For me, it just seems like a funky MOV. What's its purpose and when should I use it?

  • 8
    See also Using LEA on values that aren't addresses / pointers?: LEA is just a shift-and-add instruction. It was probably added to 8086 because the hardware is already there to decode and calculate addressing modes, not because it's "intended" only for use with addresses. Remember that pointers are just integers in assembly. Apr 17, 2018 at 5:10

17 Answers 17


As others have pointed out, LEA (load effective address) is often used as a "trick" to do certain computations, but that's not its primary purpose. The x86 instruction set was designed to support high-level languages like Pascal and C, where arrays—especially arrays of ints or small structs—are common. Consider, for example, a struct representing (x, y) coordinates:

struct Point
     int xcoord;
     int ycoord;

Now imagine a statement like:

int y = points[i].ycoord;

where points[] is an array of Point. Assuming the base of the array is already in EBX, and variable i is in EAX, and xcoord and ycoord are each 32 bits (so ycoord is at offset 4 bytes in the struct), this statement can be compiled to:

MOV EDX, [EBX + 8*EAX + 4]    ; right side is "effective address"

which will land y in EDX. The scale factor of 8 is because each Point is 8 bytes in size. Now consider the same expression used with the "address of" operator &:

int *p = &points[i].ycoord;

In this case, you don't want the value of ycoord, but its address. That's where LEA (load effective address) comes in. Instead of a MOV, the compiler can generate

LEA ESI, [EBX + 8*EAX + 4]

which will load the address in ESI.

  • 163
    Wouldn't it have been cleaner to extend the mov instruction and leave off the brackets? MOV EDX, EBX + 8*EAX + 4 Aug 15, 2011 at 12:43
  • 27
    @imacake By replacing LEA with a specialized MOV you keep the syntax clean: [] brackets are always the equivalent of dereferencing a pointer in C. Without brackets, you always deal with the pointer itself. Nov 4, 2011 at 13:54
  • 182
    Doing math in a MOV instruction (EBX+8*EAX+4) isn't valid. LEA ESI, [EBX + 8*EAX + 4] is valid because this is an addressing mode that x86 supports. en.wikipedia.org/wiki/X86#Addressing_modes
    – Erik
    Jan 7, 2012 at 6:07
  • 34
    @JonathanDickinson LEA is like a MOV with an indirect source, except it only does the indirection and not the MOV. It doesn't actually read from the computed address, just computes it.
    – hobbs
    Aug 28, 2013 at 2:57
  • 37
    Erik, tour comment is not accurate. MOV eax, [ebx+8*ecx+4] is valid. However MOV returns the contents of thst memory location whereas LEA returns the address
    – Olorin
    Apr 23, 2015 at 15:40

From the "Zen of Assembly" by Abrash:

LEA, the only instruction that performs memory addressing calculations but doesn't actually address memory. LEA accepts a standard memory addressing operand, but does nothing more than store the calculated memory offset in the specified register, which may be any general purpose register.

What does that give us? Two things that ADD doesn't provide:

  1. the ability to perform addition with either two or three operands, and
  2. the ability to store the result in any register; not just one of the source operands.

And LEA does not alter the flags.


  • LEA EAX, [ EAX + EBX + 1234567 ] calculates EAX + EBX + 1234567 (that's three operands)
  • LEA EAX, [ EBX + ECX ] calculates EBX + ECX without overriding either with the result.
  • multiplication by constant (by two, three, five or nine), if you use it like LEA EAX, [ EBX + N * EBX ] (N can be 1,2,4,8).

Other usecase is handy in loops: the difference between LEA EAX, [ EAX + 1 ] and INC EAX is that the latter changes EFLAGS but the former does not; this preserves CMP state.

