3DNow! instruction set. Following execution of
, the state of the
registers is undefined, and this allows a
faster context switch between
and
instructions. The
instruction can also be used
before executing
instructions
FFREE
: Flag Floating-Point Register as UnusedFFREE fpureg ; DD C0+r [8086,FPU] FFREEP fpureg ; DF C0+r [286,FPU,UNDOC]
marks the given register as being empty.
marks the given register as being
empty, and then pops the register stack.
FIADD
: Floating-Point/Integer AdditionFIADD mem16 ; DE /0 [8086,FPU] FIADD mem32 ; DA /0 [8086,FPU]
adds the 16-bit or 32-bit integer stored
in the given memory location to
, storing the
result in
.
FICOM
, FICOMP
: Floating-Point/Integer CompareFICOM mem16 ; DE /2 [8086,FPU] FICOM mem32 ; DA /2 [8086,FPU]
FICOMP mem16 ; DE /3 [8086,FPU] FICOMP mem32 ; DA /3 [8086,FPU]
compares
with the 16-bit or 32-bit integer stored in the given memory location, and
sets the FPU flags accordingly.
does the
same, but pops the register stack afterwards.
FIDIV
, FIDIVR
: Floating-Point/Integer DivisionFIDIV mem16 ; DE /6 [8086,FPU] FIDIV mem32 ; DA /6 [8086,FPU]
FIDIVR mem16 ; DE /7 [8086,FPU] FIDIVR mem32 ; DA /7 [8086,FPU]
divides
by
the 16-bit or 32-bit integer stored in the given memory location, and
stores the result in
.
does the division the other way up: it
divides the integer by
, but still stores the
result in
.
FILD
, FIST
, FISTP
: Floating-Point/Integer ConversionFILD mem16 ; DF /0 [8086,FPU] FILD mem32 ; DB /0 [8086,FPU] FILD mem64 ; DF /5 [8086,FPU]
FIST mem16 ; DF /2 [8086,FPU] FIST mem32 ; DB /2 [8086,FPU]
FISTP mem16 ; DF /3 [8086,FPU] FISTP mem32 ; DB /3 [8086,FPU] FISTP mem64 ; DF /7 [8086,FPU]
loads an integer out of a memory
location, converts it to a real, and pushes it on the FPU register stack.
converts
to an
integer and stores that in memory;
does the
same as
, but pops the register stack
afterwards.
FIMUL
: Floating-Point/Integer MultiplicationFIMUL mem16 ; DE /1 [8086,FPU] FIMUL mem32 ; DA /1 [8086,FPU]
multiplies
by the 16-bit or 32-bit integer stored in the given memory location, and
stores the result in
.
FINCSTP
: Increment Floating-Point Stack PointerFINCSTP ; D9 F7 [8086,FPU]
increments the `top' field in the
floating-point status word. This has the effect of rotating the FPU
register stack by one, as if the register stack had been popped; however,
unlike the popping of the stack performed by many FPU instructions, it does
not flag the new
(previously
) as empty. See also
(section
B.4.75).
FINIT
, FNINIT
: Initialise Floating-Point UnitFINIT ; 9B DB E3 [8086,FPU] FNINIT ; DB E3 [8086,FPU]
initialises the FPU to its default
state. It flags all registers as empty, without actually change their
values, clears the top of stack pointer.
does the same, without first waiting for pending exceptions to clear.
FISUB
: Floating-Point/Integer SubtractionFISUB mem16 ; DE /4 [8086,FPU] FISUB mem32 ; DA /4 [8086,FPU]
FISUBR mem16 ; DE /5 [8086,FPU] FISUBR mem32 ; DA /5 [8086,FPU]
subtracts the 16-bit or 32-bit integer
stored in the given memory location from
, and
stores the result in
.
does the subtraction the other way round,
i.e. it subtracts
from the given integer, but
still stores the result in
.
FLD
: Floating-Point LoadFLD mem32 ; D9 /0 [8086,FPU] FLD mem64 ; DD /0 [8086,FPU] FLD mem80 ; DB /5 [8086,FPU] FLD fpureg ; D9 C0+r [8086,FPU]
loads a floating-point value out of the
given register or memory location, and pushes it on the FPU register stack.
FLDxx
: Floating-Point Load ConstantsFLD1 ; D9 E8 [8086,FPU] FLDL2E ; D9 EA [8086,FPU] FLDL2T ; D9 E9 [8086,FPU] FLDLG2 ; D9 EC [8086,FPU] FLDLN2 ; D9 ED [8086,FPU] FLDPI ; D9 EB [8086,FPU] FLDZ ; D9 EE [8086,FPU]
These instructions push specific standard constants on the FPU register stack.
Instruction Constant pushed
FLD1 1 FLDL2E base-2 logarithm of e FLDL2T base-2 log of 10 FLDLG2 base-10 log of 2 FLDLN2 base-e log of 2 FLDPI pi FLDZ zero
FLDCW
: Load Floating-Point Control WordFLDCW mem16 ; D9 /5 [8086,FPU]
loads a 16-bit value out of memory and
stores it into the FPU control word (governing things like the rounding
mode, the precision, and the exception masks). See also
(section
B.4.103). If exceptions are enabled and you don't want to generate one,
use
or
(section B.4.71) before loading the new
control word.
FLDENV
: Load Floating-Point EnvironmentFLDENV mem ; D9 /4 [8086,FPU]
loads the FPU operating environment
(control word, status word, tag word, instruction pointer, data pointer and
last opcode) from memory. The memory area is 14 or 28 bytes long, depending
on the CPU mode at the time. See also
(section B.4.104).
FMUL
, FMULP
: Floating-Point MultiplyFMUL mem32 ; D8 /1 [8086,FPU] FMUL mem64 ; DC /1 [8086,FPU]
FMUL fpureg ; D8 C8+r [8086,FPU] FMUL ST0,fpureg ; D8 C8+r [8086,FPU]
FMUL TO fpureg ; DC C8+r [8086,FPU] FMUL fpureg,ST0 ; DC C8+r [8086,FPU]
FMULP fpureg ; DE C8+r [8086,FPU] FMULP fpureg,ST0 ; DE C8+r [8086,FPU]
multiplies
by the given operand, and stores the result in
, unless the
qualifier is used in which case it stores the result in the operand.
performs the same operation as
, and then pops the register stack.
FNOP
: Floating-Point No OperationFNOP ; D9 D0 [8086,FPU]
does nothing.
FPATAN
, FPTAN
: Arctangent and TangentFPATAN ; D9 F3 [8086,FPU] FPTAN ; D9 F2 [8086,FPU]
computes the arctangent, in radians, of
the result of dividing
by
, stores the result in
, and pops the register stack. It works like
the C
function, in that changing the sign
of both
and
changes the output value by pi (so it performs true rectangular-to-polar
coordinate conversion, with
being the Y
coordinate and
being the X coordinate, not
merely an arctangent).
computes the tangent of the value in
(in radians), and stores the result back into
.
The absolute value of
must be less than
2**63.
FPREM
, FPREM1
: Floating-Point Partial RemainderFPREM ; D9 F8 [8086,FPU] FPREM1 ; D9 F5 [386,FPU]
These instructions both produce the remainder obtained by dividing
by
. This is
calculated, notionally, by dividing
by
, rounding the result to an integer,
multiplying by
again, and computing the value
which would need to be added back on to the result to get back to the
original value in
.
The two instructions differ in the way the notional round-to-integer
operation is performed.
does it by rounding
towards zero, so that the remainder it returns always has the same sign as
the original value in
;
does it by rounding to the nearest
integer, so that the remainder always has at most half the magnitude of
.
Both instructions calculate partial remainders, meaning that
they may not manage to provide the final result, but might leave
intermediate results in
instead. If this
happens, they will set the C2 flag in the FPU status word; therefore, to
calculate a remainder, you should repeatedly execute
or
until
C2 becomes clear.
FRNDINT
: Floating-Point Round to IntegerFRNDINT ; D9 FC [8086,FPU]
rounds the contents of
to an integer, according to the current
rounding mode set in the FPU control word, and stores the result back in
.
FSAVE
, FRSTOR
: Save/Restore Floating-Point StateFSAVE mem ; 9B DD /6 [8086,FPU] FNSAVE mem ; DD /6 [8086,FPU]
FRSTOR mem ; DD /4 [8086,FPU]
saves the entire floating-point unit
state, including all the information saved by
(section
B.4.104) plus the contents of all the registers, to a 94 or 108 byte
area of memory (depending on the CPU mode).
restores the floating-point state from the
same area of memory.
does the same as
, without first waiting for pending
floating-point exceptions to clear.
FSCALE
: Scale Floating-Point Value by Power of TwoFSCALE ; D9 FD [8086,FPU]
scales a number by a power of two: it
rounds
towards zero to obtain an integer,
then multiplies
by two to the power of that
integer, and stores the result in
.
FSETPM
: Set Protected ModeFSETPM ; DB E4 [286,FPU]
This instruction initialises protected mode on the 287 floating-point coprocessor. It is only meaningful on that processor: the 387 and above treat the instruction as a no-operation.
FSIN
, FSINCOS
: Sine and CosineFSIN ; D9 FE [386,FPU] FSINCOS ; D9 FB [386,FPU]
calculates the sine of
(in radians) and stores the result in
.
does the
same, but then pushes the cosine of the same value on the register stack,
so that the sine ends up in
and the cosine in
.
is faster
than executing
and
(see section
B.4.74) in succession.
The absolute value of
must be less than
2**63.
FSQRT
: Floating-Point Square RootFSQRT ; D9 FA [8086,FPU]
calculates the square root of
and stores the result in
.
FST
, FSTP
: Floating-Point StoreFST mem32 ; D9 /2 [8086,FPU] FST mem64 ; DD /2 [8086,FPU] FST fpureg ; DD D0+r [8086,FPU]
FSTP mem32 ; D9 /3 [8086,FPU] FSTP mem64 ; DD /3 [8086,FPU] FSTP mem80 ; DB /7 [8086,FPU] FSTP fpureg ; DD D8+r [8086,FPU]
stores the value in
into the given memory location or other FPU
register.
does the same, but then pops the
register stack.
FSTCW
: Store Floating-Point Control WordFSTCW mem16 ; 9B D9 /7 [8086,FPU] FNSTCW mem16 ; D9 /7 [8086,FPU]
stores the
control word (governing things like the rounding mode, the precision, and
the exception masks) into a 2-byte memory area. See also
(section
B.4.90).
does the same thing as
, without first waiting for pending
floating-point exceptions to clear.
FSTENV
: Store Floating-Point EnvironmentFSTENV mem ; 9B D9 /6 [8086,FPU] FNSTENV mem ; D9 /6 [8086,FPU]
stores the
operating environment (control word, status
word, tag word, instruction pointer, data pointer and last opcode) into
memory. The memory area is 14 or 28 bytes long, depending on the CPU mode
at the time. See also
(section B.4.91).
does the same thing as
, without first waiting for pending
floating-point exceptions to clear.
FSTSW
: Store Floating-Point Status WordFSTSW mem16 ; 9B DD /7 [8086,FPU] FSTSW AX ; 9B DF E0 [286,FPU]
FNSTSW mem16 ; DD /7 [8086,FPU] FNSTSW AX ; DF E0 [286,FPU]
stores the
status word into
or into a 2-byte memory area.
does the same thing as
, without first waiting for pending
floating-point exceptions to clear.
FSUB
, FSUBP
, FSUBR
, FSUBRP
: Floating-Point SubtractFSUB mem32 ; D8 /4 [8086,FPU] FSUB mem64 ; DC /4 [8086,FPU]
FSUB fpureg ; D8 E0+r [8086,FPU] FSUB ST0,fpureg ; D8 E0+r [8086,FPU]
FSUB TO fpureg ; DC E8+r [8086,FPU] FSUB fpureg,ST0 ; DC E8+r [8086,FPU]
FSUBR mem32 ; D8 /5 [8086,FPU] FSUBR mem64 ; DC /5 [8086,FPU]
FSUBR fpureg ; D8 E8+r [8086,FPU] FSUBR ST0,fpureg ; D8 E8+r [8086,FPU]
FSUBR TO fpureg ; DC E0+r [8086,FPU] FSUBR fpureg,ST0 ; DC E0+r [8086,FPU]
FSUBP fpureg ; DE E8+r [8086,FPU] FSUBP fpureg,ST0 ; DE E8+r [8086,FPU]
FSUBRP fpureg ; DE E0+r [8086,FPU] FSUBRP fpureg,ST0 ; DE E0+r [8086,FPU]
FSUB
subtracts the given operand from
ST0
and stores the result back in
ST0
, unless the TO
qualifier is given, in which case it subtracts
ST0
from the given operand and stores the result
in the operand.
FSUBR
does the same thing, but does the
subtraction the other way up: so if TO
is not
given, it subtracts ST0
from the given operand
and stores the result in ST0
, whereas if
TO
is given it subtracts its operand from
ST0
and stores the result in the operand.
FSUBP
operates like
FSUB TO
, but pops the register stack once it has
finished.
FSUBRP
operates like
FSUBR TO
, but pops the register stack once it has
finished.
FTST
: Test ST0
Against ZeroFTST ; D9 E4 [8086,FPU]
compares
with zero and sets the FPU flags accordingly.
is treated as the left-hand side of the comparison, so that a `less-than'
result is generated if
is negative.
FUCOMxx
: Floating-Point Unordered CompareFUCOM fpureg ; DD E0+r [386,FPU] FUCOM ST0,fpureg ; DD E0+r [386,FPU]
FUCOMP fpureg ; DD E8+r [386,FPU] FUCOMP ST0,fpureg ; DD E8+r [386,FPU]
FUCOMPP ; DA E9 [386,FPU]
FUCOMI fpureg ; DB E8+r [P6,FPU] FUCOMI ST0,fpureg ; DB E8+r [P6,FPU]
FUCOMIP fpureg ; DF E8+r [P6,FPU] FUCOMIP ST0,fpureg ; DF E8+r [P6,FPU]
FUCOM
compares ST0
with the given operand, and sets the FPU flags accordingly.
ST0
is treated as the left-hand side of the
comparison, so that the carry flag is set (for a `less-than' result) if
ST0
is less than the given operand.
FUCOMP
does the same as
FUCOM
, but pops the register stack afterwards.
FUCOMPP
compares ST0
with ST1
and then pops the register stack twice.
FUCOMI
and FUCOMIP
work like the corresponding forms of FUCOM
and
FUCOMP
, but write their results directly to the
CPU flags register rather than the FPU status word, so they can be
immediately followed by conditional jump or conditional move instructions.
The
instructions differ from the
instructions
(section B.4.73) only in the way they handle
quiet NaNs:
will handle them silently and
set the condition code flags to an `unordered' result, whereas
will generate an exception.
FXAM
: Examine Class of Value in ST0
FXAM ; D9 E5 [8086,FPU]
sets the FPU flags
,
and
depending on the type of value stored in
:
Register contents Flags
Unsupported format 000 NaN 001 Finite number 010 Infinity 011 Zero 100 Empty register 101 Denormal 110
Additionally, the
flag is set to the sign
of the number.
FXCH
: Floating-Point ExchangeFXCH ; D9 C9 [8086,FPU] FXCH fpureg ; D9 C8+r [8086,FPU] FXCH fpureg,ST0 ; D9 C8+r [8086,FPU] FXCH ST0,fpureg ; D9 C8+r [8086,FPU]
exchanges
with a given FPU register. The no-operand form exchanges
with
.
FXRSTOR
: Restore FP
, MMX
and SSE
StateFXRSTOR memory ; 0F AE /1 [P6,SSE,FPU]
The
instruction reloads the
,
and
state (environment and registers), from the
512 byte memory area defined by the source operand. This data should have
been written by a previous
.
FXSAVE
: Store FP
, MMX
and SSE
StateFXSAVE memory ; 0F AE /0 [P6,SSE,FPU]
The FXSAVE instruction writes the
current
,
and
technology states (environment and
registers), to the 512 byte memory area defined by the destination operand.
It does this without checking for pending unmasked floating-point
exceptions (similar to the operation of
).
Unlike the
instructions, the
processor retains the contents of the
,
and
state in
the processor after the state has been saved. This instruction has been
optimised to maximize floating-point save performance.
FXTRACT
: Extract Exponent and SignificandFXTRACT ; D9 F4 [8086,FPU]
separates the number in
into its exponent and significand (mantissa),
stores the exponent back into
, and then
pushes the significand on the register stack (so that the significand ends
up in
, and the exponent in
).
FYL2X
, FYL2XP1
: Compute Y times Log2(X) or Log2(X+1)FYL2X ; D9 F1 [8086,FPU] FYL2XP1 ; D9 F9 [8086,FPU]
multiplies
by the base-2 logarithm of
, stores the result
in
, and pops the register stack (so that the
result ends up in
).
must be non-zero and positive.
works the same way, but replacing the
base-2 log of
with that of
plus one. This time,
must have magnitude no greater than 1 minus
half the square root of two.
HLT
: Halt ProcessorHLT ; F4 [8086,PRIV]
puts the processor into a halted state,
where it will perform no more operations until restarted by an interrupt or
a reset.
On the 286 and later processors, this is a privileged instruction.
IBTS
: Insert Bit StringIBTS r/m16,reg16 ; o16 0F A7 /r [386,UNDOC] IBTS r/m32,reg32 ; o32 0F A7 /r [386,UNDOC]
The implied operation of this instruction is:
IBTS r/m16,AX,CL,reg16 IBTS r/m32,EAX,CL,reg32
Writes a bit string from the source operand to the destination.
indicates the number of bits to be copied,
from the low bits of the source.
indicates
the low order bit offset in the destination that is written to. For
example, if
is set to 4 and
(for 16-bit code) is set to 5, bits 0-3 of
will be copied to bits 5-8 of
. This instruction is very poorly documented,
and I have been unable to find any official source of documentation on it.
is supported only on the early Intel
386s, and conflicts with the opcodes for
(on early Intel 486s). NASM supports
it only for completeness. Its counterpart is
(see section B.4.332).
IDIV
: Signed Integer DivideIDIV r/m8 ; F6 /7 [8086] IDIV r/m16 ; o16 F7 /7 [8086] IDIV r/m32 ; o32 F7 /7 [386]
performs signed integer division. The
explicit operand provided is the divisor; the dividend and destination
operands are implicit, in the following way:
IDIV r/m8
, AX
is divided by the given operand; the quotient is stored in
AL
and the remainder in
AH
.
IDIV r/m16
,
DX:AX
is divided by the given operand; the
quotient is stored in AX
and the remainder in
DX
.
IDIV r/m32
,
EDX:EAX
is divided by the given operand; the
quotient is stored in EAX
and the remainder in
EDX
.
