| Opcode | Instruction | Op/En | 64-Bit Mode | Compat/Leg Mode | Description |
|---|---|---|---|---|---|
| 9D | POPF | NP | Valid | Valid | Pop top of stack into lower 16 bits of EFLAGS. |
| 9D | POPFD | NP | N.E. | Valid | Pop top of stack into EFLAGS. |
| 9D | POPFQ | NP | Valid | N.E. | Pop top of stack and zero-extend into RFLAGS. |
| Op/En | Operand 1 | Operand 2 | Operand 3 | Operand 4 |
| NP | NA | NA | NA | NA |
Pops a doubleword (POPFD) from the top of the stack (if the current operand-size attribute is 32) and stores the value in the EFLAGS register, or pops a word from the top of the stack (if the operand-size attribute is 16) and stores it in the lower 16 bits of the EFLAGS register (that is, the FLAGS register). These instructions reverse the operation of the PUSHF/PUSHFD instructions.
The POPF (pop flags) and POPFD (pop flags double) mnemonics reference the same opcode. The POPF instruction is intended for use when the operand-size attribute is 16; the POPFD instruction is intended for use when the operand-size attribute is 32. Some assemblers may force the operand size to 16 for POPF and to 32 for POPFD. Others may treat the mnemonics as synonyms (POPF/POPFD) and use the setting of the operand-size attribute to determine the size of values to pop from the stack.
The effect of POPF/POPFD on the EFLAGS register changes, depending on the mode of operation. See the Table 4-12 and key below for details.
When operating in protected, compatibility, or 64-bit mode at privilege level 0 (or in real-address mode, the equiv-alent to privilege level 0), all non-reserved flags in the EFLAGS register except RF1, VIP, VIF, and VM may be modi-fied. VIP, VIF and VM remain unaffected.
When operating in protected, compatibility, or 64-bit mode with a privilege level greater than 0, but less than or equal to IOPL, all flags can be modified except the IOPL field and RF1, IF, VIP, VIF, and VM; these remain unaf-fected. The AC and ID flags can only be modified if the operand-size attribute is 32. The interrupt flag (IF) is altered only when executing at a level at least as privileged as the IOPL. If a POPF/POPFD instruction is executed with insufficient privilege, an exception does not occur but privileged bits do not change.
When operating in virtual-8086 mode (EFLAGS.VM = 1) without the virtual-8086 mode extensions (CR4.VME = 0), the POPF/POPFD instructions can be used only if IOPL = 3; otherwise, a general-protection exception (#GP) occurs. If the virtual-8086 mode extensions are enabled (CR4.VME = 1), POPF (but not POPFD) can be executed in virtual-8086 mode with IOPL < 3.
In 64-bit mode, use REX.W to pop the top of stack to RFLAGS. The mnemonic assigned is POPFQ (note that the 32-bit operand is not encodable). POPFQ pops 64 bits from the stack, loads the lower 32 bits into RFLAGS, and zero extends the upper bits of RFLAGS.
See Chapter 3 of the Intel® 64 and IA-32 Architectures Software Developer’s Manual, Volume 1, for more informa-tion about the EFLAGS registers.
1.
RF is always zero after the execution of POPF. This is because POPF, like all instructions, clears RF as it begins to execute.
Notes
21
20
19
18
17
16
14
13:12
11
10
9
8
7
6
4
2
0
Size
ID
VIP
VIF
AC
VM
RF
NT
IOPL
OF
DF
IF
TF
SF
ZF
AF
PF
CF
Real-Address
16
0
0-3
0
Mode (CR0.PE
32
0
0-3
0
= 0)
Protected,
16
0
0-3
0
Compatibility,
16
1-3
<CPL
0
and 64-Bit
Modes
16
1-3
≥CPL
0
32, 64
0
0-3
0
(CR0.PE = 1, EFLAGS.VM =
32, 64
1-3
<CPL
0
0)
32, 64
1-3
≥CPL
0
1
Virtual-8086 (CR0.PE = 1,
16
3
3
0
EFLAGS.VM =
1
1,
CR4.VME = 0)
32
3
3
0
2
VME
16
3
0-2
0/
(CR0.PE = 1,
X
EFLAGS.VM =
16
3
3
0
1,
1
CR4.VME = 1)
32
3
3
0
NOTES:
1. #GP fault - no flag update
2. #GP fault with no flag update if VIP=1 in EFLAGS register and IF=1 in FLAGS value on stack
IF VM = 0 (* Not in Virtual-8086 Mode *)
THEN IF CPL = 0
THEN
IF OperandSize = 32;
THEN
EFLAGS ← Pop(); (* 32-bit pop *)
