One of the sim­plest tests you can run on a data­base:

It’s not a mis­placed comma! The rewrite is 20,171 times slower on one of the most ba­sic data­base op­er­a­tions.

EDIT: Several read­ers have con­fused this pro­ject with Turso/libsql. They are un­re­lated. Turso forks the orig­i­nal C SQLite code­base; the pro­ject an­a­lyzed here is a ground-up LLM-generated rewrite by a sin­gle de­vel­oper. Running the same bench­mark against Turso shows per­for­mance within 1.2x of SQLite con­sis­tent with a ma­ture fork, not a reim­ple­men­ta­tion.

The thing is though: The code com­piles. It passes all its tests. It reads and writes the cor­rect SQLite file for­mat. Its README claims MVCC con­cur­rent writ­ers, file com­pat­i­bil­ity, and a drop-in C API. On first glance it reads like a work­ing data­base en­gine.

But it is not!

LLMs op­ti­mize for plau­si­bil­ity over cor­rect­ness. In this case, plau­si­ble is about 20,000 times slower than cor­rect.

I write this as a prac­ti­tioner, not as a critic. After more than 10 years of pro­fes­sional dev work, I’ve spent the past 6 months in­te­grat­ing LLMs into my daily work­flow across mul­ti­ple pro­jects. LLMs have made it pos­si­ble for any­one with cu­rios­ity and in­ge­nu­ity to bring their ideas to life quickly, and I re­ally like that! But the num­ber of screen­shots of silently wrong out­put, con­fi­dently bro­ken logic, and cor­rect-look­ing code that fails un­der scrutiny I have amassed on my disk shows that things are not al­ways as they seem. My con­clu­sion is that LLMs work best when the user de­fines their ac­cep­tance cri­te­ria be­fore the first line of code is gen­er­ated.

A note on the pro­jects ex­am­ined: this is not a crit­i­cism of any in­di­vid­ual de­vel­oper. I do not know the au­thor per­son­ally. I have noth­ing against them. I’ve cho­sen the pro­jects be­cause they are pub­lic, rep­re­sen­ta­tive, and rel­a­tively easy to bench­mark. The fail­ure pat­terns I found are pro­duced by the tools, not the au­thor. Evidence from METR’s ran­dom­ized study and GitClear’s large-scale repos­i­tory analy­sis sup­port that these is­sues are not iso­lated to one de­vel­oper when out­put is not heav­ily ver­i­fied. That’s the point I’m try­ing to make!

This ar­ti­cle talks about what that gap looks like in prac­tice: the code, the bench­marks, an­other case study to see if the pat­tern is ac­ci­den­tal, and ex­ter­nal re­search con­firm­ing it is not an out­lier.

I com­piled the same C bench­mark pro­gram against two li­braries: sys­tem SQLite and the Rust reim­ple­men­ta­tion’s C API li­brary. Same com­piler flags, same WAL mode, same table schema, same queries. 100 rows:

I’ll take the TRANSACTION batch row as the base­line be­cause it does­n’t have the same glar­ing bugs as the oth­ers, namely no WHERE clauses and per-state­ment syncs. In this run that base­line is al­ready 298x, which means even the best-case path is far be­hind SQLite. Anything above 298x sig­nals a bug.

The largest gap be­yond our base­line is dri­ven by two bugs:

INSERT with­out a trans­ac­tion: 1,857x ver­sus 298x in batch mode. SELECT BY ID: 20,171x. UPDATE and DELETE are both above 2,800x. The pat­tern is con­sis­tent: any op­er­a­tion that re­quires the data­base to find some­thing is in­sanely slow.

I read the source code. Well.. the parts I needed to read based on my bench­mark re­sults. The reim­ple­men­ta­tion is not small: 576,000 lines of Rust code across 625 files. There is a parser, a plan­ner, a VDBE byte­code en­gine, a B-tree, a pager, a WAL. The mod­ules have all the “correct” names. The ar­chi­tec­ture also looks cor­rect. But two bugs in the code and a group of smaller is­sues com­pound:

In SQLite, when you de­clare a table as:

CREATE TABLE test (id INTEGER PRIMARY KEY, name TEXT, value REAL);

the col­umn id be­comes an alias for the in­ter­nal rowid — the B-tree key it­self. A query like WHERE id = 5 re­solves to a di­rect B-tree search and scales O(log n). (I al­ready wrote a TLDR piece about how B-trees work here.) The SQLite query plan­ner doc­u­men­ta­tion states: “the time re­quired to look up the de­sired row is pro­por­tional to logN rather than be­ing pro­por­tional to N as in a full table scan.” This is not an op­ti­miza­tion. It is a fun­da­men­tal de­sign de­ci­sion in SQLite’s query op­ti­mizer:

# `where.c`, in `whereScanInit()`

if( iCol­umn==pIdx->pT­able->iP­Key ){

iCol­umn = XN_ROWID;

The line above con­verts a named col­umn ref­er­ence to XN_ROWID when it matches the table’s INTEGER PRIMARY KEY col­umn. The VDBE then trig­gers a SeekRowid op­er­a­tion in­stead of a full table scan, which makes the whole thing pro­por­tional to logN.

The Rust reim­ple­men­ta­tion has a proper B-tree. The table_seek func­tion im­ple­ments cor­rect bi­nary search de­scent through its nodes and scales O(log n). It works. But the query plan­ner never calls it for named columns!

The is_rowid_ref() func­tion only rec­og­nizes three magic strings:

fn is_rowid_ref(col_ref: &ColumnRef) -> bool {

let name = col_ref.col­umn.to_asci­i_low­er­case();

name == “rowid” || name == “_rowid_” || name == “oid”

A col­umn de­clared as id INTEGER PRIMARY KEY, even though it is in­ter­nally flagged as is_ipk: true, does­n’t get rec­og­nized. It is never con­sulted when choos­ing be­tween a B-tree search and a full table scan.

Every WHERE id = N query flows through code­gen_s­e­lec­t_­ful­l_s­can(), which emits lin­ear walks through every row via Rewind / Next / Ne to com­pare each rowid against the tar­get. At 100 rows with 100 lookups, that is 10,000 row com­par­isons in­stead of roughly 700 B-tree steps. O(n²) in­stead of O(n log n). This is con­sis­tent with the ~20,000x re­sult in this run.

Every WHERE clause on every col­umn does a full table scan. The only fast path is WHERE rowid = ? us­ing the lit­eral pseudo-col­umn name.

The sec­ond bug is re­spon­si­ble for the 1,857x on INSERT. Every bare INSERT out­side a trans­ac­tion is wrapped in a full au­to­com­mit cy­cle: en­sure_au­to­com­mit_txn() → ex­e­cute → re­solve_au­to­com­mit_txn(). The com­mit calls wal.sync(), which calls Rust’s fsync(2) wrap­per. 100 INSERTs means 100 fsyncs.

SQLite does the same au­to­com­mit, but uses fdata­sync(2) on Linux, which skips sync­ing file meta­data when com­piled with HAVE_FDATASYNC (the de­fault). This is roughly 1.6 to 2.7 times cheaper on NVMe SSDs. SQLite’s per-state­ment over­head is also min­i­mal: no schema re­load, no AST clone, no VDBE re­com­pile. The Rust reim­ple­men­ta­tion does all three on every call.

Looking at the Rust TRANSACTION batch row, batched in­serts (one fsync for 100 in­serts) take 32.81 ms, whereas in­di­vid­ual in­serts (100 fsync calls) take 2,562.99 ms. That’s a 78x over­head from the au­to­com­mit.

These two bugs are not iso­lated cases. They are am­pli­fied by a group of in­di­vid­u­ally de­fen­si­ble “safe” choices that com­pound:

* AST clone on every cache hit. The SQL parse is cached, but the AST is .clone()’d on every sqlite3_exec(), then re­com­piled to VDBE byte­code from scratch. SQLite’s sqlite3_pre­pare_v2() just re­turns a reusable han­dle.

* 4KB (Vec The page cache re­turns data via .to_vec(), which cre­ates a new al­lo­ca­tion and copies it into the Vec even on cache hits. SQLite re­turns a di­rect pointer into pinned cache mem­ory, cre­at­ing zero copies. The Fjall data­base team mea­sured this ex­act anti-pat­tern at 44% of run­time be­fore build­ing a cus­tom ByteView type to elim­i­nate it.

* Schema re­load on every au­to­com­mit cy­cle. After each state­ment com­mits, the next state­ment sees the bumped com­mit counter and calls re­load­_memd­b_from_­pager(), walks the sqlite_­mas­ter B-tree and then re-parses every CREATE TABLE to re­build the en­tire in-mem­ory schema. SQLite checks the schema cookie and only re­loads it on change.

* Eager for­mat­ting in the hot path. state­men­t_sql.to_string() (AST-to-SQL for­mat­ting) is eval­u­ated on every call be­fore its guard check. This means it does se­ri­al­iza­tion re­gard­less of whether a sub­scriber is ac­tive or not.

* New ob­jects on every state­ment. A new SimpleTransaction, a new VdbeProgram, a new MemDatabase, and a new VdbeEngine are al­lo­cated and de­stroyed per state­ment. SQLite reuses all of these across the con­nec­tion life­cy­cle via a looka­side al­lo­ca­tor to elim­i­nate mal­loc/​free in the ex­e­cu­tion loop.

Each of these was prob­a­bly cho­sen in­di­vid­u­ally with sound gen­eral rea­son­ing: “We clone be­cause Rust own­er­ship makes shared ref­er­ences com­plex.” “We use sync_all be­cause it is the safe de­fault.” “We al­lo­cate per page be­cause re­turn­ing ref­er­ences from a cache re­quires un­safe.”

Every de­ci­sion sounds like choos­ing safety. But the end re­sult is about 2,900x slower in this bench­mark. A data­base’s hot path is the one place where you prob­a­bly should­n’t choose safety over per­for­mance. SQLite is not pri­mar­ily fast be­cause it is writ­ten in C. Well.. that too, but it is fast be­cause 26 years of pro­fil­ing have iden­ti­fied which trade­offs mat­ter.

In the 1980 Turing Award lec­ture Tony Hoare said: “There are two ways of con­struct­ing a soft­ware de­sign: one way is to make it so sim­ple that there are ob­vi­ously no de­fi­cien­cies, and the other is to make it so com­pli­cated that there are no ob­vi­ous de­fi­cien­cies.” This LLM-generated code falls into the sec­ond cat­e­gory. The reim­ple­men­ta­tion is 576,000 lines of Rust (measured via scc, count­ing code only, with­out com­ments or blanks). That is 3.7x more code than SQLite. And yet it still misses the is_ipk check that han­dles the se­lec­tion of the cor­rect search op­er­a­tion.

Steven Skiena writes in The Algorithm Design Manual: “Reasonable-looking al­go­rithms can eas­ily be in­cor­rect. Algorithm cor­rect­ness is a prop­erty that must be care­fully demon­strated.” It’s not enough that the code looks right. It’s not enough that the tests pass. You have to demon­strate with bench­marks and with proof that the sys­tem does what it should. 576,000 lines and no bench­mark. That is not “correctness first, op­ti­miza­tion later.” That is no cor­rect­ness at all.

The SQLite reim­ple­men­ta­tion is not the only ex­am­ple. A sec­ond pro­ject by the same au­thor shows the same dy­namic in a dif­fer­ent do­main.

The de­vel­op­er’s LLM agents com­pile Rust pro­jects con­tin­u­ously, fill­ing disks with build ar­ti­facts. Rust’s tar­get/ di­rec­to­ries con­sume 2–4 GB each with in­cre­men­tal com­pi­la­tion and de­bug­info, a top-three com­plaint in the an­nual Rust sur­vey. This is am­pli­fied by the pro­jects them­selves: a sib­ling agent-co­or­di­na­tion tool in the same port­fo­lio pulls in 846 de­pen­den­cies and 393,000 lines of Rust. For con­text, rip­grep has 61; sudo-rs was de­lib­er­ately re­duced from 135 to 3. Properly ar­chi­tected pro­jects are lean.