Unsigned integer division is performed by the
instruction: see
section B.4.59.
IMUL
: Signed Integer MultiplyIMUL r/m8 ; F6 /5 [8086] IMUL r/m16 ; o16 F7 /5 [8086] IMUL r/m32 ; o32 F7 /5 [386]
IMUL reg16,r/m16 ; o16 0F AF /r [386] IMUL reg32,r/m32 ; o32 0F AF /r [386]
IMUL reg16,imm8 ; o16 6B /r ib [186] IMUL reg16,imm16 ; o16 69 /r iw [186] IMUL reg32,imm8 ; o32 6B /r ib [386] IMUL reg32,imm32 ; o32 69 /r id [386]
IMUL reg16,r/m16,imm8 ; o16 6B /r ib [186] IMUL reg16,r/m16,imm16 ; o16 69 /r iw [186] IMUL reg32,r/m32,imm8 ; o32 6B /r ib [386] IMUL reg32,r/m32,imm32 ; o32 69 /r id [386]
performs signed integer multiplication.
For the single-operand form, the other operand and destination are
implicit, in the following way:
IMUL r/m8
, AL
is multiplied by the given operand; the product is stored in
AX
.
IMUL r/m16
, AX
is multiplied by the given operand; the product is stored in
DX:AX
.
IMUL r/m32
, EAX
is multiplied by the given operand; the product is stored in
EDX:EAX
.
The two-operand form multiplies its two operands and stores the result in the destination (first) operand. The three-operand form multiplies its last two operands and stores the result in the first operand.
The two-operand form with an immediate second operand is in fact a
shorthand for the three-operand form, as can be seen by examining the
opcode descriptions: in the two-operand form, the code
takes both its register and
parts from the same operand (the first one).
In the forms with an 8-bit immediate operand and another longer source
operand, the immediate operand is considered to be signed, and is
sign-extended to the length of the other source operand. In these cases,
the
qualifier is necessary to force NASM to
generate this form of the instruction.
Unsigned integer multiplication is performed by the
instruction: see
section B.4.184.
IN
: Input from I/O PortIN AL,imm8 ; E4 ib [8086] IN AX,imm8 ; o16 E5 ib [8086] IN EAX,imm8 ; o32 E5 ib [386] IN AL,DX ; EC [8086] IN AX,DX ; o16 ED [8086] IN EAX,DX ; o32 ED [386]
reads a byte, word or doubleword from the
specified I/O port, and stores it in the given destination register. The
port number may be specified as an immediate value if it is between 0 and
255, and otherwise must be stored in
. See also
(section
B.4.194).
INC
: Increment IntegerINC reg16 ; o16 40+r [8086] INC reg32 ; o32 40+r [386] INC r/m8 ; FE /0 [8086] INC r/m16 ; o16 FF /0 [8086] INC r/m32 ; o32 FF /0 [386]
adds 1 to its operand. It does
not affect the carry flag: to affect the carry flag, use
(see
section B.4.3).
affects all the other flags according to the result.
This instruction can be used with a
prefix to allow atomic execution.
See also
(section B.4.58).
INSB
, INSW
, INSD
: Input String from I/O PortINSB ; 6C [186] INSW ; o16 6D [186] INSD ; o32 6D [386]
inputs a byte from the I/O port specified
in
and stores it at
or
. It
then increments or decrements (depending on the direction flag: increments
if the flag is clear, decrements if it is set)
or
.
The register used is
if the address size is
16 bits, and
if it is 32 bits. If you need to
use an address size not equal to the current
setting, you can use an explicit
or
prefix.
Segment override prefixes have no effect for this instruction: the use
of
for the load from
or
cannot be
overridden.
and
work
in the same way, but they input a word or a doubleword instead of a byte,
and increment or decrement the addressing register by 2 or 4 instead of 1.
The
prefix may be used to repeat the
instruction
(or
- again, the address size chooses which) times.
See also
,
and
(section B.4.195).
INT
: Software InterruptINT imm8 ; CD ib [8086]
causes a software interrupt through a
specified vector number from 0 to 255.
The code generated by the
instruction is
always two bytes long: although there are short forms for some
instructions, NASM does not generate them
when it sees the
mnemonic. In order to
generate single-byte breakpoint instructions, use the
or
instructions (see section B.4.123) instead.
INT3
, INT1
, ICEBP
, INT01
: BreakpointsINT1 ; F1 [P6] ICEBP ; F1 [P6] INT01 ; F1 [P6]
INT3 ; CC [8086] INT03 ; CC [8086]
and
are
short one-byte forms of the instructions
and
(see section
B.4.122). They perform a similar function to their longer counterparts,
but take up less code space. They are used as breakpoints by debuggers.
INT1
, and its alternative synonyms
INT01
and ICEBP
, is an
instruction used by in-circuit emulators (ICEs). It is present, though not
documented, on some processors down to the 286, but is only documented for
the Pentium Pro. INT3
is the instruction normally
used as a breakpoint by debuggers.
INT3
, and its synonym
INT03
, is not precisely equivalent to
INT 3
: the short form, since it is designed to be
used as a breakpoint, bypasses the normal IOPL
checks in virtual-8086 mode, and also does not go through interrupt
redirection.
INTO
: Interrupt if OverflowINTO ; CE [8086]
performs an
software interrupt (see
section B.4.122) if and only if the overflow
flag is set.
INVD
: Invalidate Internal CachesINVD ; 0F 08 [486]
invalidates and empties the processor's
internal caches, and causes the processor to instruct external caches to do
the same. It does not write the contents of the caches back to memory
first: any modified data held in the caches will be lost. To write the data
back first, use
(section B.4.328).
INVLPG
: Invalidate TLB EntryINVLPG mem ; 0F 01 /7 [486]
invalidates the translation lookahead
buffer (TLB) entry associated with the supplied memory address.
IRET
, IRETW
, IRETD
: Return from InterruptIRET ; CF [8086] IRETW ; o16 CF [8086] IRETD ; o32 CF [386]
returns from an interrupt (hardware or
software) by means of popping
(or
),
and the flags
off the stack and then continuing execution from the new
.
pops
,
and the flags as 2 bytes each, taking 6 bytes
off the stack in total.
pops
as 4 bytes, pops a further 4 bytes of which
the top two are discarded and the bottom two go into
, and pops the flags as 4 bytes as well, taking
12 bytes off the stack.
is a shorthand for either
or
,
depending on the default
setting at the
time.
Jcc
: Conditional BranchJcc imm ; 70+cc rb [8086] Jcc NEAR imm ; 0F 80+cc rw/rd [386]
The conditional jump instructions execute a near (same segment) jump if
and only if their conditions are satisfied. For example,
jumps only if the zero flag is not set.
The ordinary form of the instructions has only a 128-byte range; the
form is a 386 extension to the instruction
set, and can span the full size of a segment. NASM will not override your
choice of jump instruction: if you want
,
you have to use the
keyword.
The
keyword is allowed on the first form
of the instruction, for clarity, but is not necessary.
For details of the condition codes, see section B.2.2.
JCXZ
, JECXZ
: Jump if CX/ECX ZeroJCXZ imm ; a16 E3 rb [8086] JECXZ imm ; a32 E3 rb [386]
performs a short jump (with maximum range
128 bytes) if and only if the contents of the
register is 0.
does the same thing, but
with
.
JMP
: JumpJMP imm ; E9 rw/rd [8086] JMP SHORT imm ; EB rb [8086] JMP imm:imm16 ; o16 EA iw iw [8086] JMP imm:imm32 ; o32 EA id iw [386] JMP FAR mem ; o16 FF /5 [8086] JMP FAR mem32 ; o32 FF /5 [386] JMP r/m16 ; o16 FF /4 [8086] JMP r/m32 ; o32 FF /4 [386]
jumps to a given address. The address may
be specified as an absolute segment and offset, or as a relative jump
within the current segment.
has a maximum range of 128
bytes, since the displacement is specified as only 8 bits, but takes up
less code space. NASM does not choose when to generate
for you: you must explicitly code
every time you want a short jump.
You can choose between the two immediate far jump forms
(
) by the use of the
and
keywords:
) or
.
The
forms execute a far jump by
loading the destination address out of memory. The address loaded consists
of 16 or 32 bits of offset (depending on the operand size), and 16 bits of
segment. The operand size may be overridden using
or
.
The
forms execute a near jump (within
the same segment), loading the destination address out of memory or out of
a register. The keyword
may be specified,
for clarity, in these forms, but is not necessary. Again, operand size can
be overridden using
or
.
As a convenience, NASM does not require you to jump to a far symbol by
coding the cumbersome
,
but instead allows the easier synonym
.
The
forms given above are near calls;
NASM will accept the
keyword (e.g.
), even though it is not
strictly necessary.
LAHF
: Load AH from FlagsLAHF ; 9F [8086]
sets the
register according to the contents of the low byte of the flags word.
The operation of
is:
AH <-- SF:ZF:0:AF:0:PF:1:CF
See also
(section B.4.282).
LAR
: Load Access RightsLAR reg16,r/m16 ; o16 0F 02 /r [286,PRIV] LAR reg32,r/m32 ; o32 0F 02 /r [286,PRIV]
takes the segment selector specified by
its source (second) operand, finds the corresponding segment descriptor in
the GDT or LDT, and loads the access-rights byte of the descriptor into its
destination (first) operand.
LDMXCSR
: Load Streaming SIMD Extension Control/StatusLDMXCSR mem32 ; 0F AE /2 [KATMAI,SSE]
loads 32-bits of data from the
specified memory location into the
control/status register.
is used to enable
masked/unmasked exception handling, to set rounding modes, to set
flush-to-zero mode, and to view exception status flags.
For details of the
register, see the
Intel processor docs.
See also
(section B.4.302
LDS
, LES
, LFS
, LGS
, LSS
: Load Far PointerLDS reg16,mem ; o16 C5 /r [8086] LDS reg32,mem ; o32 C5 /r [386]
LES reg16,mem ; o16 C4 /r [8086] LES reg32,mem ; o32 C4 /r [386]
LFS reg16,mem ; o16 0F B4 /r [386] LFS reg32,mem ; o32 0F B4 /r [386]
LGS reg16,mem ; o16 0F B5 /r [386] LGS reg32,mem ; o32 0F B5 /r [386]
LSS reg16,mem ; o16 0F B2 /r [386] LSS reg32,mem ; o32 0F B2 /r [386]
These instructions load an entire far pointer (16 or 32 bits of offset,
plus 16 bits of segment) out of memory in one go.
, for example, loads 16 or 32 bits from the
given memory address into the given register (depending on the size of the
register), then loads the next 16 bits from memory into
.
,
,
and
work in the same way but use the other
segment registers.
LEA
: Load Effective AddressLEA reg16,mem ; o16 8D /r [8086] LEA reg32,mem ; o32 8D /r [386]
, despite its syntax, does not access
memory. It calculates the effective address specified by its second operand
as if it were going to load or store data from it, but instead it stores
the calculated address into the register specified by its first operand.
This can be used to perform quite complex calculations (e.g.
) in one instruction.
, despite being a purely arithmetic
instruction which accesses no memory, still requires square brackets around
its second operand, as if it were a memory reference.
The size of the calculation is the current address size, and the size that the result is stored as is the current operand size. If the address and operand size are not the same, then if the addressing mode was 32-bits, the low 16-bits are stored, and if the address was 16-bits, it is zero-extended to 32-bits before storing.
LEAVE
: Destroy Stack FrameLEAVE ; C9 [186]
destroys a stack frame of the form
created by the
instruction (see
section B.4.65). It is functionally
equivalent to
followed by
(or
followed by
in 16-bit mode).
LFENCE
: Load FenceLFENCE ; 0F AE /5 [WILLAMETTE,SSE2]
performs a serialising operation on all
loads from memory that were issued before the
instruction. This guarantees that all
memory reads before the
instruction are
visible before any reads after the
instruction.
is ordered respective to other
instruction,
, any memory read and any other serialising
instruction (such as
).
Weakly ordered memory types can be used to achieve higher processor
performance through such techniques as out-of-order issue and speculative
reads. The degree to which a consumer of data recognizes or knows that the
data is weakly ordered varies among applications and may be unknown to the
producer of this data. The
instruction
provides a performance-efficient way of ensuring load ordering between
routines that produce weakly-ordered results and routines that consume that
data.
uses the following ModRM encoding:
Mod (7:6) = 11B Reg/Opcode (5:3) = 101B R/M (2:0) = 000B
All other ModRM encodings are defined to be reserved, and use of these encodings risks incompatibility with future processors.
See also
(section B.4.288) and
(section
B.4.151).
LGDT
, LIDT
, LLDT
: Load Descriptor TablesLGDT mem ; 0F 01 /2 [286,PRIV] LIDT mem ; 0F 01 /3 [286,PRIV] LLDT r/m16 ; 0F 00 /2 [286,PRIV]
and
both
take a 6-byte memory area as an operand: they load a 32-bit linear address
and a 16-bit size limit from that area (in the opposite order) into the
(global descriptor table register) or
(interrupt descriptor table register). These
are the only instructions which directly use linear addresses,
rather than segment/offset pairs.
takes a segment selector as an operand.
The processor looks up that selector in the GDT and stores the limit and
base address given there into the
(local
descriptor table register).
See also
,
and
(section
B.4.289).
LMSW
: Load/Store Machine Status WordLMSW r/m16 ; 0F 01 /6 [286,PRIV]
loads the bottom four bits of the source
operand into the bottom four bits of the
control register (or the Machine Status Word, on 286 processors). See also
(section
B.4.296).
LOADALL
, LOADALL286
: Load Processor StateLOADALL ; 0F 07 [386,UNDOC] LOADALL286 ; 0F 05 [286,UNDOC]
This instruction, in its two different-opcode forms, is apparently supported on most 286 processors, some 386 and possibly some 486. The opcode differs between the 286 and the 386.
The function of the instruction is to load all information relating to
the state of the processor out of a block of memory: on the 286, this block
is located implicitly at absolute address
,
and on the 386 and 486 it is at
.
LODSB
, LODSW
, LODSD
: Load from StringLODSB ; AC [8086] LODSW ; o16 AD [8086] LODSD ; o32 AD [386]
loads a byte from
or
into
. It then increments or decrements
(depending on the direction flag: increments if the flag is clear,
decrements if it is set)
or
.
The register used is
if the address size is
16 bits, and
if it is 32 bits. If you need to
use an address size not equal to the current
setting, you can use an explicit
or
prefix.
The segment register used to load from
or
can be overridden by using a segment
register name as a prefix (for example,
).
and
work
in the same way, but they load a word or a doubleword instead of a byte,
and increment or decrement the addressing registers by 2 or 4 instead of 1.
LOOP
, LOOPE
, LOOPZ
, LOOPNE
, LOOPNZ
: Loop with CounterLOOP imm ; E2 rb [8086] LOOP imm,CX ; a16 E2 rb [8086] LOOP imm,ECX ; a32 E2 rb [386]
LOOPE imm ; E1 rb [8086] LOOPE imm,CX ; a16 E1 rb [8086] LOOPE imm,ECX ; a32 E1 rb [386] LOOPZ imm ; E1 rb [8086] LOOPZ imm,CX ; a16 E1 rb [8086] LOOPZ imm,ECX ; a32 E1 rb [386]
LOOPNE imm ; E0 rb [8086] LOOPNE imm,CX ; a16 E0 rb [8086] LOOPNE imm,ECX ; a32 E0 rb [386] LOOPNZ imm ; E0 rb [8086] LOOPNZ imm,CX ; a16 E0 rb [8086] LOOPNZ imm,ECX ; a32 E0 rb [386]
decrements its counter register (either
or
- if one is
not specified explicitly, the
setting
dictates which is used) by one, and if the counter does not become zero as
a result of this operation, it jumps to the given label. The jump has a
range of 128 bytes.
(or its synonym
) adds the additional condition that it only
jumps if the counter is nonzero and the zero flag is set.
Similarly,
(and
) jumps only if the counter is nonzero and
the zero flag is clear.
LSL
: Load Segment LimitLSL reg16,r/m16 ; o16 0F 03 /r [286,PRIV] LSL reg32,r/m32 ; o32 0F 03 /r [286,PRIV]
is given a segment selector in its source
(second) operand; it computes the segment limit value by loading the
segment limit field from the associated segment descriptor in the
or
. (This
involves shifting left by 12 bits if the segment limit is page-granular,
and not if it is byte-granular; so you end up with a byte limit in either
case.) The segment limit obtained is then loaded into the destination
(first) operand.
LTR
: Load Task RegisterLTR r/m16 ; 0F 00 /3 [286,PRIV]
looks up the segment base and limit in the
GDT or LDT descriptor specified by the segment selector given as its
operand, and loads them into the Task Register.
MASKMOVDQU
: Byte Mask WriteMASKMOVDQU xmm1,xmm2 ; 66 0F F7 /r [WILLAMETTE,SSE2]
stores data from xmm1 to the
location specified by
. The size of the
store depends on the address-size attribute. The most significant bit in
each byte of the mask register xmm2 is used to selectively write the data
(0 = no write, 1 = write) on a per-byte basis.
MASKMOVQ
: Byte Mask WriteMASKMOVQ mm1,mm2 ; 0F F7 /r [KATMAI,MMX]
stores data from mm1 to the location
specified by
. The size of the store
depends on the address-size attribute. The most significant bit in each
byte of the mask register mm2 is used to selectively write the data (0 = no
write, 1 = write) on a per-byte basis.
MAXPD
: Return Packed Double-Precision FP MaximumMAXPD xmm1,xmm2/m128 ; 66 0F 5F /r [WILLAMETTE,SSE2]
performs a SIMD compare of the packed
double-precision FP numbers from xmm1 and xmm2/mem, and stores the maximum
values of each pair of values in xmm1. If the values being compared are
both zeroes, source2 (xmm2/m128) would be returned. If source2 (xmm2/m128)
is an SNaN, this SNaN is forwarded unchanged to the destination (i.e., a
QNaN version of the SNaN is not returned).
MAXPS
: Return Packed Single-Precision FP MaximumMAXPS xmm1,xmm2/m128 ; 0F 5F /r [KATMAI,SSE]
performs a SIMD compare of the packed
single-precision FP numbers from xmm1 and xmm2/mem, and stores the maximum
values of each pair of values in xmm1. If the values being compared are
both zeroes, source2 (xmm2/m128) would be returned. If source2 (xmm2/m128)
is an SNaN, this SNaN is forwarded unchanged to the destination (i.e., a
QNaN version of the SNaN is not returned).