(* All non-reserved flags except RF, VIP, VIF, and VM can be modified; VIP, VIF, VM, and all reserved bits are unaffected. RF is cleared. *)
ELSE IF (Operandsize = 64)
RFLAGS = Pop(); (* 64-bit pop *)
(* All non-reserved flags except RF, VIP, VIF, and VM can be modified;
VIP, VIF, VM, and all reserved bits are unaffected. RF is cleared. *)
ELSE (* OperandSize = 16 *)
EFLAGS[15:0] ← Pop(); (* 16-bit pop *)
(* All non-reserved flags can be modified. *)
FI;
ELSE (* CPL > 0 *)
IF OperandSize = 32
THEN
IF CPL > IOPL
THEN
EFLAGS ← Pop(); (* 32-bit pop *)
(* All non-reserved bits except IF, IOPL, VIP, VIF, VM and RF can be modified;
IF, IOPL, VIP, VIF, VM and all reserved bits are unaffected; RF is cleared. *)
ELSE
EFLAGS ← Pop(); (* 32-bit pop *)
(* All non-reserved bits except IOPL, VIP, VIF, VM and RF can be modified;
IOPL, VIP, VIF, VM and all reserved bits are unaffected; RF is cleared. *)
FI;
ELSE IF (Operandsize = 64)
IF CPL > IOPL
THEN
RFLAGS ← Pop(); (* 64-bit pop *)
(* All non-reserved bits except IF, IOPL, VIP, VIF, VM and RF can be modified;
IF, IOPL, VIP, VIF, VM and all reserved bits are unaffected; RF is cleared. *)
ELSE
RFLAGS ← Pop(); (* 64-bit pop *)
(* All non-reserved bits except IOPL, VIP, VIF, VM and RF can be modified;
IOPL, VIP, VIF, VM and all reserved bits are unaffected; RF is cleared. *)
FI;
ELSE (* OperandSize = 16 *)
EFLAGS[15:0] ← Pop(); (* 16-bit pop *)
(* All non-reserved bits except IOPL can be modified; IOPL and all reserved bits are unaffected. *)
FI;
FI;
ELSE IF CR4.VME = 1 (* In Virtual-8086 Mode with VME Enabled *)
IF IOPL = 3
THEN IF OperandSize = 32
THEN
EFLAGS ← Pop();
(* All non-reserved bits except IOPL, VIP, VIF, VM, and RF can be modified;
VIP, VIF, VM, IOPL and all reserved bits are unaffected. RF is cleared. *)
ELSE
EFLAGS[15:0] ← Pop(); FI;
(* All non-reserved bits except IOPL can be modified;
IOPL and all reserved bits are unaffected. *)
FI;
ELSE (* IOPL < 3 *)
IF (Operandsize = 32)
THEN
#GP(0); (* Trap to virtual-8086 monitor. *)
ELSE (* Operandsize = 16 *)
tempFLAGS ← Pop();
IF EFLAGS.VIP = 1 AND tempFLAGS[9] = 1
THEN #GP(0);
ELSE
EFLAGS.VIF ← tempFLAGS[9];
EFLAGS[15:0] ← tempFLAGS;
(* All non-reserved bits except IOPL and IF can be modified;
IOPL, IF, and all reserved bits are unaffected. *)
FI;
FI;
FI;
ELSE (* In Virtual-8086 Mode *)
IF IOPL = 3
THEN IF OperandSize = 32
THEN
EFLAGS ← Pop();
(* All non-reserved bits except IOPL, VIP, VIF, VM, and RF can be modified;
VIP, VIF, VM, IOPL and all reserved bits are unaffected. RF is cleared. *)
ELSE
EFLAGS[15:0] ← Pop(); FI;
(* All non-reserved bits except IOPL can be modified;
IOPL and all reserved bits are unaffected. *)
ELSE (* IOPL < 3 *)
#GP(0); (* Trap to virtual-8086 monitor. *)
FI;
FI;
FI;
All flags may be affected; see the Operation section for details.
| #SS(0) | If the top of stack is not within the stack segment. |
| #PF(fault-code) | If a page fault occurs. |
| #AC(0) | If an unaligned memory reference is made while the current privilege level is 3 and alignment checking is enabled. |
| #UD | If the LOCK prefix is used. |
| #SS | If the top of stack is not within the stack segment. |
| #UD | If the LOCK prefix is used. |
| #GP(0) |
If the I/O privilege level is less than 3. If an attempt is made to execute the POPF/POPFD instruction with an operand-size override prefix. |
| #SS(0) | If the top of stack is not within the stack segment. |
| #PF(fault-code) | If a page fault occurs. |
| #AC(0) | If an unaligned memory reference is made while alignment checking is enabled. |
| #UD | If the LOCK prefix is used. |
Same as for protected mode exceptions.
| #GP(0) | If the memory address is in a non-canonical form. |
| #SS(0) | If the stack address is in a non-canonical form. |
| #PF(fault-code) | If a page fault occurs. |
| #AC(0) | If alignment checking is enabled and an unaligned memory reference is made while the current privilege level is 3. |
| #UD | If the LOCK prefix is used. |