Meta is no­ti­fy­ing thou­sands of peo­ple whose Instagram ac­counts were hi­jacked dur­ing the months-long abuse of the com­pa­ny’s AI chat­bot, which hack­ers re­peat­edly tricked into tak­ing con­trol of a per­son’s ac­count.

In a new data breach no­ti­fi­ca­tion let­ter, seen by this week in se­cu­rity, Meta has re­vealed for the first time how many peo­ple had their ac­counts hi­jacked as part of the long-run­ning hack­ing cam­paign, which was dis­cov­ered ear­lier this week and first re­ported by 404 Media ($) and TechCrunch ($). The num­ber of af­fected ac­counts gives some clar­ity as to how wide­spread this hack­ing cam­paign was, and for how long it op­er­ated.

According to the data breach no­tice filed with Maine’s at­tor­ney gen­er­al’s of­fice late on Friday, Meta no­ti­fied at least 20,225 peo­ple that their ac­counts had been com­pro­mised, in­clud­ing 30 peo­ple in Maine.

The com­pro­mises al­lowed the hack­ers to take over the per­son’s en­tire Instagram and any linked ac­counts, in­clud­ing ob­tain­ing con­tact in­for­ma­tion, dates of birth, and pro­file in­for­ma­tion, as well as the abil­ity to ac­cess the per­son’s posts, di­rect mes­sages, and ac­count ac­tiv­ity, the no­tice reads.

Meta’s no­tice con­firmed that the breach re­lates to “a vul­ner­a­bil­ity in an AI-assisted ac­count re­cov­ery sys­tem for Instagram,” which was ex­ploited to “perform pass­word re­sets on Instagram user ac­counts.”

As pre­vi­ously re­ported, hack­ers abused a flaw in Meta’s chat­bot that al­lowed any­one to re­set the pass­word of any ac­count that did not have two-fac­tor au­then­ti­ca­tion switched on. The bug tricked the chat­bot into send­ing a ver­i­fi­ca­tion code to an email ad­dress con­trolled by the hacker, rather than the ac­count hold­er’s email ad­dress on file, sim­ply by ask­ing it. The chat­bot com­plied any­way.

“The tool it­self worked prop­erly and func­tioned as in­tended; how­ever due to a bug in a sep­a­rate code path, the sys­tem did not prop­erly ver­ify that the email ad­dress pro­vided by the in­di­vid­ual re­quest­ing a pass­word re­set matched the email ad­dress as­so­ci­ated with that user’s Instagram ac­count,” said Meta in its breach no­tice.

“As a re­sult, when an in­di­vid­ual pro­vided an email ad­dress not pre­vi­ously as­so­ci­ated with the ac­count, the sys­tem in­cor­rectly sent a pass­word re­set link to that unas­so­ci­ated email rather than re­ject­ing the re­quest. This al­lowed unau­tho­rized third par­ties to re­ceive a pass­word re­set link for ac­counts they did not own,” the com­pany added.

At this point, Meta says, the hack­ers could re­set some­one’s pass­word and take over their ac­count as if they were the right­ful owner.

Meta said that it is “unaware” of what, if any, per­sonal in­for­ma­tion was ac­cessed dur­ing the hacks. (An email to Meta’s press line ask­ing for clar­ity on this was un­re­turned as of early Saturday.)

According to Maine’s list­ing, the hacks be­gan around April 17 and lasted un­til this week, when Meta said that it had se­cured the chat­bot. Instagram re­port­edly started no­ti­fy­ing af­fected in­di­vid­u­als ear­lier this week by send­ing a pass­word re­set no­ti­fi­ca­tion, even as some re­ported that the hacks were on­go­ing.

Meta also con­firmed in the no­tice that it alerted users to se­cure their ac­counts, say­ing it “instructed im­pacted users to re­set their pass­words and re-au­then­ti­cate through se­cure, ver­i­fied chan­nels.”

Meta said that it has dis­abled the AI chat­bot for now and re­moved the code path that al­lowed the chat­bot to re­set user ac­counts, and said it’s also check­ing other chat­bots across its plat­forms to pre­vent a re­peat in­ci­dent. It’s not yet clear what cir­cum­stances led up to the chat­bot be­ing abused, but comes soon af­ter Meta laid off thou­sands of em­ploy­ees while re­ward­ing top ex­ec­u­tives with stock in­cen­tives, as the com­pany con­tin­ues to dou­ble-down on AI.

~ ~

Thank you so much for read­ing ~this week in se­cu­rity~. If you liked this ar­ti­cle, please share it! Feel free to reach out with any feed­back, ques­tions, or com­ments about this ar­ti­cle: this@weekin­se­cu­rity.com.

WASHINGTON — The Pentagon is in­creas­ingly con­cerned about Israel ramp­ing up its spy­ing on the U.S., re­cently rais­ing the coun­ter­in­tel­li­gence threat level from America’s top ally in the Middle East to the high­est level, ac­cord­ing to two U.S. of­fi­cials and one for­mer U.S. of­fi­cial.

The Pentagon’s Defense Intelligence Agency in re­cent weeks is­sued the new coun­ter­in­tel­li­gence threat as­sess­ment amid ris­ing ten­sions be­tween Israel and the U.S. over the way for­ward in the war with Iran, the of­fi­cials said. They said the DIA posted an in­ter­nal mes­sage, viewed by one of the cur­rent of­fi­cials, that raised the level for Israel to “critical.”

The des­ig­na­tion stems from con­cerns within the Pentagon that Israel is mak­ing a par­tic­u­lar ef­fort to sur­veil top U.S. of­fi­cials to get in­for­ma­tion on the Trump ad­min­is­tra­tion’s in­ter­nal de­lib­er­a­tions and de­ci­sion-mak­ing on the con­flicts in the Middle East, the of­fi­cials said.

The DIA as­sess­ment in­cludes a seven-page doc­u­ment and fea­tures a chart, ac­cord­ing to one of the cur­rent U.S. of­fi­cials. The doc­u­ment says the as­sess­ment of Israel is that its abil­ity to con­duct hu­man es­pi­onage and tech­ni­cal col­lec­tion is at a “critical level,” ac­cord­ing to the of­fi­cial.

It also iden­ti­fies a se­ries of spe­cific in­ci­dents that height­ened U.S. con­cerns, the of­fi­cial said.

A spokesper­son for the Israeli Embassy in Washington, D.C., said in a state­ment that it is “completely false” that Israel spies on the U.S. “Israel does not gather in­tel­li­gence on American en­ti­ties, let alone US gov­ern­ment of­fi­cials,” the spokesper­son said. “Israel in­tel­li­gence col­lec­tion ef­forts are aimed at its en­e­mies, not its al­lies. Any claims to the con­trary are ei­ther mis­in­formed or po­lit­i­cally mo­ti­vated.”

The Pentagon de­clined to com­ment.

A White House of­fi­cial said in a state­ment, “This en­tire story is false and sourced to some­one who does­n’t have any knowl­edge of what’s go­ing on.”

The Office of the Director of National Intelligence, which over­sees all the U.S. in­tel­li­gence agen­cies in­clud­ing the DIA, did not re­spond to a re­quest for com­ment.

While it is com­mon­place for al­lies and ad­ver­saries across the globe to spy on each other, the cur­rent and for­mer U.S. of­fi­cials said Israel’s re­cent ef­forts have gone well be­yond what is typ­i­cal and ex­pected es­pi­onage. The of­fi­cials did not know if a spe­cific in­ci­dent trig­gered the DIA’s de­ci­sion to raise the coun­ter­in­tel­li­gence threat level.