  • 46
    @AbidRahmanK some examples: LEA EAX, [ EAX + EBX + 1234567 ] calculates the sum of EAX, EBX and 1234567 (that's three operands). LEA EAX, [ EBX + ECX ] calculates EBX + ECX without overriding either with the result. The third thing LEA is used for (not listed by Frank) is multiplication by constant (by two, three, five or nine), if you use it like LEA EAX, [ EBX + N * EBX ] (N can be 1,2,4,8). Other usecase is handy in loops: the difference between LEA EAX, [ EAX + 1 ] and INC EAX is that the latter changes EFLAGS but the former does not; this preserves CMP state
    – FrankH.
    Aug 22, 2013 at 10:01
  • 6
    @ripDaddy69 yes, sort of - if by "load" you mean "performs the address calculation / pointer arithmetics". It does not access memory (i.e. not "dereference" the pointer as it'd be called in C programming terms).
    – FrankH.
    Oct 29, 2013 at 9:04
  • 2
    +1: This makes explicit what kinds of 'tricks' LEA can be used for... (see "LEA (load effective address) is often used as a "trick" to do certain computations" in IJ Kennedy's popular answer above) Mar 31, 2014 at 0:45
  • 10
    There's a big difference between 2 operand LEA which is fast and 3 operand LEA which is slow. The Intel Optimization manual says fast path LEA is single cycle and slow path LEA takes three cycles. Moreover, on Skylake there are two fast path functional units (ports 1 and 5) and there's only one slow path functional unit (port 1). Assembly/Compiler Coding Rule 33 in the manual even warns against using 3 operand LEA.
    – Olsonist
    Apr 1, 2019 at 15:46
  • 2
    I felt a lack of exact numbers for this example, so here they are. Let's say EBX=5, ECX=3. Then after LEA EAX, [EBX + ECX] EAX will contain 8. And after LEA EAX, [EBX + ECX + 2] EAX will contain 10. Sep 19, 2019 at 4:53

Another important feature of the LEA instruction is that it does not alter the condition codes such as CF and ZF, while computing the address by arithmetic instructions like ADD or MUL does. This feature decreases the level of dependency among instructions and thus makes room for further optimization by the compiler or hardware scheduler.

  • 3
    Yes, lea is sometimes useful for the compiler (or human coder) to do math without clobbering a flag result. But lea isn't faster than add. Most x86 instructions write flags. High-performance x86 implementations have to rename EFLAGS or otherwise avoid the write-after-write hazard for normal code to run fast, so instructions that avoid flag writes aren't better because of that. (partial flag stuff can create issues, see INC instruction vs ADD 1: Does it matter?) Apr 16, 2018 at 2:58
  • 2
    @PeterCordes : Hate to bring this up here but - am I alone in thinking this new [x86-lea] tag is redundant and unnecessary? Apr 16, 2018 at 3:43
  • 4
    @MichaelPetch: Yeah, I think it's too specific. It seems to confuse beginner who don't understand machine language and that everything (including pointers) are just bits / bytes / integers, so there are lots of questions about it with huge numbers of votes. But having a tag for it implies that there's room for an open-ended number of future questions, when in fact there are about 2 or 3 total that aren't just duplicates. (what is it? How to use it for multiplying integers? and how it runs internally on AGUs vs. ALUs and with what latency / throughput. And maybe it's "intended" purpose) Apr 16, 2018 at 5:14
  • @PeterCordes : I agree, and if anything all these posts being edited are pretty much a duplicate of a few of the exiting LEA related questions. Rather than a tag, any duplicates should be identified and marked imho. Apr 16, 2018 at 5:16
  • 1
    @EvanCarroll: hang on tagging all the LEA questions, if you haven't already finished. As discussed above, we think x86-lea too specific for a tag, and there's not a lot of scope for future non-duplicate questions. I think it would be a lot of work to actually choose a "best" Q&A as a dup target for most of them, though, or to actually decide which ones to get mods to merge. Apr 16, 2018 at 5:19

Despite all the explanations, LEA is an arithmetic operation:

LEA Rt, [Rs1+a*Rs2+b] =>  Rt = Rs1 + a*Rs2 + b

It's just that its name is extremelly stupid for a shift+add operation. The reason for that was already explained in the top rated answers (i.e. it was designed to directly map high level memory references).

  • 11
    And that the arithmetic is performed by the address-calculation hardware.
    – Ben Voigt
    Jul 12, 2013 at 17:37
  • 38
    @BenVoigt I used to say that, because I'm an old bloke :-) Traditionally, x86 CPUs did use the addressing units for this, agreed. But the "separation" has become very blurry these days. Some CPUs no longer have dedicated AGUs at all, others have chosen not to execute LEA on the AGUs but on the ordinary integer ALUs. One has to read the CPU specs very closely these days to find out "where stuff runs" ...
    – FrankH.
    Aug 22, 2013 at 10:06
  • 2
    @FrankH.: out-of-order CPUs typically run LEA on ALUs, while some in-order CPUs (like Atom) sometimes run it on an AGUs (because they can't be busy handling a memory access). Dec 3, 2015 at 17:03
  • 5
    No, the name is not stupid. LEA gives you the address which arises from any memory-related addressing mode. It is not a shift and add operation.
    – Kaz
    Apr 26, 2017 at 18:54
  • 4
    FWIW there are very few (if any) current x86 CPUs that perform the operation on the AGU. Most or all just use an ALU like any other arithmetic op.
    – BeeOnRope
    Apr 26, 2017 at 22:06

Maybe just another thing about LEA instruction. You can also use LEA for fast multiplying registers by 3, 5 or 9.

