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GitHub - MinishLab/semble: Fast and Accurate Code Search for Agents. Uses ~98% fewer tokens than grep+read

github.com

413 shares · 19 trendiness

Semble is a code search library built for agents. It returns the exact code snippets they need instantly, using ~98% fewer tokens than grep+read. Indexing and searching a full codebase end-to-end takes under a second, with ~200x faster indexing and ~10x faster queries than a code-specialized transformer, at 99% of its retrieval quality (see benchmarks). Everything runs on CPU with no API keys, GPU, or external services. Run it as an MCP server or call it from the shell via AGENTS.md and any agent (Claude Code, Cursor, Codex, OpenCode, etc.) gets instant access to any repo.

Quickstart

Your agent queries Semble in natural language (e.g. “How is authentication handled?“) and gets back only the relevant code snippets, without grepping or reading full ﬁles. Set it up as an MCP server or via AGENTS.md:

MCP (Claude Code)

Add Semble to Claude Code (requires uv):

claude mcp add semble -s user — uvx –from “semble[mcp]” semble

Using Codex, OpenCode, or Cursor? See MCP Server for setup instructions.

Bash / AGENTS.md

Install Semble, then add the snippet below to your AGENTS.md or CLAUDE.md:

pip install semble # Install with pip uv tool install semble # Or install with uv

## Code Search

Use `semble search` to ﬁnd code by describing what it does or naming a symbol/identiﬁer, instead of grep:

```bash semble search “authentication ﬂow” ./my-project semble search “save_pretrained” ./my-project semble search “save model to disk” ./my-project –top-k 10 ```

Use `semble ﬁnd-related` to discover code similar to a known location (pass `ﬁle_path` and `line` from a prior search result):

```bash semble ﬁnd-related src/auth.py 42 ./my-project ```

`path` defaults to the current directory when omitted; git URLs are accepted.

If `semble` is not on `$PATH`, use `uvx –from “semble[mcp]” semble` in its place.

### Workﬂow

1. Start with `semble search` to ﬁnd relevant chunks. 2. Inspect full ﬁles only when the returned chunk is not enough context. 3. Optionally use `semble ﬁnd-related` with a promising result’s `ﬁle_path` and `line` to discover related implementations. 4. Use grep only when you need exhaustive literal matches or quick conﬁrmation of an exact string.

Once installed, run semble savings to see how many tokens Semble has saved you. Note that for sub-agent support in Claude Code or Codex, you need the full Bash / AGENTS.md setup below.

pip install –upgrade semble # with pip uv tool upgrade semble # with uv uv cache clean semble # for MCP users (restart your MCP client after)

Main Features

Fast: indexes an average repo in ~250 ms and answers queries in ~1.5 ms, all on CPU.

Accurate: NDCG@10 of 0.854 on our benchmarks, on par with code-specialized transformer models, at a fraction of the size and cost.

Token-efﬁcient: returns only the relevant chunks, using ~98% fewer tokens than grep+read.

Zero setup: runs on CPU with no API keys, GPU, or external services required.

MCP server: works with Claude Code, Cursor, Codex, OpenCode, and any other MCP-compatible agent.

Local and remote: pass a local path or a git URL.

MCP Server

Semble can run as an MCP server so agents can search any codebase directly. Repos are cloned and indexed on demand, and indexes are cached for the lifetime of the session. Local paths are watched for ﬁle changes and re-indexed automatically.

Setup

Requires uv to be installed.

Claude Code

claude mcp add semble -s user — uvx –from “semble[mcp]” semble

Codex

Add to ~/.codex/conﬁg.toml:

[mcp_servers.semble] command = “uvx” args = [“–from”, “semble[mcp]”, “semble”]

OpenCode

Add to ~/.opencode/conﬁg.json:

{ “mcp”: { “semble”: { “type”: “local”, “command”: [“uvx”, “–from”, “semble[mcp]”, “semble”] } } }

Cursor

Add to ~/.cursor/mcp.json (or .cursor/mcp.json in your project):

{ “mcpServers”: { “semble”: { “command”: “uvx”, “args”: [“–from”, “semble[mcp]”, “semble”] } } }

Tools

Bash / AGENTS.md

An alternative to MCP is to invoke Semble via Bash. For Claude Code and Codex CLI, this is the only option for sub-agents, which cannot call MCP tools directly, though it can also be used alongside MCP for the top-level agent.