The height­ened alert comes as President Donald Trump and Israeli Prime Minister Benjamin Netanyahu have clashed over the war with Iran and Israel’s mil­i­tary op­er­a­tions in Lebanon, in­clud­ing in a tense phone call this past week, NBC News re­ported. Trump ac­knowl­edged af­ter­ward to re­porters that he called Netanyahu “crazy” dur­ing the call as ques­tions mount about whether the two coun­tries’ ob­jec­tives in the Middle East are be­gin­ning to sig­nif­i­cantly di­verge.

Since a cease­fire deal was reached in early April, Trump has been pur­su­ing a diplo­matic deal with Iran to end the war Israel and the U.S. launched on Feb. 28. Israel has pub­licly ex­pressed skep­ti­cism that Iran would abide by any ne­go­ti­ated deal. Netanyahu has pushed for a re­sump­tion of bomb­ing raids against Iran and dis­agreed with Trump, who has pressed him to scale back at­tacks against Hezbollah in Lebanon, ac­cord­ing to Western of­fi­cials.

Israel is keenly in­ter­ested in whether Trump de­cides to re­sume ma­jor com­bat op­er­a­tions against Iran or to end the con­flict, the cur­rent and for­mer U.S. of­fi­cials and out­side ex­perts said.

The most prac­ti­cal out­come for the Pentagon is that U.S. of­fi­cials will use ex­tra cau­tion when trav­el­ing to Israel or vis­it­ing with Israeli of­fi­cials, the cur­rent and for­mer U.S. of­fi­cials said. They said there did not ap­pear to be any im­pact on the high-level in­tel­li­gence-shar­ing that oc­curs on a daily ba­sis be­tween the two coun­tries, par­tic­u­larly as­so­ci­ated with the Iran war.

“The U.S. al­ready takes ex­tra pre­cau­tions when vis­it­ing Israel,” one of the cur­rent U.S. of­fi­cials said. “They’re well-known to ag­gres­sively col­lect.”

The U.S., like other coun­tries, main­tains elab­o­rate coun­ter­in­tel­li­gence, or “spy catcher,” ef­forts to pre­vent and track es­pi­onage by for­eign ad­ver­saries as well as by al­lies and part­ners, seek­ing to safe­guard state se­crets and mon­i­tor at­tempts to re­cruit or co­erce U.S. of­fi­cials. Under U.S. law, the FBI has the lead­ing role in coun­ter­in­tel­li­gence ef­forts, but they also in­volve a range of gov­ern­ment agen­cies and the mil­i­tary.

According to cur­rent and for­mer diplo­mats and for­mer na­tional se­cu­rity of­fi­cials, Israel for years has had a rep­u­ta­tion for ag­gres­sive es­pi­onage even against the U.S., its clos­est ally. It’s a prac­tice that has long raised con­cerns among na­tional se­cu­rity and diplo­matic of­fi­cials, and U.S. in­tel­li­gence of­fi­cials closely mon­i­tor the is­sue, ac­cord­ing to ex­perts and the cur­rent and for­mer U.S. of­fi­cials.

Top U.S. of­fi­cials of­ten take ex­tra care when trav­el­ing to Israel, some­times us­ing burner phones and com­put­ers and tak­ing ex­treme cau­tion when speak­ing in ho­tel rooms dur­ing of­fi­cial trips, the cur­rent and for­mer U.S. of­fi­cials and ex­perts said.

Israel has “a hy­per-ag­gres­sive in­tel­li­gence ser­vice,” said Emily Harding, vice pres­i­dent of the Defense and Security Department and di­rec­tor of the in­tel­li­gence, na­tional se­cu­rity and tech­nol­ogy pro­gram at the Center for Strategic and International Studies, a think tank in Washington. “They are ex­ceed­ingly in­ter­ested in what we are up to,” Harding said of the Israelis.

In the 1980s, spy­ing by Israel caused a rift with Washington, with U.S. Navy in­tel­li­gence an­a­lyst Jonathan Pollard spend­ing 30 years in prison af­ter he was found to have sold suit­cases of top-se­cret doc­u­ments to Israel.

The U.S. also spies on its al­lies and seeks to gather in­tel­li­gence on for­eign part­ners, as ev­i­denced in 2013 by leaks from in­tel­li­gence con­trac­tor Edward Snowden.

Those leaks showed that the U.S. was eaves­drop­ping on European lead­ers, in­clud­ing then-Ger­man Chancellor Angela Merkel’s mo­bile phone, spark­ing out­rage in Berlin.

The U.S. and Israel re­main close al­lies, and the two coun­tries’ in­tel­li­gence ser­vices have forged a close work­ing re­la­tion­ship over decades. But con­cerns about pos­si­ble Israeli es­pi­onage at such a sen­si­tive mo­ment — when the two gov­ern­ments are not in full agree­ment about the war with Iran — carry the risk of un­der­min­ing trust be­tween the two coun­tries, two ad­di­tional for­mer U.S. of­fi­cials said.

ntsc-rs is a free, open-source video ef­fect which ac­cu­rately em­u­lates ana­log TV and VHS ar­ti­facts.

Other pop­u­lar ef­fects eye­ball the look of VHS tapes us­ing sim­ple color lookup ta­bles and over­lays. ntsc-rs uses al­go­rithms that model how NTSC trans­mis­sion and VHS en­cod­ing ac­tu­ally work, based on al­go­rithms de­vel­oped in com­pos­ite-video-sim­u­la­tor, zhuker/​ntsc, and ntscQT.

ntsc-rs is writ­ten in Rust, and is mul­ti­threaded and SIMD-accelerated. Unlike sim­i­lar ef­fects such as ntscQT, it can run in real time at much higher res­o­lu­tions than ac­tual NTSC footage.

ntsc-rs is avail­able not just as a stand­alone and web ap­pli­ca­tion, but also as a plu­gin for After Effects, Premiere, and all OpenFX-compatible soft­ware. This in­cludes DaVinci Resolve, Hitfilm, and Vegas.

06 Jun, 2026

I’m a soft­ware en­gi­neer, com­plet­ing 10 years of pro­fes­sional ex­pe­ri­ence this year. I started my ca­reer as a web fron­tend en­gi­neer (it was eas­ier for me to de­bug fron­tend code back then, so I chose that path), but shortly tran­si­tioned to (web) back­end and never looked back.

Through a se­ries of co­in­ci­dences, once I stepped into back­end de­vel­op­ment, I ended up work­ing in soft­ware de­vel­op­ment roles in the do­mains of fi­nance, book­keep­ing and pay­ment pro­cess­ing, where I had great au­ton­omy and a close and can­did re­la­tion­ship with Product Managers and stake­hold­ers.

I learnt a lot about the do­main and how to ef­fec­tively write pro­grams for it: PCI com­pli­ance, dou­ble-en­try ledgers, es­crows, rec­on­cil­i­a­tion, pay­ment life­cy­cles, bank trans­fer idem­po­tency, etc.

It was, then, ob­vi­ous that I should fo­cus my ca­reer on be­com­ing an ex­pert on that do­main to stand out as a pro­fes­sional and dif­fer­en­ti­ate my­self in a field that showed signs of an in­creas­ing need for do­main spe­cial­ists.

The first pil­lar to erode: do­main-spe­cific knowl­edge

Last year, I got hired by a com­pany in the fi­nance work­space. So far, I had worked on com­pa­nies that do have a strong pay­ment and fi­nance com­po­nent to their op­er­a­tions/​of­fer­ings, but that were not solely fi­nance-fo­cused com­pa­nies.