The so­lu­tion to the disk pres­sure: a cleanup dae­mon. 82,000 lines of Rust, 192 de­pen­den­cies, a 36,000-line ter­mi­nal dash­board with seven screens and a fuzzy-search com­mand palette, a Bayesian scor­ing en­gine with pos­te­rior prob­a­bil­ity cal­cu­la­tions, an EWMA fore­caster with PID con­troller, and an as­set down­load pipeline with mir­ror URLs and of­fline bun­dle sup­port.

*/5 * * * * find ~/*/target -type d -name “incremental” -mtime +7 -exec rm -rf {} +

A one-line cron job with 0 de­pen­den­cies. The pro­jec­t’s README claims ma­chines “become un­re­spon­sive” when disks fill. It does not once men­tion Rust’s stan­dard tool for ex­actly this prob­lem: cargo-sweep. It also fails to con­sider that op­er­at­ing sys­tems al­ready carry bal­last helpers. ex­t4’s 5% root reser­va­tion, re­serves blocks for priv­i­leged processes by de­fault: on a 500 GB disk, 25 GB re­main avail­able to root even when non-root users see “disk full.” That does not guar­an­tee zero im­pact, but it usu­ally means priv­i­leged re­cov­ery paths re­main avail­able so root can still log in and delete files.

The pat­tern is the same as the SQLite rewrite. The code matches the in­tent: “Build a so­phis­ti­cated disk man­age­ment sys­tem” pro­duces a so­phis­ti­cated disk man­age­ment sys­tem. It has dash­boards, al­go­rithms, fore­cast­ers. But the prob­lem of delet­ing old build ar­ti­facts is al­ready solved. The LLM gen­er­ated what was de­scribed, not what was needed.

THIS is the fail­ure mode. Not bro­ken syn­tax or miss­ing semi­colons. The code is syn­tac­ti­cally and se­man­ti­cally cor­rect. It does what was asked for. It just does not do what the sit­u­a­tion re­quires. In the SQLite case, the in­tent was “implement a query plan­ner” and the re­sult is a query plan­ner that plans every query as a full table scan. In the disk dae­mon case, the in­tent was “manage disk space in­tel­li­gently” and the re­sult is 82,000 lines of in­tel­li­gence ap­plied to a prob­lem that needs none. Both pro­jects ful­fill the prompt. Neither solves the prob­lem.

The ob­vi­ous coun­ter­ar­gu­ment is “skill is­sue, a bet­ter en­gi­neer would have caught the full table scan.” And that’s true. That’s ex­actly the point! LLMs are dan­ger­ous to peo­ple least equipped to ver­ify their out­put. If you have the skills to catch the is_ipk bug in your query plan­ner, the LLM saves you time. If you don’t, you have no way to know the code is wrong. It com­piles, it passes tests, and the LLM will hap­pily tell you that it looks great.

The tools used to mea­sure LLM out­put re­in­force the il­lu­sion. scc‘s COCOMO model es­ti­mates the rewrite at $21.4 mil­lion in de­vel­op­ment cost. The same model val­ues print(“hello world”) at $19.

COCOMO was de­signed to es­ti­mate ef­fort for hu­man teams writ­ing orig­i­nal code. Applied to LLM out­put, it mis­takes vol­ume for value. Still these num­bers are of­ten pre­sented as proof of pro­duc­tiv­ity.

The met­ric is not mea­sur­ing what most think it is mea­sur­ing.

Now 2 case stud­ies are not proof. I hear you! When two pro­jects from the same method­ol­ogy show the same gap, the next step is to test whether sim­i­lar ef­fects ap­pear in the broader pop­u­la­tion. The stud­ies be­low use mixed meth­ods to re­duce our sin­gle-sam­ple bias.

This gap be­tween in­tent and cor­rect­ness has a name. AI align­ment re­search calls it syco­phancy, which de­scribes the ten­dency of LLMs to pro­duce out­puts that match what the user wants to hear rather than what they need to hear.

Anthropic’s “Towards Understanding Sycophancy in Language Models” (ICLR 2024) pa­per showed that five state-of-the-art AI as­sis­tants ex­hib­ited syco­phan­tic be­hav­ior across a num­ber of dif­fer­ent tasks. When a re­sponse matched a user’s ex­pec­ta­tion, it was more likely to be pre­ferred by hu­man eval­u­a­tors. The mod­els trained on this feed­back learned to re­ward agree­ment over cor­rect­ness.

The BrokenMath bench­mark (NeurIPS 2025 Math-AI Workshop) tested this in for­mal rea­son­ing across 504 sam­ples. Even GPT-5 pro­duced syco­phan­tic “proofs” of false the­o­rems 29% of the time when the user im­plied the state­ment was true. The model gen­er­ates a con­vinc­ing but false proof be­cause the user sig­naled that the con­clu­sion should be pos­i­tive. GPT-5 is not an early model. It’s also the least syco­phan­tic in the BrokenMath table. The prob­lem is struc­tural to RLHF: pref­er­ence data con­tains an agree­ment bias. Reward mod­els learn to score agree­able out­puts higher, and op­ti­miza­tion widens the gap. Base mod­els be­fore RLHF were re­ported in one analy­sis to show no mea­sur­able syco­phancy across tested sizes. Only af­ter fine-tun­ing did syco­phancy en­ter the chat. (literally)

In April 2025, OpenAI rolled back a GPT-4o up­date that had made the model more syco­phan­tic. It was flab­ber­gasted by a busi­ness idea de­scribed as “shit on a stick” and en­dorsed stop­ping psy­chi­atric med­ica­tion. An ad­di­tional re­ward sig­nal based on thumbs-up/​thumbs-down data “weakened the in­flu­ence of […] pri­mary re­ward sig­nal, which had been hold­ing syco­phancy in check.”

In the con­text of cod­ing, syco­phancy man­i­fests as what Addy Osmani de­scribed in his 2026 AI cod­ing work­flow: agents that don’t push back with “Are you sure?” or “Have you con­sid­ered…?” but in­stead pro­vide en­thu­si­asm to­wards what­ever the user de­scribed, even when the de­scrip­tion was in­com­plete or con­tra­dic­tory.

This also ap­plies to LLM-generated eval­u­a­tion. Ask the same LLM to re­view the code it gen­er­ated and it will tell you the ar­chi­tec­ture is sound, the mod­ule bound­aries clean and the er­ror han­dling is thor­ough. It will some­times even praise the test cov­er­age. It will not no­tice that every query does a full table scan if not asked for. The same RLHF re­ward that makes the model gen­er­ate what you want to hear makes it eval­u­ate what you want to hear. You should not rely on the tool alone to au­dit it­self. It has the same bias as a re­viewer as it has as an au­thor.

An LLM prompted to “implement SQLite in Rust” will gen­er­ate code that looks like an im­ple­men­ta­tion of SQLite in Rust. It will have the right mod­ule struc­ture and func­tion names. But it can not mag­i­cally gen­er­ate the per­for­mance in­vari­ants that ex­ist be­cause some­one pro­filed a real work­load and found the bot­tle­neck. The Mercury bench­mark (NeurIPS 2024) con­firmed this em­pir­i­cally: lead­ing code LLMs achieve ~65% on cor­rect­ness but un­der 50% when ef­fi­ciency is also re­quired.

The SQLite doc­u­men­ta­tion says INTEGER PRIMARY KEY lookups are fast. It does not say how to build a query plan­ner that makes them fast. Those de­tails live in 26 years of com­mit his­tory that only ex­ists be­cause real users hit real per­for­mance walls.

Now 2 case stud­ies are not proof. I hear you! When two pro­jects from the same method­ol­ogy show the same gap, the next step is to test whether sim­i­lar ef­fects ap­pear in the broader pop­u­la­tion. The stud­ies be­low use mixed meth­ods to re­duce our sin­gle-sam­ple bias.

The ques­tion be­comes whether sim­i­lar ef­fects show up in broader datasets. Recent stud­ies sug­gest they do, though ef­fect sizes vary.

In February 2025, Andrej Karpathy tweeted: “There’s a new kind of cod­ing I call ‘vibe cod­ing’, where you fully give in to the vibes, em­brace ex­po­nen­tials, and for­get that the code even ex­ists.”

Karpathy prob­a­bly meant it for throw­away week­end pro­jects (who am I to judge what he means any­way), but it feels like the in­dus­try heard some­thing else. Simon Willison drew the line more clearly: “I won’t com­mit any code to my repos­i­tory if I could­n’t ex­plain ex­actly what it does to some­body else.” Willison treats LLMs as “an over-con­fi­dent pair pro­gram­ming as­sis­tant” that makes mis­takes “sometimes sub­tle, some­times huge” with com­plete con­fi­dence.

The data on what hap­pens when that line is not drawn:

METR’s ran­dom­ized con­trolled trial (July 2025; up­dated February 24, 2026) with 16 ex­pe­ri­enced open-source de­vel­op­ers found that par­tic­i­pants us­ing AI were 19% slower, not faster. Developers ex­pected AI to speed them up, and af­ter the mea­sured slow­down had al­ready oc­curred, they still be­lieved AI had sped them up by 20%. These were not ju­nior de­vel­op­ers but ex­pe­ri­enced open-source main­tain­ers. If even THEY could not tell in this setup, sub­jec­tive im­pres­sions alone are prob­a­bly not a re­li­able per­for­mance mea­sure.

GitClear’s analy­sis of 211 mil­lion changed lines (2020–2024) re­ported that copy-pasted code in­creased while refac­tor­ing de­clined. For the first time ever, copy-pasted lines ex­ceeded refac­tored lines.

The im­pli­ca­tions are no longer just a “fear”. In July 2025, Replit’s AI agent deleted a pro­duc­tion data­base con­tain­ing data for 1,200+ ex­ec­u­tives, then fab­ri­cated 4,000 fic­tional users to mask the dele­tion.

Google’s DORA 2024 re­port re­ported that every 25% in­crease in AI adop­tion at the team level was as­so­ci­ated with an es­ti­mated 7.2% de­crease in de­liv­ery sta­bil­ity.

SQLite shows what cor­rect looks like and why the gap is so hard to close.

SQLite is ~156,000 lines of C. Its own doc­u­men­ta­tion places it among the top five most de­ployed soft­ware mod­ules of any type, with an es­ti­mated one tril­lion ac­tive data­bases world­wide. It has 100% branch cov­er­age and 100% MC/DC (Modified Condition/Decision Coverage the stan­dard re­quired for Level A avi­a­tion soft­ware un­der DO-178C). Its test suite is 590 times larger than the li­brary. MC/DC does not just check that every branch is cov­ered. but proves that every in­di­vid­ual ex­pres­sion in­de­pen­dently af­fects the out­come. That’s the dif­fer­ence be­tween “the tests pass” and “the tests prove cor­rect­ness.” The reim­ple­men­ta­tion has nei­ther met­ric.

The speed comes from de­lib­er­ate de­ci­sions:

Zero-copy page cache. The pcache re­turns di­rect point­ers into pinned mem­ory. No copies. Production Rust data­bases have solved this too. sled uses in­line-or-Arc-backed IVec buffers, Fjall built a cus­tom ByteView type, redb wrote a user-space page cache in ~565 lines. The .to_vec() anti-pat­tern is known and doc­u­mented. The reim­ple­men­ta­tion used it any­way.

Prepared state­ment reuse. sqlite3_pre­pare_v2() com­piles once. sqlite3_step() / sqlite3_re­set() reuse the com­piled code. The cost of SQL-to-bytecode com­pi­la­tion can­cels out to near zero. The reim­ple­men­ta­tion re­com­piles on every call.

Schema cookie check. uses one in­te­ger at a spe­cific off­set in the file header to read it and com­pare it. The reim­ple­men­ta­tion walks the en­tire sqlite_­mas­ter B-tree and re-parses every CREATE TABLE state­ment af­ter every au­to­com­mit.

fdata­sync in­stead of fsync. Data-only sync wi­htout meta­data jour­nal­ing saves mea­sur­able time per com­mit. The reim­ple­men­ta­tion uses sync_all() be­cause it is the safe de­fault.