To add Bash support, append the following to your AGENTS.md or CLAUDE.md:

## Code Search

Use `semble search` to ﬁnd code by describing what it does or naming a symbol/identiﬁer, instead of grep:

```bash semble search “authentication ﬂow” ./my-project semble search “save_pretrained” ./my-project semble search “save model to disk” ./my-project –top-k 10 ```

Use `semble ﬁnd-related` to discover code similar to a known location (pass `ﬁle_path` and `line` from a prior search result):

```bash semble ﬁnd-related src/auth.py 42 ./my-project ```

`path` defaults to the current directory when omitted; git URLs are accepted.

If `semble` is not on `$PATH`, use `uvx –from “semble[mcp]” semble` in its place.

## Workﬂow

Claude Code sub-agent: Claude Code also supports a dedicated sub-agent. Run this once in your project root:

semble init # or, if semble is not on $PATH: uvx –from “semble[mcp]” semble init

This writes .claude/agents/semble-search.md.

CLI

Semble also ships as a standalone CLI. This is useful in scripts or anywhere you want search results without an MCP session.

# Search a local repo semble search “authentication ﬂow” ./my-project

# Search for a symbol or identiﬁer semble search “save_pretrained” ./my-project

# Search a remote repo (cloned on demand) semble search “save model to disk” https://github.com/MinishLab/model2vec

# Limit results semble search “save model to disk” ./my-project –top-k 10

# Find code similar to a known location semble ﬁnd-related src/auth.py 42 ./my-project

path defaults to the current directory when omitted; git URLs are accepted. If semble is not on $PATH, use uvx –from “semble[mcp]” semble in its place.

semble savings shows how many tokens semble has saved across all your searches:

semble savings # summary by period semble savings –verbose # also show breakdown by call type

Semble Token Savings ════════════════════════════════════════════════════════════════ Period Calls Savings ──────────────────────────────────────────────────────────────── Today 42 [███████████████░] ~58.4k tokens (95%) Last 7 days 287 [██████████████░░] ~312.4k tokens (90%) All time 1.4k [██████████████░░] ~1.2M tokens (89%)

Savings are calculated as follows: for each call, semble records the total character count of the unique ﬁles containing returned chunks and the character count of the snippets returned. Estimated tokens saved is (ﬁle chars − snippet chars) / 4 (4 chars per token). This is a conservative estimate: the baseline is reading matched ﬁles in full, which is how coding agents often explore unfamiliar code.

Stats are stored in ~/.semble/savings.jsonl.

Semble can also be used as a Python library for programmatic access, useful when building custom tooling or integrating search directly into your own code.

from semble import SembleIndex

# Index a local directory index = SembleIndex.from_path(”./my-project”)

# Index a remote git repository index = SembleIndex.from_git(“https://github.com/MinishLab/model2vec”)

# Search the index with a natural-language or code query results = index.search(“save model to disk”, top_k=3)

# Find code similar to a speciﬁc result related = index.ﬁnd_related(results[0], top_k=3)

# Each result exposes the matched chunk result = results[0] result.chunk.ﬁle_path # “model2vec/model.py” result.chunk.start_line # 127 result.chunk.end_line # 150 result.chunk.content # “def save_pretrained(self, path: PathLike, …”

Benchmarks

We benchmark quality and speed across ~1,250 queries over 63 repositories in 19 languages (left), and token efﬁciency against grep+read at equivalent recall levels (right).