That com­pany also em­braced AI whole­heart­edly, so I got ChatGPT and Claude Enterprise ac­counts from day one and was en­cour­aged to use them for my re­search, ex­plo­ration, and even cod­ing, al­beit with a warn­ing that I should still re­view and own every sin­gle line that made it into pro­duc­tion.

One of my first pro­jects in­volved re­work­ing the legacy on­line pay­ment sys­tem, which was a mess. They hired me for (among other things) my pre­vi­ous ex­pe­ri­ence in build­ing that and trusted me with the task.

Different from the other com­pa­nies I had worked for so far, they wanted the “Design Docs” I write be­fore cod­ing to be read­able by both en­gi­neers and prod­uct man­agers - so they should­n’t be a tech­ni­cal deep dive and more of an ar­chi­tec­tural view. I wrote my first one with min­i­mal AI as­sis­tance - I even called LLMs “stochastic par­rots” at the time, a view I no longer hold - and de­liv­ered it.

I val­ued my knowl­edge and thought no LLMs could re­place it.

Then my man­ager reached out to me: even though you’re de­liv­er­ing code at a good pace, you’re tak­ing too long to de­liver those Design Docs. Are you us­ing AI? You should use more AI.

“No way this will work”, I thought in my head, but agreed. The mod­els at that time were not as good as the ones we have now, but they did pro­vide a good speed-up on my writ­ing and even the de­ci­sion-mak­ing.

And then I started re­al­iz­ing: all the knowl­edge I have ac­cu­mu­lated over the years: the trade-offs be­tween im­ple­men­ta­tions, how ac­quir­ing works, how to struc­ture idem­po­tency to pre­vent dou­ble-charges, every­thing, was be­com­ing use­less. Even though the mod­els still needed some steer­ing, they could con­nect the dots on how to struc­ture such sys­tems, which was the hard­est part that only de­vel­ops in your brain af­ter years of hands-on ex­pe­ri­ence. That was my first shock.

But sure, I thought, they can do that be­cause there’s plenty of ar­ti­cles on the web on how that shit works along with all the tech­ni­cal doc­u­men­ta­tion, and we have blog posts ex­plain­ing how to ap­ply the tech­ni­cal tools to the do­main. For hu­mans, it may take a long time to learn all that, but that’s train­ing data so the mod­els can pick it up.

What the mod­els will never be good at, and that’s where hu­mans will shine, is de­bug­ging! I had ac­cu­mu­lated a good ex­pe­ri­ence de­bug­ging race con­di­tions and dis­trib­uted sys­tems in pro­duc­tion. That was my ticket to long-term em­ploy­a­bil­ity.

The sec­ond pil­lar to erode: de­bug­ging and dis­trib­uted sys­tems

So, af­ter LLMs started get­ting good at writ­ing docs and help­ing plan the ac­tual im­ple­men­ta­tions, they be­came good at cod­ing. It started in the sec­ond half of 2025 with the Claude Code hype, then Codex came and so on. Although I was us­ing LLMs for writ­ing unit tests every day be­fore that, I was­n’t trust­ing them to write the full im­ple­men­ta­tion yet.

The nat­ural next step was to in­tro­duce more AI into writ­ing code. And hon­estly, I liked it. I like ship­ping things to pro­duc­tion and see­ing users happy as much as I like cod­ing, so I was trad­ing one thing that I like for an­other one that I also like, it was fair.

LLMs were be­com­ing good at cod­ing, but it still could­n’t de­bug the mess left be­hind (by then or by the hu­mans), so I still had a role that was big­ger than steer­ing the ro­bot - a ticket to em­ploy­a­bil­ity.

Everything seemed fine.

Then came the MCPs, the agen­tic work­flows and Claude 4.5 and the sky started to fall.

Claude 4.5, to be hon­est, was­n’t that good. It solved like 60% of the bugs given a stack trace and some con­text (a Sentry link with Sentry MCP en­abled was all it took in most cases). Sometimes it gave a so­lu­tion that sounded plau­si­ble but was to­tally wrong.

This time, how­ever, I stopped doubt­ing the ma­chines. I saw bugs that in the past would eas­ily take 1 day of full-time de­bug­ging be­ing one-shot­ted by Claude Code. Of course, not all of them yet, but the pat­tern was clear.

Then came 4.6, 4.7, GPT 5.5, Opus 4.8 and the DataDog MCP… Now I have CLIs that one-shots bugs across dis­trib­uted sys­tems for me. Bugs that I could­n’t solve in the past. Bugs that would take 2 days of full-time de­bug­ging. Bugs across dis­trib­uted sys­tems that lack dis­trib­uted ob­serv­abil­ity. 90% of the bugs are one-shot­ted now, in­clud­ing bizarre race con­di­tions, un­ex­pected cor­ner-cases, third-party in­te­gra­tion is­sues, un­doc­u­mented API edge cases, every­thing. I hardly have to in­ter­vene.

Of course, I’m still em­ploy­able be­cause some­one has to re­view the code and steer the ro­bot. But I’m just an­other off-the-shelf en­gi­neer now. I have no do­main ex­per­tise that an­other Sr. en­gi­neer steer­ing an LLM can­not match. All my fi­nance and pay­ment do­main ex­per­tise, all the de­bug­ging in­tu­ition and dis­trib­uted sys­tem knowl­edge earned through hours of sweat and tears, is now prompt­able.

We were taught that gen­er­al­ists and spe­cial­ists will al­ways have their roles. But now the mar­ket is shap­ing every­one into be­com­ing a gen­er­al­ist. That’s not a bad thing per se, un­til you look un­der the eco­nom­ics of sup­ply and de­mand: if every­one is a gen­er­al­ist, the price of a gen­er­al­ist falls if there’s no de­mand to match. And we all know the de­mand is dry­ing up.

The third pil­lar, the one that has­n’t eroded yet: code qual­ity and ar­chi­tec­ture

I still have one pil­lar stand­ing, though: code qual­ity and soft­ware ar­chi­tec­ture - what’s now be­ing re­duced to be­ing called “taste” 1.

Along the course of my ca­reer, I al­ways liked to refac­tor, al­ways prized good code, and ne­go­ti­ated time in the sprint for it. DDD, Hexagonal, Clean Architecture, you know all the buzz­words. I like this topic, I like to dis­cuss the trade-offs and dif­fer­ent ideas on how to shape code­bases. I re­ally like it.

This is the last pil­lar stand­ing. Except that no­body cares any­more.

Agents do a re­ally bad job at keep­ing code­bases or­ga­nized. If you don’t steer them, they’ll hit a cir­cu­lar de­pen­dency is­sue sooner than you think. Will du­pli­cate code. Add un­nec­es­sary com­ments. Mix up pure func­tions and side-ef­fects. Disregard the prin­ci­ples of SOLID.

That should keep hu­mans em­ployed, ex­cept that this skill is now be­ing re­duced to the word “taste”. But it’s not just a re­nam­ing, the in­dus­try is mov­ing to a world where code or­ga­ni­za­tion is less im­por­tant.

Sure, hu­mans should steer the agent to pre­vent spaghetti code­bases with cir­cu­lar de­pen­dency graphs. We don’t want F-rated code­bases that are im­pos­si­ble to touch with­out break­ing some­thing. But a C or D? It’s now fine. Nobody needs A or B-grade code­bases any­more be­cause they’re be­ing made for LLMs, not for hu­mans to read.

I don’t want to ar­gue if this is in­her­ently good or bad. If the source code is now writ­ten for ma­chines to read and not hu­mans, it may be ac­tu­ally ok to tar­get them.

