# Interleave bits efficiently

I need to make `uint64_t` out of 2 `uint32_t` interleaving the bits: if `A=a0a1a2...a31` and `B=b0b1...b31`, I need C=`a0b0a1b1...a31b31`. Is there a way to do this efficiently? So far I've got only the naive approach with a `for` loop of 32 iterations, where each iteration does `C|=((A&(1<<i))<<i)|((B&(1<<i))<<(i+1))`.

I guess there should be some mathematical trick like multiplying A and B by some special number which results in interleaving their bits with zeros in the resulting 64-bit number, so that what only remains is to `or` these products. But I can't find such multiplier.

Another potential way to go is a compiler intrinsic or assembly instruction, but I don't know of such.

• This looks like it may work. Not sure if or how it scales though. Commented Sep 14, 2016 at 12:25
• It should scale fairly easily; add an initial shift by 16 and mask by `0x0000ffff0000ffff`, and extend all the other masks appropriately. So the new first step severs and moves the high 16 bits into the low part of the topmost word. Commented Sep 14, 2016 at 12:40
• Can you use x86's BMI2 instruction set? Two 64-bit PDEP with opposite masks and one ordinary bitwise-OR should do the trick. The intrinsic for PDEP is `_pdep_u64()` Commented Sep 14, 2016 at 13:50
• @PeterCordes, that's a superior theoretical solution, but in practice I don't have BMI2/PDEP neither in Phenom 2 processor, nor in CUDA. Commented Sep 14, 2016 at 18:47

NathanOliver's link offers the 16-bit -> 32-bit implementation:

``````static const unsigned int B[] = {0x55555555, 0x33333333, 0x0F0F0F0F, 0x00FF00FF};
static const unsigned int S[] = {1, 2, 4, 8};

unsigned int x; // Interleave lower 16 bits of x and y, so the bits of x
unsigned int y; // are in the even positions and bits from y in the odd;
unsigned int z; // z gets the resulting 32-bit Morton Number.
// x and y must initially be less than 65536.

x = (x | (x << S[3])) & B[3];
x = (x | (x << S[2])) & B[2];
x = (x | (x << S[1])) & B[1];
x = (x | (x << S[0])) & B[0];

y = [the same thing on y]

z = x | (y << 1);
``````

Which works by:

1. leave the low 8 bits of x where they are. Move the high 8 bits up by 8;
2. divide in half and do the same thing, this time leaving the low pairs of 4 bits where they are and moving the others up by 4;
3. and again, and again.

I.e. it proceeds as:

``````   0000 0000 0000 0000  abcd efgh ijkl mnop
-> 0000 0000 abcd efgh  0000 0000 ijkl mnop
-> 0000 abcd 0000 efgh  0000 ijkl 0000 mnop
-> 00ab 00cd 00ef 00gh  00ij 00kl 00mn 00op
-> 0a0b 0c0d 0e0f 0g0h  0i0j 0k0l 0m0n 0o0p
``````

And then combines the two inputs together.

As per my earlier comment, to extend that to 64 bits, just add an initial shift by 16 and mask by `0x0000ffff0000ffff`, either because you can intuitively follow the pattern or as a divide-and-conquer step, turning the 32-bit problem into two non-overlapping 16-bit problems and then using the 16-bit solution.

• Divide&conquer approach doubles the number of required operations, while extension with the 5th array item and `or-and-assign`, if it works, increases the operation count by 1.25x . Commented Sep 14, 2016 at 17:37
• Divide and conquer doesn't double in this case because the 32-bit value, divided into two 16-bit quantities, fits in a 64-bit word throughout, which your CPU can act upon atomically. But we're arguing semantics. I count it as logically an initial division, even though the divided thing continues to fit inside one scalar. Commented Sep 14, 2016 at 18:21
• thanks, I misunderstood initially. I though you mean performing these 4 `or-and-assign` operations first on lower 32 bits, then on higher 32 bits. Commented Sep 14, 2016 at 18:42
• @J.Schultke The question was already tagged `[c++]` so that's the default code formatting for unmarked blocks, without `<!-- language: lang-c++ -->` comments or backticks language. I don't think your edit changed the syntax highlighting of the first code block at all. The other minor changes were improvements so not rolling it back, but in future you can make your edits less noisy by keeping that in mind and looking for actual bad highlighting. Commented Aug 21, 2020 at 0:26

For larger integers, it's worth mentioning the clmul x86 extension for finite field multiplication (carryless multiplication). Interleaving an integer with zeros is equivalent to a carryless multiplication of the integer with itself, which is a single ALU instruction.