MAXSD
: Return Scalar Double-Precision FP MaximumMAXSD xmm1,xmm2/m64 ; F2 0F 5F /r [WILLAMETTE,SSE2]
compares the low-order double-precision
FP numbers from xmm1 and xmm2/mem, and stores the maximum value in xmm1. If
the values being compared are both zeroes, source2 (xmm2/m64) would be
returned. If source2 (xmm2/m64) is an SNaN, this SNaN is forwarded
unchanged to the destination (i.e., a QNaN version of the SNaN is not
returned). The high quadword of the destination is left unchanged.
MAXSS
: Return Scalar Single-Precision FP MaximumMAXSS xmm1,xmm2/m32 ; F3 0F 5F /r [KATMAI,SSE]
compares the low-order single-precision
FP numbers from xmm1 and xmm2/mem, and stores the maximum value in xmm1. If
the values being compared are both zeroes, source2 (xmm2/m32) would be
returned. If source2 (xmm2/m32) is an SNaN, this SNaN is forwarded
unchanged to the destination (i.e., a QNaN version of the SNaN is not
returned). The high three doublewords of the destination are left
unchanged.
MFENCE
: Memory FenceMFENCE ; 0F AE /6 [WILLAMETTE,SSE2]
performs a serialising operation on all
loads from memory and writes to memory that were issued before the
instruction. This guarantees that all
memory reads and writes before the
instruction are completed before any reads and writes after the
instruction.
is ordered respective to other
instructions,
,
, any
memory read and any other serialising instruction (such as
).
Weakly ordered memory types can be used to achieve higher processor
performance through such techniques as out-of-order issue, speculative
reads, write-combining, and write-collapsing. The degree to which a
consumer of data recognizes or knows that the data is weakly ordered varies
among applications and may be unknown to the producer of this data. The
instruction provides a
performance-efficient way of ensuring load and store ordering between
routines that produce weakly-ordered results and routines that consume that
data.
uses the following ModRM encoding:
Mod (7:6) = 11B Reg/Opcode (5:3) = 110B R/M (2:0) = 000B
All other ModRM encodings are defined to be reserved, and use of these encodings risks incompatibility with future processors.
See also
(section B.4.137) and
(section
B.4.288).
MINPD
: Return Packed Double-Precision FP MinimumMINPD xmm1,xmm2/m128 ; 66 0F 5D /r [WILLAMETTE,SSE2]
performs a SIMD compare of the packed
double-precision FP numbers from xmm1 and xmm2/mem, and stores the minimum
values of each pair of values in xmm1. If the values being compared are
both zeroes, source2 (xmm2/m128) would be returned. If source2 (xmm2/m128)
is an SNaN, this SNaN is forwarded unchanged to the destination (i.e., a
QNaN version of the SNaN is not returned).
MINPS
: Return Packed Single-Precision FP MinimumMINPS xmm1,xmm2/m128 ; 0F 5D /r [KATMAI,SSE]
performs a SIMD compare of the packed
single-precision FP numbers from xmm1 and xmm2/mem, and stores the minimum
values of each pair of values in xmm1. If the values being compared are
both zeroes, source2 (xmm2/m128) would be returned. If source2 (xmm2/m128)
is an SNaN, this SNaN is forwarded unchanged to the destination (i.e., a
QNaN version of the SNaN is not returned).
MINSD
: Return Scalar Double-Precision FP MinimumMINSD xmm1,xmm2/m64 ; F2 0F 5D /r [WILLAMETTE,SSE2]
compares the low-order double-precision
FP numbers from xmm1 and xmm2/mem, and stores the minimum value in xmm1. If
the values being compared are both zeroes, source2 (xmm2/m64) would be
returned. If source2 (xmm2/m64) is an SNaN, this SNaN is forwarded
unchanged to the destination (i.e., a QNaN version of the SNaN is not
returned). The high quadword of the destination is left unchanged.
MINSS
: Return Scalar Single-Precision FP MinimumMINSS xmm1,xmm2/m32 ; F3 0F 5D /r [KATMAI,SSE]
compares the low-order single-precision
FP numbers from xmm1 and xmm2/mem, and stores the minimum value in xmm1. If
the values being compared are both zeroes, source2 (xmm2/m32) would be
returned. If source2 (xmm2/m32) is an SNaN, this SNaN is forwarded
unchanged to the destination (i.e., a QNaN version of the SNaN is not
returned). The high three doublewords of the destination are left
unchanged.
MOV
: Move DataMOV r/m8,reg8 ; 88 /r [8086] MOV r/m16,reg16 ; o16 89 /r [8086] MOV r/m32,reg32 ; o32 89 /r [386] MOV reg8,r/m8 ; 8A /r [8086] MOV reg16,r/m16 ; o16 8B /r [8086] MOV reg32,r/m32 ; o32 8B /r [386]
MOV reg8,imm8 ; B0+r ib [8086] MOV reg16,imm16 ; o16 B8+r iw [8086] MOV reg32,imm32 ; o32 B8+r id [386] MOV r/m8,imm8 ; C6 /0 ib [8086] MOV r/m16,imm16 ; o16 C7 /0 iw [8086] MOV r/m32,imm32 ; o32 C7 /0 id [386]
MOV AL,memoffs8 ; A0 ow/od [8086] MOV AX,memoffs16 ; o16 A1 ow/od [8086] MOV EAX,memoffs32 ; o32 A1 ow/od [386] MOV memoffs8,AL ; A2 ow/od [8086] MOV memoffs16,AX ; o16 A3 ow/od [8086] MOV memoffs32,EAX ; o32 A3 ow/od [386]
MOV r/m16,segreg ; o16 8C /r [8086] MOV r/m32,segreg ; o32 8C /r [386] MOV segreg,r/m16 ; o16 8E /r [8086] MOV segreg,r/m32 ; o32 8E /r [386]
MOV reg32,CR0/2/3/4 ; 0F 20 /r [386] MOV reg32,DR0/1/2/3/6/7 ; 0F 21 /r [386] MOV reg32,TR3/4/5/6/7 ; 0F 24 /r [386] MOV CR0/2/3/4,reg32 ; 0F 22 /r [386] MOV DR0/1/2/3/6/7,reg32 ; 0F 23 /r [386] MOV TR3/4/5/6/7,reg32 ; 0F 26 /r [386]
copies the contents of its source (second)
operand into its destination (first) operand.
In all forms of the
instruction, the two
operands are the same size, except for moving between a segment register
and an
operand. These instructions are
treated exactly like the corresponding 16-bit equivalent (so that, for
example,
functions identically to
but saves a prefix when in 32-bit
mode), except that when a segment register is moved into a 32-bit
destination, the top two bytes of the result are undefined.
may not use
as a destination.
is only a supported register on the
Pentium and above.
Test registers are supported on 386/486 processors and on some non-Intel Pentium class processors.
MOVAPD
: Move Aligned Packed Double-Precision FP ValuesMOVAPD xmm1,xmm2/mem128 ; 66 0F 28 /r [WILLAMETTE,SSE2] MOVAPD xmm1/mem128,xmm2 ; 66 0F 29 /r [WILLAMETTE,SSE2]
moves a double quadword containing 2
packed double-precision FP values from the source operand to the
destination. When the source or destination operand is a memory location,
it must be aligned on a 16-byte boundary.
To move data in and out of memory locations that are not known to be on
16-byte boundaries, use the
instruction
(section B.4.182).
MOVAPS
: Move Aligned Packed Single-Precision FP ValuesMOVAPS xmm1,xmm2/mem128 ; 0F 28 /r [KATMAI,SSE] MOVAPS xmm1/mem128,xmm2 ; 0F 29 /r [KATMAI,SSE]
moves a double quadword containing 4
packed single-precision FP values from the source operand to the
destination. When the source or destination operand is a memory location,
it must be aligned on a 16-byte boundary.
To move data in and out of memory locations that are not known to be on
16-byte boundaries, use the
instruction
(section B.4.183).
MOVD
: Move Doubleword to/from MMX RegisterMOVD mm,r/m32 ; 0F 6E /r [PENT,MMX] MOVD r/m32,mm ; 0F 7E /r [PENT,MMX] MOVD xmm,r/m32 ; 66 0F 6E /r [WILLAMETTE,SSE2] MOVD r/m32,xmm ; 66 0F 7E /r [WILLAMETTE,SSE2]
copies 32 bits from its source (second)
operand into its destination (first) operand. When the destination is a
64-bit
register or a 128-bit
register, the input value is zero-extended to
fill the destination register.
MOVDQ2Q
: Move Quadword from XMM to MMX register.MOVDQ2Q mm,xmm ; F2 OF D6 /r [WILLAMETTE,SSE2]
moves the low quadword from the source
operand to the destination operand.
MOVDQA
: Move Aligned Double QuadwordMOVDQA xmm1,xmm2/m128 ; 66 OF 6F /r [WILLAMETTE,SSE2] MOVDQA xmm1/m128,xmm2 ; 66 OF 7F /r [WILLAMETTE,SSE2]
moves a double quadword from the source
operand to the destination operand. When the source or destination operand
is a memory location, it must be aligned to a 16-byte boundary.
To move a double quadword to or from unaligned memory locations, use the
instruction
(section B.4.162).
MOVDQU
: Move Unaligned Double QuadwordMOVDQU xmm1,xmm2/m128 ; F3 OF 6F /r [WILLAMETTE,SSE2] MOVDQU xmm1/m128,xmm2 ; F3 OF 7F /r [WILLAMETTE,SSE2]
moves a double quadword from the source
operand to the destination operand. When the source or destination operand
is a memory location, the memory may be unaligned.
To move a double quadword to or from known aligned memory locations, use
the
instruction
(section B.4.161).
MOVHLPS
: Move Packed Single-Precision FP High to LowMOVHLPS xmm1,xmm2 ; OF 12 /r [KATMAI,SSE]
moves the two packed single-precision
FP values from the high quadword of the source register xmm2 to the low
quadword of the destination register, xmm2. The upper quadword of xmm1 is
left unchanged.
The operation of this instruction is:
dst[0-63] := src[64-127], dst[64-127] remains unchanged.
MOVHPD
: Move High Packed Double-Precision FPMOVHPD xmm,m64 ; 66 OF 16 /r [WILLAMETTE,SSE2] MOVHPD m64,xmm ; 66 OF 17 /r [WILLAMETTE,SSE2]
moves a double-precision FP value
between the source and destination operands. One of the operands is a
64-bit memory location, the other is the high quadword of an
register.
The operation of this instruction is:
mem[0-63] := xmm[64-127];
or
xmm[0-63] remains unchanged; xmm[64-127] := mem[0-63].
MOVHPS
: Move High Packed Single-Precision FPMOVHPS xmm,m64 ; 0F 16 /r [KATMAI,SSE] MOVHPS m64,xmm ; 0F 17 /r [KATMAI,SSE]
moves two packed single-precision FP
values between the source and destination operands. One of the operands is
a 64-bit memory location, the other is the high quadword of an
register.
The operation of this instruction is:
mem[0-63] := xmm[64-127];
or
xmm[0-63] remains unchanged; xmm[64-127] := mem[0-63].
MOVLHPS
: Move Packed Single-Precision FP Low to HighMOVLHPS xmm1,xmm2 ; OF 16 /r [KATMAI,SSE]
moves the two packed single-precision
FP values from the low quadword of the source register xmm2 to the high
quadword of the destination register, xmm2. The low quadword of xmm1 is
left unchanged.
The operation of this instruction is:
dst[0-63] remains unchanged; dst[64-127] := src[0-63].
MOVLPD
: Move Low Packed Double-Precision FPMOVLPD xmm,m64 ; 66 OF 12 /r [WILLAMETTE,SSE2] MOVLPD m64,xmm ; 66 OF 13 /r [WILLAMETTE,SSE2]
moves a double-precision FP value
between the source and destination operands. One of the operands is a
64-bit memory location, the other is the low quadword of an
register.
The operation of this instruction is:
mem(0-63) := xmm(0-63);
or
xmm(0-63) := mem(0-63); xmm(64-127) remains unchanged.
MOVLPS
: Move Low Packed Single-Precision FPMOVLPS xmm,m64 ; OF 12 /r [KATMAI,SSE] MOVLPS m64,xmm ; OF 13 /r [KATMAI,SSE]
moves two packed single-precision FP
values between the source and destination operands. One of the operands is
a 64-bit memory location, the other is the low quadword of an
register.
The operation of this instruction is:
mem(0-63) := xmm(0-63);
or
xmm(0-63) := mem(0-63); xmm(64-127) remains unchanged.
MOVMSKPD
: Extract Packed Double-Precision FP Sign MaskMOVMSKPD reg32,xmm ; 66 0F 50 /r [WILLAMETTE,SSE2]
inserts a 2-bit mask in r32, formed
of the most significant bits of each double-precision FP number of the
source operand.
MOVMSKPS
: Extract Packed Single-Precision FP Sign MaskMOVMSKPS reg32,xmm ; 0F 50 /r [KATMAI,SSE]
inserts a 4-bit mask in r32, formed
of the most significant bits of each single-precision FP number of the
source operand.
MOVNTDQ
: Move Double Quadword Non TemporalMOVNTDQ m128,xmm ; 66 0F E7 /r [WILLAMETTE,SSE2]
moves the double quadword from the
source register to the destination memory
location, using a non-temporal hint. This store instruction minimizes cache
pollution.
MOVNTI
: Move Doubleword Non TemporalMOVNTI m32,reg32 ; 0F C3 /r [WILLAMETTE,SSE2]
moves the doubleword in the source
register to the destination memory location, using a non-temporal hint.
This store instruction minimizes cache pollution.
MOVNTPD
: Move Aligned Four Packed Single-Precision FP Values Non TemporalMOVNTPD m128,xmm ; 66 0F 2B /r [WILLAMETTE,SSE2]
moves the double quadword from the
source register to the destination memory
location, using a non-temporal hint. This store instruction minimizes cache
pollution. The memory location must be aligned to a 16-byte boundary.
MOVNTPS
: Move Aligned Four Packed Single-Precision FP Values Non TemporalMOVNTPS m128,xmm ; 0F 2B /r [KATMAI,SSE]
moves the double quadword from the
source register to the destination memory
location, using a non-temporal hint. This store instruction minimizes cache
pollution. The memory location must be aligned to a 16-byte boundary.
MOVNTQ
: Move Quadword Non TemporalMOVNTQ m64,mm ; 0F E7 /r [KATMAI,MMX]
moves the quadword in the
source register to the destination memory
location, using a non-temporal hint. This store instruction minimizes cache
pollution.
MOVQ
: Move Quadword to/from MMX RegisterMOVQ mm1,mm2/m64 ; 0F 6F /r [PENT,MMX] MOVQ mm1/m64,mm2 ; 0F 7F /r [PENT,MMX]
MOVQ xmm1,xmm2/m64 ; F3 0F 7E /r [WILLAMETTE,SSE2] MOVQ xmm1/m64,xmm2 ; 66 0F D6 /r [WILLAMETTE,SSE2]
copies 64 bits from its source (second)
operand into its destination (first) operand. When the source is an
register, the low quadword is moved. When the
destination is an
register, the destination
is the low quadword, and the high quadword is cleared.
MOVQ2DQ
: Move Quadword from MMX to XMM register.MOVQ2DQ xmm,mm ; F3 OF D6 /r [WILLAMETTE,SSE2]
moves the quadword from the source
operand to the low quadword of the destination operand, and clears the high
quadword.
MOVSB
, MOVSW
, MOVSD
: Move StringMOVSB ; A4 [8086] MOVSW ; o16 A5 [8086] MOVSD ; o32 A5 [386]
copies the byte at
or
to
or
. It
then increments or decrements (depending on the direction flag: increments
if the flag is clear, decrements if it is set)
and
(or
and
).
The registers used are
and
if the address size is 16 bits, and
and
if it is 32
bits. If you need to use an address size not equal to the current
setting, you can use an explicit
or
prefix.
The segment register used to load from
or
can be overridden by using a segment
register name as a prefix (for example,
). The use of
for the store to
or
cannot be
overridden.
and
work
in the same way, but they copy a word or a doubleword instead of a byte,
and increment or decrement the addressing registers by 2 or 4 instead of 1.
The
prefix may be used to repeat the
instruction
(or
- again, the address size chooses which) times.
MOVSD
: Move Scalar Double-Precision FP ValueMOVSD xmm1,xmm2/m64 ; F2 0F 10 /r [WILLAMETTE,SSE2] MOVSD xmm1/m64,xmm2 ; F2 0F 11 /r [WILLAMETTE,SSE2]
moves a double-precision FP value from
the source operand to the destination operand. When the source or
destination is a register, the low-order FP value is read or written.
MOVSS
: Move Scalar Single-Precision FP ValueMOVSS xmm1,xmm2/m32 ; F3 0F 10 /r [KATMAI,SSE] MOVSS xmm1/m32,xmm2 ; F3 0F 11 /r [KATMAI,SSE]
moves a single-precision FP value from
the source operand to the destination operand. When the source or
destination is a register, the low-order FP value is read or written.
MOVSX
, MOVZX
: Move Data with Sign or Zero ExtendMOVSX reg16,r/m8 ; o16 0F BE /r [386] MOVSX reg32,r/m8 ; o32 0F BE /r [386] MOVSX reg32,r/m16 ; o32 0F BF /r [386]
MOVZX reg16,r/m8 ; o16 0F B6 /r [386] MOVZX reg32,r/m8 ; o32 0F B6 /r [386] MOVZX reg32,r/m16 ; o32 0F B7 /r [386]
sign-extends its source (second) operand
to the length of its destination (first) operand, and copies the result
into the destination operand.
does the
same, but zero-extends rather than sign-extending.
MOVUPD
: Move Unaligned Packed Double-Precision FP ValuesMOVUPD xmm1,xmm2/mem128 ; 66 0F 10 /r [WILLAMETTE,SSE2] MOVUPD xmm1/mem128,xmm2 ; 66 0F 11 /r [WILLAMETTE,SSE2]
moves a double quadword containing 2
packed double-precision FP values from the source operand to the
destination. This instruction makes no assumptions about alignment of
memory operands.
To move data in and out of memory locations that are known to be on
16-byte boundaries, use the
instruction
(section B.4.157).
MOVUPS
: Move Unaligned Packed Single-Precision FP ValuesMOVUPS xmm1,xmm2/mem128 ; 0F 10 /r [KATMAI,SSE] MOVUPS xmm1/mem128,xmm2 ; 0F 11 /r [KATMAI,SSE]
moves a double quadword containing 4
packed single-precision FP values from the source operand to the
destination. This instruction makes no assumptions about alignment of
memory operands.
To move data in and out of memory locations that are known to be on
16-byte boundaries, use the
instruction
(section B.4.158).
MUL
: Unsigned Integer MultiplyMUL r/m8 ; F6 /4 [8086] MUL r/m16 ; o16 F7 /4 [8086] MUL r/m32 ; o32 F7 /4 [386]
performs unsigned integer multiplication.