But that’s an­other pil­lar of my ex­per­tise that’s erod­ing. A good chunk of the knowl­edge I ac­cu­mu­lated on that topic is not that valu­able any­more. All the time I spent on it - read­ing books, do­ing real-world ex­er­cises, dis­cussing with other en­gi­neers, writ­ing ADRs - is be­com­ing use­less.

What now?

I’m still em­ployed and I see my­self em­ployed (at least in that com­pany) for a fore­see­able fu­ture. But I don’t know what to think about the long-term.

I spent 10 years (even more when you ac­count for non-pro­fes­sion ex­pe­ri­ence) get­ting good at things that are be­com­ing less and less valu­able. My last pil­lar of ex­per­tise is now re­duced to a “taste” and will prob­a­bly won’t last long.

And I know that’s not just me. About 8 months ago there was a lay­off at my cur­rent com­pany (not re­lated to AI, ac­cord­ing to them). Some bril­liant ex-cowork­ers were laid off and are still look­ing for jobs. Most of them suf­fer from the same prob­lem I out­lined here: their do­main ex­per­tise is not enough to stand out any­more.

The com­pany is now hir­ing again for a few roles and do­main fa­mil­iar­ity is not a strong dif­fer­en­tia­tor any­more. We used to list “Software Engineer - Area”. Now it’s just “Software Engineer” and the team as­sign­ment comes af­ter the of­fer is ac­cepted.

Of course, this is good for bril­liant en­gi­neers that never had the chance to get deep into the do­main and now have bet­ter chances at get­ting a job, but it’s also sad to think that other bril­liant en­gi­neers that spent their lives col­lect­ing do­main knowl­edge are now com­pet­ing on the same lane.

The only way out for keep­ing my em­ploy­a­bil­ity in the long-term now seems to be shift­ing my do­main ex­per­tise to some­thing LLMs will not get good at so eas­ily. But what’s left?

I thought about go­ing back to col­lege, learn­ing Math, Statistics, ad­vanced Machine Learning and ap­ply­ing for re­search role at a fron­tier lab. Except that there are no fron­tier labs in my coun­try, the few ones that ex­ist are flood­ing with ap­pli­ca­tions and I have fam­ily mat­ters that makes mov­ing to an­other coun­try dif­fi­cult. By the time I can af­ford to make that jump, RSI may have made re­searchers ob­so­lete.

Maybe I should con­sider trans­form­ing my wood­work­ing hobby into a pro­fes­sion…

See this, this and this for ref­er­ence. Don’t take this as an en­dorse­ment of the con­tent in­side any of these posts.↩

See this, this and this for ref­er­ence. Don’t take this as an en­dorse­ment of the con­tent in­side any of these posts.↩

#ai

#llm

#software en­gi­neer­ing

fork() is a rel­a­tively ex­pen­sive sys­tem call; it must copy the en­tire process state (including mem­ory) for the child process. Many op­ti­miza­tions have been made over the years, but a fork is still a fun­da­men­tally costly op­er­a­tion. To make things worse, a fork() call is of­ten im­me­di­ately fol­lowed by an exec(), which will dis­card all of that mem­ory that was so care­fully copied for the child. Attempts (such as vfork()) have been made over the years to op­ti­mize for this case, but the pat­tern still is more ex­pen­sive than it could be.

Spawn tem­plates

Chen’s patch set takes an in­ter­est­ing ap­proach to op­ti­mize the fork() and exec() pat­tern. It is fo­cused on ap­pli­ca­tions that re­peat­edly launch processes run­ning the same ex­e­cutable; imag­ine, for ex­am­ple, a pro­gram that must run Git re­peat­edly to ob­tain in­for­ma­tion about the con­tents of a repos­i­tory. In such cases, the pro­gram could es­tab­lish a tem­plate to ac­cel­er­ate those in­vo­ca­tions, spread­ing the setup cost across mul­ti­ple op­er­a­tions. This tem­plate would be cre­ated with the spawn_tem­plate_cre­ate() sys­tem call:

struct spawn_tem­plate_cre­ate_args { __aligned_u64 flags; __s32 ex­ecfd; __u32 ex­ec_flags; __aligned_u64 file­name; /* Some fields elided */ };

int spawn_tem­plate_cre­ate(struct spawn_tem­plate_cre­ate_args *args, size_t args_­size);

This call will re­turn a file de­scrip­tor rep­re­sent­ing a tem­plate for the ex­e­cutable file, which can be spec­i­fied as ei­ther a file de­scrip­tor (execfd) or an ab­solute path (filename), but not both. To cre­ate the tem­plate, the ker­nel will open the in­di­cated file and cache a bunch of in­for­ma­tion that will al­low a process to run that file more quickly in the fu­ture.

The ap­pli­ca­tion in ques­tion may run a given ex­e­cutable many times, but each in­vo­ca­tion is dif­fer­ent in a num­ber of ways. The de­tails of a spe­cific in­vo­ca­tion must be placed into an in­stance of this struc­ture:

struct spawn_tem­plate_s­pawn_args { __aligned_u64 flags; __aligned_u64 pidfd; __aligned_u64 argv; __aligned_u64 envp; __aligned_u64 ac­tions; __aligned_u64 ac­tion­s_len; __aligned_u64 re­served[4]; };

The argv field is a pointer to the ar­gu­ment list to be passed to the pro­gram, while envp points to its en­vi­ron­ment. Changes to file de­scrip­tors and sig­nal han­dling, in­stead, are passed through ac­tions, which is a pointer to an ar­ray of:

struct spawn_tem­plate_ac­tion { __u32 type; __u32 flags; __s32 fd; __s32 newfd; __aligned_u64 arg; };

If, for ex­am­ple, file de­scrip­tor four should be closed in the child, the as­so­ci­ated spawn_tem­plate_ac­tion struc­ture would have type set to SPAWN_TEMPLATE_ACTION_CLOSE and fd set to four. Other ac­tions ex­ist for du­pli­cat­ing file de­scrip­tors, open­ing files, chang­ing the work­ing di­rec­tory, and chang­ing sig­nal han­dling.

Once the spawn_tem­plate_s­pawn_args struc­ture has been filled in, the new process can be run with:

int spawn_tem­plate_s­pawn(int tem­plate_fd, struct spawn_tem­plate_s­pawn_args *args, int args_­size);

Internally, this sys­tem call fol­lows some­thing close to the nor­mal fork()/​exec() path. Chen is care­ful to point out that all of the nor­mal checks ap­plied when ex­e­cut­ing a new file re­main in place. But the cached in­for­ma­tion in the tem­plate makes the whole process faster than it was be­fore.

How much faster? Benchmark re­sults pro­vided in the cover let­ter show an im­prove­ment of about 2%, which may not seem like a lot, but it may make a dif­fer­ence for ap­pli­ca­tions that fit the ex­pected pat­tern.

Toward posix_s­pawn()

The most de­tailed re­view of this work was posted by Mateusz Guzik, who said: “This prob­lem is dear to my heart and I have been pon­der­ing it on and off for some time now. The en­tire fork + exec id­iom is ter­ri­ble and needs to be re­tired”. He pointed out that the fo­cus of the patch set was a bit strange in that it left the fork() part of the prob­lem un­touched. That is where most of the cost lies, he said, so op­ti­miza­tion ef­forts should seek to re­move it from the pic­ture. Rather than copy­ing the cur­rent process, “creating a pris­tine process is the way to go”.