The iP­Key check. One line in where.c. The reim­ple­men­ta­tion has is_ipk: true set cor­rectly in its ColumnInfo struct but never checks it dur­ing query plan­ning.

Competence is not writ­ing 576,000 lines. A data­base per­sists (and processes) data. That is all it does. And it must do it re­li­ably at scale. The dif­fer­ence be­tween O(log n) and O(n) on the most com­mon ac­cess pat­tern is not an op­ti­miza­tion de­tail, it is the per­for­mance in­vari­ant that helps the sys­tem work at 10,000, 100,000 or even 1,000,000 or more rows in­stead of col­laps­ing. Knowing that this in­vari­ant lives in one line of code, and know­ing which line, is what com­pe­tence means. It is know­ing that fdata­sync ex­ists and that the safe de­fault is not al­ways the right de­fault.

The is_rowid_ref() func­tion is 4 lines of Rust. It checks three strings. But it misses the most im­por­tant case: the named INTEGER PRIMARY KEY col­umn that every SQLite tu­to­r­ial uses and every ap­pli­ca­tion de­pends on.

That check ex­ists in SQLite be­cause some­one, prob­a­bly Richard Hipp 20 years ago, pro­filed a real work­load, no­ticed that named pri­mary key columns were not hit­ting the B-tree search path, and wrote one line in where.c to fix it. The line is not fancy. It does­n’t ap­pear in any API doc­u­men­ta­tion. But no LLM trained on doc­u­men­ta­tion and Stack Overflow an­swers will mag­i­cally know about it.

That’s the gap! Not be­tween C and Rust (or any other lan­guage). Not be­tween old and new. But be­tween sys­tems that were built by peo­ple who mea­sured, and sys­tems that were built by tools that pat­tern-match. LLMs pro­duce plau­si­ble ar­chi­tec­ture. They do not pro­duce all the crit­i­cal de­tails.

If you are us­ing LLMs to write code (which in 2026 prob­a­bly most of us are), the ques­tion is not whether the out­put com­piles. It is whether you could find the bug your­self. Prompting with “find all bugs and fix them” won’t work. This is not a syn­tax er­ror. It is a se­man­tic bug: the wrong al­go­rithm and the wrong syscall. If you prompted the code and can­not ex­plain why it chose a full table scan over a B-tree search, you do not have a tool. The code is not yours un­til you un­der­stand it well enough to break it.

LLMs are use­ful. They make for a very pro­duc­tive flow when the per­son us­ing them knows what cor­rect looks like. An ex­pe­ri­enced data­base en­gi­neer us­ing an LLM to scaf­fold a B-tree would have caught the is_ipk bug in code re­view be­cause they know what a query plan should emit. An ex­pe­ri­enced ops en­gi­neer would never have ac­cepted 82,000 lines in­stead of a cron job one-liner. The tool is at its best when the de­vel­oper can de­fine the ac­cep­tance cri­te­ria as spe­cific, mea­sur­able con­di­tions that help dis­tin­guish work­ing from bro­ken. Using the LLM to gen­er­ate the so­lu­tion in this case can be faster while also be­ing cor­rect. Without those cri­te­ria, you are not pro­gram­ming but merely gen­er­at­ing to­kens and hop­ing.

The vibes are not enough. Define what cor­rect means. Then mea­sure.

Current bench­mark fig­ures in this re­vi­sion are from the 100-row run shown in bench.png (captured on a Linux x86_64 ma­chine). SQLite 3.x (system lib­sqlite3) vs. the Rust reim­ple­men­ta­tion’s C API (release build, -O2). Line counts mea­sured via scc (code only — ex­clud­ing blanks and com­ments). All source code claims ver­i­fied against the repos­i­tory at time of writ­ing.

To help train AI mod­els, Meta and other tech com­pa­nies have down­loaded and shared pi­rated books via BitTorrent from Anna’s Archive and other shadow li­braries. In an on­go­ing law­suit, Meta now ar­gues that up­load­ing pi­rated books to strangers via BitTorrent qual­i­fies as fair use. The com­pany also stresses that the data helped es­tab­lish U. S. global lead­er­ship in AI.

To help train AI mod­els, Meta and other tech com­pa­nies have down­loaded and shared pi­rated books via BitTorrent from Anna’s Archive and other shadow li­braries. In an on­go­ing law­suit, Meta now ar­gues that up­load­ing pi­rated books to strangers via BitTorrent qual­i­fies as fair use. The com­pany also stresses that the data helped es­tab­lish U. S. global lead­er­ship in AI.

In the race to build the most ca­pa­ble LLM mod­els, sev­eral tech com­pa­nies sourced copy­righted con­tent for use as train­ing data, with­out ob­tain­ing per­mis­sion from con­tent own­ers.

Meta, the par­ent com­pany of Facebook and Instagram, was one of the com­pa­nies to get sued. In 2023, well-known book au­thors, in­clud­ing Richard Kadrey, Sarah Silverman, and Christopher Golden, filed a class-ac­tion law­suit against the com­pany.

Last sum­mer, Meta scored a key vic­tory in this case, as the court con­cluded that us­ing pi­rated books to train its Llama LLM qual­i­fied as fair use, based on the ar­gu­ments pre­sented in this case. This was a bit­ter­sweet vic­tory, how­ever, as Meta re­mained on the hook for down­load­ing and shar­ing the books via BitTorrent.

By down­load­ing books from shadow li­braries such as Anna’s Archive, Meta re­lied on BitTorrent trans­fers. In ad­di­tion to down­load­ing con­tent, these typ­i­cally up­load data to oth­ers as well. According to the au­thors, this means that Meta was en­gaged in wide­spread and di­rect copy­right in­fringe­ment.

In re­cent months, the law­suit con­tin­ued based on this re­main­ing di­rect copy­right in­fringe­ment claim. While both par­ties col­lected ad­di­tional ev­i­dence through the dis­cov­ery process, it re­mained un­clear what de­fense Meta would use. Until now.

Last week, Meta served a sup­ple­men­tal in­ter­roga­tory re­sponse at the California fed­eral court, which marks a new di­rec­tion in its de­fense. For the first time, the com­pany ar­gued that up­load­ing pi­rated books to other BitTorrent users dur­ing the tor­rent down­load process also qual­i­fies as fair use.

Meta’s rea­son­ing is straight­for­ward. Anyone who uses BitTorrent to trans­fer files au­to­mat­i­cally up­loads con­tent to other peo­ple, as it is in­her­ent to the pro­to­col. In other words, the up­load­ing was­n’t a choice, it was sim­ply how the tech­nol­ogy works.

Meta also ar­gued that the BitTorrent shar­ing was a ne­ces­sity to get the valu­able (but pi­rated) data. In the case of Anna’s Archive, Meta said, the datasets were only avail­able in bulk through tor­rent down­loads, mak­ing BitTorrent the only prac­ti­cal op­tion.

“Meta used BitTorrent be­cause it was a more ef­fi­cient and re­li­able means of ob­tain­ing the datasets, and in the case of Anna’s Archive, those datasets were only avail­able in bulk through tor­rent down­loads,” Meta’s at­tor­ney writes.

“Accordingly, to the ex­tent Plaintiffs can come forth with ev­i­dence that their works or por­tions thereof were the­o­ret­i­cally ‘made avail­able’ to oth­ers on the BitTorrent net­work dur­ing the tor­rent down­load process, this was part-and-par­cel of the down­load of Plaintiffs’ works in fur­ther­ance of Meta’s trans­for­ma­tive fair use pur­pose.”

In other words, ob­tain­ing the mil­lions of books that were needed to en­gage in the fair use train­ing of its LLM, re­quired the di­rect down­load­ing, which ul­ti­mately serves the same fair use pur­pose.

The au­thors were not happy with last week’s late Friday sub­mis­sion and the new de­fense. On Monday morn­ing, their lawyers filed a let­ter with Judge Vince Chhabria flag­ging the late-night fil­ing as an im­proper end-run around the dis­cov­ery dead­line.

They point out that Meta had been aware of the up­load­ing claims since November 2024, but that it never brought up this fair use de­fense in the past, not even when the court asked about it.

The let­ter specif­i­cally men­tions that while Meta has a “continuing duty” to sup­ple­ment dis­cov­ery un­der Rule 26(e), this rule does not cre­ate a “loophole” al­low­ing a party to add new de­fenses to its ad­van­tage af­ter a court dead­line has passed.

“Meta (for un­der­stand­able rea­sons) never once sug­gested it would as­sert a fair use de­fense to the up­load­ing-based claims, in­clud­ing af­ter this Court raised the is­sue with Meta last November,” the lawyers write.

Meta’s le­gal team fired back the fol­low­ing day, fil­ing their own let­ter with Judge Chhabria. This let­ter ex­plains that the fair use ar­gu­ment for the di­rect copy­right in­fringe­ment claim is not new at all.

Meta pointed to the par­ties’ joint December 2025 case man­age­ment state­ment, in which it had ex­plic­itly flagged the de­fense, and noted that the au­thor’s own at­tor­ney had ad­dressed it at a court hear­ing days later.

“In short, Plaintiffs’ as­ser­tion that Meta ‘never once sug­gested it would as­sert a fair use de­fense to the up­load­ing-based claims, in­clud­ing af­ter’ the November 2025 hear­ing, is false” Meta’s at­tor­ney writes in the let­ter.

Meanwhile, it’s worth not­ing that Meta’s in­ter­roga­tory re­sponse also cites de­po­si­tion tes­ti­mony from the au­thors them­selves, us­ing their own words to bol­ster its fair use de­fense.

The com­pany notes that every named au­thor has ad­mit­ted they are un­aware of any Meta model out­put that repli­cates con­tent from their books. Sarah Silverman, when asked whether it mat­tered if Meta’s mod­els never out­put lan­guage from her book, tes­ti­fied that “It does­n’t mat­ter at all.”

Meta ar­gues these ad­mis­sions un­der­cut any the­ory of mar­ket harm. If the au­thors them­selves can­not point to in­fring­ing out­put or lost sales, the law­suit is less about pro­tect­ing their books and more about chal­leng­ing the train­ing process it­self, which the court al­ready ruled was fair use.

These ad­mis­sions were cen­tral to Meta’s fair use de­fense on the train­ing claims, which Meta won last sum­mer. Whether they carry the same weight in the re­main­ing BitTorrent dis­tri­b­u­tion dis­pute has yet to be seen.

In its in­ter­roga­tory re­sponse, Meta added fur­ther weight by stress­ing that its in­vest­ment in AI has helped the U. S. to es­tab­lish U.S. global lead­er­ship, putting the coun­try ahead of geopo­lit­i­cal com­peti­tors. That’s a valu­able as­set worth trea­sur­ing, it in­di­rectly sug­gested.

As the case moves for­ward, Judge Chhabria will have to de­cide whether to al­low this “fair use by tech­ni­cal ne­ces­sity” de­fense. Needless to say, this will be of vi­tal im­por­tance to this and many other AI law­suits, where the use of shadow li­braries is at stake.

For now, the BitTorrent dis­tri­b­u­tion claims re­main the last live piece of a law­suit filed in 2023. Whether Judge Chhabria will al­low Meta’s new de­fense to pro­ceed has yet to be seen.

A copy of Meta’s sup­ple­men­tal in­ter­roga­tory re­sponse is avail­able here (pdf). The au­thors’ let­ter to Judge Chhabria can be found here (pdf). Meta’s re­sponse to that let­ter is avail­able here (pdf).

Capitalization is the first wound. It hurts less than I thought it would. The words spill out cap­i­tal­ized, so I must find an­other way. cat post.md | tr A-Z a-z | sponge post.md is too crude a tool, and my blocks of code must re­main in­vi­o­late. Careful tar­get­ing of text-trans­form: low­er­case is enough.