The other operand to the multiplication, and the destination operand, are
implicit, in the following way:
MUL r/m8
, AL
is
multiplied by the given operand; the product is stored in
AX
.
MUL r/m16
, AX
is multiplied by the given operand; the product is stored in
DX:AX
.
MUL r/m32
, EAX
is multiplied by the given operand; the product is stored in
EDX:EAX
.
Signed integer multiplication is performed by the
instruction: see
section B.4.118.
MULPD
: Packed Single-FP MultiplyMULPD xmm1,xmm2/mem128 ; 66 0F 59 /r [WILLAMETTE,SSE2]
performs a SIMD multiply of the packed
double-precision FP values in both operands, and stores the results in the
destination register.
MULPS
: Packed Single-FP MultiplyMULPS xmm1,xmm2/mem128 ; 0F 59 /r [KATMAI,SSE]
performs a SIMD multiply of the packed
single-precision FP values in both operands, and stores the results in the
destination register.
MULSD
: Scalar Single-FP MultiplyMULSD xmm1,xmm2/mem32 ; F2 0F 59 /r [WILLAMETTE,SSE2]
multiplies the lowest double-precision
FP values of both operands, and stores the result in the low quadword of
xmm1.
MULSS
: Scalar Single-FP MultiplyMULSS xmm1,xmm2/mem32 ; F3 0F 59 /r [KATMAI,SSE]
multiplies the lowest single-precision
FP values of both operands, and stores the result in the low doubleword of
xmm1.
NEG
, NOT
: Two's and One's ComplementNEG r/m8 ; F6 /3 [8086] NEG r/m16 ; o16 F7 /3 [8086] NEG r/m32 ; o32 F7 /3 [386]
NOT r/m8 ; F6 /2 [8086] NOT r/m16 ; o16 F7 /2 [8086] NOT r/m32 ; o32 F7 /2 [386]
replaces the contents of its operand by
the two's complement negation (invert all the bits and then add one) of the
original value.
, similarly, performs one's
complement (inverts all the bits).
NOP
: No OperationNOP ; 90 [8086]
performs no operation. Its opcode is the
same as that generated by
or
(depending on the processor mode;
see section B.4.333).
OR
: Bitwise OROR r/m8,reg8 ; 08 /r [8086] OR r/m16,reg16 ; o16 09 /r [8086] OR r/m32,reg32 ; o32 09 /r [386]
OR reg8,r/m8 ; 0A /r [8086] OR reg16,r/m16 ; o16 0B /r [8086] OR reg32,r/m32 ; o32 0B /r [386]
OR r/m8,imm8 ; 80 /1 ib [8086] OR r/m16,imm16 ; o16 81 /1 iw [8086] OR r/m32,imm32 ; o32 81 /1 id [386]
OR r/m16,imm8 ; o16 83 /1 ib [8086] OR r/m32,imm8 ; o32 83 /1 ib [386]
OR AL,imm8 ; 0C ib [8086] OR AX,imm16 ; o16 0D iw [8086] OR EAX,imm32 ; o32 0D id [386]
performs a bitwise OR operation between its
two operands (i.e. each bit of the result is 1 if and only if at least one
of the corresponding bits of the two inputs was 1), and stores the result
in the destination (first) operand.
In the forms with an 8-bit immediate second operand and a longer first
operand, the second operand is considered to be signed, and is
sign-extended to the length of the first operand. In these cases, the
qualifier is necessary to force NASM to
generate this form of the instruction.
The MMX instruction
(see
section B.4.247) performs the same operation
on the 64-bit MMX registers.
ORPD
: Bit-wise Logical OR of Double-Precision FP DataORPD xmm1,xmm2/m128 ; 66 0F 56 /r [WILLAMETTE,SSE2]
return a bit-wise logical OR between xmm1
and xmm2/mem, and stores the result in xmm1. If the source operand is a
memory location, it must be aligned to a 16-byte boundary.
ORPS
: Bit-wise Logical OR of Single-Precision FP DataORPS xmm1,xmm2/m128 ; 0F 56 /r [KATMAI,SSE]
return a bit-wise logical OR between xmm1
and xmm2/mem, and stores the result in xmm1. If the source operand is a
memory location, it must be aligned to a 16-byte boundary.
OUT
: Output Data to I/O PortOUT imm8,AL ; E6 ib [8086] OUT imm8,AX ; o16 E7 ib [8086] OUT imm8,EAX ; o32 E7 ib [386] OUT DX,AL ; EE [8086] OUT DX,AX ; o16 EF [8086] OUT DX,EAX ; o32 EF [386]
writes the contents of the given source
register to the specified I/O port. The port number may be specified as an
immediate value if it is between 0 and 255, and otherwise must be stored in
. See also
(section B.4.119).
OUTSB
, OUTSW
, OUTSD
: Output String to I/O PortOUTSB ; 6E [186] OUTSW ; o16 6F [186] OUTSD ; o32 6F [386]
loads a byte from
or
and
writes it to the I/O port specified in
. It
then increments or decrements (depending on the direction flag: increments
if the flag is clear, decrements if it is set)
or
.
The register used is
if the address size is
16 bits, and
if it is 32 bits. If you need to
use an address size not equal to the current
setting, you can use an explicit
or
prefix.
The segment register used to load from
or
can be overridden by using a segment
register name as a prefix (for example,
).
and
work
in the same way, but they output a word or a doubleword instead of a byte,
and increment or decrement the addressing registers by 2 or 4 instead of 1.
The
prefix may be used to repeat the
instruction
(or
- again, the address size chooses which) times.
PACKSSDW
, PACKSSWB
, PACKUSWB
: Pack DataPACKSSDW mm1,mm2/m64 ; 0F 6B /r [PENT,MMX] PACKSSWB mm1,mm2/m64 ; 0F 63 /r [PENT,MMX] PACKUSWB mm1,mm2/m64 ; 0F 67 /r [PENT,MMX]
PACKSSDW xmm1,xmm2/m128 ; 66 0F 6B /r [WILLAMETTE,SSE2] PACKSSWB xmm1,xmm2/m128 ; 66 0F 63 /r [WILLAMETTE,SSE2] PACKUSWB xmm1,xmm2/m128 ; 66 0F 67 /r [WILLAMETTE,SSE2]
All these instructions start by combining the source and destination
operands, and then splitting the result in smaller sections which it then
packs into the destination register. The
versions pack two 64-bit operands into one 64-bit register, while the
versions pack two 128-bit operands into one
128-bit register.
PACKSSWB
splits the combined value into
words, and then reduces the words to bytes, using signed saturation. It
then packs the bytes into the destination register in the same order the
words were in.
PACKSSDW
performs the same operation as
PACKSSWB
, except that it reduces doublewords to
words, then packs them into the destination register.
PACKUSWB
performs the same operation as
PACKSSWB
, except that it uses unsigned saturation
when reducing the size of the elements.
To perform signed saturation on a number, it is replaced by the largest
signed number (
or
) that will fit, and if it is too
small it is replaced by the smallest signed number
(
or
) that
will fit. To perform unsigned saturation, the input is treated as unsigned,
and the input is replaced by the largest unsigned number that will fit.
PADDB
, PADDW
, PADDD
: Add Packed IntegersPADDB mm1,mm2/m64 ; 0F FC /r [PENT,MMX] PADDW mm1,mm2/m64 ; 0F FD /r [PENT,MMX] PADDD mm1,mm2/m64 ; 0F FE /r [PENT,MMX]
PADDB xmm1,xmm2/m128 ; 66 0F FC /r [WILLAMETTE,SSE2] PADDW xmm1,xmm2/m128 ; 66 0F FD /r [WILLAMETTE,SSE2] PADDD xmm1,xmm2/m128 ; 66 0F FE /r [WILLAMETTE,SSE2]
performs packed addition of the two
operands, storing the result in the destination (first) operand.
PADDB
treats the operands as packed bytes,
and adds each byte individually;
PADDW
treats the operands as packed words;
PADDD
treats its operands as packed
doublewords.
When an individual result is too large to fit in its destination, it is wrapped around and the low bits are stored, with the carry bit discarded.
PADDQ
: Add Packed Quadword IntegersPADDQ mm1,mm2/m64 ; 0F D4 /r [PENT,MMX]
PADDQ xmm1,xmm2/m128 ; 66 0F D4 /r [WILLAMETTE,SSE2]
adds the quadwords in the source and
destination operands, and stores the result in the destination register.
When an individual result is too large to fit in its destination, it is wrapped around and the low bits are stored, with the carry bit discarded.
PADDSB
, PADDSW
: Add Packed Signed Integers With SaturationPADDSB mm1,mm2/m64 ; 0F EC /r [PENT,MMX] PADDSW mm1,mm2/m64 ; 0F ED /r [PENT,MMX]
PADDSB xmm1,xmm2/m128 ; 66 0F EC /r [WILLAMETTE,SSE2] PADDSW xmm1,xmm2/m128 ; 66 0F ED /r [WILLAMETTE,SSE2]
performs packed addition of the two
operands, storing the result in the destination (first) operand.
treats the operands as packed bytes, and
adds each byte individually; and
treats
the operands as packed words.
When an individual result is too large to fit in its destination, a saturated value is stored. The resulting value is the value with the largest magnitude of the same sign as the result which will fit in the available space.
PADDSIW
: MMX Packed Addition to Implicit DestinationPADDSIW mmxreg,r/m64 ; 0F 51 /r [CYRIX,MMX]
, specific to the Cyrix extensions to
the MMX instruction set, performs the same function as
, except that the result is placed in an
implied register.
To work out the implied register, invert the lowest bit in the register
number. So
would put the result
in
, but
would put the result in
.
PADDUSB
, PADDUSW
: Add Packed Unsigned Integers With SaturationPADDUSB mm1,mm2/m64 ; 0F DC /r [PENT,MMX] PADDUSW mm1,mm2/m64 ; 0F DD /r [PENT,MMX]
PADDUSB xmm1,xmm2/m128 ; 66 0F DC /r [WILLAMETTE,SSE2] PADDUSW xmm1,xmm2/m128 ; 66 0F DD /r [WILLAMETTE,SSE2]
performs packed addition of the two
operands, storing the result in the destination (first) operand.
treats the operands as packed bytes, and
adds each byte individually; and
treats
the operands as packed words.
When an individual result is too large to fit in its destination, a saturated value is stored. The resulting value is the maximum value that will fit in the available space.
PAND
, PANDN
: MMX Bitwise AND and AND-NOTPAND mm1,mm2/m64 ; 0F DB /r [PENT,MMX] PANDN mm1,mm2/m64 ; 0F DF /r [PENT,MMX]
PAND xmm1,xmm2/m128 ; 66 0F DB /r [WILLAMETTE,SSE2] PANDN xmm1,xmm2/m128 ; 66 0F DF /r [WILLAMETTE,SSE2]
performs a bitwise AND operation between
its two operands (i.e. each bit of the result is 1 if and only if the
corresponding bits of the two inputs were both 1), and stores the result in
the destination (first) operand.
performs the same operation, but
performs a one's complement operation on the destination (first) operand
first.
PAUSE
: Spin Loop HintPAUSE ; F3 90 [WILLAMETTE,SSE2]
provides a hint to the processor that
the following code is a spin loop. This improves processor performance by
bypassing possible memory order violations. On older processors, this
instruction operates as a
.
PAVEB
: MMX Packed AveragePAVEB mmxreg,r/m64 ; 0F 50 /r [CYRIX,MMX]
, specific to the Cyrix MMX extensions,
treats its two operands as vectors of eight unsigned bytes, and calculates
the average of the corresponding bytes in the operands. The resulting
vector of eight averages is stored in the first operand.
This opcode maps to
on
processors that support the SSE instruction set.
PAVGB
PAVGW
: Average Packed IntegersPAVGB mm1,mm2/m64 ; 0F E0 /r [KATMAI,MMX] PAVGW mm1,mm2/m64 ; 0F E3 /r [KATMAI,MMX,SM]
PAVGB xmm1,xmm2/m128 ; 66 0F E0 /r [WILLAMETTE,SSE2] PAVGW xmm1,xmm2/m128 ; 66 0F E3 /r [WILLAMETTE,SSE2]
and
add
the unsigned data elements of the source operand to the unsigned data
elements of the destination register, then adds 1 to the temporary results.
The results of the add are then each independently right-shifted by one bit
position. The high order bits of each element are filled with the carry
bits of the corresponding sum.
PAVGB
operates on packed unsigned bytes, and
PAVGW
operates on packed unsigned words.
PAVGUSB
: Average of unsigned packed 8-bit valuesPAVGUSB mm1,mm2/m64 ; 0F 0F /r BF [PENT,3DNOW]
adds the unsigned data elements of the
source operand to the unsigned data elements of the destination register,
then adds 1 to the temporary results. The results of the add are then each
independently right-shifted by one bit position. The high order bits of
each element are filled with the carry bits of the corresponding sum.
This instruction performs exactly the same operations as the
instruction
(section B.4.205).
PCMPxx
: Compare Packed Integers.PCMPEQB mm1,mm2/m64 ; 0F 74 /r [PENT,MMX] PCMPEQW mm1,mm2/m64 ; 0F 75 /r [PENT,MMX] PCMPEQD mm1,mm2/m64 ; 0F 76 /r [PENT,MMX]
PCMPGTB mm1,mm2/m64 ; 0F 64 /r [PENT,MMX] PCMPGTW mm1,mm2/m64 ; 0F 65 /r [PENT,MMX] PCMPGTD mm1,mm2/m64 ; 0F 66 /r [PENT,MMX]
PCMPEQB xmm1,xmm2/m128 ; 66 0F 74 /r [WILLAMETTE,SSE2] PCMPEQW xmm1,xmm2/m128 ; 66 0F 75 /r [WILLAMETTE,SSE2] PCMPEQD xmm1,xmm2/m128 ; 66 0F 76 /r [WILLAMETTE,SSE2]
PCMPGTB xmm1,xmm2/m128 ; 66 0F 64 /r [WILLAMETTE,SSE2] PCMPGTW xmm1,xmm2/m128 ; 66 0F 65 /r [WILLAMETTE,SSE2] PCMPGTD xmm1,xmm2/m128 ; 66 0F 66 /r [WILLAMETTE,SSE2]
The
instructions all treat their
operands as vectors of bytes, words, or doublewords; corresponding elements
of the source and destination are compared, and the corresponding element
of the destination (first) operand is set to all zeros or all ones
depending on the result of the comparison.
PCMPxxB
treats the operands as vectors of
bytes;
PCMPxxW
treats the operands as vectors of
words;
PCMPxxD
treats the operands as vectors of
doublewords;
PCMPEQx
sets the corresponding element of the
destination operand to all ones if the two elements compared are equal;
PCMPGTx
sets the destination element to all
ones if the element of the first (destination) operand is greater (treated
as a signed integer) than that of the second (source) operand.
PDISTIB
: MMX Packed Distance and Accumulate with Implied RegisterPDISTIB mm,m64 ; 0F 54 /r [CYRIX,MMX]
, specific to the Cyrix MMX extensions,
treats its two input operands as vectors of eight unsigned bytes. For each
byte position, it finds the absolute difference between the bytes in that
position in the two input operands, and adds that value to the byte in the
same position in the implied output register. The addition is saturated to
an unsigned byte in the same way as
.
To work out the implied register, invert the lowest bit in the register
number. So
would put the result
in
, but
would put the result in
.
Note that
cannot take a register as
its second source operand.
Operation:
dstI[0-7] := dstI[0-7] + ABS(src0[0-7] - src1[0-7]), dstI[8-15] := dstI[8-15] + ABS(src0[8-15] - src1[8-15]), ....... ....... dstI[56-63] := dstI[56-63] + ABS(src0[56-63] - src1[56-63]).
PEXTRW
: Extract WordPEXTRW reg32,mm,imm8 ; 0F C5 /r ib [KATMAI,MMX] PEXTRW reg32,xmm,imm8 ; 66 0F C5 /r ib [WILLAMETTE,SSE2]
moves the word in the source register
(second operand) that is pointed to by the count operand (third operand),
into the lower half of a 32-bit general purpose register. The upper half of
the register is cleared to all 0s.
When the source operand is an
register,
the two least significant bits of the count specify the source word. When
it is an
register, the three least
significant bits specify the word location.
PF2ID
: Packed Single-Precision FP to Integer ConvertPF2ID mm1,mm2/m64 ; 0F 0F /r 1D [PENT,3DNOW]
converts two single-precision FP values
in the source operand to signed 32-bit integers, using truncation, and
stores them in the destination operand. Source values that are outside the
range supported by the destination are saturated to the largest absolute
value of the same sign.
PF2IW
: Packed Single-Precision FP to Integer Word ConvertPF2IW mm1,mm2/m64 ; 0F 0F /r 1C [PENT,3DNOW]
converts two single-precision FP values
in the source operand to signed 16-bit integers, using truncation, and
stores them in the destination operand. Source values that are outside the
range supported by the destination are saturated to the largest absolute
value of the same sign.
PFACC
: Packed Single-Precision FP AccumulatePFACC mm1,mm2/m64 ; 0F 0F /r AE [PENT,3DNOW]
adds the two single-precision FP values
from the destination operand together, then adds the two single-precision
FP values from the source operand, and places the results in the low and
high doublewords of the destination operand.
The operation is:
dst[0-31] := dst[0-31] + dst[32-63], dst[32-63] := src[0-31] + src[32-63].
PFADD
: Packed Single-Precision FP AdditionPFADD mm1,mm2/m64 ; 0F 0F /r 9E [PENT,3DNOW]
performs addition on each of two packed
single-precision FP value pairs.
dst[0-31] := dst[0-31] + src[0-31], dst[32-63] := dst[32-63] + src[32-63].
PFCMPxx
: Packed Single-Precision FP Compare PFCMPEQ mm1,mm2/m64 ; 0F 0F /r B0 [PENT,3DNOW] PFCMPGE mm1,mm2/m64 ; 0F 0F /r 90 [PENT,3DNOW] PFCMPGT mm1,mm2/m64 ; 0F 0F /r A0 [PENT,3DNOW]
The
instructions compare the packed
single-point FP values in the source and destination operands, and set the
destination according to the result. If the condition is true, the
destination is set to all 1s, otherwise it's set to all 0s.
PFCMPEQ
tests whether dst == src;
PFCMPGE
tests whether dst >= src;
PFCMPGT
tests whether dst > src.
PFMAX
: Packed Single-Precision FP MaximumPFMAX mm1,mm2/m64 ; 0F 0F /r A4 [PENT,3DNOW]
returns the higher of each pair of
single-precision FP values. If the higher value is zero, it is returned as
positive zero.