LEA EAX, [EAX * 2 + EAX]   ;EAX = EAX * 3
LEA EAX, [EAX * 4 + EAX]   ;EAX = EAX * 5
LEA EAX, [EAX * 8 + EAX]   ;EAX = EAX * 9
  • 16
    +1 for the trick. But I would like to ask a question (may be stupid), why not directly multiply with three like this LEA EAX, [EAX*3] ? Apr 6, 2013 at 6:57
  • 16
    @Abid Rahman K: There is no such as instruction unde x86 CPU instruction set.
    – GJ.
    Apr 6, 2013 at 17:23
  • 67
    @AbidRahmanK despite the intel asm syntax makes it look like a multiplication, the lea instruction can encode only shift operations. The opcode has 2 bits to describe the shift, hence you can multiply only by 1,2,4 or 8.
    – mkm
    Aug 5, 2013 at 13:03
  • 9
    @Koray Tugay: You can use shift left like shlinstruction for multiplying registers by 2,4,8,16... it is faster and shorter. But for multiplying with numbers different of power of 2 we normaly use mul instruction which is more pretentious and slower.
    – GJ.
    Jan 15, 2015 at 20:45
  • 12
    @GJ. although there's no such encoding, some assemblers accept this as a shortcut, e.g. fasm. So e.g. lea eax,[eax*3] would translate to equivalent of lea eax,[eax+eax*2].
    – Ruslan
    May 6, 2016 at 11:24

lea is an abbreviation of "load effective address". It loads the address of the location reference by the source operand to the destination operand. For instance, you could use it to:

lea ebx, [ebx+eax*8]

to move ebx pointer eax items further (in a 64-bit/element array) with a single instruction. Basically, you benefit from complex addressing modes supported by x86 architecture to manipulate pointers efficiently.


The biggest reason that you use LEA over a MOV is if you need to perform arithmetic on the registers that you are using to calculate the address. Effectively, you can perform what amounts to pointer arithmetic on several of the registers in combination effectively for "free."

What's really confusing about it is that you typically write an LEA just like a MOV but you aren't actually dereferencing the memory. In other words:


This will move the content of what ESP+4 points to into EAX.


This will move the effective address EBX * 8 into EAX, not what is found in that location. As you can see, also, it is possible to multiply by factors of two (scaling) while a MOV is limited to adding/subtracting.

  • 1
    Sorry everyone. @big.heart fooled me by giving an answer to this three hours ago, getting it to show up as "new" in my Assembly question scouring. May 6, 2015 at 1:01
  • 3
    Why does the syntax use brackets when it does not do memory addressing?
    – golopot
    Mar 18, 2017 at 22:28
  • 5
    @q4w56 This is one of those things where the answer is, "That's just how you do it." I believe it's one of the reasons that people have such a hard time figuring out what LEA does. Mar 19, 2017 at 7:32
  • 3
    @q4w56: it's a shift+add instruction that uses memory operand syntax and machine-code encoding. On some CPUs it may even use the AGU hardware, but that's a historical detail. The still-relevant fact is that the decoder hardware already exists for decoding this kind of shift+add, and LEA lets us use it for arithmetic instead of memory addressing. (Or for address calculations if one input actually is a pointer). Sep 30, 2017 at 0:44

The 8086 has a large family of instructions that accept a register operand and an effective address, perform some computations to compute the offset part of that effective address, and perform some operation involving the register and the memory referred to by the computed address. It was fairly simple to have one of the instructions in that family behave as above except for skipping that actual memory operation. Thus, the instructions:

mov ax,[bx+si+5]
lea ax,[bx+si+5]

were implemented almost identically internally. The difference is a skipped step. Both instructions work something like:

temp = fetched immediate operand (5)
temp += bx
temp += si
address_out = temp  (skipped for LEA)
trigger 16-bit read  (skipped for LEA)
temp = data_in  (skipped for LEA)
ax = temp