• Good choice, and with 64 bit input / 128 bit output it's even pretty much ideal. But it's also worth noting thay this is currently still a somewhat "new" extension and will not be available on AMD Phenom II and Intels Ivy Bridge processors which you may still encounter in the wild. Commented Jul 29, 2020 at 19:57
• @Ext3h: felixcloutier.com/x86/pclmulqdq is available since Westmere for Intel (2nd-gen Nehalem). godbolt.org/z/jWaGWv. But yes, it's an extension, not baseline x86-64. Commented Jul 29, 2020 at 20:00
• Since we're mentioning x86 extensions, BMI2 `pdep r64, r64, r/m64` is efficient on Intel (1 uop, 3c latency) but not AMD. It can expand a 32-bit to a 64-bit integer with zeros in between. (BMI2 is available on Haswell and later, and on AMD Zen and later, but `pdep`/`pext` are very slow on Zen) Commented Jul 29, 2020 at 20:37
• @PeterCordes Zen3 and up PDEP and PEXT are fast again.
– orlp
Commented Mar 6 at 17:57

To make saolof's answer concrete, the following is an implementation using the CLMUL instruction set, interleaving two pairs of `uint32_t`s per call:

``````#include <immintrin.h>
#include <stdint.h>

typedef struct {
uint32_t x;
uint32_t y;
} uint32_2;

static inline void interleave_clmul(uint32_2 *input, uint64_t *out) {
__m128i xy = _mm_load_si128((const __m128i *)input);

xy = _mm_shuffle_epi32(xy, 0b11011000);

// Two carryless multiplies
__m128i p2 = _mm_clmulepi64_si128(xy, xy, 0x11);
__m128i p1 = _mm_clmulepi64_si128(xy, xy, 0x00);

// Bitwise interleave the results
p2 = _mm_slli_epi16(p2, 1);
__m128i p3 = _mm_or_si128(p1, p2);

_mm_storeu_si128((__m128i *)out, p3);
}
``````

That compiles down to the following:

``````interleave_clmul(uint32_2*, unsigned long*):
vpshufd         xmm0, xmmword ptr [rdi], 216    # xmm0 = mem[0,2,1,3]
vpclmulqdq      xmm1, xmm0, xmm0, 17
vpclmulqdq      xmm0, xmm0, xmm0, 0
vpor            xmm0, xmm0, xmm1
vmovdqu         xmmword ptr [rsi], xmm0
ret
``````

Replace `_mm_load_si128` with `_mm_loadu_si128` if your data is not aligned--unaligned loads aren't that much slower on x86 anyway. This system is faster than the corresponding implementation with `pdep` instructions in terms of throughput.

``````Naive
Total rdtsc: 1295559857, iterations: 1000, count: 10000
clmul-based
Total rdtsc: 17751716, iterations: 1000, count: 10000
pdep-based
Total rdtsc: 26123417, iterations: 1000, count: 10000
pdep-based unrolled
Total rdtsc: 24281811, iterations: 1000, count: 10000
``````