PFMIN
: Packed Single-Precision FP MinimumPFMIN mm1,mm2/m64 ; 0F 0F /r 94 [PENT,3DNOW]
returns the lower of each pair of
single-precision FP values. If the lower value is zero, it is returned as
positive zero.
PFMUL
: Packed Single-Precision FP MultiplyPFMUL mm1,mm2/m64 ; 0F 0F /r B4 [PENT,3DNOW]
returns the product of each pair of
single-precision FP values.
dst[0-31] := dst[0-31] * src[0-31], dst[32-63] := dst[32-63] * src[32-63].
PFNACC
: Packed Single-Precision FP Negative AccumulatePFNACC mm1,mm2/m64 ; 0F 0F /r 8A [PENT,3DNOW]
performs a negative accumulate of the
two single-precision FP values in the source and destination registers. The
result of the accumulate from the destination register is stored in the low
doubleword of the destination, and the result of the source accumulate is
stored in the high doubleword of the destination register.
The operation is:
dst[0-31] := dst[0-31] - dst[32-63], dst[32-63] := src[0-31] - src[32-63].
PFPNACC
: Packed Single-Precision FP Mixed AccumulatePFPNACC mm1,mm2/m64 ; 0F 0F /r 8E [PENT,3DNOW]
performs a positive accumulate of the
two single-precision FP values in the source register and a negative
accumulate of the destination register. The result of the accumulate from
the destination register is stored in the low doubleword of the
destination, and the result of the source accumulate is stored in the high
doubleword of the destination register.
The operation is:
dst[0-31] := dst[0-31] - dst[32-63], dst[32-63] := src[0-31] + src[32-63].
PFRCP
: Packed Single-Precision FP Reciprocal ApproximationPFRCP mm1,mm2/m64 ; 0F 0F /r 96 [PENT,3DNOW]
performs a low precision estimate of the
reciprocal of the low-order single-precision FP value in the source
operand, storing the result in both halves of the destination register. The
result is accurate to 14 bits.
For higher precision reciprocals, this instruction should be followed by
two more instructions:
(section B.4.221) and
(section
B.4.221). This will result in a 24-bit accuracy. For more details, see
the AMD 3DNow! technology manual.
PFRCPIT1
: Packed Single-Precision FP Reciprocal, First Iteration StepPFRCPIT1 mm1,mm2/m64 ; 0F 0F /r A6 [PENT,3DNOW]
performs the first intermediate step
in the calculation of the reciprocal of a single-precision FP value. The
first source value (
is the original value,
and the second source value (
is the
result of a
instruction.
For the final step in a reciprocal, returning the full 24-bit accuracy
of a single-precision FP value, see
(section B.4.222). For more details, see the
AMD 3DNow! technology manual.
PFRCPIT2
: Packed Single-Precision FP Reciprocal/ Reciprocal Square Root, Second Iteration StepPFRCPIT2 mm1,mm2/m64 ; 0F 0F /r B6 [PENT,3DNOW]
performs the second and final
intermediate step in the calculation of a reciprocal or reciprocal square
root, refining the values returned by the
and
instructions, respectively.
The first source value (
) is the output of
either a
or a
instruction, and the second source is
the output of either the
or the
instruction. For more details, see the
AMD 3DNow! technology manual.
PFRSQIT1
: Packed Single-Precision FP Reciprocal Square Root, First Iteration StepPFRSQIT1 mm1,mm2/m64 ; 0F 0F /r A7 [PENT,3DNOW]
performs the first intermediate step
in the calculation of the reciprocal square root of a single-precision FP
value. The first source value (
is the square
of the result of a
instruction, and the
second source value (
is the original
value.
For the final step in a calculation, returning the full 24-bit accuracy
of a single-precision FP value, see
(section B.4.222). For more details, see the
AMD 3DNow! technology manual.
PFRSQRT
: Packed Single-Precision FP Reciprocal Square Root ApproximationPFRSQRT mm1,mm2/m64 ; 0F 0F /r 97 [PENT,3DNOW]
performs a low precision estimate of
the reciprocal square root of the low-order single-precision FP value in
the source operand, storing the result in both halves of the destination
register. The result is accurate to 15 bits.
For higher precision reciprocals, this instruction should be followed by
two more instructions:
(section B.4.223) and
(section
B.4.221). This will result in a 24-bit accuracy. For more details, see
the AMD 3DNow! technology manual.
PFSUB
: Packed Single-Precision FP SubtractPFSUB mm1,mm2/m64 ; 0F 0F /r 9A [PENT,3DNOW]
subtracts the single-precision FP values
in the source from those in the destination, and stores the result in the
destination operand.
dst[0-31] := dst[0-31] - src[0-31], dst[32-63] := dst[32-63] - src[32-63].
PFSUBR
: Packed Single-Precision FP Reverse SubtractPFSUBR mm1,mm2/m64 ; 0F 0F /r AA [PENT,3DNOW]
subtracts the single-precision FP
values in the destination from those in the source, and stores the result
in the destination operand.
dst[0-31] := src[0-31] - dst[0-31], dst[32-63] := src[32-63] - dst[32-63].
PI2FD
: Packed Doubleword Integer to Single-Precision FP ConvertPI2FD mm1,mm2/m64 ; 0F 0F /r 0D [PENT,3DNOW]
converts two signed 32-bit integers in
the source operand to single-precision FP values, using truncation of
significant digits, and stores them in the destination operand.
PF2IW
: Packed Word Integer to Single-Precision FP ConvertPI2FW mm1,mm2/m64 ; 0F 0F /r 0C [PENT,3DNOW]
converts two signed 16-bit integers in
the source operand to single-precision FP values, and stores them in the
destination operand. The input values are in the low word of each
doubleword.
PINSRW
: Insert WordPINSRW mm,r16/r32/m16,imm8 ;0F C4 /r ib [KATMAI,MMX] PINSRW xmm,r16/r32/m16,imm8 ;66 0F C4 /r ib [WILLAMETTE,SSE2]
loads a word from a 16-bit register (or
the low half of a 32-bit register), or from memory, and loads it to the
word position in the destination register, pointed at by the count operand
(third operand). If the destination is an
register, the low two bits of the count byte are used, if it is an
register the low 3 bits are used. The
insertion is done in such a way that the other words from the destination
register are left untouched.
PMACHRIW
: Packed Multiply and Accumulate with RoundingPMACHRIW mm,m64 ; 0F 5E /r [CYRIX,MMX]
takes two packed 16-bit integer
inputs, multiplies the values in the inputs, rounds on bit 15 of each
result, then adds bits 15-30 of each result to the corresponding position
of the implied destination register.
The operation of this instruction is:
dstI[0-15] := dstI[0-15] + (mm[0-15] *m64[0-15] + 0x00004000)[15-30], dstI[16-31] := dstI[16-31] + (mm[16-31]*m64[16-31] + 0x00004000)[15-30], dstI[32-47] := dstI[32-47] + (mm[32-47]*m64[32-47] + 0x00004000)[15-30], dstI[48-63] := dstI[48-63] + (mm[48-63]*m64[48-63] + 0x00004000)[15-30].
Note that
cannot take a register as
its second source operand.
PMADDWD
: MMX Packed Multiply and AddPMADDWD mm1,mm2/m64 ; 0F F5 /r [PENT,MMX] PMADDWD xmm1,xmm2/m128 ; 66 0F F5 /r [WILLAMETTE,SSE2]
treats its two inputs as vectors of
signed words. It multiplies corresponding elements of the two operands,
giving doubleword results. These are then added together in pairs and
stored in the destination operand.
The operation of this instruction is:
dst[0-31] := (dst[0-15] * src[0-15]) + (dst[16-31] * src[16-31]); dst[32-63] := (dst[32-47] * src[32-47]) + (dst[48-63] * src[48-63]);
The following apply to the
version of the
instruction:
dst[64-95] := (dst[64-79] * src[64-79]) + (dst[80-95] * src[80-95]); dst[96-127] := (dst[96-111] * src[96-111]) + (dst[112-127] * src[112-127]).
PMAGW
: MMX Packed MagnitudePMAGW mm1,mm2/m64 ; 0F 52 /r [CYRIX,MMX]
, specific to the Cyrix MMX extensions,
treats both its operands as vectors of four signed words. It compares the
absolute values of the words in corresponding positions, and sets each word
of the destination (first) operand to whichever of the two words in that
position had the larger absolute value.
PMAXSW
: Packed Signed Integer Word MaximumPMAXSW mm1,mm2/m64 ; 0F EE /r [KATMAI,MMX] PMAXSW xmm1,xmm2/m128 ; 66 0F EE /r [WILLAMETTE,SSE2]
compares each pair of words in the two
source operands, and for each pair it stores the maximum value in the
destination register.
PMAXUB
: Packed Unsigned Integer Byte MaximumPMAXUB mm1,mm2/m64 ; 0F DE /r [KATMAI,MMX] PMAXUB xmm1,xmm2/m128 ; 66 0F DE /r [WILLAMETTE,SSE2]
compares each pair of bytes in the two
source operands, and for each pair it stores the maximum value in the
destination register.
PMINSW
: Packed Signed Integer Word MinimumPMINSW mm1,mm2/m64 ; 0F EA /r [KATMAI,MMX] PMINSW xmm1,xmm2/m128 ; 66 0F EA /r [WILLAMETTE,SSE2]
compares each pair of words in the two
source operands, and for each pair it stores the minimum value in the
destination register.
PMINUB
: Packed Unsigned Integer Byte MinimumPMINUB mm1,mm2/m64 ; 0F DA /r [KATMAI,MMX] PMINUB xmm1,xmm2/m128 ; 66 0F DA /r [WILLAMETTE,SSE2]
compares each pair of bytes in the two
source operands, and for each pair it stores the minimum value in the
destination register.
PMOVMSKB
: Move Byte Mask To IntegerPMOVMSKB reg32,mm ; 0F D7 /r [KATMAI,MMX] PMOVMSKB reg32,xmm ; 66 0F D7 /r [WILLAMETTE,SSE2]
returns an 8-bit or 16-bit mask
formed of the most significant bits of each byte of source operand (8-bits
for an
register, 16-bits for an
register).
PMULHRWC
, PMULHRIW
: Multiply Packed 16-bit Integers With Rounding, and Store High WordPMULHRWC mm1,mm2/m64 ; 0F 59 /r [CYRIX,MMX] PMULHRIW mm1,mm2/m64 ; 0F 5D /r [CYRIX,MMX]
These instructions take two packed 16-bit integer inputs, multiply the values in the inputs, round on bit 15 of each result, then store bits 15-30 of each result to the corresponding position of the destination register.
PMULHRWC
, the destination is the first
source operand.
PMULHRIW
, the destination is an implied
register (worked out as described for PADDSIW
(section B.4.200)).
The operation of this instruction is:
dst[0-15] := (src1[0-15] *src2[0-15] + 0x00004000)[15-30] dst[16-31] := (src1[16-31]*src2[16-31] + 0x00004000)[15-30] dst[32-47] := (src1[32-47]*src2[32-47] + 0x00004000)[15-30] dst[48-63] := (src1[48-63]*src2[48-63] + 0x00004000)[15-30]
See also
(section B.4.239) for a 3DNow! version of
this instruction.
PMULHRWA
: Multiply Packed 16-bit Integers With Rounding, and Store High WordPMULHRWA mm1,mm2/m64 ; 0F 0F /r B7 [PENT,3DNOW]
takes two packed 16-bit integer
inputs, multiplies the values in the inputs, rounds on bit 16 of each
result, then stores bits 16-31 of each result to the corresponding position
of the destination register.
The operation of this instruction is:
dst[0-15] := (src1[0-15] *src2[0-15] + 0x00008000)[16-31]; dst[16-31] := (src1[16-31]*src2[16-31] + 0x00008000)[16-31]; dst[32-47] := (src1[32-47]*src2[32-47] + 0x00008000)[16-31]; dst[48-63] := (src1[48-63]*src2[48-63] + 0x00008000)[16-31].
See also
(section B.4.238) for a Cyrix version of
this instruction.
PMULHUW
: Multiply Packed 16-bit Integers, and Store High WordPMULHUW mm1,mm2/m64 ; 0F E4 /r [KATMAI,MMX] PMULHUW xmm1,xmm2/m128 ; 66 0F E4 /r [WILLAMETTE,SSE2]
takes two packed unsigned 16-bit
integer inputs, multiplies the values in the inputs, then stores bits 16-31
of each result to the corresponding position of the destination register.
PMULHW
, PMULLW
: Multiply Packed 16-bit Integers, and StorePMULHW mm1,mm2/m64 ; 0F E5 /r [PENT,MMX] PMULLW mm1,mm2/m64 ; 0F D5 /r [PENT,MMX]
PMULHW xmm1,xmm2/m128 ; 66 0F E5 /r [WILLAMETTE,SSE2] PMULLW xmm1,xmm2/m128 ; 66 0F D5 /r [WILLAMETTE,SSE2]
takes two packed unsigned 16-bit
integer inputs, and multiplies the values in the inputs, forming doubleword
results.
PMULHW
then stores the top 16 bits of each
doubleword in the destination (first) operand;
PMULLW
stores the bottom 16 bits of each
doubleword in the destination operand.
PMULUDQ
: Multiply Packed Unsigned 32-bit Integers, and Store.PMULUDQ mm1,mm2/m64 ; 0F F4 /r [WILLAMETTE,SSE2] PMULUDQ xmm1,xmm2/m128 ; 66 0F F4 /r [WILLAMETTE,SSE2]
takes two packed unsigned 32-bit
integer inputs, and multiplies the values in the inputs, forming quadword
results. The source is either an unsigned doubleword in the low doubleword
of a 64-bit operand, or it's two unsigned doublewords in the first and
third doublewords of a 128-bit operand. This produces either one or two
64-bit results, which are stored in the respective quadword locations of
the destination register.
The operation is:
dst[0-63] := dst[0-31] * src[0-31]; dst[64-127] := dst[64-95] * src[64-95].
PMVccZB
: MMX Packed Conditional MovePMVZB mmxreg,mem64 ; 0F 58 /r [CYRIX,MMX] PMVNZB mmxreg,mem64 ; 0F 5A /r [CYRIX,MMX] PMVLZB mmxreg,mem64 ; 0F 5B /r [CYRIX,MMX] PMVGEZB mmxreg,mem64 ; 0F 5C /r [CYRIX,MMX]
These instructions, specific to the Cyrix MMX extensions, perform
parallel conditional moves. The two input operands are treated as vectors
of eight bytes. Each byte of the destination (first) operand is either
written from the corresponding byte of the source (second) operand, or left
alone, depending on the value of the byte in the implied operand
(specified in the same way as
, in
section B.4.200).
PMVZB
performs each move if the corresponding
byte in the implied operand is zero;
PMVNZB
moves if the byte is non-zero;
PMVLZB
moves if the byte is less than zero;
PMVGEZB
moves if the byte is greater than or
equal to zero.
Note that these instructions cannot take a register as their second source operand.
POP
: Pop Data from StackPOP reg16 ; o16 58+r [8086] POP reg32 ; o32 58+r [386]
POP r/m16 ; o16 8F /0 [8086] POP r/m32 ; o32 8F /0 [386]
POP CS ; 0F [8086,UNDOC] POP DS ; 1F [8086] POP ES ; 07 [8086] POP SS ; 17 [8086] POP FS ; 0F A1 [386] POP GS ; 0F A9 [386]
loads a value from the stack (from
or
)
and then increments the stack pointer.
The address-size attribute of the instruction determines whether
or
is used as
the stack pointer: to deliberately override the default given by the
setting, you can use an
or
prefix.
The operand-size attribute of the instruction determines whether the
stack pointer is incremented by 2 or 4: this means that segment register
pops in
mode will pop 4 bytes off the
stack and discard the upper two of them. If you need to override that, you
can use an
or
prefix.
The above opcode listings give two forms for general-purpose register
pop instructions: for example,
has the two
forms
and
.
NASM will always generate the shorter form when given
. NDISASM will disassemble both.
is not a documented instruction, and is
not supported on any processor above the 8086 (since they use
as an opcode prefix for instruction set
extensions). However, at least some 8086 processors do support it, and so
NASM generates it for completeness.
POPAx
: Pop All General-Purpose RegistersPOPA ; 61 [186] POPAW ; o16 61 [186] POPAD ; o32 61 [386]
POPAW
pops a word from the stack into each
of, successively, DI
,
SI
, BP
, nothing (it
discards a word from the stack which was a placeholder for
SP
), BX
,
DX
, CX
and
AX
. It is intended to reverse the operation of
PUSHAW
(see section
B.4.264), but it ignores the value for SP
that was pushed on the stack by PUSHAW
.
POPAD
pops twice as much data, and places the
results in EDI
, ESI
,
EBP
, nothing (placeholder for
ESP
), EBX
,
EDX
, ECX
and
EAX
. It reverses the operation of
PUSHAD
.
is an alias mnemonic for either
or
,
depending on the current
setting.
Note that the registers are popped in reverse order of their numeric values in opcodes (see section B.2.1).
POPFx
: Pop Flags RegisterPOPF ; 9D [8086] POPFW ; o16 9D [8086] POPFD ; o32 9D [386]
POPFW
pops a word from the stack and stores
it in the bottom 16 bits of the flags register (or the whole flags
register, on processors below a 386).
POPFD
pops a doubleword and stores it in the
entire flags register.
is an alias mnemonic for either
or
,
depending on the current
setting.
See also
(section B.4.265).
POR
: MMX Bitwise ORPOR mm1,mm2/m64 ; 0F EB /r [PENT,MMX] POR xmm1,xmm2/m128 ; 66 0F EB /r [WILLAMETTE,SSE2]
performs a bitwise OR operation between
its two operands (i.e. each bit of the result is 1 if and only if at least
one of the corresponding bits of the two inputs was 1), and stores the
result in the destination (first) operand.
PREFETCH
: Prefetch Data Into CachesPREFETCH mem8 ; 0F 0D /0 [PENT,3DNOW] PREFETCHW mem8 ; 0F 0D /1 [PENT,3DNOW]
and
fetch the line of data from memory that
contains the specified byte.
performs
differently on the Athlon to earlier processors.
For more details, see the 3DNow! Technology Manual.
PREFETCHh
: Prefetch Data Into Caches PREFETCHNTA m8 ; 0F 18 /0 [KATMAI] PREFETCHT0 m8 ; 0F 18 /1 [KATMAI] PREFETCHT1 m8 ; 0F 18 /2 [KATMAI] PREFETCHT2 m8 ; 0F 18 /3 [KATMAI]
The
instructions fetch the line of
data from memory that contains the specified byte. It is placed in the
cache according to rules specified by locality hints
:
The hints are:
T0
(temporal data) - prefetch data into all
levels of the cache hierarchy.
T1
(temporal data with respect to first level
cache) - prefetch data into level 2 cache and higher.