As for why Intel thought this instruction was worth including, I'm not exactly sure, but the fact that it was cheap to implement would have been a big factor. Another factor would have been the fact that Intel's assembler allowed symbols to be defined relative to the BP register. If fnord was defined as a BP-relative symbol (e.g. BP+8), one could say:

mov ax,fnord  ; Equivalent to "mov ax,[BP+8]"

If one wanted to use something like stosw to store data to a BP-relative address, being able to say

mov ax,0 ; Data to store
mov cx,16 ; Number of words
lea di,fnord
rep movs fnord  ; Address is ignored EXCEPT to note that it's an SS-relative word ptr

was more convenient than:

mov ax,0 ; Data to store
mov cx,16 ; Number of words
mov di,bp
add di,offset fnord (i.e. 8)
rep movs fnord  ; Address is ignored EXCEPT to note that it's an SS-relative word ptr

Note that forgetting the world "offset" would cause the contents of location [BP+8], rather than the value 8, to be added to DI. Oops.


The LEA (Load Effective Address) instruction is a way of obtaining the address which arises from any of the Intel processor's memory addressing modes.

That is to say, if we have a data move like this:


it moves the contents of the designated memory location into the target register.

If we replace the MOV by LEA, then the address of the memory location is calculated in exactly the same way by the <MEM-OPERAND> addressing expression. But instead of the contents of the memory location, we get the location itself into the destination.

LEA is not a specific arithmetic instruction; it is a way of intercepting the effective address arising from any one of the processor's memory addressing modes.

For instance, we can use LEA on just a simple direct address. No arithmetic is involved at all:

MOV EAX, GLOBALVAR   ; fetch the value of GLOBALVAR into EAX
LEA EAX, GLOBALVAR   ; fetch the address of GLOBALVAR into EAX.

This is valid; we can test it at the Linux prompt:

$ as
LEA 0, %eax
$ objdump -d a.out

a.out:     file format elf64-x86-64

Disassembly of section .text:

0000000000000000 <.text>:
   0:   8d 04 25 00 00 00 00    lea    0x0,%eax

Here, there is no addition of a scaled value, and no offset. Zero is moved into EAX. We could do that using MOV with an immediate operand also.

This is the reason why people who think that the brackets in LEA are superfluous are severely mistaken; the brackets are not LEA syntax but are part of the addressing mode.

LEA is real at the hardware level. The generated instruction encodes the actual addressing mode and the processor carries it out to the point of calculating the address. Then it moves that address to the destination instead of generating a memory reference. (Since the address calculation of an addressing mode in any other instruction has no effect on CPU flags, LEA has no effect on CPU flags.)

Contrast with loading the value from address zero:

$ as
movl 0, %eax
$ objdump -d a.out | grep mov
   0:   8b 04 25 00 00 00 00    mov    0x0,%eax

It's a very similar encoding, see? Just the 8d of LEA has changed to 8b.

Of course, this LEA encoding is longer than moving an immediate zero into EAX:

$ as
movl $0, %eax
$ objdump -d a.out | grep mov
   0:   b8 00 00 00 00          mov    $0x0,%eax

There is no reason for LEA to exclude this possibility though just because there is a shorter alternative; it's just combining in an orthogonal way with the available addressing modes.


As the existing answers mentioned, LEA has the advantages of performing memory addressing arithmetic without accessing memory, saving the arithmetic result to a different register instead of the simple form of add instruction. The real underlying performance benefit is that modern processor has a separate LEA ALU unit and port for effective address generation (including LEA and other memory reference address), this means the arithmetic operation in LEA and other normal arithmetic operation in ALU could be done in parallel in one core.

Check this article of Haswell architecture for some details about LEA unit: http://www.realworldtech.com/haswell-cpu/4/

Another important point which is not mentioned in other answers is LEA REG, [MemoryAddress] instruction is PIC (position independent code) which encodes the PC relative address in this instruction to reference MemoryAddress. This is different from MOV REG, MemoryAddress which encodes relative virtual address and requires relocating/patching in modern operating systems (like ASLR is common feature). So LEA can be used to convert such non PIC to PIC.