The quality benchmark (left) scores retrieval quality (NDCG@10) against total latency; semble achieves 99% of the quality of the 137M-parameter CodeRankEmbed Hybrid while indexing 218x faster. The token efﬁciency benchmark (right) measures how many tokens each method needs to reach a given recall level; semble uses 98% fewer tokens on average and hits 94% recall at only 2k tokens, while grep+read needs a full 100k context window to reach 85%. See benchmarks for per-language results, ablations, and full methodology.

How it works

Semble splits each ﬁle into code-aware chunks using tree-sitter, then scores every query against the chunks with two complementary retrievers: static Model2Vec embeddings using the code-specialized potion-code-16M model for semantic similarity, and BM25 for lexical matches on identiﬁers and API names. The two score lists are fused with Reciprocal Rank Fusion (RRF).

After fusing, results are reranked with a set of code-aware signals:

Adaptive weighting. Symbol-like queries (Foo::bar, _private, getUserById) get more lexical weight, while natural-language queries stay balanced between semantic and lexical retrievers.

Deﬁnition boosts. A chunk that deﬁnes the queried symbol (a class, def, func, etc.) is ranked above chunks that merely reference it.

Identiﬁer stems. Query tokens are stemmed and matched against identiﬁer stems in a chunk, giving an additional weight to chunks that contain them. For example, querying parse conﬁg boosts chunks containing parseConﬁg, ConﬁgParser, or conﬁg_parser.

File coherence. When multiple chunks from the same ﬁle match the query, the ﬁle is boosted so the top result reﬂects broad ﬁle-level relevance rather than a single out-of-context chunk.

Noise penalties. Test ﬁles, compat//legacy/ shims, example code, and .d.ts declaration stubs are down-ranked so canonical implementations surface ﬁrst.

Because the embedding model is static with no transformer forward pass at query time, all of this runs in milliseconds on CPU.

License

MIT

Citing

If you use Semble in your research, please cite the following:

@software{minishlab2026semble, author = {{van Dongen}, Thomas and Stephan Tulkens}, title = {Semble: Fast and Accurate Code Search for Agents}, year = {2026}, publisher = {Zenodo}, doi = {10.5281/zenodo.19785932}, url = {https://github.com/MinishLab/semble}, license = {MIT} }

Read more Read the original on github.com →

Read the original on github.com →

GenCAD: Image-conditioned Computer-Aided Design Generation with Transformer-based Contrastive Representation and Diffusion Priors

gencad.github.io

409 shares · 21 trendiness

Abstract

We present GenCAD, an image-conditional CAD generation model. Our model not only generates the 3D CAD but also the entire parameterized CAD command history, CAD program, as output.

The complexity of CAD data structures such as boundary representation (B-rep) makes it difﬁcult to train efﬁcient AI models. Due to the ease of data availability, common approaches often resort to representations like meshes, voxels, or point clouds, which sacriﬁce the accuracy and modiﬁability of true CAD models that are critical for engineering tasks, manufacturing and design space exploration. Here we propose GenCAD, an image conditional generative model that generates parametric CAD command sequences, also known as CAD programs, that can be converted to a 3D solid model using a geometry kernel. At the core of GenCAD, we develop a strong representation learning framework for multiple modalities of computational engineering designs.

Our proposed GenCAD architecture is a combination of four critical steps; 1) an autoregressive transformer encoder is used for learning the latent representation of the CAD command sequences, 2) a contrastive learning-based model is used to learn the joint representations of the latent spaces between CAD command sequences and CAD-images, 3) a latent diffusion model that can generate the latent representation of CAD command sequences conditioned on CAD-images, and 4) ﬁnally, a decoder model that can convert cad latents into a sequence of parametric CAD commands. Most importantly, GenCAD does not merely generate a 3D solid but also the entire CAD program. Our work represents a step forward in CAD, offering more precise and modiﬁable 3D modeling from images, potentially enhancing automated design processes.