T2
(temporal data with respect to second
level cache) - prefetch data into level 2 cache and higher.
NTA
(non-temporal data with respect to all
cache levels) - prefetch data into non-temporal cache structure and into a
location close to the processor, minimizing cache pollution.
Note that this group of instructions doesn't provide a guarantee that the data will be in the cache when it is needed. For more details, see the Intel IA32 Software Developer Manual, Volume 2.
PSADBW
: Packed Sum of Absolute DifferencesPSADBW mm1,mm2/m64 ; 0F F6 /r [KATMAI,MMX] PSADBW xmm1,xmm2/m128 ; 66 0F F6 /r [WILLAMETTE,SSE2]
The PSADBW instruction computes the
absolute value of the difference of the packed unsigned bytes in the two
source operands. These differences are then summed to produce a word result
in the lower 16-bit field of the destination register; the rest of the
register is cleared. The destination operand is an
or an
register.
The source operand can either be a register or a memory operand.
PSHUFD
: Shuffle Packed DoublewordsPSHUFD xmm1,xmm2/m128,imm8 ; 66 0F 70 /r ib [WILLAMETTE,SSE2]
shuffles the doublewords in the source
(second) operand according to the encoding specified by imm8, and stores
the result in the destination (first) operand.
Bits 0 and 1 of imm8 encode the source position of the doubleword to be copied to position 0 in the destination operand. Bits 2 and 3 encode for position 1, bits 4 and 5 encode for position 2, and bits 6 and 7 encode for position 3. For example, an encoding of 10 in bits 0 and 1 of imm8 indicates that the doubleword at bits 64-95 of the source operand will be copied to bits 0-31 of the destination.
PSHUFHW
: Shuffle Packed High WordsPSHUFHW xmm1,xmm2/m128,imm8 ; F3 0F 70 /r ib [WILLAMETTE,SSE2]
shuffles the words in the high quadword
of the source (second) operand according to the encoding specified by imm8,
and stores the result in the high quadword of the destination (first)
operand.
The operation of this instruction is similar to the
instruction, except that the source and
destination are the top quadword of a 128-bit operand, instead of being
64-bit operands. The low quadword is copied from the source to the
destination without any changes.
PSHUFLW
: Shuffle Packed Low WordsPSHUFLW xmm1,xmm2/m128,imm8 ; F2 0F 70 /r ib [WILLAMETTE,SSE2]
shuffles the words in the low quadword
of the source (second) operand according to the encoding specified by imm8,
and stores the result in the low quadword of the destination (first)
operand.
The operation of this instruction is similar to the
instruction, except that the source and
destination are the low quadword of a 128-bit operand, instead of being
64-bit operands. The high quadword is copied from the source to the
destination without any changes.
PSHUFW
: Shuffle Packed WordsPSHUFW mm1,mm2/m64,imm8 ; 0F 70 /r ib [KATMAI,MMX]
shuffles the words in the source
(second) operand according to the encoding specified by imm8, and stores
the result in the destination (first) operand.
Bits 0 and 1 of imm8 encode the source position of the word to be copied to position 0 in the destination operand. Bits 2 and 3 encode for position 1, bits 4 and 5 encode for position 2, and bits 6 and 7 encode for position 3. For example, an encoding of 10 in bits 0 and 1 of imm8 indicates that the word at bits 32-47 of the source operand will be copied to bits 0-15 of the destination.
PSLLx
: Packed Data Bit Shift Left LogicalPSLLW mm1,mm2/m64 ; 0F F1 /r [PENT,MMX] PSLLW mm,imm8 ; 0F 71 /6 ib [PENT,MMX]
PSLLW xmm1,xmm2/m128 ; 66 0F F1 /r [WILLAMETTE,SSE2] PSLLW xmm,imm8 ; 66 0F 71 /6 ib [WILLAMETTE,SSE2]
PSLLD mm1,mm2/m64 ; 0F F2 /r [PENT,MMX] PSLLD mm,imm8 ; 0F 72 /6 ib [PENT,MMX]
PSLLD xmm1,xmm2/m128 ; 66 0F F2 /r [WILLAMETTE,SSE2] PSLLD xmm,imm8 ; 66 0F 72 /6 ib [WILLAMETTE,SSE2]
PSLLQ mm1,mm2/m64 ; 0F F3 /r [PENT,MMX] PSLLQ mm,imm8 ; 0F 73 /6 ib [PENT,MMX]
PSLLQ xmm1,xmm2/m128 ; 66 0F F3 /r [WILLAMETTE,SSE2] PSLLQ xmm,imm8 ; 66 0F 73 /6 ib [WILLAMETTE,SSE2]
PSLLDQ xmm1,imm8 ; 66 0F 73 /7 ib [WILLAMETTE,SSE2]
performs logical left shifts of the data
elements in the destination (first) operand, moving each bit in the
separate elements left by the number of bits specified in the source
(second) operand, clearing the low-order bits as they are vacated.
shifts bytes, not bits.
PSLLW
shifts word sized elements.
PSLLD
shifts doubleword sized elements.
PSLLQ
shifts quadword sized elements.
PSLLDQ
shifts double quadword sized elements.
PSRAx
: Packed Data Bit Shift Right ArithmeticPSRAW mm1,mm2/m64 ; 0F E1 /r [PENT,MMX] PSRAW mm,imm8 ; 0F 71 /4 ib [PENT,MMX]
PSRAW xmm1,xmm2/m128 ; 66 0F E1 /r [WILLAMETTE,SSE2] PSRAW xmm,imm8 ; 66 0F 71 /4 ib [WILLAMETTE,SSE2]
PSRAD mm1,mm2/m64 ; 0F E2 /r [PENT,MMX] PSRAD mm,imm8 ; 0F 72 /4 ib [PENT,MMX]
PSRAD xmm1,xmm2/m128 ; 66 0F E2 /r [WILLAMETTE,SSE2] PSRAD xmm,imm8 ; 66 0F 72 /4 ib [WILLAMETTE,SSE2]
performs arithmetic right shifts of the
data elements in the destination (first) operand, moving each bit in the
separate elements right by the number of bits specified in the source
(second) operand, setting the high-order bits to the value of the original
sign bit.
PSRAW
shifts word sized elements.
PSRAD
shifts doubleword sized elements.
PSRLx
: Packed Data Bit Shift Right LogicalPSRLW mm1,mm2/m64 ; 0F D1 /r [PENT,MMX] PSRLW mm,imm8 ; 0F 71 /2 ib [PENT,MMX]
PSRLW xmm1,xmm2/m128 ; 66 0F D1 /r [WILLAMETTE,SSE2] PSRLW xmm,imm8 ; 66 0F 71 /2 ib [WILLAMETTE,SSE2]
PSRLD mm1,mm2/m64 ; 0F D2 /r [PENT,MMX] PSRLD mm,imm8 ; 0F 72 /2 ib [PENT,MMX]
PSRLD xmm1,xmm2/m128 ; 66 0F D2 /r [WILLAMETTE,SSE2] PSRLD xmm,imm8 ; 66 0F 72 /2 ib [WILLAMETTE,SSE2]
PSRLQ mm1,mm2/m64 ; 0F D3 /r [PENT,MMX] PSRLQ mm,imm8 ; 0F 73 /2 ib [PENT,MMX]
PSRLQ xmm1,xmm2/m128 ; 66 0F D3 /r [WILLAMETTE,SSE2] PSRLQ xmm,imm8 ; 66 0F 73 /2 ib [WILLAMETTE,SSE2]
PSRLDQ xmm1,imm8 ; 66 0F 73 /3 ib [WILLAMETTE,SSE2]
performs logical right shifts of the
data elements in the destination (first) operand, moving each bit in the
separate elements right by the number of bits specified in the source
(second) operand, clearing the high-order bits as they are vacated.
shifts bytes, not bits.
PSRLW
shifts word sized elements.
PSRLD
shifts doubleword sized elements.
PSRLQ
shifts quadword sized elements.
PSRLDQ
shifts double quadword sized elements.
PSUBx
: Subtract Packed IntegersPSUBB mm1,mm2/m64 ; 0F F8 /r [PENT,MMX] PSUBW mm1,mm2/m64 ; 0F F9 /r [PENT,MMX] PSUBD mm1,mm2/m64 ; 0F FA /r [PENT,MMX] PSUBQ mm1,mm2/m64 ; 0F FB /r [WILLAMETTE,SSE2]
PSUBB xmm1,xmm2/m128 ; 66 0F F8 /r [WILLAMETTE,SSE2] PSUBW xmm1,xmm2/m128 ; 66 0F F9 /r [WILLAMETTE,SSE2] PSUBD xmm1,xmm2/m128 ; 66 0F FA /r [WILLAMETTE,SSE2] PSUBQ xmm1,xmm2/m128 ; 66 0F FB /r [WILLAMETTE,SSE2]
subtracts packed integers in the source
operand from those in the destination operand. It doesn't differentiate
between signed and unsigned integers, and doesn't set any of the flags.
PSUBB
operates on byte sized elements.
PSUBW
operates on word sized elements.
PSUBD
operates on doubleword sized elements.
PSUBQ
operates on quadword sized elements.
PSUBSxx
, PSUBUSx
: Subtract Packed Integers With SaturationPSUBSB mm1,mm2/m64 ; 0F E8 /r [PENT,MMX] PSUBSW mm1,mm2/m64 ; 0F E9 /r [PENT,MMX]
PSUBSB xmm1,xmm2/m128 ; 66 0F E8 /r [WILLAMETTE,SSE2] PSUBSW xmm1,xmm2/m128 ; 66 0F E9 /r [WILLAMETTE,SSE2]
PSUBUSB mm1,mm2/m64 ; 0F D8 /r [PENT,MMX] PSUBUSW mm1,mm2/m64 ; 0F D9 /r [PENT,MMX]
PSUBUSB xmm1,xmm2/m128 ; 66 0F D8 /r [WILLAMETTE,SSE2] PSUBUSW xmm1,xmm2/m128 ; 66 0F D9 /r [WILLAMETTE,SSE2]
and
subtracts packed integers in the source operand from those in the
destination operand, and use saturation for results that are outside the
range supported by the destination operand.
PSUBSB
operates on signed bytes, and uses
signed saturation on the results.
PSUBSW
operates on signed words, and uses
signed saturation on the results.
PSUBUSB
operates on unsigned bytes, and uses
signed saturation on the results.
PSUBUSW
operates on unsigned words, and uses
signed saturation on the results.
PSUBSIW
: MMX Packed Subtract with Saturation to Implied DestinationPSUBSIW mm1,mm2/m64 ; 0F 55 /r [CYRIX,MMX]
, specific to the Cyrix extensions to
the MMX instruction set, performs the same function as
, except that the result is not placed in
the register specified by the first operand, but instead in the implied
destination register, specified as for
(section B.4.200).
PSWAPD
: Swap Packed Data PSWAPD mm1,mm2/m64 ; 0F 0F /r BB [PENT,3DNOW]
swaps the packed doublewords in the
source operand, and stores the result in the destination operand.
In the
and
processors, this opcode uses the mnemonic
, and it swaps the order of words when
copying from the source to the destination.
The operation in the
and
processors is
dst[0-15] = src[48-63]; dst[16-31] = src[32-47]; dst[32-47] = src[16-31]; dst[48-63] = src[0-15].
The operation in the
,
and later processors is:
dst[0-31] = src[32-63]; dst[32-63] = src[0-31].
PUNPCKxxx
: Unpack and Interleave DataPUNPCKHBW mm1,mm2/m64 ; 0F 68 /r [PENT,MMX] PUNPCKHWD mm1,mm2/m64 ; 0F 69 /r [PENT,MMX] PUNPCKHDQ mm1,mm2/m64 ; 0F 6A /r [PENT,MMX]
PUNPCKHBW xmm1,xmm2/m128 ; 66 0F 68 /r [WILLAMETTE,SSE2] PUNPCKHWD xmm1,xmm2/m128 ; 66 0F 69 /r [WILLAMETTE,SSE2] PUNPCKHDQ xmm1,xmm2/m128 ; 66 0F 6A /r [WILLAMETTE,SSE2] PUNPCKHQDQ xmm1,xmm2/m128 ; 66 0F 6D /r [WILLAMETTE,SSE2]
PUNPCKLBW mm1,mm2/m32 ; 0F 60 /r [PENT,MMX] PUNPCKLWD mm1,mm2/m32 ; 0F 61 /r [PENT,MMX] PUNPCKLDQ mm1,mm2/m32 ; 0F 62 /r [PENT,MMX]
PUNPCKLBW xmm1,xmm2/m128 ; 66 0F 60 /r [WILLAMETTE,SSE2] PUNPCKLWD xmm1,xmm2/m128 ; 66 0F 61 /r [WILLAMETTE,SSE2] PUNPCKLDQ xmm1,xmm2/m128 ; 66 0F 62 /r [WILLAMETTE,SSE2] PUNPCKLQDQ xmm1,xmm2/m128 ; 66 0F 6C /r [WILLAMETTE,SSE2]
all treat their operands as vectors,
and produce a new vector generated by interleaving elements from the two
inputs. The
instructions start by
throwing away the bottom half of each input operand, and the
instructions throw away the top half.
The remaining elements, are then interleaved into the destination, alternating elements from the second (source) operand and the first (destination) operand: so the leftmost part of each element in the result always comes from the second operand, and the rightmost from the destination.
PUNPCKxBW
works a byte at a time, producing
word sized output elements.
PUNPCKxWD
works a word at a time, producing
doubleword sized output elements.
PUNPCKxDQ
works a doubleword at a time,
producing quadword sized output elements.
PUNPCKxQDQ
works a quadword at a time,
producing double quadword sized output elements.
So, for example, for
operands, if the
first operand held
and the
second held
, then:
PUNPCKHBW
would return
0x7B7A6B6A5B5A4B4A
.
PUNPCKHWD
would return
0x7B6B7A6A5B4B5A4A
.
PUNPCKHDQ
would return
0x7B6B5B4B7A6A5A4A
.
PUNPCKLBW
would return
0x3B3A2B2A1B1A0B0A
.
PUNPCKLWD
would return
0x3B2B3A2A1B0B1A0A
.
PUNPCKLDQ
would return
0x3B2B1B0B3A2A1A0A
.
PUSH
: Push Data on StackPUSH reg16 ; o16 50+r [8086] PUSH reg32 ; o32 50+r [386]
PUSH r/m16 ; o16 FF /6 [8086] PUSH r/m32 ; o32 FF /6 [386]
PUSH CS ; 0E [8086] PUSH DS ; 1E [8086] PUSH ES ; 06 [8086] PUSH SS ; 16 [8086] PUSH FS ; 0F A0 [386] PUSH GS ; 0F A8 [386]
PUSH imm8 ; 6A ib [186] PUSH imm16 ; o16 68 iw [186] PUSH imm32 ; o32 68 id [386]
decrements the stack pointer
(
or
) by 2 or 4,
and then stores the given value at
or
.
The address-size attribute of the instruction determines whether
or
is used as
the stack pointer: to deliberately override the default given by the
setting, you can use an
or
prefix.
The operand-size attribute of the instruction determines whether the
stack pointer is decremented by 2 or 4: this means that segment register
pushes in
mode will push 4 bytes on the
stack, of which the upper two are undefined. If you need to override that,
you can use an
or
prefix.
The above opcode listings give two forms for general-purpose register
push instructions: for example,
has the
two forms
and
.
NASM will always generate the shorter form when given
. NDISASM will disassemble both.
Unlike the undocumented and barely supported
,
is a
perfectly valid and sensible instruction, supported on all processors.
The instruction
may be used to
distinguish an 8086 from later processors: on an 8086, the value of
stored is the value it has after the
push instruction, whereas on later processors it is the value
before the push instruction.
PUSHAx
: Push All General-Purpose RegistersPUSHA ; 60 [186] PUSHAD ; o32 60 [386] PUSHAW ; o16 60 [186]
pushes, in succession,
,
,
,
,
,
,
and
on the stack,
decrementing the stack pointer by a total of 16.
pushes, in succession,
,
,
,
,
,
,
and
on the
stack, decrementing the stack pointer by a total of 32.
In both cases, the value of
or
pushed is its original value, as it
had before the instruction was executed.
is an alias mnemonic for either
or
,
depending on the current
setting.
Note that the registers are pushed in order of their numeric values in opcodes (see section B.2.1).
See also
(section B.4.245).
PUSHFx
: Push Flags RegisterPUSHF ; 9C [8086] PUSHFD ; o32 9C [386] PUSHFW ; o16 9C [8086]
PUSHFW
pops a word from the stack and stores
it in the bottom 16 bits of the flags register (or the whole flags
register, on processors below a 386).
PUSHFD
pops a doubleword and stores it in the
entire flags register.
is an alias mnemonic for either
or
,
depending on the current
setting.
See also
(section B.4.246).
PXOR
: MMX Bitwise XORPXOR mm1,mm2/m64 ; 0F EF /r [PENT,MMX] PXOR xmm1,xmm2/m128 ; 66 0F EF /r [WILLAMETTE,SSE2]
performs a bitwise XOR operation between
its two operands (i.e. each bit of the result is 1 if and only if exactly
one of the corresponding bits of the two inputs was 1), and stores the
result in the destination (first) operand.
RCL
, RCR
: Bitwise Rotate through Carry BitRCL r/m8,1 ; D0 /2 [8086] RCL r/m8,CL ; D2 /2 [8086] RCL r/m8,imm8 ; C0 /2 ib [186] RCL r/m16,1 ; o16 D1 /2 [8086] RCL r/m16,CL ; o16 D3 /2 [8086] RCL r/m16,imm8 ; o16 C1 /2 ib [186] RCL r/m32,1 ; o32 D1 /2 [386] RCL r/m32,CL ; o32 D3 /2 [386] RCL r/m32,imm8 ; o32 C1 /2 ib [386]
RCR r/m8,1 ; D0 /3 [8086] RCR r/m8,CL ; D2 /3 [8086] RCR r/m8,imm8 ; C0 /3 ib [186] RCR r/m16,1 ; o16 D1 /3 [8086] RCR r/m16,CL ; o16 D3 /3 [8086] RCR r/m16,imm8 ; o16 C1 /3 ib [186] RCR r/m32,1 ; o32 D1 /3 [386] RCR r/m32,CL ; o32 D3 /3 [386] RCR r/m32,imm8 ; o32 C1 /3 ib [386]
and
perform
a 9-bit, 17-bit or 33-bit bitwise rotation operation, involving the given
source/destination (first) operand and the carry bit. Thus, for example, in
the operation
, a 9-bit rotation is
performed in which
is shifted left by 1, the
top bit of
moves into the carry flag, and the
original value of the carry flag is placed in the low bit of
.