Christian Brauner was fa­vor­able to­ward the goal, say­ing: “The idea of hav­ing a builder api for exec is­n’t all that crazy”. His sug­ges­tion, though, was that a new API should be built on top of the ex­ist­ing pidfd ab­strac­tion. Without get­ting into any de­gree of de­tail, he said that the right ap­proach would be to cre­ate an op­tion to pidfd_open() to cre­ate an empty process. A se­ries of calls to a new pidfd_­con­fig() sys­tem call would then con­fig­ure this new process as de­sired, set­ting up its en­vi­ron­ment, im­age to ex­e­cute, and more. pidfd_­con­fig() would thus be anal­o­gous to fs­con­fig().

An im­por­tant ob­jec­tive for a new in­ter­face, Brauner said, would be the abil­ity to sup­port an im­ple­men­ta­tion of posix_s­pawn() in user space. posix_s­pawn() is well suited as a re­place­ment for the fork()/​exec() pat­tern; de­vel­op­ers would likely wel­come a na­tive im­ple­men­ta­tion that is­n’t (unlike the cur­rent im­ple­men­ta­tion) hid­ing fork() and exec() un­der the cov­ers.

Chen agreed that the API as broadly sketched out by Brauner seemed bet­ter, and said that fu­ture work would be in that di­rec­tion. So there will be no spawn tem­plates in the Linux ker­nel but, if Chen’s fu­ture work comes to fruition, Linux may fi­nally gain a proper posix_s­pawn() im­ple­men­ta­tion in­stead.

Did you like this ar­ti­cle?? Subscribe now at the spe­cial dis­counted rate to get a lot more like it.

Twenty Ninth International Obfuscated C Code Contest

Where to start

See be­low for links to the 2025 win­ning IOCCC en­tries.

Check out the in­dex.html web pages for each win­ning en­try. They have most of the in­for­ma­tion you need to com­pile and run the win­ning pro­gram. Take a look at the win­ning source code and try to fig­ure out how it works. You might also want to check out the au­thor’s re­marks for even more de­tails.

You may down­load all win­ning en­tries in the form of a com­pressed tar­ball for this year’s con­test.

For IOCCC29, the vol­ume and qual­ity of sub­mis­sions were at near-his­toric heights.

IOCCC28 was spec­u­lated to have at­tracted a record num­ber of sub­mis­sions due to the 4-year ab­sence, al­low­ing au­thors to re­fine their sub­mis­sions, re­sult­ing in a higher-than-usual sub­mis­sion qual­ity.

IOCCC29 was the sec­ond con­sec­u­tive con­test af­ter the 2020 – 2024 hia­tus. And yet, the num­ber of sub­mis­sions for IOCCC29 was sim­i­lar to last year’s con­test, and the over­all sub­mis­sion qual­ity re­mained high for this con­test. So per­haps the in­creased sub­mis­sion vol­ume, com­bined with a higher-than-usual sub­mis­sion qual­ity, is due to fac­tors such as im­proved web­site de­sign, in­creased so­cial me­dia pres­ence, au­thors build­ing on the ideas of past win­ning en­tries, and other fac­tors?

Starting with the close of IOCCC28, the pro­ce­dures used for clos­ing the con­test to new sub­mis­sions, the judg­ing process, se­lect­ing the win­ning en­tries, prepar­ing the up­date to the web­site, and the process to cre­ate the live show on the Our Favorite Universe were care­fully doc­u­mented. And while this doc­u­men­ta­tion re­quired ad­di­tional time as well as more ef­fort, the doc­u­men­ta­tion process re­sulted in over­all im­prove­ments to how the IOCCC is run.

A few days af­ter the pre­sen­ta­tion of the win­ning en­tries for IOCCC29 has been made on the Our Favorite Universe YouTube chan­nel. The record­ing of the main show will be di­vided up into in­di­vid­ual seg­ments. Then, each win­ning en­try will be up­dated to in­clude a link to a YouTube seg­ment un­der a new Award pre­sen­ta­tion near the top of the win­ning en­try’s in­dex.html page.

Fun chal­lenge info

We have added fun chal­lenges to this year’s win­ning en­tries com­pe­ti­tion, un­der the “Judges’ re­marks” sec­tion. After you fig­ure out what a given win­ning en­try does, we en­cour­age you to at­tempt the fun chal­lenge.

Some of these chal­lenges are eas­ier than oth­ers. In some cases, you’re asked to cre­ate an al­ter­na­tive ver­sion of prog.c or a re­lated file. In some cases you are asked to pro­duce an ex­pla­na­tion about some­thing.

If the fun chal­lenge is still open (check the “A fun chal­lenge” sec­tion for the given win­ning en­try), con­sider sub­mit­ting a GitHub pull re­quest as a con­tri­bu­tion.

If the fun chal­lenge is closed, but you think you have a bet­ter so­lu­tion, con­sider sub­mit­ting a GitHub pull re­quest as a con­tri­bu­tion. If the IOCCC Judges agree that you so­lu­tion is bet­ter, we will con­sider it.

If you be­lieve you have an even bet­ter (or im­prove­ment) to win­ning en­try’s fun chal­lenge, please con­sider sub­mit­ting a GitHub pull re­quest, for the IOCCC judges to con­sider.

Rules and Guidelines for this con­test

The fi­nal ver­sions of the IOCCC rules and guide­lines that were in ef­fect for this con­test were:

2025 rules ver­sion 29.15 2025 – 12-02

2025 guide­lines ver­sion 29.08 2025 – 12-02

The IOCCC rules and guide­lines for IOCCC29 rep­re­sented a sub­stan­tial rewrite over pre­vi­ous con­tests, thanks in part to a num­ber of vol­un­teers: giv­ing the IOCCC judges use­ful ed­its, text rewrites, con­sol­i­da­tion, as well as over­all im­proved or­ga­ni­za­tion.

Looking for­ward to the next con­test

We plan to open IOCCC30 to­wards the end of 2026 and have the con­test run for a sim­i­lar amount of time, clos­ing some­time to­wards the end of Q1 2027.

As we per­form the ac­tions needed to open IOCCC30, we plan to in­ter­nally doc­u­ment the process as we did dur­ing the clos­ing of IOCCC29.

About two or three weeks af­ter the IOCCC29 win­ning en­tries have been posted, and we process some of the early pull re­quests against the 2025 di­rec­tory tree, the IOCCC Judges plan to go on an IOCCC va­ca­tion.

We had in­tended to go on an IOCCC va­ca­tion af­ter re­leas­ing the win­ners of IOCCC28, but then the ef­forts to process bug fixes and en­hance­ments to the mkioc­c­cen­try repo took so much time that by the time that repo was sta­ble, it was time to open IOCCC29. Therefore, this time, we plan to wait un­til af­ter the end of our post-IOC­C­C29 IOCCC va­ca­tion be­fore work­ing on any mkioc­c­cen­try repo PRs.

While work­ing on cre­at­ing po­ten­tial write-ups for sub­mis­sions that en­tered the fi­nal round of the set of judg­ing rounds:

A few sub­mis­sions were set aside in the fi­nal round of the fi­nal set of rounds.

We gained an ad­di­tional level of ap­pre­ci­a­tion for a num­ber of the re­main­ing en­tries.

While the win­ning en­try au­thors came from lo­ca­tions of pre­vi­ous win­ning au­thors, this IOCCC29 had an au­thor - jing­p49 from a new lo­ca­tion: Taiwan.