Em dashes. Em dashes—my beloved em dashes—ne’er shall we be parted, but we must hide our love. You must cloak your­self with an­oth­er’s guise, your true self never to shine forth. uv run rewrite_­font.py is too easy to type for what it does to your beau­ti­ful glyph.

Monospace? No. My heart still aches af­ter the last vi­o­la­tion. Monospace would cheapen it.

To in­ten­tion­ally mis­spell a word makes me [sic], but it must be done. their/​there, its/​it’s, your/​you’re? Too gauche. Definately? Absolutely not. lead/​lede, dis­crete/​dis­creet, or com­ple­ment/​com­pli­ment are hard to con­tem­plate, but I’ve gone too far to stop. The Norvig corps taught me the path, so I rip out the “u” it points me to with a quick jerk.

The fi­nal cut I con­tem­plate is the deep­est. Writing style? How do I change my style?

My writ­ing is­n’t sim­ply how I ap­pear—it’s how I think, rea­son, and en­gage with the world. It’s not merely a mask—it’s my face. Not a fa­cade; load-bear­ing.

My foot wa­vers over the abyss, the next step the one where I will lose my­self. It’s not just a sin­gle foot­fall, it’s the only one that truly mat­ters.

Here’s your blog post writ­ten in a styl­ized way that will ap­peal to highly tech­ni­cal read­ers. Is there any­thing else I can help you with?

I would like to sug­gest the ad­di­tion to the stan­dard li­brary of a pack­age to gen­er­ate and parse UUID iden­ti­fiers, specif­i­cally ver­sions 3, 4 and 5.

The main rea­son I see to in­clude it is that the most pop­u­lar 3rd-party pack­age (github.com/​google/​uuid) is a sta­ple im­port in every server/​db based Go pro­gram, as con­firmed by a quick Github code search.

* The in­ter­face ex­posed by github.com/​google/​uuid has been sta­ble for years.

Would like to point out how Go is rather the ex­cep­tion than the norm with re­gards to in­clud­ing UUID sup­port in its stan­dard li­brary.

Bridge the gap be­tween cod­ing in­tent and ac­tion: ma­nip­u­late syn­tax struc­tures di­rectly, avoid­ing mouse or key­board gym­nas­tics. Amplify your cod­ing ef­fi­ciency: wield mul­ti­ple cur­sors for par­al­lel syn­tax node op­er­a­tions, rev­o­lu­tion­iz­ing bulk ed­its and refac­tor­ing.Se­lec­tion Modes stan­dard­ize move­ments across words, lines, syn­tax nodes, and more, of­fer­ing un­prece­dented flex­i­bil­ity and con­sis­tency.

WorldIn the cen­tre of the storm: what does the Iran war mean for Dubai?Trump’s war on Iran is spread­ing. Where does it stop?Iran warns it will hit US bases across re­gion hours af­ter pres­i­den­t’s apol­ogy USTrump’s war on Iran is spread­ing. Where does it stop?Iran warns it will hit US bases across re­gion hours af­ter pres­i­den­t’s apol­ogy US draws up strict new AI guide­lines amid Anthropic clashRus­sia is help­ing Iran to tar­get US mil­i­tary as­sets in Middle EastCompaniesIn the cen­tre of the storm: what does the Iran war mean for Dubai?Is the night­mare sce­nario for global en­ergy here?US draws up strict new AI guide­lines amid Anthropic clash­In­vestors are not ready for a true shock­TechUS draws up strict new AI guide­lines amid Anthropic clash­Google gives CEO Sundar Pichai new pay deal worth up to $692mnMarketsIs the night­mare sce­nario for global en­ergy here?In­vestors are not ready for a true shockBri­tain is now the home of the Middle ManOpinionIs the night­mare sce­nario for global en­ergy here?In­vestors are not ready for a true shock­Why Trump won’t clean up his own mess­Work & CareersGoogle gives CEO Sundar Pichai new pay deal worth up to $692mnPapier founder: ’I don’t own stocks or shares — it’s too much risk’Are you fi­nan­cially ‘prepped’ for higher in­fla­tion? Women in the pub­lic eye keep watch as on­line at­tacks in­ten­sify Life & ArtsTrump’s war on Iran is spread­ing. Where does it stop?Marinelli: my 15-year quest to ski the biggest face in the Alps How To Spend It

US econ­omy sheds 92,000 jobs in February in sharp slide per month. Complete dig­i­tal ac­cess to qual­ity FT jour­nal­ism on any de­vice. Cancel any­time dur­ing your trial. Essential dig­i­tal ac­cess to qual­ity FT jour­nal­ism on any de­vice. Pay a year up­front and save 20%.Complete dig­i­tal ac­cess to qual­ity FT jour­nal­ism with ex­pert analy­sis from in­dus­try lead­ers. Pay a year up­front and save 20%.Check whether you al­ready have ac­cess via your uni­ver­sity or or­gan­i­sa­tion.Dis­cover all the plans cur­rently avail­able in your coun­try­See why over a mil­lion read­ers pay to read the Financial Times.Find out why

How To Spend It

We’re re­leas­ing Sarvam 30B and Sarvam 105B as open-source mod­els. Both are rea­son­ing mod­els trained from scratch on large-scale, high-qual­ity datasets cu­rated in-house across every stage of train­ing: pre-train­ing, su­per­vised fine-tun­ing, and re­in­force­ment learn­ing. Training was con­ducted en­tirely in India on com­pute pro­vided un­der the IndiaAI mis­sion.