Turbo boost was disabled; CPU is a 1.60 GHz base clock Kaby Lake. Results seem consistent across runs. (Results on other architectures would be nice.) The (somewhat messy) testing code:

``````
#include <stdio.h>
#include <inttypes.h>
#include <string.h>
#include <stdlib.h>
#include <immintrin.h>
// rdtscp
#include <x86intrin.h>

typedef struct uint32_2 {
uint32_t x;
uint32_t y;
} uint32_2;

uint32_2* generate_pairs(const int count) {
uint32_2* p = malloc(count * sizeof(uint32_2));

uint32_t r = 401923091;
#define RNG r *= 52308420; r += 2304;

for (int i = 0; i < count; ++i) {
p[i].x = r;
RNG RNG
p[i].y = r;
RNG RNG
}

return p;
}

void interleave_naive(uint64_t* dst, uint32_2* src, int count) {
for (int i = 0; i < count; ++i) {
struct uint32_2 s = src[i];
uint32_t x = s.x, y = s.y;

uint64_t result = 0;
for (int k = 0; k < 32; ++k) {
if (x & ((uint32_t)1 << k)) {
result |= (uint64_t)1 << (2 * k);
}

if (y & ((uint32_t)1 << k)) {
result |= (uint64_t)1 << (2 * k + 1);
}
}

dst[i] = result;
}
}

void interleave_pdep(uint64_t* dst, uint32_2* src, int count) {
for (int i = 0; i < count; ++i) {
struct uint32_2 s = src[i];
uint32_t x = s.x, y = s.y;

uint64_t result = _pdep_u64(x, 0x5555555555555555) | _pdep_u64(y, 0xaaaaaaaaaaaaaaaa);

dst[i] = result;
}
}

void interleave_pdep_unrolled(uint64_t* dst, uint32_2* src, int count) {
for (int i = 0; i < count; i += 2) {
struct uint32_2 s1 = src[i];
struct uint32_2 s2 = src[i + 1];

uint32_t x1 = s1.x, y1 = s1.y;
uint32_t x2 = s2.x, y2 = s2.y;

uint64_t result1 = _pdep_u64(x1, 0x5555555555555555) | _pdep_u64(y1, 0xaaaaaaaaaaaaaaaa);
uint64_t result2 = _pdep_u64(x2, 0x5555555555555555) | _pdep_u64(y2, 0xaaaaaaaaaaaaaaaa);

dst[i] = result1;
dst[i + 1] = result2;
}
}

void interleave_clmul(uint64_t* dst, uint32_2* src, int count) {
uint32_2* end = src + count;
uint64_t* out = dst;

for (uint32_2* p = src; p < end; p += 2, out += 2) {
__m128i xy = _mm_load_si128((const __m128i *) p);

xy = _mm_shuffle_epi32(xy, 0b11011000);

__m128i p2 = _mm_clmulepi64_si128(xy, xy, 0x11);
__m128i p1 = _mm_clmulepi64_si128(xy, xy, 0x00);

p2 = _mm_slli_epi16(p2, 1);
__m128i p3 = _mm_or_si128(p1, p2);

_mm_store_si128((__m128i *)out, p3);
}
}

#define ITERATIONS 1000

void time_inv(uint32_2* pairs, int count, void (*interleave) (uint64_t*, uint32_2*, int)) {
uint64_t* result = malloc(count * sizeof(uint64_t));
uint64_t* reference_result = malloc(count * sizeof(uint64_t));

interleave_naive(reference_result, pairs, count);
// Induce page faults
memset(result, 0, count * sizeof(uint64_t));

unsigned _;
int64_t start_rdtsc = __rdtscp(&_);
for (int i = 0; i < ITERATIONS; ++i) {
interleave(result, pairs, count);
}
int64_t end_rdtsc = __rdtscp(&_);

for (int i = 0; i < count; ++i) {
if (reference_result[i] != result[i]) {
fprintf(stderr, "Incorrect value at index %d; got %" PRIx64 ", should be %" PRIx64 "\n", i, result[i], reference_result[i]);
abort();
}
}

printf("Total rdtsc: %" PRId64 ", iterations: %d, count: %d\n", end_rdtsc - start_rdtsc, ITERATIONS, count);

free(result);
}

int main() {
const int count = 10000;
uint32_2* pairs = generate_pairs(count);

printf("Naive\n");
time_inv(pairs, count, interleave_naive);
printf("clmul-based\n");
time_inv(pairs, count, interleave_clmul);
printf("pdep-based\n");
time_inv(pairs, count, interleave_pdep);
printf("pdep-based unrolled\n");
time_inv(pairs, count, interleave_pdep_unrolled);

free(pairs);
}
``````

Compile with `gcc bleh.c -o bleh -O2 -march=native`.