Read more Read the original on gencad.github.io →

Read the original on gencad.github.io →

Former Google CEO Eric Schmidt booed during graduation speech about AI

www.nbcnews.com

319 shares · 56 trendiness

Former Google CEO Eric Schmidt was booed multiple times Sunday while discussing artiﬁcial intelligence during a commencement speech at the University of Arizona.

Schmidt, who led Google for a decade, opened his remarks by reﬂecting on his own student years and the rise of the computer, — a device named Time magazine’s “Person of the Year” in 1982. He traced its evolution into the laptop and smartphone and its proliferation through the internet and social media.

While the computer connected people, “democratized knowledge” and lifted many out of poverty, it also carried a darker side, Schmidt said.

“The same platforms that gave everyone a voice, like you’re using now, also degraded the public square,” he said. “They rewarded outrage. They ampliﬁed our worst instincts. They coarsen the way we speak to each other, and that way, and in the way that we treat each other, is in the essence of a society.”

Schmidt then drew a parallel between artiﬁcial intelligence and the transformative impact of the computer — and was immediately met with boos.

“I know what many of you are feeling about that. I can hear you,” Schmidt said, addressing the crowd as many continued to boo him. “There is a fear … there is a fear in your generation that the future has already been written, that the machines are coming, that the jobs are evaporating, that the climate is breaking, that politics is fractured, and that you are inheriting a mess that you did not create, and I understand that fear.”

He went on to argue that the future remains unwritten and that the graduating class of 2026 has real power to shape how AI develops — a claim that drew further disapproval from parts of the audience.

Schmidt urged graduates to embrace freedom, open debate, equality and the willingness to engage with those they disagree with.

“If you’d let me make this point, please —” Schmidt said amid boos. “The point I’d like to make is choose a diversity of perspectives, including the perspective of the immigrant who has so often been the person who came to this country and made it better. America is at its best when we are the country that ambitious people want to come to. Let us not lose that.”

He closed by congratulating the class and offering them closing words. “The future is not yet ﬁnished. It is now your turn to shape it.”

University of Arizona spokesperson Mitch Zak said Schmidt was invited to deliver the commencement address because of his “extraordinary leadership and global contributions in technology, innovation and scientiﬁc advancement.”

“He helped lead Google’s rise into one of the world’s most inﬂuential technology companies and continues to advance research and discovery through major philanthropic and scientiﬁc initiatives, including partnerships that support important work at the University of Arizona,” Zak added.

Schmidt’s reception was not an isolated incident. Earlier this month, real estate executive Gloria Caulﬁeld was similarly booed at a commencement speech at the University of Central Florida after mentioning the controversial technology. “The rise of artiﬁcial intelligence is the next industrial revolution,” she said as the crowd erupted in boos.

Read more Read the original on www.nbcnews.com →

Read the original on www.nbcnews.com →

GitHub - zakirullin/files.md: 🌱 Your life in plain .md files

github.com

312 shares · 89 trendiness

A simple application for your .md ﬁles. All data stays on your device.

You can store whole your life:

📌 Notes

📝 Documents, Projects

💚 Journal, Habits

✅ Checklists, Tasks

All in plain .md ﬁles, local-ﬁrst. LLM-friendly.

Try it out: app.ﬁles.md (Beta)

My friends and I have been building this project for 5 years. Hope you’ll like it!

Sponsor on GitHub 💚

Another note taking app?

Maybe. But this time:

Only necessary features, restrictions foster creativity

No need to install anything, all you need is a browser

Works ofﬂine

Local-ﬁrst, ﬁles don’t leave your device

Free and open source, you can tweak it however you want

Extremely simple code. One person or an LLM can ﬁt the whole project in head

Portable, no build systems, just open web/index.html

Optional out of the box synchronization

The server is just one binary (or use iCloud/Dropbox/Google Drive for sync)

Telegram chatbot for on-the-go access to your ﬁles

How to use

Open app.ﬁles.md in Chrome browser

Click “Install ﬁles.md” on the right side of the address bar:

Open a local folder to persist changes

Occasionally hit force-refresh (Cmd+Shift+R) to get new updates.