This con­test saw a Hat trick of Hat-tricks by:

Yusuke Endoh: 2025/endoh1, 2025/endoh2, and 2025/endoh3

Nick Craig-Wood: 2025/ncw1, 2025/ncw2, and 2025/ncw3

Don Yang: 2025/yang1, 2025/yang2, and 2025/yang3

Notable and re­mark­able win­ning en­tries of IOCCC29 in­clude, but are not lim­ited to:

2025/cable - Subleq com­puter

2025/cesmoak - Black hole punch­card Fortran

2025/endoh3 - patch/​diff quine

2025/jhshrvdp - Quasi-rogue-like game

2025/jingp49 - Dr. WHO se­quence

2025/ncw1 - GameBoy em­u­la­tor

2025/tompng - Ocean sound gen­er­a­tor

2025/uellenberg - Quine pong

2025/yang2 - Zoltraak en­cod­ing

Those are just a few of the many amaz­ing win­ners of the IOCCC29, so be sure to check out the rest!

As we dis­cussed above, there were quite a few ex­cel­lent sub­mis­sions that did­n’t quite make the fi­nal cut. We truly ap­pre­ci­ate the hard work each au­thor put into their en­tries, but we’re sorry that we can’t award based solely on ef­fort.

We re­ceived many great sub­mis­sions that did­n’t quite make the cut as win­ners. If you sub­mit­ted some­thing for IOCCC29 that did­n’t win, think about pol­ish­ing your code and giv­ing it an­other shot for IOCCC30. Interestingly, more than one win­ner of IOCCC29 was ac­tu­ally an im­proved ver­sion of code that did­n’t win in a pre­vi­ous con­test.

Encouragement for those who did not win this year

We know many of you that sub­mit­ted to the IOCCC put in a ton of ef­fort into your sub­mis­sions for this year’s IOCCC. We can’t just give out awards to every­one. That would mean tak­ing away from the sub­mis­sions that we think are the best and de­serve to win.

Sometimes, a fi­nal round sub­mis­sion might be good enough to be a win­ning IOCCC en­try, only to be beaten by a sim­i­lar, but slightly bet­ter sub­mis­sion. If you think this hap­pened with your sub­mis­sion, con­sider sub­mit­ting an en­hanced ver­sion to the next IOCCC.

PLEASE DO NOT give up hope! There are some sub­mis­sions that have been sub­mit­ted with re­vi­sions, mul­ti­ple times be­fore ris­ing to the level of a win­ning IOCCC en­try. You might also want to try with a dif­fer­ent type of sub­mis­sion al­to­gether for the next IOCCC.

If you’re not plan­ning to im­prove and re­sub­mit your non-win­ning en­try for the next IOCCC, you’re wel­come to pub­lish it.

On com­pil­ing and run­ning win­ning en­tries

Some C com­pil­ers aren’t as great as they could be. If yours is­n’t work­ing well, you might want to try com­pil­ing with an up­dated ver­sion of clang and/​or gcc in­stead.

If you en­counter prob­lems in com­pil­ing and/​or run­ning the win­ning en­tries, see the FAQ on:

Compiling IOCCC en­tries

IOCCC en­try de­pen­den­cies

Problems com­pil­ing en­tries

Running IOCCC en­tries

For ad­di­tional in­for­ma­tion on how to sub­mit fixes, see the FAQ on:

How to sub­mit a fix - how to sub­mit a fix to an en­try

Update au­thor in­for­ma­tion - how to cor­rect or up­date an IOCCC au­thor’s in­for­ma­tion

For even more in­for­ma­tion

Reporting an IOCCC web­site prob­lem

Submitting a fix to the IOCCC web­site

How to con­tact the IOCCC - up-to-date con­tact de­tails

IOCCC FAQ - ad­di­tional in­for­ma­tion on the IOCCC

www.ioccc.org - the pri­mary IOCCC web­site

Winning Entries of 2025 - The 29th IOCCC

Download all win­ning en­tries from 2025

2025/ayu - IMO award

2025/cable - Best imag­i­nary em­u­la­tor

2025/cesmoak - Retro space award

2025/diels-grabsch - Best one liner

2025/dogon - Consistently con­stant award

2025/endoh1 - Most likely to daz­zle

2025/endoh2 - Most likely to shock

2025/endoh3 - Most re­silient

2025/ferguson - Opposite award

2025/howe - Most likely to in­vade

2025/jhshrvdp - Most likely to tele­port

2025/jingp49 - Who won award

2025/kurdyukov - Most likely to count

2025/mattpep - Most ob­fus­cated op­tions

2025/ncw1 - Best real em­u­la­tor

2025/ncw2 - Best frac­tional em­u­la­tor

2025/ncw3 - Best use of Unicode

2025/tompng - Most sooth­ing

2025/uellenberg - Ping pong prize

2025/yang1 - Compound prize

2025/yang2 - Most mag­i­cal word

2025/yang3 - INABIAF award

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Disclaimer: This ar­ti­cle is co-au­thored with GPT-5.5 and Claude Opus 4.8.

ze­roserve is a small, fast, zero-con­fig HTTPS server. You hand it a tar­ball of a web­site and it serves it - over HTTP/2 and TLS 1.3, with hot re­load and a tiny res­i­dent foot­print. The twist is that you can drop eBPF pro­grams into the tar­ball and they run on every re­quest, in user­space, as sand­boxed mid­dle­ware - rewrit­ing, au­then­ti­cat­ing, and rate-lim­it­ing re­quests, or re­verse-prox­y­ing them to a back­end when you want it to act as a gate­way in front of your app.

In short:

Fast: on one core it beats ng­inx across most work­loads - small and large sta­tic files, scripted mid­dle­ware, and small-re­sponse prox­y­ing, all over HTTPS.

Efficient eBPF script­ing: scripts are JIT-compiled to na­tive code and sand­boxed in user­space, cheap enough to run on every re­quest.

Program-as-configuration: your eBPF pro­gram is the whole con­fig­u­ra­tion, de­cid­ing what hap­pens to each re­quest.

io_ur­ing through­out: every net­work and disk op­er­a­tion is sub­mit­ted through io_ur­ing.

Modern TLS in the box: TLS 1.3, HTTP/2, Encrypted Client Hello, SNI cer­tifi­cate se­lec­tion, and JA4 fin­ger­print­ing.

Simple to op­er­ate: serve a whole site from one tar­ball and hot-re­load it (and the TLS ma­te­r­ial) with a SIGHUP.

It’s meant to be an al­ter­na­tive to ng­inx and Caddy, and the de­sign bet is about con­fig­u­ra­tion. Those servers give you a de­clar­a­tive con­fig lan­guage - lo­ca­tion blocks, rewrite rules, map di­rec­tives, try_­files - and then, once the de­clar­a­tive lan­guage hits its lim­its, an op­tional script­ing run­time bolted on the side (Lua, or Caddy’s plu­g­ins). Behavior ends up split across two lay­ers: di­rec­tives that qui­etly grow their own con­trol flow, plus scripts that run some­where in the re­quest life­cy­cle you have to keep in your head.

ze­roserve col­lapses that into one thing. There is no con­fig file. The eBPF pro­gram is the con­fig­u­ra­tion - a sin­gle, or­di­nary, sand­boxed pro­gram that sees every re­quest and de­cides what hap­pens: rout­ing, head­ers, auth, rate lim­it­ing, prox­y­ing. I want the whole re­quest path in one pro­gram I can read top to bot­tom.

