A colleague showed me code that I thought wouldn't be necessary, but sure enough, it was. I would expect most compilers would see all three of these attempts at equality tests as equivalent:

#include <cstdint>
#include <cstring>

struct Point {
    std::int32_t x, y;

bool naiveEqual(const Point &a, const Point &b) {
    return a.x == b.x && a.y == b.y;

bool optimizedEqual(const Point &a, const Point &b) {
    // Why can't the compiler produce the same assembly in naiveEqual as it does here?
    std::uint64_t ai, bi;
    static_assert(sizeof(Point) == sizeof(ai));
    std::memcpy(&ai, &a, sizeof(Point));
    std::memcpy(&bi, &b, sizeof(Point));
    return ai == bi;

bool optimizedEqual2(const Point &a, const Point &b) {
    return std::memcmp(&a, &b, sizeof(a)) == 0;

bool naiveEqual1(const Point &a, const Point &b) {
    // Let's try avoiding any jumps by using bitwise and:
    return (a.x == b.x) & (a.y == b.y);

But to my surprise, only the ones with memcpy or memcmp get turned into a single 64-bit compare by GCC. Why? (https://godbolt.org/z/aP1ocs)

Isn't it obvious to the optimizer that if I check equality on contiguous pairs of four bytes that that's the same as comparing on all eight bytes?

An attempt to avoid separately booleanizing the two parts compiles somewhat more efficiently (one fewer instruction and no false dependency on EDX), but still two separate 32-bit operations.

bool bithackEqual(const Point &a, const Point &b) {
    // a^b == 0 only if they're equal
    return ((a.x ^ b.x) | (a.y ^ b.y)) == 0;

GCC and Clang both have the same missed optimizations when passing the structs by value (so a is in RDI and b is in RSI because that's how x86-64 System V's calling convention packs structs into registers): https://godbolt.org/z/v88a6s. The memcpy / memcmp versions both compile to cmp rdi, rsi / sete al, but the others do separate 32-bit operations.

struct alignas(uint64_t) Point surprisingly still helps in the by-value case where arguments are in registers, optimizing both naiveEqual versions for GCC, but not the bithack XOR/OR. (https://godbolt.org/z/ofGa1f). Does this give us any hints about GCC's internals? Clang isn't helped by alignment.

  • 6
    @M.A No. See the assembly output in the supplied link. Feb 18, 2021 at 15:49
  • 14
    How about return std::memcmp(&a, &b, sizeof(a)) == 0; ? It generates the same assembly as the optimized version and is more expressive. Feb 18, 2021 at 16:00
  • 3
    @dyp: Wow, yeah, and pointlessly expands the compare result to two 64-bit elements with a vpmovsxdq / vmovmskpd instead of just using vmovmskps / cmp al, 0xf (the top 2 bits will always be set because the high zeros in the pcmpeqd input will compare equal). Or even vpmovmskb; the low 8 bits are all we need. Of course pure scalar is clearly better here, but if it was looking for something like a.x==b.x && a.y != b.y, you could do that with clang's SIMD strategy just using a different compare value, like 0x1 in the low 2 bits instead of 0x3. Feb 19, 2021 at 1:27
  • 5
    for C++20 return std::bit_cast<std::int64_t>(a) == std::bit_cast<std::int64_t>(b); is the type safe version of memcpy / memcmp and it generates the same optimized assembly,
    – bolov
    Feb 19, 2021 at 1:56
  • 4
    @BrettHale: That reasoning is very faulty. For example, x < 10 && x > 1 optimizes into a sub / cmp / setbe (unsigned below or equal) range-check godbolt.org/z/G8h3eM. GCC is certainly willing to consider doing work the C abstract machine wouldn't, especially if it can get it all done without any more instructions. (Including if-conversion from branchy source to branchless asm). One answer even points out that GCC actually does do the desired optimization if you promise it alignment of Point. Feb 19, 2021 at 9:03

3 Answers 3


If you "fix" the alignment, all give the same assembly language output (with GCC):

struct alignas(std::int64_t) Point {
    std::int32_t x, y;


As a note, some correct/legal ways to do some stuff (as type punning) is to use memcpy, so having specific optimization (or be more aggressive) when using that function seems logical.

  • 5
    But memcpy doesn't assume alignment... so the optimizedEqual doesn't assume that Point is overaligned
    – dyp
    Feb 18, 2021 at 15:53
  • 6
    So... why does the memcpy version not need alignment? The compiler sees through the memcpy in that it copies the unaligned structs to registers... is this a missing compiler optimization that the alignment somehow nudges?
    – Ben
    Feb 18, 2021 at 15:54
  • 16
    This is an interesting observation, but I don't feel that it answers the "Why?" Why are these valid, trivial, and equivalent functions producing different assembly? Feb 18, 2021 at 15:54
  • 10
    So, why does the alignment matter here? Why can't the compiler do the optimization OP did manually? Feb 18, 2021 at 16:10
  • 17
    @AyxanHaqverdili: guaranteed alignment means the optimization is even more profitable: no chance of cache-line splits when using single 64-bit loads. This might make the optimizer try harder, or bump a heuristic past some threshold of profitability. But without knowing which, this answer is just a useful observation and a workaround, not a real answer. Feb 19, 2021 at 1:14

There's a performance cliff you risk falling off of when implementing this as a single 64-bit comparison:

You break store to load forwarding.