Dump your thoughts

You can use chat to quickly dump your thoughts.

It will be synchronized across all devices.

Open the chat and send a message:

Choose where to save (can do later):

With this ﬂow you can quickly save notes, journal and checklists.

Save things in the chatbot

Open the chat, write something and press Enter:

That’s it.

Telegram Bot

Other messengers will follow

How to grow your knowledge base

Connect ideas. Let them compound. Think through.

I used app.ﬁles.md to grow my knowledge about brain and software development

I added new notes to either brain or dev folders. One idea per note

I made connections between the relevant notes in the web app (type [)

Everything is connected, just as in our brain

I spent time travelling through the notes and thinking it through

At some point, brain and dev notes appeared very related

An interconnection between domains produced an insight

I wrote an article based on that insight: Cognitive Load in Software Development

All this activity helped me to:

Think deeply (which is very important in the AI-age)

Think systematically and see the bigger picture

Write insightful texts

To achieve all that, you’ll have to use your brain, not advanced templates or AI workﬂows.

Start with no structure at all, 0 folders

One idea per note

Every note should be understood without context

Apply new knowledge immediately, don’t save it for future self

Link related notes

Revisit your notes and think through

My friends and I have been using this simple setup for ﬁve years, and it works well.

Second Brain?

I’ll quote I Deleted My Second Brain:

Obsidian is a brilliant piece of software. I love it, dearly. But like anything, without restraint, it can also be a trap. Markdown ﬁles in nested folders. Plugins that track your productivity. Graph views that suggest omniscience. There’s an illusion of mastery in watching your notes web into constellations. But constellations are projections. They tell stories. They do not guarantee understanding. When I ﬁrst started using PKM tools, I believed I was solving a problem of forgetting. Later, I believed I was solving a problem of integration. Eventually, I realized I had created a new problem: deferral. The more my system grew, the more I deferred the work of thought to some future self who would sort, tag, distill, and extract the gold. That self never arrived.

When I ﬁrst started using PKM tools, I believed I was solving a problem of forgetting. Later, I believed I was solving a problem of integration.

Eventually, I realized I had created a new problem: deferral. The more my system grew, the more I deferred the work of thought to some future self who would sort, tag, distill, and extract the gold.

That self never arrived.

The Second Brain is thrilling. Advanced guru templates, plugins and AI workﬂows… One wants to scrape the wisdom of the whole internet. There’s some beauty in this neat system. Every new note brings dopamine. Second Brain gets better and better.

However, the ﬁrst brain never actually gets smarter. And that’s an issue - in the AI age, your ﬁrst brain is as valuable as ever.

Use your brain to think through the notes.

Notes can prevent experience

Reading and taking notes can easily fool us into believing that we understand a text

We think we understand, but in reality we just know

At some point our “knowing” is so good, that we start feeling that we actually do it (or at least tried)

The worst thing is that we don’t let new experiences emerge because we already have knowledge. It’s a knowledge barrier. Life gives us opportunities to live through new experiences, but we refuse, because “we already know”.

Self-help through reading and taking notes? 🧘‍

Harm caused at the emotional level must be healed at the emotional level.

Not through intellectual work and taking notes. Reading without action is entertainment. A form of procrastination. No amount of self-help books can heal emotional wounds. What can help is psychotherapy, rescripting and chair work. Meditation. Healing happens by feeling.

When to take notes

If your goal is to:

Develop a deeper, more structured understanding of something

Do research

Write an article or a book

Then taking notes is perfectly ﬁne.

Files structure

You don’t have to think about the structure, it is predeﬁned. Although, you’re free to use whatever structure you want.