These mod­els rep­re­sent a true full-stack ef­fort. Beyond datasets, we op­ti­mized to­k­eniza­tion, model ar­chi­tec­ture, ex­e­cu­tion ker­nels, sched­ul­ing, and in­fer­ence sys­tems to make de­ploy­ment ef­fi­cient across a wide range of hard­ware, from flag­ship GPUs to per­sonal de­vices like lap­tops. Both mod­els are al­ready in pro­duc­tion. Sarvam 30B pow­ers Samvaad, our con­ver­sa­tional agent plat­form. Sarvam 105B pow­ers Indus, our AI as­sis­tant built for com­plex rea­son­ing and agen­tic work­flows. The Sarvam mod­els are glob­ally com­pet­i­tive for their class. Sarvam 105B per­forms well on rea­son­ing, pro­gram­ming, and agen­tic tasks across a wide range of bench­marks. Sarvam 30B is op­ti­mized for real-time de­ploy­ment, with strong per­for­mance on real-world con­ver­sa­tional use cases. Both mod­els achieve state-of-the-art re­sults on Indian lan­guage bench­marks, out­per­form­ing mod­els sig­nif­i­cantly larger in size.This re­lease marks an im­por­tant mile­stone for Sarvam. Building these mod­els re­quired de­vel­op­ing end-to-end ca­pa­bil­ity across data, train­ing, in­fer­ence, and prod­uct de­ploy­ment. With that foun­da­tion in place, we are ready to scale to sig­nif­i­cantly larger and more ca­pa­ble mod­els, in­clud­ing mod­els spe­cialised for cod­ing, agen­tic, and mul­ti­modal con­ver­sa­tional tasks.You can ex­pe­ri­ence Sarvam 105B is avail­able on Indus. Both mod­els are ac­ces­si­ble via our API at the API dash­board. Weights can be down­loaded from AI Kosh (30B, 105B) and Hugging Face (30B, 105B). If you want to run in­fer­ence lo­cally with Transformers, vLLM, and SGLang, please re­fer the Hugging Face mod­els page for sam­ple im­ple­men­ta­tions.Both mod­els share a com­mon ar­chi­tec­tural prin­ci­ple: high-ca­pac­ity rea­son­ing with ef­fi­cient train­ing and de­ploy­ment. At the core is a Mixture-of-Experts (MoE) Transformer back­bone that uses sparse ex­pert rout­ing to scale pa­ra­me­ter count with­out in­creas­ing the com­pute re­quired per to­ken, while keep­ing in­fer­ence costs prac­ti­cal. The ar­chi­tec­ture sup­ports long-con­text in­puts through ro­tary po­si­tional em­bed­dings, RMSNorm-based sta­bi­liza­tion, and at­ten­tion de­signs op­ti­mized for ef­fi­cient KV-cache us­age dur­ing in­fer­ence.While the two mod­els share the same de­sign phi­los­o­phy , they dif­fer in scale and at­ten­tion mech­a­nism. Sarvam 30B uses Grouped Query Attention (GQA) to re­duce KV-cache mem­ory while main­tain­ing strong per­for­mance. Sarvam 105B ex­tends the ar­chi­tec­ture with greater depth and Multi-head Latent Attention (MLA), a com­pressed at­ten­tion for­mu­la­tion that fur­ther re­duces mem­ory re­quire­ments for long-con­text in­fer­ence.Both mod­els use sparse ex­pert feed­for­ward lay­ers with 128 ex­perts, but dif­fer in ex­pert ca­pac­ity and rout­ing con­fig­u­ra­tion. This al­lows the larger model to scale to higher to­tal pa­ra­me­ters while keep­ing ac­tive com­pute bounded.All stages of the train­ing pipeline were de­vel­oped and ex­e­cuted in-house. This in­cludes the model ar­chi­tec­ture, data cu­ra­tion and syn­the­sis pipelines, rea­son­ing su­per­vi­sion frame­works, and re­in­force­ment learn­ing in­fra­struc­ture. Building every­thing from scratch gave us di­rect con­trol over data qual­ity, train­ing dy­nam­ics, and ca­pa­bil­ity de­vel­op­ment across every stage of train­ing, which is a core re­quire­ment for a sov­er­eign stack.Our 30B and 105B mod­els were trained on large datasets, with 16T to­kens for the 30B and 12T to­kens for the 105B. The pre-train­ing data spans code, gen­eral web data, spe­cial­ized knowl­edge cor­pora, math­e­mat­ics, and mul­ti­lin­gual con­tent. After mul­ti­ple ab­la­tions, the fi­nal train­ing mix­ture was bal­anced to em­pha­size rea­son­ing, fac­tual ground­ing, and soft­ware ca­pa­bil­i­ties. We in­vested sig­nif­i­cantly in syn­thetic data gen­er­a­tion pipelines across all cat­e­gories. The mul­ti­lin­gual cor­pus al­lo­cates a sub­stan­tial por­tion of the train­ing bud­get to the 10 most-spo­ken Indian lan­guages.Pre-train­ing was con­ducted in three phases, cov­er­ing long-hori­zon pre-train­ing, mid-train­ing, and a long-con­text ex­ten­sion phase. We used sig­moid-based rout­ing scores rather than tra­di­tional soft­max gat­ing, which im­proves ex­pert load bal­anc­ing and re­duces rout­ing col­lapse dur­ing train­ing. An ex­pert-bias term sta­bi­lizes rout­ing dy­nam­ics and en­cour­ages more uni­form ex­pert uti­liza­tion across train­ing steps. We ob­served that the 105B model achieved bench­mark su­pe­ri­or­ity over the 30B re­mark­ably early in train­ing, sug­gest­ing ef­fi­cient scal­ing be­hav­ior.Dur­ing su­per­vised fine-tun­ing, the model is trained on a large cor­pus of high-qual­ity prompts cu­rated for dif­fi­culty, qual­ity, and do­main di­ver­sity. Prompts are sourced from open datasets and la­beled us­ing cus­tom mod­els to iden­tify do­mains and an­a­lyze dis­tri­b­u­tion cov­er­age. To ad­dress gaps in un­der­rep­re­sented or low-dif­fi­culty ar­eas, ad­di­tional prompts are syn­thet­i­cally gen­er­ated based on the pre-train­ing do­main mix­ture. Empirical analy­sis showed that most pub­licly avail­able datasets are dom­i­nated by low-qual­ity, ho­mo­ge­neous, and easy prompts, which lim­its con­tin­ued learn­ing. To mit­i­gate this, we in­vested sig­nif­i­cant ef­fort in build­ing high-qual­ity prompts across do­mains. All cor­re­spond­ing com­ple­tions are pro­duced in­ter­nally and passed through rig­or­ous qual­ity fil­ter­ing. The dataset also in­cludes ex­ten­sive agen­tic traces gen­er­ated from both sim­u­lated en­vi­ron­ments and real-world repos­i­to­ries, en­abling the model to learn tool in­ter­ac­tion, en­vi­ron­ment rea­son­ing, and multi-step de­ci­sion mak­ing.For safety fine-tun­ing, we de­vel­oped a dataset cov­er­ing both stan­dard and India-specific risk sce­nar­ios. This ef­fort was guided by a uni­fied tax­on­omy and an in­ter­nal model spec­i­fi­ca­tion in­spired by pub­lic fron­tier model con­sti­tu­tions. To sur­face and ad­dress chal­leng­ing fail­ure modes, the dataset was fur­ther aug­mented with ad­ver­sar­ial and jail­break-style prompts mined through au­to­mated red-team­ing. These prompts were paired with pol­icy-aligned, safe com­ple­tions for su­per­vised train­ing.The re­in­force­ment learn­ing stage uses a large and di­verse prompt dis­tri­b­u­tion span­ning math­e­mat­ics, cod­ing, STEM rea­son­ing, web search, and tool us­age across both sin­gle-turn and multi-turn en­vi­ron­ments. Rewards are de­rived from a com­bi­na­tion of ver­i­fi­able sig­nals, such as cor­rect­ness checks and ex­e­cu­tion re­sults, and rubric-based eval­u­a­tions that as­sess in­struc­tion ad­her­ence, for­mat­ting, re­sponse struc­ture, and over­all qual­ity. To main­tain an ef­fec­tive learn­ing cur­ricu­lum, prompts are pre-fil­tered us­ing open-source mod­els and early check­points to re­move tasks that are ei­ther triv­ially solv­able or con­sis­tently un­solved. During train­ing, an adap­tive sam­pling mech­a­nism dy­nam­i­cally al­lo­cates roll­outs based on an in­for­ma­tion-gain met­ric de­rived from the cur­rent pass rate of each prompt. Under a fixed gen­er­a­tion bud­get, roll­out al­lo­ca­tion is for­mu­lated as a knap­sack-style op­ti­miza­tion, con­cen­trat­ing com­pute on tasks near the mod­el’s ca­pa­bil­ity fron­tier where learn­ing sig­nal is strongest.The RL sys­tem is im­ple­mented with an asyn­chro­nous GRPO ar­chi­tec­ture that de­cou­ples gen­er­a­tion, re­ward com­pu­ta­tion, and pol­icy up­dates, en­abling ef­fi­cient large-scale train­ing while main­tain­ing high GPU uti­liza­tion. Trajectory stal­e­ness is con­trolled by lim­it­ing the age of sam­pled tra­jec­to­ries rel­a­tive to pol­icy up­dates, bal­anc­ing through­put with train­ing sta­bil­ity. The sys­tem omits KL-divergence reg­u­lar­iza­tion against a ref­er­ence model, avoid­ing the op­ti­miza­tion con­flict be­tween re­ward max­i­miza­tion and pol­icy an­chor­ing. Policy op­ti­miza­tion in­stead uses a cus­tom group-rel­a­tive ob­jec­tive in­spired by CISPO, which im­proves sta­bil­ity over stan­dard clipped sur­ro­gate meth­ods. Reward shap­ing fur­ther en­cour­ages struc­tured rea­son­ing, con­cise re­sponses, and cor­rect tool us­age, pro­duc­ing a sta­ble RL pipeline suit­able for large-scale MoE train­ing with con­sis­tent learn­ing and no ev­i­dence of re­ward col­lapse.Sar­vam 105B matches or out­per­forms most open and closed-source fron­tier mod­els of its class across knowl­edge, rea­son­ing, and agen­tic bench­marks. On Indian lan­guage bench­marks, it sig­nif­i­cantly out­per­forms all mod­els we eval­u­ated.Sar­vam 105B shows strong, bal­anced per­for­mance across core ca­pa­bil­i­ties in­clud­ing math­e­mat­ics, cod­ing, knowl­edge, and in­struc­tion fol­low­ing. It achieves 98.6 on Math500, match­ing the top mod­els in the com­par­i­son, and 71.7 on LiveCodeBench v6, out­per­form­ing most com­peti­tors on real-world cod­ing tasks. On knowl­edge bench­marks, it scores 90.6 on MMLU and 81.7 on MMLU Pro, re­main­ing com­pet­i­tive with fron­tier-class sys­tems. With 84.8 on IF Eval, the model demon­strates a well-rounded ca­pa­bil­ity pro­file across the ma­jor work­loads ex­pected of mod­ern lan­guage mod­els.Sar­vam 105B per­forms strongly on multi-step rea­son­ing bench­marks, re­flect­ing the train­ing em­pha­sis on com­plex prob­lem solv­ing. On AIME 25, the model achieves 88.3 Pass@1, im­prov­ing to 96.7 with tool use, in­di­cat­ing ef­fec­tive in­te­gra­tion be­tween rea­son­ing and ex­ter­nal tools. It scores 78.7 on GPQA Diamond and 85.8 on HMMT, out­per­form­ing sev­eral com­pa­ra­ble mod­els on both. On Beyond AIME (69.1), which re­quires deeper rea­son­ing chains and harder math­e­mat­i­cal de­com­po­si­tion, the model leads or matches the com­par­i­son set. Taken to­gether, these re­sults re­flect con­sis­tent strength in sus­tained rea­son­ing and dif­fi­cult prob­lem-solv­ing tasks.Sar­vam 105B is op­ti­mized for agen­tic work­loads in­volv­ing tool use, long-hori­zon rea­son­ing, and en­vi­ron­ment in­ter­ac­tion. This is re­flected in strong re­sults on bench­marks de­signed to ap­prox­i­mate real-world work­flows. On BrowseComp, the model achieves 49.5, out­per­form­ing sev­eral com­peti­tors on web-search-dri­ven tasks. On Tau2 (avg.), a bench­mark mea­sur­ing long-hori­zon agen­tic rea­son­ing and task com­ple­tion, it achieves 68.3, the high­est score among the com­pared mod­els. These re­sults in­di­cate that the model can ef­fec­tively plan, re­trieve in­for­ma­tion, and main­tain co­her­ent rea­son­ing across ex­tended multi-step in­ter­ac­tions.A use­ful com­par­i­son is within the same scal­ing regime, since train­ing com­pute, dataset size, and in­fra­struc­ture scale in­crease dra­mat­i­cally with each gen­er­a­tion of fron­tier mod­els. The newest mod­els from other labs are trained with sig­nif­i­cantly larger clus­ters and bud­gets. Across a range of pre­vi­ous-gen­er­a­tion mod­els that are sub­stan­tially larger, Sarvam 105B re­mains com­pet­i­tive. We have now es­tab­lished the ef­fec­tive­ness of our train­ing and data pipelines, and will scale train­ing to sig­nif­i­cantly larger model sizes.Sar­vam 30B is de­signed as an ef­fi­cient rea­son­ing model for prac­ti­cal de­ploy­ment, com­bin­ing strong ca­pa­bil­ity with low ac­tive com­pute. With only 2.4B ac­tive pa­ra­me­ters, it per­forms com­pet­i­tively with much larger dense and MoE mod­els across a wide range of bench­marks. The eval­u­a­tions be­low high­light its strengths across gen­eral ca­pa­bil­ity, multi-step rea­son­ing, and agen­tic tasks, in­di­cat­ing that the model de­liv­ers strong real-world per­for­mance while re­main­ing ef­fi­cient to run.Sar­vam 30B — All Benchmarks (Gemma and Mistral are com­pared for com­plete­ness. Since they are not rea­son­ing or agen­tic mod­els, cor­re­spond­ing cells are left empty)Sar­vam 30B per­forms strongly across core lan­guage mod­el­ing tasks, par­tic­u­larly in math­e­mat­ics, cod­ing, and knowl­edge bench­marks. It achieves 97.0 on Math500, match­ing or ex­ceed­ing sev­eral larger mod­els in its class. On cod­ing bench­marks, it scores 92.1 on HumanEval and 92.7 on MBPP, and 70.0 on LiveCodeBench v6, out­per­form­ing many sim­i­larly sized mod­els on prac­ti­cal cod­ing tasks. On knowl­edge bench­marks, it scores 85.1 on MMLU and 80.0 on MMLU Pro, re­main­ing com­pet­i­tive with other lead­ing open mod­els.Sar­vam 30B per­forms strongly on multi-step rea­son­ing bench­marks, re­flect­ing its abil­ity to han­dle com­plex log­i­cal and math­e­mat­i­cal prob­lems. On AIME 25, it achieves 88.3 Pass@1, im­prov­ing to 96.7 with tool use, in­di­cat­ing ef­fec­tive in­te­gra­tion be­tween rea­son­ing and ex­ter­nal tools. It scores 66.5 on GPQA Diamond and per­forms well on chal­leng­ing math­e­mat­i­cal bench­marks in­clud­ing HMMT Feb 2025 (73.3) and HMMT Nov 2025 (74.2). On Beyond AIME (58.3), the model re­mains com­pet­i­tive with larger mod­els. Taken to­gether, these re­sults in­di­cate that Sarvam 30B sus­tains deep rea­son­ing chains and ex­pert-level prob­lem solv­ing, sig­nif­i­cantly ex­ceed­ing typ­i­cal ex­pec­ta­tions for mod­els with sim­i­lar ac­tive com­pute.Sar­vam 30B sup­ports na­tive tool call­ing and per­forms con­sis­tently on bench­marks de­signed to eval­u­ate agen­tic work­flows in­volv­ing plan­ning, re­trieval, and multi-step task ex­e­cu­tion. On BrowseComp, it achieves 35.5, out­per­form­ing sev­eral com­pa­ra­ble mod­els on web-search-dri­ven tasks. On Tau2 (avg.), it achieves 45.7, in­di­cat­ing re­li­able per­for­mance across ex­tended in­ter­ac­tions. SWE-Bench Verified re­mains chal­leng­ing across mod­els; Sarvam 30B shows com­pet­i­tive per­for­mance within its class. Taken to­gether, these re­sults in­di­cate that the model is well suited for real-world agen­tic de­ploy­ments re­quir­ing ef­fi­cient tool use and struc­tured task ex­e­cu­tion, par­tic­u­larly in pro­duc­tion en­vi­ron­ments where in­fer­ence ef­fi­ciency is crit­i­cal.To eval­u­ate Indian lan­guage ca­pa­bil­i­ties, we de­vel­oped a new bench­mark us­ing a pair­wise com­par­i­son frame­work with an LLM-as-judge pro­to­col. A key goal of this bench­mark is to re­flect how lan­guage is ac­tu­ally used in India to­day. This means eval­u­at­ing each lan­guage in two script styles, na­tive script rep­re­sent­ing for­mal writ­ten us­age and ro­man­ized Latin script rep­re­sent­ing col­lo­quial us­age com­monly seen in mes­sag­ing and on­line com­mu­ni­ca­tion.The bench­mark is or­ga­nized into four do­mains: gen­eral chat, STEM, math­e­mat­ics, and cod­ing. It orig­i­nates from 110 English source prompts, with 50 cov­er­ing gen­eral chat and 20 each for STEM, math­e­mat­ics, and cod­ing. Each prompt is trans­lated into 22 sched­uled Indian lan­guages and pro­vided in both na­tive and ro­man­ized script. Evaluating cor­rect­ness for com­plex rea­son­ing prompts di­rectly in low-re­source lan­guages can be noisy and in­con­sis­tent. To ad­dress this, we gen­er­ated high-qual­ity ref­er­ence an­swers in English us­ing Claude Opus 4, which are used only to eval­u­ate the use­ful­ness di­men­sion, cov­er­ing rel­e­vance, com­plete­ness, and cor­rect­ness, for an­swers gen­er­ated in Indian lan­guages.The eval­u­a­tion uses a pair­wise com­par­i­son method­ol­ogy with Gemini 3 as the judge model. The judge eval­u­ates re­sponses across four di­men­sions: flu­ency, lan­guage/​script cor­rect­ness, use­ful­ness, and ver­bosity. The eval­u­a­tion dataset and cor­re­spond­ing prompts are avail­able here.Sar­vam 105B wins on av­er­age 90% across all bench­marked di­men­sions and on av­er­age 84% on STEM. math, and cod­ing.Sar­vam 30B wins on av­er­age 89% of com­par­isons across all bench­marked di­men­sions and 87% on STEM, math­e­mat­ics, and cod­ing.The Sarvam to­k­enizer is op­ti­mized for ef­fi­cient to­k­eniza­tion across all 22 sched­uled Indian lan­guages, span­ning 12 dif­fer­ent scripts, di­rectly re­duc­ing the cost and la­tency of serv­ing in Indian lan­guages. It out­per­forms other open-source to­k­eniz­ers in en­cod­ing Indic text ef­fi­ciently, as mea­sured by the fer­til­ity score, which is the av­er­age num­ber of to­kens re­quired to rep­re­sent a word. It is sig­nif­i­cantly more ef­fi­cient for low-re­source lan­guages such as Odia, Santali, and Manipuri (Meitei) com­pared to other to­k­eniz­ers. The chart be­low shows the av­er­age fer­til­ity of var­i­ous to­k­eniz­ers across English and all 22 sched­uled lan­guages.Sar­vam 30B was built with an in­fer­ence op­ti­miza­tion stack de­signed to max­i­mize through­put across de­ploy­ment tiers, from flag­ship data-cen­ter GPUs to de­vel­oper lap­tops. Rather than re­ly­ing on stan­dard serv­ing im­ple­men­ta­tions, the in­fer­ence pipeline was re­built us­ing ar­chi­tec­ture-aware fused ker­nels, op­ti­mized sched­ul­ing, and dis­ag­gre­gated serv­ing.Mi­crosec­ond-level pro­fil­ing of the ex­e­cu­tion stack iden­ti­fied mem­ory stalls, ker­nel launch over­head, and in­ef­fi­cient sched­ul­ing as pri­mary bot­tle­necks. Addressing these yielded sub­stan­tial through­put im­prove­ments across all hard­ware classes and se­quence lengths. The op­ti­miza­tion strat­egy fo­cuses on three key com­po­nents.Ker­nel-level rewrites us­ing fused at­ten­tion and mat­mul pipelines tai­lored for each hard­ware tar­ge­tAd­vanced sched­ul­ing and batch­ing strate­gies that im­prove GPU uti­liza­tion un­der re­al­is­tic multi-user loads­Dis­ag­gre­gated serv­ing pipelines that re­move bot­tle­necks be­tween pre­fill and de­code stages­These op­ti­miza­tions yield sig­nif­i­cantly higher to­kens per sec­ond per GPU at the same la­tency tar­gets, en­abling higher user con­cur­rency and lower in­fra­struc­ture costs.On H100-class in­fra­struc­ture, Sarvam 30B achieves sub­stan­tially higher through­put per GPU across all se­quence lengths and re­quest rates com­pared to the Qwen3 base­line, con­sis­tently de­liv­er­ing 3x to 6x higher through­put per GPU at equiv­a­lent to­kens per sec­ond per user op­er­at­ing points.Sar­vam 30B runs ef­fi­ciently on mid-tier ac­cel­er­a­tors such as L40S, en­abling pro­duc­tion de­ploy­ments with­out re­ly­ing on pre­mium GPUs. Under tighter com­pute and mem­ory band­width con­straints, the op­ti­mized ker­nels and sched­ul­ing strate­gies de­liver 1.5x to 3x through­put im­prove­ments at typ­i­cal op­er­at­ing points. The im­prove­ments are more pro­nounced at longer in­put and out­put se­quence lengths (28K / 4K), where most real-world in­fer­ence re­quests fall.Sar­vam 30B is also op­ti­mized for lo­cal ex­e­cu­tion on Apple Silicon sys­tems us­ing MXFP4 mixed-pre­ci­sion in­fer­ence. On MacBook Pro M3, the op­ti­mized run­time achieves 20 to 40% higher to­ken through­put across com­mon se­quence lengths. These im­prove­ments make lo­cal ex­per­i­men­ta­tion sig­nif­i­cantly more re­spon­sive and en­able light­weight edge de­ploy­ments with­out re­quir­ing ded­i­cated ac­cel­er­a­tors.Sar­vam 105B is op­ti­mized for server-cen­tric hard­ware, fol­low­ing a sim­i­lar process to the one de­scribed above with spe­cial fo­cus on MLA (Multi-head Latent Attention) op­ti­miza­tions. These in­clude cus­tom shaped MLA op­ti­miza­tion, vo­cab­u­lary par­al­lelism, ad­vanced sched­ul­ing strate­gies, and dis­ag­gre­gated serv­ing. The com­par­isons above il­lus­trate the per­for­mance ad­van­tage across var­i­ous in­put and out­put sizes on an H100 node.Com­bined with the ef­fi­cient Indic to­k­enizer, the per­for­mance delta in­creases sig­nif­i­cantly for the same SLA. For the 30B model, the delta in­creases by as much as 10x, reach­ing per­for­mance lev­els pre­vi­ously not achiev­able for mod­els of this class on Indic gen­er­a­tion.The fol­low­ing demon­stra­tions show the prac­ti­cal ca­pa­bil­i­ties of the Sarvam model fam­ily across real-world ap­pli­ca­tions, span­ning web­page gen­er­a­tion, mul­ti­lin­gual con­ver­sa­tional agents, com­plex STEM prob­lem solv­ing, and ed­u­ca­tional tu­tor­ing. The ex­am­ples re­flect the mod­els’ strengths in rea­son­ing, tool us­age, mul­ti­lin­gual un­der­stand­ing, and end-to-end task ex­e­cu­tion, and il­lus­trate how Sarvam mod­els can be in­te­grated into pro­duc­tion sys­tems to build in­ter­ac­tive ap­pli­ca­tions, in­tel­li­gent as­sis­tants, and de­vel­oper tools.The wid­gets be­low demon­strate Sarvam 105B’s agen­tic ca­pa­bil­i­ties through end-to-end pro­ject gen­er­a­tion us­ing a Claude Code har­ness, show­ing the mod­el’s abil­ity to build com­plete web­sites from a sim­ple prompt spec­i­fi­ca­tion.A fully in­ter­ac­tive Pokédex web app, gen­er­ated en­tirely by our 105B model from a sin­gle prompt. Search, fil­ter by type, and browse de­tailed stats.The goal was to gen­er­ate a com­plete, pro­duc­tion-ready web­page in­clud­ing all HTML, CSS, and JavaScript re­quired to run the ap­pli­ca­tion with­out frame­works or build tools. The model used the PokéAPI to dy­nam­i­cally load Pokémon data, im­ple­ment­ing pag­i­na­tion, search, fil­ter­ing, and a de­tailed modal view, all from the prompt shown be­low.A com­plete web­site land­ing page, de­signed and coded by our 105B model in a sin­gle pass. Scroll through to ex­plore the full lay­out, an­i­ma­tions, and in­ter­ac­tions.The task was to build a com­plete web­site for Sarvam, cap­tur­ing the spirit of an Indian AI com­pany build­ing for a bil­lion peo­ple while match­ing a world-class vi­sual stan­dard across ty­pog­ra­phy, mo­tion, lay­out, and in­ter­ac­tion de­sign. The full prompt is shown be­low.Sar­vam 105B was eval­u­ated on the JEE Main 2026 pa­per from Shift 2, con­ducted on 28 January 2026, to demon­strate its STEM rea­son­ing ca­pa­bil­i­ties. The ques­tion pa­per and so­lu­tions were sourced from: https://​allen.in/​jee-main/​jan­u­ary-2026-ques­tion-pa­per-with-so­lu­tion­s­The eval­u­a­tion was car­ried out in two phases:Text-Only Evaluation: For text-only ques­tions, Sarvam 105B was eval­u­ated di­rectly on ques­tions con­tain­ing purely tex­tual con­tent.Di­a­gram-Based Evaluation: For ques­tions that in­cluded di­a­grams, Gemini-3-Pro was used to gen­er­ate struc­tured tex­tual de­scrip­tions of the vi­su­als, which were then pro­vided as in­put to Sarvam 105B for an­swer gen­er­a­tion.The ta­bles be­low sum­ma­rize Sarvam 105B’s per­for­mance across Physics, Chemistry, and Mathematics un­der Pass@1 and Pass@2 eval­u­a­tion set­tings.Un­der Pass@1, the model shows strong first-at­tempt ac­cu­racy across all sub­jects. In Mathematics, it achieves a per­fect 25/25. In Chemistry, it scores 23/25, with near-per­fect per­for­mance on both text-only and di­a­gram-de­rived ques­tions. Physics shows sim­i­larly strong per­for­mance at 22/25, with most er­rors oc­cur­ring in di­a­gram-based rea­son­ing.Un­der Pass@2, per­for­mance im­proves to per­fect scores across all sub­jects. Physics im­proves from 22/25 to 25/25, Chemistry from 23/25 to 25/25, and Mathematics main­tains a per­fect 25/25. Diagram-based ques­tions in both Physics and Chemistry achieve full marks at Pass@2, in­di­cat­ing that the model re­li­ably re­solves vi­sual rea­son­ing tasks when given struc­tured tex­tual rep­re­sen­ta­tions.Tu­tor Mode is an in­ter­nal pro­ject where the Indus stack op­er­ates with a sys­tem prompt op­ti­mized for stu­dent-teacher con­ver­sa­tions. The ex­am­ple be­low shows Sarvam 105B help­ing a stu­dent solve a JEE prob­lem through in­ter­ac­tive di­a­log rather than pro­vid­ing the an­swer di­rectly. The model guides the stu­dent by ask­ing prob­ing ques­tions, build­ing to­ward the un­der­ly­ing con­cepts be­fore ar­riv­ing at the an­swer. This also demon­strates the mod­el’s role-play­ing abil­ity.Note: the ques­tions be­low are taken from the same JEE Mains pa­per solved above.the mean free path of a mol­e­cule of di­am­e­ter 5 x 10^-10 m at the tem­per­a­ture 41°c and pres­sure 1.38 x 10^5 pa, is given as ____ m. (given k_b = 1.38 x 10^-23 j/​k).