The number of bits to rotate by is given by the second operand. Only the bottom five bits of the rotation count are considered by processors above the 8086.
You can force the longer (286 and upwards, beginning with a
byte) form of
by using a
prefix:
. Similarly with
.
RCPPS
: Packed Single-Precision FP ReciprocalRCPPS xmm1,xmm2/m128 ; 0F 53 /r [KATMAI,SSE]
returns an approximation of the
reciprocal of the packed single-precision FP values from xmm2/m128. The
maximum error for this approximation is: |Error| <= 1.5 x 2^-12
RCPSS
: Scalar Single-Precision FP ReciprocalRCPSS xmm1,xmm2/m128 ; F3 0F 53 /r [KATMAI,SSE]
returns an approximation of the
reciprocal of the lower single-precision FP value from xmm2/m32; the upper
three fields are passed through from xmm1. The maximum error for this
approximation is: |Error| <= 1.5 x 2^-12
RDMSR
: Read Model-Specific RegistersRDMSR ; 0F 32 [PENT,PRIV]
reads the processor Model-Specific
Register (MSR) whose index is stored in
, and
stores the result in
. See also
(section
B.4.329).
RDPMC
: Read Performance-Monitoring CountersRDPMC ; 0F 33 [P6]
reads the processor
performance-monitoring counter whose index is stored in
, and stores the result in
.
This instruction is available on P6 and later processors and on MMX class processors.
RDSHR
: Read SMM Header Pointer RegisterRDSHR r/m32 ; 0F 36 /0 [386,CYRIX,SMM]
reads the contents of the SMM header
pointer register and saves it to the destination operand, which can be
either a 32 bit memory location or a 32 bit register.
See also
(section B.4.330).
RDTSC
: Read Time-Stamp CounterRDTSC ; 0F 31 [PENT]
reads the processor's time-stamp counter
into
.
RET
, RETF
, RETN
: Return from Procedure CallRET ; C3 [8086] RET imm16 ; C2 iw [8086]
RETF ; CB [8086] RETF imm16 ; CA iw [8086]
RETN ; C3 [8086] RETN imm16 ; C2 iw [8086]
RET
, and its exact synonym
RETN
, pop IP
or
EIP
from the stack and transfer control to the
new address. Optionally, if a numeric second operand is provided, they
increment the stack pointer by a further imm16
bytes after popping the return address.
RETF
executes a far return: after popping
IP
/EIP
, it then pops
CS
, and then increments the stack
pointer by the optional argument if present.
ROL
, ROR
: Bitwise RotateROL r/m8,1 ; D0 /0 [8086] ROL r/m8,CL ; D2 /0 [8086] ROL r/m8,imm8 ; C0 /0 ib [186] ROL r/m16,1 ; o16 D1 /0 [8086] ROL r/m16,CL ; o16 D3 /0 [8086] ROL r/m16,imm8 ; o16 C1 /0 ib [186] ROL r/m32,1 ; o32 D1 /0 [386] ROL r/m32,CL ; o32 D3 /0 [386] ROL r/m32,imm8 ; o32 C1 /0 ib [386]
ROR r/m8,1 ; D0 /1 [8086] ROR r/m8,CL ; D2 /1 [8086] ROR r/m8,imm8 ; C0 /1 ib [186] ROR r/m16,1 ; o16 D1 /1 [8086] ROR r/m16,CL ; o16 D3 /1 [8086] ROR r/m16,imm8 ; o16 C1 /1 ib [186] ROR r/m32,1 ; o32 D1 /1 [386] ROR r/m32,CL ; o32 D3 /1 [386] ROR r/m32,imm8 ; o32 C1 /1 ib [386]
and
perform
a bitwise rotation operation on the given source/destination (first)
operand. Thus, for example, in the operation
, an 8-bit rotation is performed in which
is shifted left by 1 and the original top bit
of
moves round into the low bit.
The number of bits to rotate by is given by the second operand. Only the bottom five bits of the rotation count are considered by processors above the 8086.
You can force the longer (286 and upwards, beginning with a
byte) form of
by using a
prefix:
. Similarly with
.
RSDC
: Restore Segment Register and DescriptorRSDC segreg,m80 ; 0F 79 /r [486,CYRIX,SMM]
restores a segment register (DS, ES, FS,
GS, or SS) from mem80, and sets up its descriptor.
RSLDT
: Restore Segment Register and DescriptorRSLDT m80 ; 0F 7B /0 [486,CYRIX,SMM]
restores the Local Descriptor Table
(LDTR) from mem80.
RSM
: Resume from System-Management ModeRSM ; 0F AA [PENT]
returns the processor to its normal
operating mode when it was in System-Management Mode.
RSQRTPS
: Packed Single-Precision FP Square Root ReciprocalRSQRTPS xmm1,xmm2/m128 ; 0F 52 /r [KATMAI,SSE]
computes the approximate reciprocals
of the square roots of the packed single-precision floating-point values in
the source and stores the results in xmm1. The maximum error for this
approximation is: |Error| <= 1.5 x 2^-12
RSQRTSS
: Scalar Single-Precision FP Square Root ReciprocalRSQRTSS xmm1,xmm2/m128 ; F3 0F 52 /r [KATMAI,SSE]
returns an approximation of the
reciprocal of the square root of the lowest order single-precision FP value
from the source, and stores it in the low doubleword of the destination
register. The upper three fields of xmm1 are preserved. The maximum error
for this approximation is: |Error| <= 1.5 x 2^-12
RSTS
: Restore TSR and DescriptorRSTS m80 ; 0F 7D /0 [486,CYRIX,SMM]
restores Task State Register (TSR) from
mem80.
SAHF
: Store AH to FlagsSAHF ; 9E [8086]
sets the low byte of the flags word
according to the contents of the
register.
The operation of
is:
AH --> SF:ZF:0:AF:0:PF:1:CF
See also
(section B.4.131).
SAL
, SAR
: Bitwise Arithmetic ShiftsSAL r/m8,1 ; D0 /4 [8086] SAL r/m8,CL ; D2 /4 [8086] SAL r/m8,imm8 ; C0 /4 ib [186] SAL r/m16,1 ; o16 D1 /4 [8086] SAL r/m16,CL ; o16 D3 /4 [8086] SAL r/m16,imm8 ; o16 C1 /4 ib [186] SAL r/m32,1 ; o32 D1 /4 [386] SAL r/m32,CL ; o32 D3 /4 [386] SAL r/m32,imm8 ; o32 C1 /4 ib [386]
SAR r/m8,1 ; D0 /7 [8086] SAR r/m8,CL ; D2 /7 [8086] SAR r/m8,imm8 ; C0 /7 ib [186] SAR r/m16,1 ; o16 D1 /7 [8086] SAR r/m16,CL ; o16 D3 /7 [8086] SAR r/m16,imm8 ; o16 C1 /7 ib [186] SAR r/m32,1 ; o32 D1 /7 [386] SAR r/m32,CL ; o32 D3 /7 [386] SAR r/m32,imm8 ; o32 C1 /7 ib [386]
and
perform
an arithmetic shift operation on the given source/destination (first)
operand. The vacated bits are filled with zero for
, and with copies of the original high bit of
the source operand for
.
is a synonym for
(see section
B.4.290). NASM will assemble either one to the same code, but NDISASM
will always disassemble that code as
.
The number of bits to shift by is given by the second operand. Only the bottom five bits of the shift count are considered by processors above the 8086.
You can force the longer (286 and upwards, beginning with a
byte) form of
by using a
prefix:
. Similarly with
.
SALC
: Set AL from Carry FlagSALC ; D6 [8086,UNDOC]
is an early undocumented instruction
similar in concept to
(section B.4.287). Its function is to set
to zero if the carry flag is clear, or to
if it is set.
SBB
: Subtract with BorrowSBB r/m8,reg8 ; 18 /r [8086] SBB r/m16,reg16 ; o16 19 /r [8086] SBB r/m32,reg32 ; o32 19 /r [386]
SBB reg8,r/m8 ; 1A /r [8086] SBB reg16,r/m16 ; o16 1B /r [8086] SBB reg32,r/m32 ; o32 1B /r [386]
SBB r/m8,imm8 ; 80 /3 ib [8086] SBB r/m16,imm16 ; o16 81 /3 iw [8086] SBB r/m32,imm32 ; o32 81 /3 id [386]
SBB r/m16,imm8 ; o16 83 /3 ib [8086] SBB r/m32,imm8 ; o32 83 /3 ib [386]
SBB AL,imm8 ; 1C ib [8086] SBB AX,imm16 ; o16 1D iw [8086] SBB EAX,imm32 ; o32 1D id [386]
performs integer subtraction: it subtracts
its second operand, plus the value of the carry flag, from its first, and
leaves the result in its destination (first) operand. The flags are set
according to the result of the operation: in particular, the carry flag is
affected and can be used by a subsequent
instruction.
In the forms with an 8-bit immediate second operand and a longer first
operand, the second operand is considered to be signed, and is
sign-extended to the length of the first operand. In these cases, the
qualifier is necessary to force NASM to
generate this form of the instruction.
To subtract one number from another without also subtracting the
contents of the carry flag, use
(section B.4.305).
SCASB
, SCASW
, SCASD
: Scan StringSCASB ; AE [8086] SCASW ; o16 AF [8086] SCASD ; o32 AF [386]
compares the byte in
with the byte at
or
,
and sets the flags accordingly. It then increments or decrements (depending
on the direction flag: increments if the flag is clear, decrements if it is
set)
(or
).
The register used is
if the address size is
16 bits, and
if it is 32 bits. If you need to
use an address size not equal to the current
setting, you can use an explicit
or
prefix.
Segment override prefixes have no effect for this instruction: the use
of
for the load from
or
cannot be
overridden.
and
work
in the same way, but they compare a word to
or
a doubleword to
instead of a byte to
, and increment or decrement the addressing
registers by 2 or 4 instead of 1.
The
and
prefixes (equivalently,
and
) may be used to repeat the instruction up
to
(or
- again,
the address size chooses which) times until the first unequal or equal byte
is found.
SETcc
: Set Register from ConditionSETcc r/m8 ; 0F 90+cc /2 [386]
sets the given 8-bit operand to zero if
its condition is not satisfied, and to 1 if it is.
SFENCE
: Store FenceSFENCE ; 0F AE /7 [KATMAI]
performs a serialising operation on all
writes to memory that were issued before the
instruction. This guarantees that all
memory writes before the
instruction are
visible before any writes after the
instruction.
is ordered respective to other
instruction,
, any memory write and any other
serialising instruction (such as
).
Weakly ordered memory types can be used to achieve higher processor
performance through such techniques as out-of-order issue, write-combining,
and write-collapsing. The degree to which a consumer of data recognizes or
knows that the data is weakly ordered varies among applications and may be
unknown to the producer of this data. The
instruction provides a performance-efficient way of insuring store ordering
between routines that produce weakly-ordered results and routines that
consume this data.
uses the following ModRM encoding:
Mod (7:6) = 11B Reg/Opcode (5:3) = 111B R/M (2:0) = 000B
All other ModRM encodings are defined to be reserved, and use of these encodings risks incompatibility with future processors.
See also
(section B.4.137) and
(section
B.4.151).
SGDT
, SIDT
, SLDT
: Store Descriptor Table PointersSGDT mem ; 0F 01 /0 [286,PRIV] SIDT mem ; 0F 01 /1 [286,PRIV] SLDT r/m16 ; 0F 00 /0 [286,PRIV]
and
both
take a 6-byte memory area as an operand: they store the contents of the
GDTR (global descriptor table register) or IDTR (interrupt descriptor table
register) into that area as a 32-bit linear address and a 16-bit size limit
from that area (in that order). These are the only instructions which
directly use linear addresses, rather than segment/offset pairs.
stores the segment selector corresponding
to the LDT (local descriptor table) into the given operand.
See also
,
and
(section
B.4.138).
SHL
, SHR
: Bitwise Logical ShiftsSHL r/m8,1 ; D0 /4 [8086] SHL r/m8,CL ; D2 /4 [8086] SHL r/m8,imm8 ; C0 /4 ib [186] SHL r/m16,1 ; o16 D1 /4 [8086] SHL r/m16,CL ; o16 D3 /4 [8086] SHL r/m16,imm8 ; o16 C1 /4 ib [186] SHL r/m32,1 ; o32 D1 /4 [386] SHL r/m32,CL ; o32 D3 /4 [386] SHL r/m32,imm8 ; o32 C1 /4 ib [386]
SHR r/m8,1 ; D0 /5 [8086] SHR r/m8,CL ; D2 /5 [8086] SHR r/m8,imm8 ; C0 /5 ib [186] SHR r/m16,1 ; o16 D1 /5 [8086] SHR r/m16,CL ; o16 D3 /5 [8086] SHR r/m16,imm8 ; o16 C1 /5 ib [186] SHR r/m32,1 ; o32 D1 /5 [386] SHR r/m32,CL ; o32 D3 /5 [386] SHR r/m32,imm8 ; o32 C1 /5 ib [386]
and
perform
a logical shift operation on the given source/destination (first) operand.
The vacated bits are filled with zero.
A synonym for
is
(see section
B.4.283). NASM will assemble either one to the same code, but NDISASM
will always disassemble that code as
.
The number of bits to shift by is given by the second operand. Only the bottom five bits of the shift count are considered by processors above the 8086.
You can force the longer (286 and upwards, beginning with a
byte) form of
by using a
prefix:
. Similarly with
.
SHLD
, SHRD
: Bitwise Double-Precision ShiftsSHLD r/m16,reg16,imm8 ; o16 0F A4 /r ib [386] SHLD r/m16,reg32,imm8 ; o32 0F A4 /r ib [386] SHLD r/m16,reg16,CL ; o16 0F A5 /r [386] SHLD r/m16,reg32,CL ; o32 0F A5 /r [386]
SHRD r/m16,reg16,imm8 ; o16 0F AC /r ib [386] SHRD r/m32,reg32,imm8 ; o32 0F AC /r ib [386] SHRD r/m16,reg16,CL ; o16 0F AD /r [386] SHRD r/m32,reg32,CL ; o32 0F AD /r [386]
SHLD
performs a double-precision left shift.
It notionally places its second operand to the right of its first, then
shifts the entire bit string thus generated to the left by a number of bits
specified in the third operand. It then updates only the first
operand according to the result of this. The second operand is not
modified.
SHRD
performs the corresponding right shift:
it notionally places the second operand to the left of the first,
shifts the whole bit string right, and updates only the first operand.
For example, if
holds
and
holds
, then the instruction
would update
to hold
.
Under the same conditions,
would
update
to hold
.
The number of bits to shift by is given by the third operand. Only the bottom five bits of the shift count are considered.
SHUFPD
: Shuffle Packed Double-Precision FP ValuesSHUFPD xmm1,xmm2/m128,imm8 ; 66 0F C6 /r ib [WILLAMETTE,SSE2]
moves one of the packed
double-precision FP values from the destination operand into the low
quadword of the destination operand; the upper quadword is generated by
moving one of the double-precision FP values from the source operand into
the destination. The select (third) operand selects which of the values are
moved to the destination register.
The select operand is an 8-bit immediate: bit 0 selects which value is moved from the destination operand to the result (where 0 selects the low quadword and 1 selects the high quadword) and bit 1 selects which value is moved from the source operand to the result. Bits 2 through 7 of the shuffle operand are reserved.
SHUFPS
: Shuffle Packed Single-Precision FP ValuesSHUFPS xmm1,xmm2/m128,imm8 ; 0F C6 /r ib [KATMAI,SSE]
moves two of the packed
single-precision FP values from the destination operand into the low
quadword of the destination operand; the upper quadword is generated by
moving two of the single-precision FP values from the source operand into
the destination. The select (third) operand selects which of the values are
moved to the destination register.
The select operand is an 8-bit immediate: bits 0 and 1 select the value to be moved from the destination operand the low doubleword of the result, bits 2 and 3 select the value to be moved from the destination operand the second doubleword of the result, bits 4 and 5 select the value to be moved from the source operand the third doubleword of the result, and bits 6 and 7 select the value to be moved from the source operand to the high doubleword of the result.
SMI
: System Management InterruptSMI ; F1 [386,UNDOC]
puts some AMD processors into SMM mode. It
is available on some 386 and 486 processors, and is only available when DR7
bit 12 is set, otherwise it generates an Int 1.
SMINT
, SMINTOLD
: Software SMM Entry (CYRIX)SMINT ; 0F 38 [PENT,CYRIX] SMINTOLD ; 0F 7E [486,CYRIX]
puts the processor into SMM mode. The
CPU state information is saved in the SMM memory header, and then execution
begins at the SMM base address.
is the same as
, but was the opcode used on the 486.
This pair of opcodes are specific to the Cyrix and compatible range of processors (Cyrix, IBM, Via).
SMSW
: Store Machine Status WordSMSW r/m16 ; 0F 01 /4 [286,PRIV]
stores the bottom half of the
control register (or the Machine Status Word,
on 286 processors) into the destination operand. See also
(section
B.4.139).
For 32-bit code, this would use the low 16-bits of the specified register (or a 16bit memory location), without needing an operand size override byte.
SQRTPD
: Packed Double-Precision FP Square RootSQRTPD xmm1,xmm2/m128 ; 66 0F 51 /r [WILLAMETTE,SSE2]
calculates the square root of the
packed double-precision FP value from the source operand, and stores the
double-precision results in the destination register.
SQRTPS
: Packed Single-Precision FP Square RootSQRTPS xmm1,xmm2/m128 ; 0F 51 /r [KATMAI,SSE]
calculates the square root of the
packed single-precision FP value from the source operand, and stores the
single-precision results in the destination register.
SQRTSD
: Scalar Double-Precision FP Square RootSQRTSD xmm1,xmm2/m128 ; F2 0F 51 /r [WILLAMETTE,SSE2]
calculates the square root of the
low-order double-precision FP value from the source operand, and stores the
double-precision result in the destination register. The high-quadword
remains unchanged.
SQRTSS
: Scalar Single-Precision FP Square RootSQRTSS xmm1,xmm2/m128 ; F3 0F 51 /r [KATMAI,SSE]
calculates the square root of the
low-order single-precision FP value from the source operand, and stores the
single-precision result in the destination register. The three high
doublewords remain unchanged.
STC
, STD
, STI
: Set FlagsSTC ; F9 [8086] STD ; FD [8086] STI ; FB [8086]
These instructions set various flags.
sets
the carry flag;
sets the direction flag; and
sets the interrupt flag (thus enabling
interrupts).
To clear the carry, direction, or interrupt flags, use the
,
and
instructions
(section B.4.20). To invert the carry flag,
use
(section
B.4.22).