Chat: Chat.md

Notes: brain/Note.md, <category>/*.md

Checklists: Read.md, Watch.md, Shop.md, MyChecklist_.md

Journal: journal/2024.08 August.md

Tasks: Later.md

Habits: habits/Ate consciously.md, habits/*.md

Images: media/* (png, jpg, webp, gif)

Archive: archive/*.md

Conﬁg: conﬁg.json

Scheme is also available at ﬁles.md/llms.txt. You can copy-paste it into CLAUDE.md or AGENTS.md, so that your AI agent would understand the structure.

Hotkeys

Useful scripts for your ﬁles

All scripts are in cmd and can be run inside your ﬁles directory. Install Go ﬁrst.

Add Whoop metrics to journal

Read more Read the original on github.com →

Read the original on github.com →

GitHub - stephenlthorn/auto-identity-remove: Automated data broker opt-out runner — removes your personal info from 30+ people-search sites on a monthly schedule

github.com

303 shares · 52 trendiness

Automated data broker opt-out runner for macOS. Removes your personal information from 500+ people-search sites and data broker databases on a monthly schedule — with CAPTCHA solving, persistent state tracking (so completed opt-outs aren’t resubmitted every run), and an iMessage notiﬁcation when done.

What it does

Each month, the script:

Searches each data broker site for your name + state

Finds your speciﬁc listing (for sites that need a proﬁle URL)

Fills and submits the opt-out form automatically

Solves CAPTCHAs via CapSolver (AI-powered, ~$0.001/solve)

Skips brokers you were already removed from recently (90-day re-check window)

Sends you an iMessage with the results summary

Opens any sites that require manual action in your browser

Requirements

macOS (uses launchd for scheduling and Messages for iMessage)

Node.js 18+

Playwright browsers installed

npx playwright install chromium

Quick Start

# 1. Clone the repo git clone https://github.com/stephenlthorn/auto-identity-remove.git cd auto-identity-remove

# 2. Install dependencies npm install

# 3. Run interactive setup (creates conﬁg.json and schedules the monthly job) node setup.js

# 4. Run manually anytime ./run.sh

Setup walkthrough

node setup.js guides you through:

Your personal info never leaves your machine. conﬁg.json and state.json are both gitignored.

CapSolver (optional but recommended)

Some opt-out forms have reCAPTCHA. Without CapSolver, those sites go to your manual list instead of being handled automatically.

Add $1 – 2 of credits (enough for months of use at ~$0.001/solve)

Paste your API key when setup.js asks, or add it to conﬁg.json:

“capsolver”: { “apiKey”: “CAP-xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx” }

Files

auto-identity-remove/ ├── setup.js ← Run once: interactive setup + scheduling ├── watcher.js ← Main runner ├── brokers.js ← Broker list with opt-out strategies ├── run.sh ← Manual trigger ├── conﬁg.example.json ← Template (copy → conﬁg.json) ├── package.json ├── .gitignore │ ├── conﬁg.json ← YOUR personal info (gitignored, created by setup.js) ├── state.json ← Opt-out history / skip logic (gitignored) └── logs/ ← Per-run JSON logs (gitignored)

State tracking

state.json tracks when each broker was last successfully opted out. The default re-check window is 90 days — brokers typically re-add your data within that window, so the script re-submits when it’s time.

{ “optOuts”: { “Spokeo”: { “lastSuccess”: “2026 – 05-01T09:00:00.000Z”, “totalRuns”: 3, “detail”: “” } } }

On each run you’ll see:

✅ Removed — opt-out submitted this run

⏭ Skipped (fresh) — removed recently, re-check not due yet

🔍 Not listed — your name wasn’t found on that site

📋 Manual needed — opened in your browser for you to handle

❌ Error — network/timeout issue, will retry next run

Brokers covered

Auto-removed (30+)

Generic — 500+ additional brokers (auto-detected)

generic-runner.js handles the remaining ~470 brokers from two public datasets:

For each site it tries four strategies in order:

Click a “Do Not Sell My Personal Information” button

Opt out via OneTrust / TrustArc / Osano privacy manager

Fill any generic opt-out form (email, name, state) and submit

Find and record a DSAR / data request link for manual follow-up

Sites requiring manual action are opened in your browser automatically.