  • 5
    The "separate LEA ALU" part is mostly untrue. Modern CPUs execute lea on one or more of the same ALUs that execute other arithmetic instructions (but generally fewer of them than other arithmetic). For instance, the Haswell CPU mentioned can execute add or sub or most other basic arithmetic operations on four different ALUs, but can only execute lea on one (complex lea) or two (simple lea). More importantly, those two lea-capable ALUs are simply two of the four that can execute other instructions, so there is no parallelism benefit as claimed.
    – BeeOnRope
    Apr 26, 2017 at 22:04
  • 3
    The article you linked (correctly) shows that LEA is on the same port as an integer ALU (add/sub/boolean), and the integer MUL unit in Haswell. (And vector ALUs including FP ADD/MUL/FMA). The simple-only LEA unit is on port 5, which also runs ADD/SUB/whatever, and vector shuffles, and other stuff. The only reason I'm not downvoting is that you point out the use of RIP-relative LEA (for x86-64 only). Sep 30, 2017 at 0:50

It seems that lots of answers already complete, I'd like to add one more example code for showing how the lea and move instruction work differently when they have the same expression format.

To make a long story short, lea instruction and mov instructions both can be used with the parentheses enclosing the src operand of the instructions. When they are enclosed with the (), the expression in the () is calculated in the same way; however, two instructions will interpret the calculated value in the src operand in a different way.

Whether the expression is used with the lea or mov, the src value is calculated as below.

D ( Rb, Ri, S ) => (Reg[Rb]+S*Reg[Ri]+ D)

However, when it is used with the mov instruction, it tries to access the value pointed to by the address generated by the above expression and store it to the destination.

In contrast of it, when the lea instruction is executed with the above expression, it loads the generated value as it is to the destination.

The below code executes the lea instruction and mov instruction with the same parameter. However, to catch the difference, I added a user-level signal handler to catch the segmentation fault caused by accessing a wrong address as a result of mov instruction.

Example code

#define _GNU_SOURCE 1 /* To pick up REG_RIP */
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <stdint.h>
#include <signal.h>

register_handler(uint32_t event, void (*handler)(int, siginfo_t *, void *))
    uint32_t ret = 0;
    struct sigaction act;

    memset(&act, 0, sizeof(act));
    act.sa_sigaction = handler;
    act.sa_flags = SA_SIGINFO;
    ret = sigaction(event, &act, NULL);
    return ret;

void segfault_handler(int signum, siginfo_t *info, void *priv)
    ucontext_t *context = (ucontext_t *)(priv);
    uint64_t rip = (uint64_t)(context->uc_mcontext.gregs[REG_RIP]);
    uint64_t faulty_addr = (uint64_t)(info->si_addr);

    printf("inst at 0x%lx tries to access memory at %ld, but failed\n",
           rip, faulty_addr);

int main(void)
    int result_of_lea = 0;

    register_handler(SIGSEGV, segfault_handler);

    // initialize registers %eax = 1, %ebx = 2

    // the compiler will emit something like
    // mov $1, %eax
    // mov $2, %ebx
    // because of the input operands
    asm("lea 4(%%rbx, %%rax, 8), %%edx \t\n"
        : "=d"(result_of_lea) // output in EDX
        : "a"(1), "b"(2)      // inputs in EAX and EBX
        :                     // no clobbers

    // lea 4(rbx, rax, 8),%edx == lea (rbx + 8*rax + 4),%edx == lea(14),%edx
    printf("Result of lea instruction: %d\n", result_of_lea);

    asm volatile("mov 4(%%rbx, %%rax, 8), %%edx"
                 : "a"(1), "b"(2)
                 : "edx" // if it didn't segfault, it would write EDX