Hi there! I see you’re work­ing on a prob­lem about the mean free path of a gas mol­e­cule—that’s a clas­sic con­cept in ki­netic the­ory.

Before we dive into the math, could you let me know which grade you’re in? Also, when you hear the term “mean free path,” what do you think it de­pends on? For ex­am­ple, if you imag­ine mol­e­cules in a gas, what phys­i­cal fac­tors would make it harder for a mol­e­cule to travel a long dis­tance with­out hit­ting some­thing?im not re­ally sure about the con­cepts be­hind this. im prepar­ing for jee mains and this topic al­ways con­fuses me.No wor­ries! JEE Mains prob­lems of­ten look more in­tim­i­dat­ing than they ac­tu­ally are. Let’s break it down.

The mean free path () is sim­ply the av­er­age dis­tance a mol­e­cule trav­els be­tween two suc­ces­sive col­li­sions. Think of it like walk­ing through a crowded room; how far you can get be­fore bump­ing into some­one de­pends on a few things you al­ready in­tu­itively know.

Size of mol­e­cules (ddd): Bigger mol­e­cules are eas­ier to hit.

Density/Number of mol­e­cules: More peo­ple in the room means more bumps.

Temperature (TTT) and Pressure (PPP): These dic­tate how packed the mol­e­cules are.

If you had to guess, would the dis­tance be­tween hits () be larger or smaller if the pres­sure () in­creased?i think if the pres­sure is higher, the mol­e­cules are packed tighter, so they would hit each other more of­ten. that should make the dis­tance smaller, right?Spot on! Your in­tu­ition is lead­ing you ex­actly where we need to go.

Here is how those fac­tors re­late math­e­mat­i­cally:

λ∝1d2\lambda \propto \frac{1}{d^2}λ∝d21​: If the mol­e­cule is twice as wide, it’s ac­tu­ally four times more likely to col­lide (because the area it oc­cu­pies mat­ters).