Manual (opened in browser for you)

Adding more brokers

Edit brokers.js and add an entry:

{ name: ‘NewBrokerSite’, method: ‘direct-form’, // or ‘search-form’, ‘email’, ‘manual’ optOutUrl: ’https://example.com/opt-out’, formFields: { ‘input[name*=“ﬁrst” i]’: F, // F, L, N, E, ST, Z are from conﬁg ‘input[name*=“last” i]’: L, ‘input[type=“email”]’: E, }, submitSelector: ‘button[type=“submit”]’, captchaLikely: false, priority: 2, }

PRs welcome — especially for brokers with veriﬁed working selectors.

Manual run

./run.sh

Dry-run mode — navigates to each site and ﬁlls forms but does NOT submit anything. Good for verifying what the script will do before your ﬁrst real run:

node watcher.js –dry-run

Or to run in the background and log output:

./run.sh >> logs/manual-run.log 2>&1 &

Uninstall / disable schedule

launchctl unload ~/Library/LaunchAgents/com.auto-identity-remove.plist rm ~/Library/LaunchAgents/com.auto-identity-remove.plist

Is it safe to submit my info to 500 opt-out forms?

A fair concern raised by some users: aren’t you just conﬁrming your data to the brokers by ﬁlling out their forms?

A few things worth knowing:

These brokers already have your info. You’re not revealing anything new — you’re using the legally-required removal mechanism they’re obligated to provide.

CCPA (California) and similar state laws require brokers to honor opt-out requests. Submitting the form creates a legal obligation to remove you. Doing nothing does not.

The script uses info you’re already listed under — your name as it appears publicly, your state, your email. It doesn’t add new data points.

The alternative is worse. Every month that passes, more brokers scrape and resell your data. Opt-outs are imperfect, but they work more often than not.

That said: if you’re in a situation where even conﬁrming your email address to a broker is a risk, this tool is not the right approach. Consider a paid service that uses a proxy email.

California residents: DELETE Registry (August 2025)

California is launching an ofﬁcial Delete Me opt-out registry on August 1, 2025. Once registered, data brokers are legally required to delete your info automatically — no individual form submissions needed for participating brokers.

Recommended: Register with the CA Delete Registry ﬁrst, then run this script for the brokers that aren’t covered.

Why not just use a paid service?

Paid services like Incogni ($96/yr) or Optery ($39/yr) are excellent and cover more brokers with professionally maintained opt-out ﬂows. This tool is for people who want full control, transparency, and no recurring subscription — or who want to handle the gaps those services miss (Acxiom, LexisNexis, ZoomInfo, Clearbit).

Using both is the strongest approach: a paid service for the bulk of brokers + this script for the gaps.

License

MIT

Read more Read the original on github.com →

Read the original on github.com →

Two F-18 fighter jets have crashed during an airshow at Mountain Home Air Force Base

idahonews.com

237 shares · 10 trendiness

MOUNTAIN HOME AFB, Idaho — All four crew members ejected safely after two Navy jets collided and crashed on Sunday during an air show at the Mountain Home Air Force Base, ofﬁcials said.

The collision involved two U.S. Navy EA-18G Growlers from the Electronic Attack Squadron 129 in Whidbey Island, Washington, said Cmdr. Amelia Umayam, spokesperson for Naval Air Forces, U.S. Paciﬁc Fleet.

The aircraft were performing an aerial demonstration when the crash happened, Umayam said in a statement. She said the four crew members from both jets safely ejected and were being evaluated by medical personnel.

Nobody at the military base was hurt, said Kim Sykes, marketing director with Silver Wings of Idaho, which helped to plan the air show.

“Everyone is safe, and I think that’s the most important thing,” Sykes said.

The base said in a social media post that it was locked down following the incident.

Videos posted online by spectators showed four parachutes opening in the sky as the aircraft plummeted to the ground near the base about 50 miles (80 kilometers) south of Boise.