Execution result

Result of lea instruction: 14
inst at 0x4007b5 tries to access memory at 14, but failed
  • 1
    Breaking up your inline asm into separate statements is unsafe, and your clobbers lists are incomplete. The basic-asm block tells the compiler is has no clobbers, but it actually modifies several registers. Also, you can use =d to tell the compiler the result is in EDX, saving a mov. You also left out an early-clobber declaration on the output. This does demonstrate what you're trying to demonstrate, but is also a misleading bad example of inline asm that will break if used in other contexts. That's a Bad Thing for a stack overflow answer. Jan 3, 2019 at 8:49
  • If you don't want to write %% on all those register names in Extended asm, then use input constraints. like asm("lea 4(%%ebx, %%eax, 8), %%edx" : "=d"(result_of_lea) : "a"(1), "b"(2));. Letting the compiler init registers means you don't have to declare clobbers, either. You're overcomplicating things by xor-zeroing before mov-immediate overwrites the whole register, too. Jan 3, 2019 at 8:55
  • @PeterCordes Thanks, Peter, do you want me to delete this answer or modify it following your comments?
    – ruach
    Jan 3, 2019 at 8:57
  • 1
    If you fix the inline asm, it's not doing any harm and maybe makes a good concrete example for beginners that didn't understand the other answers. No need to delete, and it's an easy fix like I showed in my last comment. I think it would be worth an upvote if the bad example of inline asm was fixed into a "good" example. (I didn't downvote) Jan 3, 2019 at 8:59
  • 1
    Where does anyone say that mov 4(%ebx, %eax, 8), %edx is invalid? Anyway, yes, for mov it would make sense to write "a"(1ULL) to tell the compiler you have a 64-bit value, and thus it needs to make sure it's extended to fill the whole register. In practice it will still use mov $1, %eax, because writing EAX zero-extends into RAX, unless you have a weird situation of surrounding code where the compiler knew that RAX = 0xff00000001 or something. For lea, you're still using 32-bit operand-size, so the any stray high bits in input registers have no effect on the 32-bit result. Jan 3, 2019 at 13:22

The LEA instruction can be used to avoid time consuming calculations of effective addresses by the CPU. If an address is used repeatedly it is more effective to store it in a register instead of calculating the effective address every time it is used.

  • Not necessarily on modern x86. Most of the addressing modes have the same cost, with some caveats. So [esi] is rarely cheaper than say [esi + 4200] and is only rarely cheaper than [esi + ecx*8 + 4200].
    – BeeOnRope
    Jun 26, 2016 at 5:29
  • @BeeOnRope [esi] isn't cheaper than [esi + ecx*8 + 4200]. But why bother comparing? They are not equivalent. If you want the former to designate the same memory location as the latter, you need additional instructions: you have to add to esi the value of ecx multiplied by 8. Uh oh, multiplication is going to clobber your CPU flags! Then you have to add the 4200. These additional instructions add to the code size (taking up space in the instruction cache, cycles to fetch).
    – Kaz
    Apr 26, 2017 at 19:28
  • 2
    @Kaz - I think you were missing my point (or else I missed the point of the OP). My understanding is that the OP is saying that if you are going to use something like [esi + 4200] repeatedly in a sequence of instructions, then it is better to first load the effective address into a register and use that. For example, rather than writing add eax, [esi + 4200]; add ebx, [esi + 4200]; add ecx, [esi + 4200], you should prefer lea edi, [esi + 4200]; add eax, [edi]; add ebx, [edi]; add ecx, [edi], which is rarely faster. At least that's the plain interpretation of this answer.
    – BeeOnRope
    Apr 26, 2017 at 21:06
  • So the reason I was comparing [esi] and [esi + 4200] (or [esi + ecx*8 + 4200] is that this is the simplification the OP is proposing (as I understand it): that N instructions with the same complex address are transformed into N instructions with simple (one reg) addressing, plus one lea, since complex addressing is "time consuming". In fact, it is slower even on modern x86, but only latency-wise which seems unlikely to matter for consecutive instructions with the same address.
    – BeeOnRope
    Apr 26, 2017 at 21:09
  • 1
    Perhaps you relieve some register pressure, yes - but the opposite may be the case: if the registers you generated the effective address with are live, you need another register to save the result of lea so it increases pressure in that case. In general, storing intermediates is a cause of register pressure, not a solution to it - but I think in most situations it is a wash. @Kaz
    – BeeOnRope
    Apr 26, 2017 at 22:00

LEA vs MOV (reply to the original question)

LEA is not a funky MOV. When you use MOV, it calculates the address and accesses the memory. LEA just calculates the address, it doesn't actually access memory. This is the difference.

In 8086 and later, LEA just sets a sum of up to two source registers and an immediate value to a destination register. For example, lea bp, [bx+si+3] sets to the bp register the sum of bx plus si plus 3. You cannot achieve this calculation to save the result to a register with MOV.

The 80386 processor introduced a series of scaling modes, in which the index register value can be multiplied by a valid scaling factor to obtain the displacement. The valid scale factors are 1, 2, 4, and 8. Therefore, you can use instructions like lea ebp, [ebx+esi*8+3].