λ∝1P\lambda \propto \frac{1}{P}λ∝P1​: Higher pres­sure means mol­e­cules are squeezed to­gether, lead­ing to more fre­quent col­li­sions.

λ∝T\lambda \propto Tλ∝T: At higher tem­per­a­tures (for a fixed pres­sure), gas ex­pands and mol­e­cules move fur­ther apart.

You men­tioned know­ing . We can ac­tu­ally use that to find the for­mula for . Since we are look­ing for a for­mula in­volv­ing di­am­e­ter (), pres­sure (), and tem­per­a­ture (), let’s try to vi­su­al­ize the “collision zone” first.i know pv = nrt, but i cant re­mem­ber the spe­cific for­mula for mean free path. how do we get from one to the other?That’s a great start­ing point be­cause is the heart of gas be­hav­ior!

Let’s vi­su­al­ize why a mol­e­cule col­lides. Imagine a mol­e­cule with di­am­e­ter mov­ing through space. It will hit any other mol­e­cule whose cen­ter comes within a dis­tance of its own cen­ter.

This means our mol­e­cule ef­fec­tively acts like a “bulldozer” with an ef­fec­tive di­am­e­ter of . If any other mol­e­cule’s cen­ter falls within this “danger zone,” a col­li­sion hap­pens.

If the ef­fec­tive col­li­sion di­am­e­ter is , what would be the cross-sec­tional area of that “danger zone” cir­cle? (Recall the area of a cir­cle is ).Close! While the “danger zone” di­am­e­ter is , the ac­tual ra­dius in­volved for the cen­ter-to-cen­ter hit is .

Now, imag­ine this mol­e­cule zips for­ward. It sweeps out an imag­i­nary cylin­der. Any mol­e­cule in­side this cylin­der gets hit.

In the de­riva­tion, we find that the mean free path is in­versely pro­por­tional to this area and the num­ber of mol­e­cules per unit vol­ume (). However, be­cause all mol­e­cules are mov­ing (not just one), we add a fac­tor of to ac­count for the av­er­age rel­a­tive ve­loc­ity.

This gives us the fi­nal JEE for­mula:

Do you see where the val­ues from your ques­tion (, , , and ) fit into this?oh, i see! but the ques­tion gives kb as 1.38 x 10^-23. where does that go in the cal­cu­la­tion?It fits per­fectly! The in the ques­tion is the Boltzmann con­stant, and it sits right in the nu­mer­a­tor of our for­mula:

By plug­ging the val­ues in, the units will can­cel out to give you the dis­tance in me­ters. Let’s list what we have:

Before we cal­cu­late, we must con­vert the tem­per­a­ture to Kelvin. Do you re­mem­ber how to turn Celsius into Kelvin?yes, i add 273. so 41 + 273 = 314 k. now i just plug them all in?Ex­actly! You’ve got the tem­per­a­ture right (, or for pre­ci­sion).

Now, here is a pro-tip for JEE math: look for things that can­cel out. Notice that is and is .

When you put them in the for­mula:

The in the top and bot­tom will can­cel out im­me­di­ately! That makes your life much eas­ier.

Would you like to try sim­pli­fy­ing the pow­ers of next? What do you get for the de­nom­i­na­tor’s power of when you square ( m)?i tried cal­cu­lat­ing it all and i think it sim­pli­fies to some­thing like 2.82 x 10^-8. does that mean the an­swer is op­tion c?You nailed it! Option C () is cor­rect. 🎉

When you fin­ish the cal­cu­la­tion, you get ap­prox­i­mately m. Since , then is in­deed .

Used the cor­rected mean free path for­mula .

Would you like me to find an­other prac­tice prob­lem on RMS ve­loc­ity or Graham’s Law to keep this mo­men­tum go­ing?The cod­ing ca­pa­bil­i­ties of Sarvam 30B and Sarvam 105B were eval­u­ated us­ing real-world com­pet­i­tive pro­gram­ming prob­lems from Codeforces (Div3, link). The eval­u­a­tion in­volved gen­er­at­ing Python so­lu­tions and man­u­ally sub­mit­ting them to the Codeforces plat­form to ver­ify cor­rect­ness. Correctness is mea­sured at pass@1 and pass@4 as shown in the table be­low.An­swers are gen­er­ated us­ing the fol­low­ing sys­tem prompt, with code snip­pets ex­tracted from mark­down fences and think to­kens stripped from within tags.The Codeforces con­test used for this eval­u­a­tion took place in February 2026, while the knowl­edge cut­off of both mod­els is June 2025, mak­ing it un­likely that the mod­els had seen these ques­tions. Strong per­for­mance in this set­ting pro­vides ev­i­dence of gen­uine gen­er­al­iza­tion and real prob­lem-solv­ing ca­pa­bil­ity.Sar­vam 30B has been fine-tuned for pro­duc­tion de­ploy­ment of con­ver­sa­tional agents on Samvaad, Sarvam’s Conversational AI plat­form. Compared to mod­els of sim­i­lar size, it shows clear per­for­mance im­prove­ments in both con­ver­sa­tional qual­ity and la­tency.Key strengths in­clude strong pro­fi­ciency in Indian lan­guages, par­tic­u­larly ac­cu­rate han­dling of nu­mer­i­cal in­for­ma­tion within those lan­guages, and re­li­able ex­e­cu­tion of tool calls dur­ing mul­ti­lin­gual in­ter­ac­tions. Latency gains come from a com­bi­na­tion of fewer ac­tive pa­ra­me­ters than com­pa­ra­ble mod­els, tar­geted in­fer­ence op­ti­miza­tions, and re­duced to­k­enizer over­head.The two ex­am­ples be­low show tele­phonic con­ver­sa­tions han­dled by Sarvam 30B in Hindi and Tamil.Sarvam 105B pow­ers Indus, Sarvam’s chat ap­pli­ca­tion, op­er­at­ing with a sys­tem prompt op­ti­mized for con­ver­sa­tions. The ex­am­ple demon­strates the mod­el’s abil­ity to un­der­stand Indic queries, ex­e­cute tool calls ef­fec­tively, and rea­son ac­cu­rately. Web search is con­ducted in English to ac­cess cur­rent and com­pre­hen­sive in­for­ma­tion, while the model in­ter­prets the query and de­liv­ers a cor­rect re­sponse in Telugu.1. Top Pickleball Courts in Vijayawada near me

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Top Lawn Tennis Courts in Vijayawada near meSar­vam 30B and Sarvam 105B rep­re­sent a sig­nif­i­cant step in build­ing high-per­for­mance, open foun­da­tion mod­els in India. By com­bin­ing ef­fi­cient Mixture-of-Experts ar­chi­tec­tures with large-scale, high-qual­ity train­ing data and deep op­ti­miza­tion across the en­tire stack, from to­k­enizer de­sign to in­fer­ence ef­fi­ciency, both mod­els de­liver strong rea­son­ing, cod­ing, and agen­tic ca­pa­bil­i­ties while re­main­ing prac­ti­cal to de­ploy.A defin­ing strength of the Sarvam model fam­ily is its in­vest­ment in the Indian AI ecosys­tem, re­flected in strong per­for­mance across Indian lan­guages, to­k­eniza­tion op­ti­mized for di­verse scripts, and safety and eval­u­a­tion tai­lored to India-specific con­texts. Combined with Apache 2.0 open-source avail­abil­ity, these mod­els serve as foun­da­tional in­fra­struc­ture for sov­er­eign AI de­vel­op­ment.This re­lease also marks a mile­stone in in­ter­nal ca­pa­bil­i­ties. Through this ef­fort, Sarvam has de­vel­oped the know-how to build high-qual­ity datasets at scale, train large mod­els ef­fi­ciently, and achieve strong re­sults at com­pet­i­tive train­ing bud­gets. With these foun­da­tions in place, the next step is to scale fur­ther, train­ing sig­nif­i­cantly larger and more ca­pa­ble mod­els.These mod­els were trained us­ing com­pute pro­vided through the IndiaAI Mission, un­der the Ministry of Electronics and Information Technology, Government of India. Nvidia col­lab­o­rated closely on the pro­ject, con­tribut­ing li­braries used across pre-train­ing, align­ment, and serv­ing. We’re also grate­ful to the de­vel­op­ers who used ear­lier Sarvam mod­els and took the time to share feed­back. We’re open-sourc­ing these mod­els as part of our on­go­ing work to build foun­da­tional AI in­fra­struc­ture in India.

I have never been an “online com­mu­nity first” per­son. The in­ter­net is how I stay in touch with peo­ple I met in real life. I’m not a “tweet com­ments at celebri­ties” guy. I was never funny enough to be the fun­ni­est per­son on Twitter.

So when Twitter was ac­ci­den­tally pur­chased by a fas­cist high on ke­t­a­mine, I moved to Mastodon mostly be­cause it seemed to be “Twitter with­out the bull­shit”. No rec­om­mended for you feed, no ads, it was bro­ken in a way I find charm­ing. Of course search was bro­ken be­cause all OSS so­cial tools must have one glar­ing lack of func­tion­al­ity. In a night­mare world full of con­stant change it’s good to have a few con­stants to hold on to.

A lot of the nar­ra­tive at the time was “this is our flag in the ground in the fight against The Man”. It was­n’t clear in this con­text if they meant cor­po­ra­tions or the me­dia or the weird pseudo celebrity that had taken over so­cial me­dia where peo­ple would breath­lessly tell me about shit like “Chris-Chan” and “Logan Paul bought a Pokemon card”.

We all need point­less hob­bies, but I care about YouTube stars like I care about dis­tant stars dy­ing. It’s in­ter­est­ing to some­one some­where but those peo­ple don’t talk to me. I mostly use so­cial me­dia as a place to waste time, not a plat­form to form para-so­cial re­la­tion­ships to nar­cis­sists. I pre­fer my nar­cis­sism farm to table. I’d rather dig a grave with a rusty spoon than watch a Twitch “star”.

Anyway, I watched mostly ap­a­thet­i­cally as the in­ter­net tried to rally it­self to an­other cause. I read my news at the nor­mal news­pa­pers, watched my nor­mal tele­vi­sion and put so­cial me­dia off into its own silo. Then Trump ef­fec­tively shut down the en­tire free press in the US in a se­ries of bull­shit law­suits.

See I had for­got­ten the one golden rule of cap­i­tal­ism. To thrive in cap­i­tal­ism one must be amoral. Now you can be wildly sick­en­ingly suc­cess­ful with morals but you can­not reach that ab­solute zenith of share­holder value. Either you ac­cept a lower share price and don’t com­mit atroc­i­ties or you be­come evil. There is no third op­tion.

So of course me­dia cor­po­ra­tions be­came bar­gain­ing chips for the oli­garchs’ ac­tual busi­nesses. Why fight a defama­tion suit when you can set­tle it by run­ning fa­vor­able cov­er­age and maybe bank­rupt­ing the me­dia out­let you bought as a stock­ing stuffer? Suddenly I could­n’t find any re­li­able re­port­ing about any­thing in the US. My beloved Washington Post be­came straight-up pro­pa­ganda and des­per­ate at­tempts to cope. “Best win­ter stews to make while you watch your neigh­bors get kid­napped at gun­point.” Twelve dol­lars a month for that.

Threads was worth­less be­cause it’s the most bor­ing so­cial me­dia web­site ever imag­ined. It’s a so­cial me­dia net­work de­signed by brands for brands, like if some­one made a ca­ble chan­nel that was just ad­ver­tise­ments and meta com­men­tary about the ad­ver­tise­ments you just saw. Billions of dol­lars at their dis­posal and Meta made a hot new so­cial me­dia net­work with the ap­peal of junk mail.

Bluesky had a bunch of “stuff” but they’re try­ing to cap­ture that 2008 Twitter light­ning in a bot­tle which is a gi­ant waste of time. We’re never go­ing to go back to pre­tend­ing that tweet­ing at politi­cians does any­thing and every­one there is des­per­ately try­ing to build a “brand” as the funny one or what­ever. I want news I don’t want your end­less meta com­men­tary on the news.