Perf stats for each implementation are below. CLMUL seems to do 1.5c/pair, bottlenecking on port 5 contention by 2 `pclmulqdq` and 1 `vpshufd`, while the pdep implementations bottleneck on port 1, on which `pdep` executes, resulting in 2c/pair:

``````clmul-based
Total rdtsc: 1774895925, total milliseconds: 985.575000, iterations: 100000, count: 10000

Performance counter stats for './interleave':

556,602,052      uops_dispatched_port.port_0                                     (49.87%)
1,556,592,314      cycles                                                        (49.86%)
469,021,017      uops_dispatched_port.port_1                                     (49.86%)
472,968,452      uops_dispatched_port.port_2                                     (50.08%)
519,804,531      uops_dispatched_port.port_3                                     (50.13%)
499,980,587      uops_dispatched_port.port_4                                     (50.14%)
1,509,928,584      uops_dispatched_port.port_5                                     (50.14%)
1,484,649,884      uops_dispatched_port.port_6                                     (49.92%)

pdep-based
Total rdtsc: 2588637876, total milliseconds: 1438.065000, iterations: 100000, count: 10000

Performance counter stats for './interleave':

745,844,862      uops_dispatched_port.port_0                                     (50.02%)
2,289,048,624      cycles                                                        (50.02%)
2,033,116,738      uops_dispatched_port.port_1                                     (50.02%)
1,508,870,090      uops_dispatched_port.port_2                                     (50.02%)
1,498,920,409      uops_dispatched_port.port_3                                     (49.98%)
1,056,089,339      uops_dispatched_port.port_4                                     (49.98%)
843,399,033      uops_dispatched_port.port_5                                     (49.98%)
1,414,062,891      uops_dispatched_port.port_6                                     (49.98%)

pdep-based unrolled
Total rdtsc: 2387027127, total milliseconds: 1325.857000, iterations: 100000, count: 10000

Performance counter stats for './interleave':

532,577,450      uops_dispatched_port.port_0                                     (49.64%)
2,099,782,071      cycles                                                        (49.94%)
2,004,347,972      uops_dispatched_port.port_1                                     (50.24%)
1,532,203,395      uops_dispatched_port.port_2                                     (50.54%)
1,467,988,364      uops_dispatched_port.port_3                                     (50.36%)
1,701,095,132      uops_dispatched_port.port_4                                     (50.06%)
543,597,866      uops_dispatched_port.port_5                                     (49.76%)
930,460,812      uops_dispatched_port.port_6                                     (49.46%)
``````
• It's non-obvious that CLMUL would be faster on Haswell; it's 3 uops there, with 2c throughput (`2*p0+1*p5` - uops.info) to produce 128 bits of output vs. `pdep` being 1 uop with 1c throughput (3c latency) to produce 64 bits. (And an `lea` to interleave, if you write the source with `pdep(x,mask) + (pdep(y,mask)<<1)`. For `|` to be fast, you'd need 2 different pdep constants to avoid a shift). For a single pair of 32-bit inputs, we only need a 64-bit constant, and 2x `pdep` + `lea`. For a big array, I'd expect about equal. Commented Jul 20, 2022 at 0:54
• CLMUL is great on Broadwell and later (1 uop, 1c throughput), or 3 uops (2c throughput) for the YMM/ZMM version on Ice Lake. Then down to 1 uop again for the YMM/ZMM version on Alder Lake. On AMD, it's 4 uops (2c throughput not fully pipelined) for the XMM version on Zen1/2/3 (and the YMM version which is new in Zen3). uops.info. But `pdep` is disastrously slow on Zen 1/2, only having proper hw support in Zen3. Commented Jul 20, 2022 at 1:04
• @PeterCordes I encourage you to benchmark it; I don't remember this answer well and I might have only used _pdep_u32, which would be unfortunate. Commented Jul 20, 2022 at 3:25
• I don't have a Haswell to benchmark on, only a Skylake. But `pdep` performance is the same on SKL, so I could look at cycles per pair. 2 cycles per pair of uint32_t inputs would be the theoretical best case. (2x load + 2x pdep + lea + store is 6 uops even without loop overhead, but has 2c throughput so there's room for loop overhead.) 2.27 sounds reasonable in practice. Commented Jul 20, 2022 at 3:37
• Damn you're good; 1.5 cycles it is. Indeed rdtsc and the actual frequency are not the same even with turbo disabled; will investigate tmrw morning. Commented Jul 20, 2022 at 6:09

Would a short, precalculated array lookup count as a "mathematical trick"?

Precalculate an array of 256 `uint16_t`s:

``````static const uint16_t lookup[256]={0x0000, 0x0001, 0x0005 ..., 0x5555};
``````

We can interleave two eight-bit values, and come up with a 16 bit value easily:

``````uint16_t interleave(uint8_t a, uint8_t b)
{
return (lookup[a] << 1) | lookup[b];
}
``````

How to extend this to interleave two 32-bit values into a 64-bit value should be obvious: call this four times, for each one of the four bytes that make up a `uint32_t`, then `<<` an `|` the results together. Bribe the compiler to inline the whole thing, and the end result should be fairly quick and cheap.

Since RAM is cheap these days, you might want to consider a precalculated table of 65536 `uint32_t`s, also.

• RAM is cheap; cache-misses aren't. Most programs area already bottlenecked on memory more than CPU. This might win a microbenchmark where no other code uses up your cache footprint, but it won't win in real life unless this operation happens in bursts in a really tight loop. Commented Sep 14, 2016 at 13:57
• It's still a good idea in some cases. I need to interleave two bytes, but doing it through 2 lookups of the upper and lower 4-bit nibbles of each byte might be worth it. Commented Jan 3, 2020 at 14:02
• @MadsY: Indeed, 4-bit LUTs (16x 1-byte entries) are small enough to actually stay hot in cache reliably, and can be a good tradeoff between memory and computation (and + shift to isolate each nibble, OR to combine). Commented Jul 29, 2020 at 19:49