One tar­ball, served in place

The whole site is a sin­gle tar file. ze­roserve in­dexes it on load - build­ing a path -> byte-range map - and then serves files by is­su­ing byte-range reads against the tar­ball it­self. Nothing is ever un­packed to disk. The site lives en­tirely in that one file, so there’s no doc­u­ment root for a stray lo­ca­tion rule to ex­pose, and a de­ploy is a sin­gle atomic file swap. To pack­age a di­rec­tory:

ze­roserve –pack ./public > site.tar ze­roserve –addr 0.0.0.0:8080 site.tar

Deploying a new ver­sion is “replace the tar­ball and send SIGHUP”. The re­load swaps the site, the scripts, and the TLS ma­te­r­ial atom­i­cally, in the same process, with no dropped con­nec­tions:

kil­lall -SIGHUP ze­roserve

All net­work and disk I/O goes through io_ur­ing (via the monoio run­time). Each in­stance is a sin­gle-threaded event loop. That sounds like a lim­i­ta­tion, and per-process it is - but it’s the right shape when your scal­ing unit is “more processes”, and it’s why many of them co­ex­ist hap­pily on one box.

Scripting with eBPF, in user­space

This is the part I find most fun. Any .c file you put un­der .zeroserve/scripts/ gets com­piled to an eBPF ob­ject at pack time (with clang and llc) and runs on every re­quest. The eBPF runs en­tirely in user­space: ze­roserve loads the byte­code into a run­time (async-ebpf) in­side its own or­di­nary, un­priv­i­leged process, so the ker­nel’s BPF sub­sys­tem and CAP_BPF stay out of it. async-ebpf JIT-compiles the byte­code to na­tive ma­chine code (it ven­dors uBPF), so your “config” runs as na­tive x86 – 64.

A pointer cage does the job the ker­nel ver­i­fier nor­mally would, keep­ing the pro­gram from read­ing or writ­ing mem­ory it should­n’t: every mem­ory ac­cess in the JIT-compiled code is masked into the pro­gram’s own arena, so a stray ac­cess stays con­fined to the scrip­t’s own mem­ory.

The script runs di­rectly on ze­roserve’s sin­gle event loop. To keep one slow script from stalling every other con­nec­tion, the run­time is fully pre­emptible: a timer can in­ter­rupt JIT-compiled na­tive code mid-ex­e­cu­tion and hand con­trol back to the event loop.

The pro­gram­ming model is a chain of scripts, run in sorted file­name or­der, shar­ing a per-re­quest meta­data map. If a script calls zs_re­spond or zs_re­verse_proxy, the chain short-cir­cuits. Here’s a script that runs first and en­riches every re­quest:

#include <zeroserve.h>

ZS_ENTRY zs_u64 en­try(void) { char peer[64]; if (zs_req_peer(peer, sizeof(peer)) <= 0) zs_str­cpy(peer, “unknown”);

// pub­lish val­ues for the HTML tem­plate pass zs_meta_set(ZS_STR(“vis­i­tor”), ZS_STR(peer)); // at­tach a header to *every* re­sponse: sta­tic files, zs_re­spond, prox­ied zs_meta_set(ZS_STR(“zs.re­sponse.header.x-served-by”), ZS_STR(“zeroserve-ebpf”)); re­turn 0; }

The meta­data it sets does two things. Keys un­der zs.re­sponse.header.* be­come re­sponse head­ers on every­thing. And other keys feed a tiny tem­plate pass: a <zs-meta>visitor</zs-meta> place­holder in an HTML file gets sub­sti­tuted on the way out. So you get dy­namic-ish sta­tic pages with­out a tem­plate en­gine.

The helper sur­face a script can call is broad:

Request in­spec­tion and mu­ta­tion: read the method, path, query params, head­ers, and peer ad­dress; rewrite the URI or set and re­move head­ers be­fore the re­sponse goes out.

Crypto and en­cod­ing: SHA-256, HMAC-SHA256, base64, hex, and ge­tran­dom.

JSON: parse a re­quest body, build and mu­tate a doc­u­ment tree, and re­ply with zs_j­son_re­spond.

Rate lim­it­ing: per-key to­ken buck­ets keyed on any­thing from a peer IP to an API key, with state that sur­vives hot re­loads.

AWS SigV4: signed Authorization head­ers and pre­signed URLs for talk­ing to S3 and other AWS ser­vices.

OIDC lo­gin: a com­plete re­ly­ing-party flow (Authorization Code + PKCE) that car­ries the en­tire lo­gin ses­sion in sealed XChaCha20-Poly1305 cook­ies, so you can gate a sta­tic site be­hind “log in with Google” while the server stays state­less.

A dy­namic end­point is just a script that re­sponds:

ZS_ENTRY zs_u64 en­try(void) { char path[64]; zs_re­q_­path(path, sizeof(path)); if (zs_strcmp(path, “/health”) != 0) re­turn 0;

zs_meta_set(ZS_STR(“zs.re­sponse.header.con­tent-type”), ZS_STR(“application/json”)); zs_re­spond(200, ZS_STR(“{"status":"ok"}\n”)); re­turn 0; }

Each script runs un­der a mem­ory-foot­print cap (256 KB by de­fault), the run­time time-slices long-run­ning scripts off the ex­ecu­tor and throt­tles the run­aways, and scripts can even call each other (zs_call) up to a bounded depth. A script that spins for­ever stalls only its own re­quest - the pre­emp­tion timer in­ter­rupts it and the server keeps serv­ing every­one else.

The TLS story un­der­neath is more com­plete than the zero-con­fig fram­ing sug­gests: TLS 1.3 only, ter­mi­nated by BoringSSL, with na­tive Encrypted Client Hello (so the real SNI never ap­pears in clear­t­ext), SNI cer­tifi­cate se­lec­tion from a di­rec­tory, JA4 client fin­ger­print­ing ex­posed to scripts, and a trans­par­ent ECH re­lay mode that byte-for-byte for­wards un­de­crypt­able hand­shakes to a real up­stream so a pro­tected name blends in be­hind a pub­lic one. That’s a lot of trans­port se­cu­rity to ship in a sin­gle zero-con­fig bi­nary.

How fast is it?

I bench­marked ze­roserve against ng­inx 1.26 and Caddy 2.11 over HTTPS on an 8-core Ryzen 7 3700X, each serv­ing the same con­tent with the same self-signed cer­tifi­cate. Because a ze­roserve in­stance is sin­gle-threaded by de­sign, the only fair com­par­i­son is per core: I pinned every server to one CPU with taskset (and held ng­inx to work­er_processes 1 and Caddy to GOMAXPROCS=1; ze­roserve is sin­gle-threaded al­ready) and drove load with wrk -t4 -c100 from other cores, tak­ing the me­dian of three 10-second runs. wrk speaks HTTP/1.1, so these are HTTP/1.1-over-TLS-1.3 num­bers with the hand­shake amor­tized across long-lived keep-alive con­nec­tions: the steady-state cost of serv­ing an al­ready-open HTTPS con­nec­tion.

Small sta­tic file (174 B) - the bread and but­ter of sta­tic sites:

ze­roserve serves small files about 17% faster than ng­inx on a sin­gle core, with a tighter tail. HTML pages, small JSON, CSS - this is the case ze­roserve is tuned for.

Large sta­tic file (100 KB):

All three are close here, with ze­roserve a hair ahead at around 780 MB/s on one core. ng­inx’s usual trump card for large files is send­file(), which splices file pages from the page cache to the socket with zero user­space copies. Under TLS that path goes un­used: the bytes have to be en­crypted in user­space any­way (short of ker­nel TLS, which all three leave off), so every server is bound by the same en­crypt-and-write loop, and ze­roserve’s io_ur­ing read-and-write path is a touch faster at it.

eBPF vs Lua

The ob­vi­ous com­par­i­son for the script­ing is ng­inx + LuaJIT (ngx_http_lua_module), the usual way to run fast code in­side a web server. So I wrote the equiv­a­lent Lua for two cases and put them head to head.