STMXCSR
: Store Streaming SIMD Extension Control/StatusSTMXCSR m32 ; 0F AE /3 [KATMAI,SSE]
stores the contents of the
control/status register to the specified
memory location.
is used to enable
masked/unmasked exception handling, to set rounding modes, to set
flush-to-zero mode, and to view exception status flags. The reserved bits
in the
register are stored as 0s.
For details of the
register, see the
Intel processor docs.
See also
(section B.4.133).
STOSB
, STOSW
, STOSD
: Store Byte to StringSTOSB ; AA [8086] STOSW ; o16 AB [8086] STOSD ; o32 AB [386]
stores the byte in
at
or
, and sets the flags accordingly. It then
increments or decrements (depending on the direction flag: increments if
the flag is clear, decrements if it is set)
(or
).
The register used is
if the address size is
16 bits, and
if it is 32 bits. If you need to
use an address size not equal to the current
setting, you can use an explicit
or
prefix.
Segment override prefixes have no effect for this instruction: the use
of
for the store to
or
cannot be
overridden.
and
work
in the same way, but they store the word in
or
the doubleword in
instead of the byte in
, and increment or decrement the addressing
registers by 2 or 4 instead of 1.
The
prefix may be used to repeat the
instruction
(or
- again, the address size chooses which) times.
STR
: Store Task RegisterSTR r/m16 ; 0F 00 /1 [286,PRIV]
stores the segment selector corresponding
to the contents of the Task Register into its operand. When the operand
size is a 16-bit register, the upper 16-bits are cleared to 0s. When the
destination operand is a memory location, 16 bits are written regardless of
the operand size.
SUB
: Subtract IntegersSUB r/m8,reg8 ; 28 /r [8086] SUB r/m16,reg16 ; o16 29 /r [8086] SUB r/m32,reg32 ; o32 29 /r [386]
SUB reg8,r/m8 ; 2A /r [8086] SUB reg16,r/m16 ; o16 2B /r [8086] SUB reg32,r/m32 ; o32 2B /r [386]
SUB r/m8,imm8 ; 80 /5 ib [8086] SUB r/m16,imm16 ; o16 81 /5 iw [8086] SUB r/m32,imm32 ; o32 81 /5 id [386]
SUB r/m16,imm8 ; o16 83 /5 ib [8086] SUB r/m32,imm8 ; o32 83 /5 ib [386]
SUB AL,imm8 ; 2C ib [8086] SUB AX,imm16 ; o16 2D iw [8086] SUB EAX,imm32 ; o32 2D id [386]
performs integer subtraction: it subtracts
its second operand from its first, and leaves the result in its destination
(first) operand. The flags are set according to the result of the
operation: in particular, the carry flag is affected and can be used by a
subsequent
instruction
(section B.4.285).
In the forms with an 8-bit immediate second operand and a longer first
operand, the second operand is considered to be signed, and is
sign-extended to the length of the first operand. In these cases, the
qualifier is necessary to force NASM to
generate this form of the instruction.
SUBPD
: Packed Double-Precision FP SubtractSUBPD xmm1,xmm2/m128 ; 66 0F 5C /r [WILLAMETTE,SSE2]
subtracts the packed double-precision FP
values of the source operand from those of the destination operand, and
stores the result in the destination operation.
SUBPS
: Packed Single-Precision FP SubtractSUBPS xmm1,xmm2/m128 ; 0F 5C /r [KATMAI,SSE]
subtracts the packed single-precision FP
values of the source operand from those of the destination operand, and
stores the result in the destination operation.
SUBSD
: Scalar Single-FP SubtractSUBSD xmm1,xmm2/m128 ; F2 0F 5C /r [WILLAMETTE,SSE2]
subtracts the low-order double-precision
FP value of the source operand from that of the destination operand, and
stores the result in the destination operation. The high quadword is
unchanged.
SUBSS
: Scalar Single-FP SubtractSUBSS xmm1,xmm2/m128 ; F3 0F 5C /r [KATMAI,SSE]
subtracts the low-order single-precision
FP value of the source operand from that of the destination operand, and
stores the result in the destination operation. The three high doublewords
are unchanged.
SVDC
: Save Segment Register and DescriptorSVDC m80,segreg ; 0F 78 /r [486,CYRIX,SMM]
saves a segment register (DS, ES, FS, GS,
or SS) and its descriptor to mem80.
SVLDT
: Save LDTR and DescriptorSVLDT m80 ; 0F 7A /0 [486,CYRIX,SMM]
saves the Local Descriptor Table (LDTR)
to mem80.
SVTS
: Save TSR and DescriptorSVTS m80 ; 0F 7C /0 [486,CYRIX,SMM]
saves the Task State Register (TSR) to
mem80.
SYSCALL
: Call Operating SystemSYSCALL ; 0F 05 [P6,AMD]
provides a fast method of transferring
control to a fixed entry point in an operating system.
EIP
register is copied into the
ECX
register.
STAR
) are copied into the
EIP
register.
STAR
register specify the
selector that is copied into the CS
register.
STAR
register
specify the selector that is copied into the SS register.
The
and
registers should not be modified by the operating system between the
execution of the
instruction and its
corresponding
instruction.
For more information, see the
(AMD
document number 21086.pdf).
SYSENTER
: Fast System CallSYSENTER ; 0F 34 [P6]
executes a fast call to a level 0
system procedure or routine. Before using this instruction, various MSRs
need to be set up:
SYSENTER_CS_MSR
contains the 32-bit segment
selector for the privilege level 0 code segment. (This value is also used
to compute the segment selector of the privilege level 0 stack segment.)
SYSENTER_EIP_MSR
contains the 32-bit offset
into the privilege level 0 code segment to the first instruction of the
selected operating procedure or routine.
SYSENTER_ESP_MSR
contains the 32-bit stack
pointer for the privilege level 0 stack.
performs the following sequence of
operations:
SYSENTER_CS_MSR
into the
CS
register.
SYSENTER_EIP_MSR
into the
EIP
register.
SYSENTER_CS_MSR
and
loads it into the SS
register.
SYSENTER_ESP_MSR
into the
ESP
register.
VM
flag in the
EFLAGS
register, if the flag is set.
In particular, note that this instruction des not save the values of
or
. If you
need to return to the calling code, you need to write your code to cater
for this.
For more information, see the Intel Architecture Software Developer's Manual, Volume 2.
SYSEXIT
: Fast Return From System CallSYSEXIT ; 0F 35 [P6,PRIV]
executes a fast return to privilege
level 3 user code. This instruction is a companion instruction to the
instruction, and can only be executed by
privilege level 0 code. Various registers need to be set up before calling
this instruction:
SYSENTER_CS_MSR
contains the 32-bit segment
selector for the privilege level 0 code segment in which the processor is
currently executing. (This value is used to compute the segment selectors
for the privilege level 3 code and stack segments.)
EDX
contains the 32-bit offset into the
privilege level 3 code segment to the first instruction to be executed in
the user code.
ECX
contains the 32-bit stack pointer for the
privilege level 3 stack.
performs the following sequence of
operations:
SYSENTER_CS_MSR
and
loads the sum into the CS
selector register.
EDX
register into the EIP
register.
SYSENTER_CS_MSR
and
loads the sum into the SS
selector register.
ECX
register
into the ESP
register.
EIP
address.
For more information on the use of the
and
instructions, see the Intel Architecture Software Developer's Manual,
Volume 2.
SYSRET
: Return From Operating SystemSYSRET ; 0F 07 [P6,AMD,PRIV]
is the return instruction used in
conjunction with the
instruction to
provide fast entry/exit to an operating system.
ECX
register, which points to the next
sequential instruction after the corresponding
SYSCALL
instruction, is copied into the
EIP
register.
STAR
register specify the
selector that is copied into the CS
register.
STAR
register
specify the selector that is copied into the SS
register.
SS
register are set to 11b
(RPL of 3) regardless of the value of bits [49-48] of the
STAR
register.
The
and
registers should not be modified by the operating system between the
execution of the
instruction and its
corresponding
instruction.
For more information, see the
(AMD
document number 21086.pdf).
TEST
: Test Bits (notional bitwise AND)TEST r/m8,reg8 ; 84 /r [8086] TEST r/m16,reg16 ; o16 85 /r [8086] TEST r/m32,reg32 ; o32 85 /r [386]
TEST r/m8,imm8 ; F6 /0 ib [8086] TEST r/m16,imm16 ; o16 F7 /0 iw [8086] TEST r/m32,imm32 ; o32 F7 /0 id [386]
TEST AL,imm8 ; A8 ib [8086] TEST AX,imm16 ; o16 A9 iw [8086] TEST EAX,imm32 ; o32 A9 id [386]
performs a `mental' bitwise AND of its
two operands, and affects the flags as if the operation had taken place,
but does not store the result of the operation anywhere.
UCOMISD
: Unordered Scalar Double-Precision FP compare and set EFLAGSUCOMISD xmm1,xmm2/m128 ; 66 0F 2E /r [WILLAMETTE,SSE2]
compares the low-order
double-precision FP numbers in the two operands, and sets the
,
and
bits in the
register. In addition, the
,
and
bits in the
register are zeroed out. The unordered
predicate (
,
and
all set) is returned if either source operand
is a
(
or
).
UCOMISS
: Unordered Scalar Single-Precision FP compare and set EFLAGSUCOMISS xmm1,xmm2/m128 ; 0F 2E /r [KATMAI,SSE]
compares the low-order
single-precision FP numbers in the two operands, and sets the
,
and
bits in the
register. In addition, the
,
and
bits in the
register are zeroed out. The unordered
predicate (
,
and
all set) is returned if either source operand
is a
(
or
).
UD0
, UD1
, UD2
: Undefined InstructionUD0 ; 0F FF [186,UNDOC] UD1 ; 0F B9 [186,UNDOC] UD2 ; 0F 0B [186]
can be used to generate an invalid opcode
exception, for testing purposes.
is specifically documented by AMD as being
reserved for this purpose.
is documented by Intel as being available
for this purpose.
is specifically documented by Intel as
being reserved for this purpose. Intel document this as the preferred
method of generating an invalid opcode exception.
All these opcodes can be used to generate invalid opcode exceptions on all currently available processors.
UMOV
: User Move DataUMOV r/m8,reg8 ; 0F 10 /r [386,UNDOC] UMOV r/m16,reg16 ; o16 0F 11 /r [386,UNDOC] UMOV r/m32,reg32 ; o32 0F 11 /r [386,UNDOC]
UMOV reg8,r/m8 ; 0F 12 /r [386,UNDOC] UMOV reg16,r/m16 ; o16 0F 13 /r [386,UNDOC] UMOV reg32,r/m32 ; o32 0F 13 /r [386,UNDOC]
This undocumented instruction is used by in-circuit emulators to access
user memory (as opposed to host memory). It is used just like an ordinary
memory/register or register/register
instruction, but accesses user space.
This instruction is only available on some AMD and IBM 386 and 486 processors.
UNPCKHPD
: Unpack and Interleave High Packed Double-Precision FP ValuesUNPCKHPD xmm1,xmm2/m128 ; 66 0F 15 /r [WILLAMETTE,SSE2]
performs an interleaved unpack of the
high-order data elements of the source and destination operands, saving the
result in
. It ignores the lower half of the
sources.
The operation of this instruction is:
dst[63-0] := dst[127-64]; dst[127-64] := src[127-64].
UNPCKHPS
: Unpack and Interleave High Packed Single-Precision FP ValuesUNPCKHPS xmm1,xmm2/m128 ; 0F 15 /r [KATMAI,SSE]
performs an interleaved unpack of the
high-order data elements of the source and destination operands, saving the
result in
. It ignores the lower half of the
sources.
The operation of this instruction is:
dst[31-0] := dst[95-64]; dst[63-32] := src[95-64]; dst[95-64] := dst[127-96]; dst[127-96] := src[127-96].
UNPCKLPD
: Unpack and Interleave Low Packed Double-Precision FP DataUNPCKLPD xmm1,xmm2/m128 ; 66 0F 14 /r [WILLAMETTE,SSE2]
performs an interleaved unpack of the
low-order data elements of the source and destination operands, saving the
result in
. It ignores the lower half of the
sources.
The operation of this instruction is:
dst[63-0] := dst[63-0]; dst[127-64] := src[63-0].
UNPCKLPS
: Unpack and Interleave Low Packed Single-Precision FP DataUNPCKLPS xmm1,xmm2/m128 ; 0F 14 /r [KATMAI,SSE]
performs an interleaved unpack of the
low-order data elements of the source and destination operands, saving the
result in
. It ignores the lower half of the
sources.
The operation of this instruction is:
dst[31-0] := dst[31-0]; dst[63-32] := src[31-0]; dst[95-64] := dst[63-32]; dst[127-96] := src[63-32].
VERR
, VERW
: Verify Segment Readability/WritabilityVERR r/m16 ; 0F 00 /4 [286,PRIV]
VERW r/m16 ; 0F 00 /5 [286,PRIV]
VERR
sets the zero flag if the segment
specified by the selector in its operand can be read from at the current
privilege level. Otherwise it is cleared.
VERW
sets the zero flag if the segment can be
written.
WAIT
: Wait for Floating-Point ProcessorWAIT ; 9B [8086] FWAIT ; 9B [8086]
, on 8086 systems with a separate 8087
FPU, waits for the FPU to have finished any operation it is engaged in
before continuing main processor operations, so that (for example) an FPU
store to main memory can be guaranteed to have completed before the CPU
tries to read the result back out.
On higher processors,
is unnecessary for
this purpose, and it has the alternative purpose of ensuring that any
pending unmasked FPU exceptions have happened before execution continues.
WBINVD
: Write Back and Invalidate CacheWBINVD ; 0F 09 [486]
invalidates and empties the processor's
internal caches, and causes the processor to instruct external caches to do
the same. It writes the contents of the caches back to memory first, so no
data is lost. To flush the caches quickly without bothering to write the
data back first, use
(section B.4.125).
WRMSR
: Write Model-Specific RegistersWRMSR ; 0F 30 [PENT]
writes the value in
to the processor Model-Specific Register
(MSR) whose index is stored in
. See also
(section
B.4.270).
WRSHR
: Write SMM Header Pointer RegisterWRSHR r/m32 ; 0F 37 /0 [386,CYRIX,SMM]
loads the contents of either a 32-bit
memory location or a 32-bit register into the SMM header pointer register.
See also
(section B.4.272).
XADD
: Exchange and AddXADD r/m8,reg8 ; 0F C0 /r [486] XADD r/m16,reg16 ; o16 0F C1 /r [486] XADD r/m32,reg32 ; o32 0F C1 /r [486]
exchanges the values in its two operands,
and then adds them together and writes the result into the destination
(first) operand. This instruction can be used with a
prefix for multi-processor synchronisation
purposes.
XBTS
: Extract Bit StringXBTS reg16,r/m16 ; o16 0F A6 /r [386,UNDOC] XBTS reg32,r/m32 ; o32 0F A6 /r [386,UNDOC]
The implied operation of this instruction is:
XBTS r/m16,reg16,AX,CL XBTS r/m32,reg32,EAX,CL
Writes a bit string from the source operand to the destination.
indicates the number of bits to be copied, and
indicates the low order bit offset in the
source. The bits are written to the low order bits of the destination
register. For example, if
is set to 4 and
(for 16-bit code) is set to 5, bits 5-8 of
will be copied to bits 0-3 of
. This instruction is very poorly documented,
and I have been unable to find any official source of documentation on it.
is supported only on the early Intel
386s, and conflicts with the opcodes for
(on early Intel 486s). NASM supports
it only for completeness. Its counterpart is
(see section B.4.116).
XCHG
: ExchangeXCHG reg8,r/m8 ; 86 /r [8086] XCHG reg16,r/m8 ; o16 87 /r [8086] XCHG reg32,r/m32 ; o32 87 /r [386]
XCHG r/m8,reg8 ; 86 /r [8086] XCHG r/m16,reg16 ; o16 87 /r [8086] XCHG r/m32,reg32 ; o32 87 /r [386]
XCHG AX,reg16 ; o16 90+r [8086] XCHG EAX,reg32 ; o32 90+r [386] XCHG reg16,AX ; o16 90+r [8086] XCHG reg32,EAX ; o32 90+r [386]
exchanges the values in its two operands.
It can be used with a
prefix for purposes of
multi-processor synchronisation.
or
(depending on the
setting) generates the opcode
, and so is a synonym for
(section
B.4.190).
XLATB
: Translate Byte in Lookup TableXLAT ; D7 [8086] XLATB ; D7 [8086]
adds the value in
, treated as an unsigned byte, to
or
, and loads
the byte from the resulting address (in the segment specified by
) back into
.
The base register used is
if the address
size is 16 bits, and
if it is 32 bits. If you
need to use an address size not equal to the current
setting, you can use an explicit
or
prefix.
The segment register used to load from
or
can be overridden by using a segment
register name as a prefix (for example,
).
XOR
: Bitwise Exclusive ORXOR r/m8,reg8 ; 30 /r [8086] XOR r/m16,reg16 ; o16 31 /r [8086] XOR r/m32,reg32 ; o32 31 /r [386]
XOR reg8,r/m8 ; 32 /r [8086] XOR reg16,r/m16 ; o16 33 /r [8086] XOR reg32,r/m32 ; o32 33 /r [386]
XOR r/m8,imm8 ; 80 /6 ib [8086] XOR r/m16,imm16 ; o16 81 /6 iw [8086] XOR r/m32,imm32 ; o32 81 /6 id [386]
XOR r/m16,imm8 ; o16 83 /6 ib [8086] XOR r/m32,imm8 ; o32 83 /6 ib [386]
XOR AL,imm8 ; 34 ib [8086] XOR AX,imm16 ; o16 35 iw [8086] XOR EAX,imm32 ; o32 35 id [386]
performs a bitwise XOR operation between
its two operands (i.e. each bit of the result is 1 if and only if exactly
one of the corresponding bits of the two inputs was 1), and stores the
result in the destination (first) operand.
In the forms with an 8-bit immediate second operand and a longer first
operand, the second operand is considered to be signed, and is
sign-extended to the length of the first operand. In these cases, the
qualifier is necessary to force NASM to
generate this form of the instruction.
The
instruction
(see section
B.4.266) performs the same operation on the 64-bit
registers.
XORPD
: Bitwise Logical XOR of Double-Precision FP ValuesXORPD xmm1,xmm2/m128 ; 66 0F 57 /r [WILLAMETTE,SSE2]
returns a bit-wise logical XOR between
the source and destination operands, storing the result in the destination
operand.
XORPS
: Bitwise Logical XOR of Single-Precision FP ValuesXORPS xmm1,xmm2/m128 ; 0F 57 /r [KATMAI,SSE]
returns a bit-wise logical XOR between
the source and destination operands, storing the result in the destination
operand.