LDS & LES (optional further reading)

In contrast to LEA, there are instructions LDS and LES, that, to the contrary, load values from memory to the pair of registers: one segment register (DS or ES) and one general register. There are also versions for the other registers: LFS, LGS and LSS for FS, GS and SS segment registers, respectively (introduced in 80386).

So, these instructions load "far" pointer - a pointer consisting of a 16-bit segment selector and a 16-bit (or a 32-bit, depending on the mode) offset, so the total far pointer size was 32-bit in 16-bit mode and 48-bit in 32-bit mode.

These are handy instructions for 16-bit mode, be it 16-bit real mode or 16-bit protected mode.

Under 32-bit mode, there is no need in these instructions since OSes set all segment bases to zero (flat memory model), so there is no need to load segment registers. We just use 32-bit pointers, not 48.

Under 64-bit modes, these instructions are not implemented. Their opcodes give access violation interrupt (exception). Since Intel's implementation of VEX - "vector extensions - (AVX), Intel took their opcodes of LDS and LES and started using them for VEX prefixes. As Peter Cordes pointed out, that is why only x/ymm0..7 are accessible in 32-bit mode (quote): "the VEX prefixes were carefully designed to only overlap with invalid encodings of LDS and LES in 32-bit mode, where R̅ X̅ B̅ are all 1. That's why some of the bits are inverted in VEX prefixes".

  • 1
    [bx*2+si+3] isn't a valid 16-bit addressing mode. 16-bit doesn't allow any scale factors. lea bp, [ebx*2 + esi + 3] would be legal, though, in 16-bit mode on a 386 or later. (Normally you write the base first and then the scaled-index, but assemblers would accept that.) Aug 17, 2021 at 13:47
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    LES/LDS/... being useless in 32-bit mode is only by convention; OSes choose to use a flat memory model. The hardware does support non-zero segment bases in 32-bit mode, unlike 64-bit mode. So it's true in practice for normal OSes, but not necessarily for x86 in general. So maybe "since OSes set all segment registers the same" or something, to imply that it's a choice, not a requirement, for 32-bit mode to work that way, but still without spending a lot of words on it and distracting from your point. Aug 17, 2021 at 13:59
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    Yeah, I think it's a good idea to still edit more clearly why LES/LDS aren't used. I made an edit, and also fixed your mention of SSE2 for VEX prefixes. Aug 19, 2021 at 12:40
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    Not that I noticed, otherwise I would have fixed it or mentioned it. Aug 19, 2021 at 12:49
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    @supercat: you're not leaving any bits for privilege-level, and (for CS) operating mode (default of 16 vs. 32-bit operand-size and address-size). Or for a segment limit. I guess you're picturing 386 should have used a totally separate mechanism to do privilege-level and mode switching (or that CS would still work like it does now). But have other segments use segmentation mostly real-mode style just to expand the virtual address space beyond 4GiB? But then the page-tables would have more virtual bits to translate, so two levels of 10 bits each wouldn't do it. 4GB was already huge for 386 Apr 16, 2022 at 5:23

Here is an example.

// compute parity of permutation from lexicographic index
int parity (int p)
  assert (p >= 0);
  int r = p, k = 1, d = 2;
  while (p >= k) {
    p /= d;
    d += (k << 2) + 6; // only one lea instruction
    k += 2;
    r ^= p;
  return r & 1;

With -O (optimize) as compiler option, gcc will find the lea instruction for the indicated code line.


LEA : just an "arithmetic" instruction..

