Performance Comparison of SWC and Babel
JavaScript is single-threaded. The JS thread is not a good place to do heavy computation. Let's talk about babel and swc, which are both computation-heavy.
Synchronous Benchmark
Let's do a benchmark for the single-core workload. Note this uses transformSync, which is rarely useful in the wild.
[transform]
swc (es3) x 616 ops/sec ±4.36% (88 runs sampled)
swc (es2015) x 677 ops/sec ±2.01% (90 runs sampled)
swc (es2016) x 1,963 ops/sec ±0.45% (93 runs sampled)
swc (es2017) x 1,971 ops/sec ±0.35% (94 runs sampled)
swc (es2018) x 2,555 ops/sec ±0.35% (93 runs sampled)
swc-optimize (es3) x 645 ops/sec ±0.40% (90 runs sampled)
babel (es5) x 34.05 ops/sec ±1.15% (58 runs sampled)SWC is very fast. Although swc (es3) does more work than babel (es5), swc (es3) is faster than babel (es5).
Real-World Benchmark
transformSync and transformFileSync are rarely used in the real world, as it blocks the current thread. await Promise.all() is frequently used as is better than:
for (const promise in promises) {
await promise;
}Let's create a benchmark for actual real-world usage using Promise.all().
Ideal Case
First, I created a benchmark for the ideal case. It invokes [n] promises at once where n is the number of physical CPU cores. See node-swc repository (opens in a new tab) for the full code.
const os = require("os");
const cpuCount = os.cpus().length;
const SOURCE = `
// See the link above
`;
const SUITES = [
// ...
// See the link above
];
const arr = [];
for (let i = 0; i < cpuCount / 2; i++) {
arr.push(0);
}
console.info(`CPU Core: ${cpuCount}; Parallelism: ${arr.length}`);
console.info(
`Note that output of this benchmark should be multiplied by ${arr.length} as this test uses Promise.all`
);
SUITES.map(args => {
const [name, requirePath, fn] = args;
const func = fn.bind(null, require(requirePath));
bench(name, async done => {
await Promise.all(arr.map(v => func()));
done();
});
});I ran benchmarks on my old desktop. It has E3-v1275 and 24GB of ram. The output below is copied as-is from benchmark output.
CPU Core: 8; Parallelism: 4
Note that output of this benchmark should be multiplied by 4 as this test uses Promise.all
[multicore]
swc (es3) x 426 ops/sec ±3.75% (73 runs sampled)
swc (es2015) x 422 ops/sec ±3.57% (74 runs sampled)
swc (es2016) x 987 ops/sec ±2.53% (75 runs sampled)
swc (es2017) x 987 ops/sec ±3.44% (75 runs sampled)
swc (es2018) x 1,221 ops/sec ±2.46% (77 runs sampled)
swc-optimize (es3) x 429 ops/sec ±1.94% (82 runs sampled)
babel (es5) x 6.82 ops/sec ±17.18% (40 runs sampled)Now, we need to multiply it by 4, as we do 4 operations per iteration.
swc (es3) x 1704 ops/sec ±3.75% (73 runs sampled)
swc (es2015) x 1688 ops/sec ±3.57% (74 runs sampled)
swc (es2016) x 3948 ops/sec ±2.53% (75 runs sampled)
swc (es2017) x 3948 ops/sec ±3.44% (75 runs sampled)
swc (es2018) x 4884 ops/sec ±2.46% (77 runs sampled)
swc-optimize (es3) x 1716 ops/sec ±1.94% (82 runs sampled)
babel (es5) x 27.28 ops/sec ±17.18% (40 runs sampled)This is an actual result.
The performance of babel (es5) is dropped. Async is not free. Even though, 34.05 ops/sec => 27.28 ops/sec is much better than I expected.
Benchmark for Many Operations
I modified the benchmark file slightly to make it creates 100 promises per iteration.
CPU Core: 8; Parallelism: 100
Note that output of this benchmark should be multiplied by 100 as this test uses Promise.all
[multicore]
swc (es3) x 21.99 ops/sec ±1.83% (54 runs sampled)
swc (es2015) x 19.11 ops/sec ±3.39% (48 runs sampled)
swc (es2016) x 55.80 ops/sec ±6.97% (71 runs sampled)
swc (es2017) x 62.59 ops/sec ±2.12% (74 runs sampled)
swc (es2018) x 81.08 ops/sec ±5.22% (75 runs sampled)
swc-optimize (es3) x 18.60 ops/sec ±2.13% (50 runs sampled)
babel (es5) x 0.32 ops/sec ±19.10% (6 runs sampled)It must be multiplied by 100 as above.
swc (es3) x 2199 ops/sec ±1.83% (54 runs sampled)
swc (es2015) x 1911 ops/sec ±3.39% (48 runs sampled)
swc (es2016) x 5580 ops/sec ±6.97% (71 runs sampled)
swc (es2017) x 6259 ops/sec ±2.12% (74 runs sampled)
swc (es2018) x 8108 ops/sec ±5.22% (75 runs sampled)
swc-optimize (es3) x 1860 ops/sec ±2.13% (50 runs sampled)
babel (es5) x 32 ops/sec ±19.10% (6 runs sampled)Why does the performance of SWC not drop drastically? The secret is Node.js. Node.js internally manages a worker thread pool, and SWC runs on it. Thus, even though you create 100 promises at once, the number of worker threads is much smaller than it.
Conclusion
| name | 1 core, sync | 4 promises | 100 promises |
|---|---|---|---|
| swc (es3) | 616 ops/sec | 1704 ops/sec | 2199 ops/sec |
| swc (es2015) | 677 ops/sec | 1688 ops/sec | 1911 ops/sec |
| swc (es2016) | 1963 ops/sec | 3948 op s/sec | 5580 ops/sec |
| swc (es2017) | 1971 ops/sec | 3948 ops/sec | 6259 ops/sec |
| swc (es2018) | 2555 ops/sec | 4884 ops/sec | 8108 ops/sec |
| swc-optimize (es3) | 645 ops/sec | 1716 ops/sec | 1860 ops/sec |
| babel (es5) | 34.05 ops/sec | 27.28 ops/sec | 32 ops/sec |
swc scales well, as it does almost all work in the worker thread. From the fact that the throughput of 100 promises was better than 4 promises, we can conclude that the worker thread pool of Node.js utilizes hyperthreading.
swc scales up with the number of cpu cores. Promise.all is enough for scaling.