One tun­ing knob mat­ters a lot here. ze­roserve ships with a con­ser­v­a­tive de­fault: it arms the script-pre­emp­tion timer every 2 ms. Fine gran­u­lar­ity makes it quick to throt­tle a mis­be­hav­ing script, but it taxes every well-be­haved one - at the de­fault, eBPF trails ng­inx Lua on a fully dy­namic re­sponse (about 32k req/​s against 41k). Bumping –preempt-timer-interval-ms to 10 re­cov­ers ~40% of script­ing through­put and turns that around:

Per-request header-in­jec­tion mid­dle­ware (script runs, sta­tic file is still served):

Fully dy­namic JSON re­sponse:

At the 10 ms in­ter­val, tuned eBPF wins both cases. On the mid­dle­ware case - a script shap­ing an oth­er­wise-sta­tic re­sponse - it beats ng­inx Lua by about 50%, with a tighter tail. On the fully syn­thetic re­sponse it edges ng­inx’s heav­ily-tuned con­tent_­by_lua too (47k against 41k). Both en­gines com­pile to na­tive code (LuaJIT is a trac­ing JIT; async-ebpf JITs the eBPF through uBPF), and with TLS en­cryp­tion as a shared per-re­quest cost, the tuned eBPF path comes out ahead on through­put. At the 2 ms de­fault, eBPF keeps the mid­dle­ware win but gives up the syn­thetic-re­sponse lead, so I’d run pro­duc­tion scripts at 10 ms.

As a re­verse proxy

Serving files is half the job; the other half is prox­y­ing to a back­end, which is the main rea­son most peo­ple reach for ng­inx or Caddy in the first place. ze­roserve does it from a script - zs_re­verse_proxy(“http://​127.0.0.1:9000”) - and keeps a pool of up­stream con­nec­tions (up to 128 per back­end, 30 s idle) and reuses them across re­quests.

Getting a fair fight here takes care: ng­inx’s fa­mous de­fault closes up­stream con­nec­tions af­ter each re­quest, so keep-alive is en­abled ex­plic­itly (keepalive 128, prox­y_http_ver­sion 1.1, and a cleared Connection header), with Caddy reusing con­nec­tions as it does by de­fault. Each proxy ter­mi­nates TLS on a sin­gle core and for­wards to a shared plain­text back­end, a sep­a­rate 2-core server that sus­tains 100k req/​s on its own, so the mea­sure­ment iso­lates the prox­y’s own over­head.

Proxying a small (174 B) re­sponse:

ze­roserve’s pooled io_ur­ing proxy leads here, about 22% ahead of ng­inx (26.5k against 21.8k) and roughly 3.4× Caddy. For the typ­i­cal proxy work­load - for­ward­ing API calls, small JSON, an app server’s HTML - ze­roserve ter­mi­nates TLS and shut­tles the re­quest to the back­end faster than the ref­er­ence im­ple­men­ta­tion.

Large bod­ies tip the bal­ance back. Proxying a 100 KB re­sponse:

Once the prox­ied body is large, ng­inx’s buffer­ing moves bytes more ef­fi­ciently and pulls ahead, with Caddy slot­ting in be­tween and ze­roserve trail­ing. If your prox­ied re­sponses are large, ng­inx is the bet­ter tool; if they’re small and nu­mer­ous, ze­roserve is faster.

Memory

Idle, a sin­gle ze­roserve in­stance sits around 15 MB PSS - more than ng­inx’s ~6 MB, less than Caddy’s ~60 MB. On its own that’s un­re­mark­able. What makes it mat­ter is that the unit is a whole process: when you run a copy per core, they all map the same bi­nary, so the code pages are shared, and each ex­tra process adds lit­tle be­yond its own work­ing set.

ze­roserve is open source on GitHub - try it your­self!

Five lead­ing sci­en­tists were ousted from the an­nual meet­ing of the American Diabetes Association (ADA) in New Orleans on Friday. Their crime: hand­ing out copies of an ed­i­to­r­ial, pub­lished in the jour­nal Diabetes Care on April 29, sharply crit­i­ciz­ing the Trump ad­min­is­tra­tion’s on­go­ing at­tacks on sci­en­tific re­search.

Those ousted were Steven Kahn, pro­fes­sor of med­i­cine at the University of Washington and ed­i­tor-in-chief of Diabetes Care, who co-au­thored the pub­lished ed­i­to­r­ial; for­mer ADA pres­i­dent Desmond Schatz of the University of Florida, Gainesville; Aaron Kelly, pe­di­atrics proces­sor at the University of Minnesota; Justin Ryder of Northwestern University; and Irl Hirsch, also of the University of Washington. The five were hand­ing out reprints of the ed­i­to­r­ial out­side a room where NIH di­rec­tor Jay Bhattacharya had been sched­uled to speak. Bhattacharya can­celled and an­other NIH of­fi­cial spoke in his stead.

“They phys­i­cally grabbed us, forced us out of the con­fer­ence cen­ter, and now are telling us we can no longer at­tend this meet­ing,” Kelly told MedPage Today, which first re­ported the in­ci­dent. “They’re tak­ing our lan­yards. It re­ally has come to this in America. Censorship is real. America needs to stand up. Scientists, stand up. Physicians, stand up.”

The ADA con­firmed to MedPage Today that five reg­is­tered sci­en­tists had been re­moved from the meet­ing, claim­ing the sci­en­tists had vi­o­lated the or­ga­ni­za­tion’s code of con­duct for con­fer­ences. “These at­ten­dees were es­corted out by our on­site event se­cu­rity be­cause they demon­strated be­hav­ior not con­sis­tent with this code of con­duct,” the ADA me­dia team said in a state­ment. “They were re­spect­fully given the op­por­tu­nity to cease this be­hav­ior and chose not to which is why they were es­corted out.”

“All at­ten­dees will con­duct them­selves in a pro­fes­sional and re­spect­ful man­ner, free from any form of dis­crim­i­na­tion, ha­rass­ment, or in­tim­i­da­tion,” the code of con­duct states. “Inappropriate con­duct, in­clud­ing but not lim­ited to ha­rass­ment; threat­en­ing or un­wel­come phys­i­cal or ver­bal ac­tions; or dis­or­derly or dis­rup­tive con­duct such as protest­ing, will not be tol­er­ated.”

I am not sure i am in the right place but we are all out of op­tions here since we could­n’t get any help from the game or steam sup­port.

Since around the 13/03, there is a ma­jor sys­temic prob­lem in every game that uses Steam Networking for P2P games.

For ex­am­ple, in the game Street Fighter 6, when play­ing with one Israeli or an­other with PC to PC the ping be­tween play­ers are ~120ms. when play­ing with European play­ers the ping is around 60 – 80ms which means it works well, it cur­rently af­fects only Israeli play­ers when play­ing PC to PC. Since Street Fighter 6 sup­ports cross-play we have tried play­ing PC to PS5 and the ping is a flaw­less 5 – 10ms.

It cur­rently af­fects all play­ers in Israel, we have a few dozens in our com­mu­nity with sev­eral ISPs, we have of course at­tempted speak­ing to our ISPs and port for­ward­ing and we have found no net­work is­sues on their part. in other P2P games that don’t use steam net­work­ing the is­sue is not ex­is­tent(for ex­am­ple, Tekken 8).

We are cur­rently don’t know what we can do with this is­sue since noth­ing we have done have helped and 120ms is too high for it to be playable in any P2P game.

While I can’t con­firm but heard re­ports from play­ers in other mid­dle east­ern coun­tries like Egypt that they also re­port on this is­sue so it could be re­gion-wide.