The actual fastest implementation **for a ***large* array on modern x86 CPUs would be

**change the MXCSR FP rounding mode to round towards -Infinity (aka **`floor`

). In C, this should be possible with `fenv`

stuff, or `_mm_getcsr`

/ `_mm_setcsr`

.
loop over the array doing `_mm_cvtps_epi32`

on SIMD vectors, converting 4 `float`

s to 32-bit integer using the current rounding mode. (And storing the result vectors to the destination.)

`cvtps2dq xmm0, [rdi]`

is a single micro-fused uop on any Intel or AMD CPU since K10 or Core 2. (https://agner.org/optimize/) Same for the 256-bit AVX version, with YMM vectors.

- restore the current rounding mode to the normal IEEE default mode, using the original value of the MXCSR. (round-to-nearest, with even as a tiebreak)

**This allows loading + converting + storing 1 SIMD vector of results per clock cycle, just as fast as with truncation**. (SSE2 has a special FP->int conversion instruction for truncation, exactly because it's very commonly needed by C compilers. In the bad old days with x87, even `(int)x`

required changing the x87 rounding mode to truncation and then back. `cvttps2dq`

for packed float->int with truncation (note the extra `t`

in the mnemonic). Or for scalar, going from XMM to integer registers, `cvttss2si`

or `cvttsd2si`

for scalar `double`

to scalar integer.

With some loop unrolling and/or good optimization, this should be possible without bottlenecking on the front-end, just 1-per-clock store throughput assuming no cache-miss bottlenecks. (And on Intel before Skylake, also bottlenecked on 1-per-clock packed-conversion throughput.) i.e. **16, 32, or 64 bytes per cycle, using SSE2, AVX, or AVX512.**

Without changing the current rounding mode, you need SSE4.1 `roundps`

to round a `float`

to the nearest integer `float`

using your choice of rounding modes. Or you could use one of the tricks shows in other answers that work for floats with small enough magnitude to fit in a signed 32-bit integer, since that's your ultimate destination format anyway.)

(With the right compiler options, like `-fno-math-errno`

, and the right `-march`

or `-msse4`

options, compilers can inline `floor`

using `roundps`

, or the scalar and/or double-precision equivalent, e.g. `roundsd xmm1, xmm0, 1`

, but this costs 2 uops and has 1 per 2 clock throughput on Haswell for scalar or vectors. Actually, gcc8.2 will inline `roundsd`

for `floor`

even without any fast-math options, as you can see on the Godbolt compiler explorer. But that's with `-march=haswell`

. It's unfortunately not baseline for x86-64, so you need to enable it if your machine supports it.)