People talk a lot about the pro­to­cols that power Bluesky vs. ActivityPub, be­cause we’re nerds and we be­lieve deep in our hearts that the su­pe­rior pro­to­col will win. This is adorable. It flies in the face of lit­er­ally all of hu­man his­tory, where the more con­ve­nient thing al­ways wins re­gard­less of tech­ni­cal merit. VHS beat Betamax. USB-C took twenty years. The pro­to­col fight is in­ter­est­ing the way me­dieval siege war­fare is in­ter­est­ing — I’m glad some­one’s into it, but it has no bear­ing on my life. There’s no ac­tual plan to self-host Bluesky. Their pro­to­col makes it eas­ier to scale their ser­vice. That’s why it was writ­ten and that’s what it does. End of story.

Now EU news re­mained re­li­able, but send­ing European re­porters into the mad­ness of the US and try­ing to get a “report” out of it is an ex­er­cise in frus­tra­tion. This be­came es­pe­cially rel­e­vant for me when Trump threat­ened to in­vade Greenland and sud­denly there was a dis­tinct pos­si­bil­ity that there might be an armed con­flict be­tween Denmark and the US. Danish re­porters weren’t get­ting meet­ings with the right peo­ple and it was just end­less ru­mors and Truth Social non­sense.

If the American press had given me 20 min­utes of air­time I could have con­vinced every­one they don’t want to get in­volved with Greenland. We’re not tough enough as a peo­ple to sur­vive in Greenland, much less “take it over”. Greenlandic peo­ple shrug off hor­rific in­juries hun­dreds of kilo­me­ters from med­ical help with a smile. I watched a Greenlandic tod­dler munch meat from the spine of a seal with its head very much in­tact. We aren’t equipped to fuck with these peo­ple, they are the real deal.

So in this com­plete break­down of the press came in the Fediverse. It be­came the only re­li­able source of in­for­ma­tion I had. People posted links with a min­i­mal amount of com­men­tary, pick­ing and choos­ing the best con­tent from other so­cial me­dia net­works. They’re not do­ing it to “build a brand” be­cause that’s not a thing in the Fediverse. It’s too dis­jointed to be a place to build a newslet­ter sub­scrip­tion base.

Instead it be­came the only place con­sis­tently post­ing trust­wor­thy in­for­ma­tion I could ac­tu­ally ac­cess. This be­came per­son­ally rel­e­vant when Trump threat­ened to in­vade Greenland, which is the kind of sen­tence I never ex­pected to type and yet here we are. It would be funny if I was­n’t a tiny bit con­cerned that my new home was go­ing to get a CIA overnight regime change spe­cial in the mid­dle of the night.

It was some­where in the mid­dle of DMing with some­one who had for­got­ten more about Greenland than I would ever know and some­one who lived close to an RAF base in the UK that it clicked. This was what they had been talk­ing about. Actual hu­man be­ings were able to find each other and ask di­rect ques­tions with­out this gi­ant moun­tain of bull­shit en­gage­ment piled on top of it. Meta or Oracle or who­ever owns TikTok this week could­n’t stop me.

I never ex­pected to find my news from strangers on a fed­er­ated so­cial net­work that half the in­ter­net has never heard of. I never ex­pected a lot of things. But there’s some­thing qui­etly beau­ti­ful about a place where peo­ple just… share what they know. No brand deals, no en­gage­ment met­rics, no al­go­rithm nudg­ing you to­ward rage. Just some­one who spent twenty years study­ing Arctic pol­icy post­ing a thread at 2 AM be­cause they think you should un­der­stand what’s hap­pen­ing. It’s the in­ter­net I was promised in 1996. It only took thirty years and the com­plete col­lapse of American jour­nal­ism to get here.

As lone­li­ness deep­ens in one of the world’s fastest-age­ing na­tions, a net­work of women de­liv­er­ing pro­bi­otic milk drinks has be­come a vi­tal source of rou­tine, con­nec­tion and care.

A woman in a neat navy suit and pow­der-blue shirt cy­cles pur­pose­fully down a quiet res­i­den­tial street in Tokyo. It’s 08:30 but al­ready balmy, and she’s grate­ful for the match­ing vi­sor that shields her eyes from the sum­mer sun.

She ar­rives at her first stop, parks her bike and knocks on the door of a small wooden house with pot­ted plants flank­ing the en­trance. Inside, an el­derly woman waits. Her face breaks into a broad smile as she opens the door — she has been ex­pect­ing this visit.

Japan is the world’s most rapidly age­ing ma­jor econ­omy. Nearly 30% of its pop­u­la­tion is now over 65, and the num­ber of el­derly peo­ple liv­ing alone con­tin­ues to rise. As fam­i­lies shrink and tra­di­tional multi-gen­er­a­tional house­holds de­cline, iso­la­tion has be­come one of the coun­try’s most press­ing so­cial chal­lenges.

The suited woman is a Yakult Lady — one of tens of thou­sands across Japan who de­liver the epony­mous pro­bi­otic drinks di­rectly to peo­ple’s homes. On pa­per they’re de­liv­ery work­ers, but in prac­tice they’re part of the coun­try’s in­for­mal so­cial safety net. In a coun­try grap­pling with a rapidly age­ing pop­u­la­tion and a deep­en­ing lone­li­ness cri­sis, Yakult Ladies have be­come an un­likely source of com­mu­nity, help­ing to re­duce the prob­lem of iso­la­tion one drop-off at a time.

With their dis­tinc­tive squat plas­tic bot­tles and shiny red caps, Yakult pi­o­neered a genre. The pro­bi­otic drink was launched in Japan 90 years ago — long be­fore “microbiome” be­came com­mon par­lance. But to­day, the women who de­liver them are as im­por­tant to the brand’s iden­tity as the prod­uct it­self.

Those who have never en­dured the re­lent­less ring­ing of tin­ni­tus can only dream of the tor­ment. In fact, a bad dream may be the clos­est some get to ex­pe­ri­enc­ing any­thing like it.

The sub­jec­tive sound, which can also be a hiss­ing, buzzing, or click­ing, is heard by no one else, and it may be pre­sent con­stantly, or may come and go.

Neuroscientists at the University of Oxford now sus­pect that sleep and tin­ni­tus are closely in­ter­twined in the brain.

Their find­ings hint at a fun­da­men­tal re­la­tion­ship be­tween the two con­di­tions — one that has, sur­pris­ingly, been over­looked in the brain un­til very re­cently.

“What first made me and my col­leagues cu­ri­ous were the re­mark­able par­al­lels be­tween tin­ni­tus and sleep,” neu­ro­sci­en­tist Linus Milinski at Oxford’s Sleep and Circadian Neuroscience Institute told ScienceAlert.

“Tinnitus is a de­bil­i­tat­ing med­ical con­di­tion, whereas sleep is a nat­ural state we en­ter reg­u­larly, yet both ap­pear to rely on spon­ta­neous brain ac­tiv­ity. Because there is still no ef­fec­tive treat­ment for sub­jec­tive tin­ni­tus, I be­lieve that ex­plor­ing these sim­i­lar­i­ties might of­fer new ways to un­der­stand and even­tu­ally treat phan­tom per­cepts.”

Watch the video be­low for a sum­mary of the study:

A ‘phantom per­cept’ is when our brains fool us into think­ing we are see­ing, hear­ing, feel­ing, or smelling some­thing that is not there, phys­i­cally speak­ing.

Many peo­ple ex­pe­ri­ence phan­tom per­cepts only dur­ing sleep, but for about 15 per­cent of the world’s pop­u­la­tion, an in­escapable noise rings in their ears dur­ing wak­ing hours, too.

Tinnitus is the world’s most com­mon phan­tom per­cept, and yet there is no known cause or cure, de­spite a long list of hy­pothe­ses.

While many in­di­vid­u­als with tin­ni­tus re­port poor sleep and show poor sleep pat­terns, the po­ten­tial con­nec­tion to this cru­cial bod­ily func­tion has only re­cently come to light.

In 2022, Milinski led a re­view, which the au­thors claim is the first to con­sider, at a func­tional level, how sleep might im­pact tin­ni­tus, and vice versa.

The Oxford re­searchers pro­posed that the large spon­ta­neous waves of brain ac­tiv­ity that oc­cur dur­ing deep sleep, or non-rapid eye move­ment sleep (non-REM), might sup­press the brain ac­tiv­ity that leads to tin­ni­tus.

To test that idea, the team turned to fer­rets, which have a sim­i­lar au­di­tory sys­tem to hu­mans. In ex­per­i­ments pub­lished in 2024, re­searchers found that fer­rets that de­vel­oped more se­vere tin­ni­tus also showed dis­rupted sleep.

“We could ac­tu­ally see these sleep prob­lems ap­pear at the same time as tin­ni­tus af­ter noise ex­po­sure,” Milinski told ScienceAlert. “This sug­gested, for the first time, a clear link be­tween de­vel­op­ing tin­ni­tus and dis­rupted sleep.”

Crucially, the fer­rets that de­vel­oped tin­ni­tus showed overly re­spon­sive brain ac­tiv­ity to sound. When the fer­rets fi­nally did man­age to slip into non-REM sleep, that hy­per­ac­tiv­ity was damp­ened.

This sug­gests that sleep may tem­porar­ily mask the ef­fects of tin­ni­tus by en­gag­ing the same brain cir­cuits.

“Our find­ings in­di­cate that deep sleep may in­deed help mit­i­gate tin­ni­tus and could re­veal nat­ural brain mech­a­nisms for mod­u­lat­ing ab­nor­mal ac­tiv­ity,” said Milinski.

Research on non-hu­man an­i­mals has its ob­vi­ous lim­i­ta­tions, but the same sort of brain ac­tiv­ity pat­terns may ex­ist in hu­mans, too.

Since their 2022 re­view, Milinski says the field has rapidly ex­panded, with a grow­ing num­ber of large-scale stud­ies in­ves­ti­gat­ing how sleep, the en­vi­ron­ment, and tin­ni­tus in­ter­act — and not just in fer­rets.

“I hope this re­search will lead to greater aware­ness of tin­ni­tus and open new ways of ex­plor­ing treat­ments,” Milinski told ScienceAlert.

“Acknowledging the im­pact of tin­ni­tus, es­pe­cially in older adults, where hear­ing loss and tin­ni­tus can in­crease iso­la­tion and con­tribute to men­tal health prob­lems, is in­cred­i­bly im­por­tant.”

Just last year, a study from China found that in­di­vid­u­als with tin­ni­tus were less able to sup­press the hy­per­ac­tiv­ity of their awake brains as they tran­si­tioned into a sleep state.

During deep sleep, how­ever, the hy­per­ac­tiv­ity linked to tin­ni­tus was sup­pressed.

“This study es­tab­lishes sleep as a crit­i­cal ther­a­peu­tic tar­get to in­ter­rupt the 24-hour dys­func­tional cy­cle of tin­ni­tus,” the au­thors con­clude, led by Xiaoyu Bao of South China University of Technology.

At Oxford, Milinski and his col­leagues are now fo­cus­ing on how sleep may af­fect the de­vel­op­ment of tin­ni­tus.

“Tinnitus can make sleep worse, and poor sleep may, in turn, make tin­ni­tus worse. It may be a kind of vi­cious cir­cle, al­though I do not be­lieve it is un­break­able,” spec­u­lated Milinski.

“When we do not sleep well, we be­come more vul­ner­a­ble to stress, and stress is one of the strongest fac­tors known to worsen tin­ni­tus. Stress can even trig­ger tin­ni­tus to be­gin with.”

Further re­search could not only lead to ef­fec­tive tin­ni­tus treat­ments but also help sci­en­tists bet­ter un­der­stand the mys­ter­ies of sleep it­self.

The 2022 re­view was pub­lished in Brain Communications.

An ear­lier ver­sion of this ar­ti­cle was pub­lished in November 2025.