MOV transfers data between operands but lea is just calculating

  • LEA obviously moves data; it has a destination operand. LEA doesn't always calculate; it calculates if the effective address expressed in the source operand calculates. LEA EAX, GLOBALVAR doesn't calculate; it just moves the address of GLOBALVAR into EAX.
    – Kaz
    Apr 26, 2017 at 19:26
  • @Kaz thanks for your feedback. my source was "LEA (load effective address) is essentially an arithmetic instruction—it doesn’t perform any actual memory access, but is commonly used for calculating addresses (though you can calculate general purpose integers with it)." form Eldad-Eilam book page 149 Jul 13, 2017 at 20:26
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    @Kaz: That's why LEA is redundant when the address is already a link-time constant; use mov eax, offset GLOBALVAR instead. You can use LEA, but it's slightly larger code-size than mov r32, imm32 and runs on fewer ports, because it still goes through the address-calculation process. lea reg, symbol is only useful in 64-bit for a RIP-relative LEA, when you need PIC and/or addresses outside the low 32 bits. In 32 or 16-bit code, there is zero advantage. LEA is an arithmetic instruction that exposes the ability of the CPU to decode / compute addressing modes. Mar 29, 2018 at 1:37
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    @Kaz: by the same argument, you could say that imul eax, edx, 1 doesn't calculate: it just copies edx to eax. But actually it runs your data through the multiplier with 3 cycle latency. Or that rorx eax, edx, 0 just copies (rotate by zero). Mar 29, 2018 at 1:39
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    @Kaz: At the machine-code level, the addressing mode does have to encode that there's no base. I admit that's not quite the same as an explicit +0 or something. But there's still a ModR/M byte for LEA, to specify the disp32 immediate displacement, while MOV r32,imm32 is just opcode + imm32, if you're thinking about the machine-code instruction set rather than the asm-source level syntax. (And you're using MASM syntax, which omits the [] around symbols as memory operands. So mov eax, OFFSET globalvar is taking something simpler than globalvar: just its offset.) Mar 29, 2018 at 14:22

All normal "calculating" instructions like adding multiplication, exclusive or set the status flags like zero, sign. If you use a complicated address, AX xor:= mem[0x333 +BX + 8*CX] the flags are set according to the xor operation.

Now you may want to use the address multiple times. Loading such an addres into a register is never intended to set status flags and luckily it doesn't. The phrase "load effective address" makes the programmer aware of that. That is where the weird expression comes from.

It is clear that once the processor is capable of using the complicated address to process its content, it is capable of calculating it for other purposes. Indeed it can be used to perform a transformation x <- 3*x+1 in one instruction. This is a general rule in assembly programming: Use the instructions however it rocks your boat. The only thing that counts is whether the particular transformation embodied by the instruction is useful for you.

Bottom line

MOV, X| T| AX'| R| BX|


LEA, AX'| [BX]

have the same effect on AX but not on the status flags. (This is ciasdis notation.)

  • 1
    "This is a general rule in assembly programming: Use the instructions however it rocks your boat." I wouldn't personally hand that advice out, on account of things like call lbl lbl: pop rax technically "working" as a way to get the value of rip, but you'll make branch prediction very unhappy. Use the instructions however you want, but don't be surprised if you do something tricky and it has consequences you didn't foresee
    – the6p4c
    Dec 15, 2019 at 7:23
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    @The6P4C That is a useful caveat. However if there is no alternative to making the branch prediction unhappy, one has to go for it. There is another general rule in assembly programming. There may be alternative ways to do something and you must choose wisely from alternatives.There are hundreds of way to get the content of register BL into register AL. If the remainder of RAX need not be preserved LEA may be an option. Not affecting the flags may be a good idea on some of the thousands of types of x86 processors. Groetjes Albert Jan 28, 2020 at 15:21

Forgive me if someone already mentioned, but in case anyone's wondering about the bad old days of x86 when memory segmentation was still relevant: you will always get the same results from these two instructions:

LEA AX, DS:[0x1234]


LEA AX, CS:[0x1234]

The "effective address" is just the offset part of the seg:off logical address. In this case, 0x1234.

LEA does not add the segment base. That would defeat one of the original use-cases, for doing address math to get a pointer (offset) you could actually dereference. Such as lea bx, [array + si]. If that added DS base to give a linear address, a later mov ax, [bx] would add the DS base again.
Also, the 20-bit result would often not fit in a 16-bit register.

See https://www.stevemorse.org/8086/index.html - the architect of 8086 wrote a book about the instruction set, and it's now free on his web site. The section on LEA mentions some of his design intent.

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    The "effective address" is just the "offset" part of a seg:off pair. LEA isn't affected by the segment base; both those instructions will (inefficiently) put 0x1234 into AX. x86 unfortunately doesn't have an easy way to calculate a full linear address (effective + segment base) into a register or register-pair. Jun 7, 2020 at 3:26
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    @PeterCordes Very useful, thanks for correcting me.
    – tzoz
    Jun 8, 2020 at 20:45
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    Since this previously-wrong and never got deleted (and had 2 upvotes despite that), I rewrote it to say the opposite thing about this example, and explain why. Perhaps it even does illustrate one of the purposes of LEA, now. May 8, 2022 at 16:55

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