If the 32-bit numbers in the structs are written to memory by separate store instructions, and then loaded back from memory with 64-bit load instructions quickly (before the stores hit L1$), your execution will stall until the stores commit to globally visible cache coherent L1$. If the loads are 32-bit loads that match the previous 32-bit stores, modern CPUs will avoid the store-load stall by forwarding the stored value to the load instruction before the store reaches cache. This violates sequential consistency if multiple CPUs access the memory (a CPU sees its own stores in a different order than other CPUs do), but is allowed by most modern CPU architectures, even x86. The forwarding also allows much more code to be executed completely speculatively, because if the execution has to be rolled back, no other CPU can have seen the store for the code that used the loaded value on this CPU to be speculatively executed.

If you want this to use 64-bit operations and you don't want this perf cliff, you may want to ensure the struct is also always written as a single 64-bit number.

  • 1
    Why does that change with alignment?
    – dyp
    Feb 19, 2021 at 15:30
  • 1
    What I meant was: why is the optimization performed if additional alignment is given? Does that somehow change your argument? I mean, it could cross a cache line w/o the alignment, but does it influence store->load fwd?
    – dyp
    Feb 19, 2021 at 15:45
  • 2
    your execution will stall until the stores commit to globally visible cache coherent L1$ - Not quite. There's evidence that a Store-forwarding stall on modern x86 CPUs doesn't have to wait for commit, it just has to do a slower more complete scan of the store buffer, possibly also merging with data from L1d. Can modern x86 implementations store-forward from more than one prior store? has some more detail on that evidence. It's also not a pipeline stall, OoO exec may be able to hide the latency. But yes, good point, usually something to avoid. Feb 19, 2021 at 21:45
  • 2
    But IIRC, I've been told by GCC devs that GCC doesn't know anything about store-forwarding stalls and doesn't actively try to avoid them. (Devs do, so that doesn't rule out tuning some heuristics for cost/benefit of doing wider loads, though.) Feb 19, 2021 at 21:48
  • 1
    @Noah: Read the comments in my Godbolt link. 2 stores dependent on the load that both have to be reloaded (instead of the reload reading 1 store + merging data from L1d cache) is slower because of the resource conflict: 2 stores that have to write data to the store buffer. Feb 22, 2021 at 8:42

Why can't the compiler generate [same assembly as memcpy version]?

The compiler "could" in the sense that it would be allowed to.

The compiler simply doesn't. Why it doesn't is beyond my knowledge as that requires deep knowledge of how the optimiser has been implemented. But, the answer may range from "there is no logic covering such transformation" to "the rules aren't tuned to assume one output is faster than the other" on all target CPUs.

If you use Clang instead of GCC, you'll notice that it produces same output for naiveEqual and naiveEqual1 and that assembly has no jump. It is same as for the "optimised" version except for using two 32 bit instructions in place of one 64 bit instruction. Furthermore restricting the alignment of Point as shown in Jarod42's answer has no effect to the optimiser.

MSVC behaves like Clang in the sense that it is unaffected by the alignment, but differently in the sense that it doesn't get rid of the jump in naiveEqual.

For what its worth, the compilers (I checked GCC and Clang) produce essentially same output for the C++20 defaulted comparison as they do fornaiveEqual. For whatever reason, GCC opted to use jne instead of je for the jump.

is this a missing compiler optimization

With the assumption that one is always faster than the other on the target CPUs, that would be fair conclusion.

  • 3
    clang with -march=tigerlake uses SSE.
    – dyp
    Feb 18, 2021 at 17:20
  • 3
    Also interesting: When I replace my Point with std::tuple<std::int32_t, std::int32_t> or std::pair<std::int32_t, std::int32_t> I get the same behavior... but std::array<std::int32_t, 2> is a single compare even though all three are (usually, I expect!) the same bits in memory with the same alignment.
    – Ben
    Feb 18, 2021 at 18:58
  • 3
    @Ben gcc does that array optimization, but clang doesn't...
    – dyp
    Feb 18, 2021 at 19:25
  • 2
    @supercat: As I commented in that thread, that's incorrect. C structs are all-or-nothing, unlike separate indexes relative to a pointer. Accessing a.x guarantees that a.y is accessible. Feb 20, 2021 at 2:22
  • 2
    @supercat: How is there any problem here? If the first 32 bits don't match, the == compare will be false no matter what garbage you read in the 2nd 32 bits. x86 doesn't have hardware race detection so it won't fault. Or are you talking about hypothetical badness on other ISAs, from GCC's target-independent optimizations doing this without properly checking that the target can't do race detection? Does GCC support any targets with HW race detection? Feb 20, 2021 at 22:07

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