Shane Odgen said he was ﬁlming the two jets as they came close together. A video he captured shows the two aircraft appear to make contact and then spin in tandem as the crew members eject and their parachutes open.

The planes then fall together, exploding into a ﬁreball upon impact as the crew members drop to the ground nearby.

“I was just ﬁlming, thinking they were going to split apart, and that happened, and I ﬁlmed the rest,” Ogden said in a text message.

He said he left soon after the crash because he did not want to get in the way of emergency responders.

Organizers said the popular air show, which includes ﬂying demonstrations and parachute jumps, is a celebration of aviation history and a showcase of modern military capabilities.

The U.S. Air Force Thunderbirds demonstration squadron headlined the show both days.

The National Weather Service reported good visibility and winds gusting up to 29 mph around the time of the crash.

This year’s Gunﬁghter Skies event was the ﬁrst at the base since 2018, when a hang glider died in a crash during an air show performance.

In 2003, a Thunderbirds aircraft crashed while attempting a maneuver. The pilot, who was not hurt, was able to steer the plane away from the crowd and eject less than a second before it hit the ground.

The air show industry has been working to improve safety for years at the roughly 200 events held each year in the U.S.

The last fatal crash at an air show came in 2022 when two vintage military planes collided at an event in Dallas and killed six people.

John Cudahy, president and CEO of the International Council of Air Shows, said that there used to be an average of about two deaths a year at a U.S. air show. But over the past decade, the average has been closer to one death per year, he said.

There were no air show deaths in 2025 or 2024, and a spectator hasn’t been killed at an air show since 1952.

“Safety-wise, we’ve enjoyed really an unprecedented term of few accidents,” Cudahy said.

Idaho Transportation says SH-167 is closed due to the crash and investigation from Simco Rd to SH-67 near the Mountain Home AFB. ITD says this is anticipated to be a multi-day closure.

Col. David Gunter, Wing Commander of the 366th Fighter Wing, released the following statement on Sunday.

First and foremost, we are incredibly thankful that everyone involved in today’s incident is safe. The extraordinary professionalism of our emergency response teams, including the city and county, allowed for quick response to the aircrew as well as securing the scene to ensure the safety of our guests, performers and community. And to all of our guests here today, I can’t tell you how much we appreciated your patience, trust and support.

Silver Wings of Idaho, which is a volunteer board working alongside Mountain Home Air Force Base to help plan and support the Gunﬁghter Skies 2026 Airshow, released this statement.

Today was an emotional and difﬁcult day at Gunﬁghter Skies. While the events were not what anyone expected, we are incredibly grateful and relieved that all four pilots involved are safe. That is, and always will be, the most important thing. Our hearts are with everyone affected today, the pilots, their families, the crews, and all those who worked tirelessly behind the scenes to make this event possible. Situations like this remind us how quickly things can change and how much these men and women put on the line every time they take to the skies. We also want to recognize the incredible response from Mountain Home Air Force Base along with the many local, county, and state agencies that responded today. Law enforcement, ﬁre, EMS, emergency personnel, and support teams from multiple agencies showed outstanding professionalism, teamwork, and care throughout the situation. We are beyond thankful for every person who stepped in to help keep others safe during an incredibly stressful moment. To our guests, supporters, volunteers, sponsors, and community, thank you for your patience, kindness, and understanding today. Even through unexpected circumstances, people came together and supported one another, and that meant so much. Serving on the Silver Wings of Idaho board and helping bring this airshow to our community has truly been an honor. This weekend was ﬁlled with so much hard work, dedication, and heart from countless people behind the scenes. Today reminded all of us that while airshows inspire and excite us, safety and the people behind the mission will always come ﬁrst. Tonight, we are simply thankful that everyone made it home safe.

(Reporting from the Associated Press and Idahonews.com)

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Read the original on idahonews.com →

Where are the vibecoded Photoshops?

indiepixel.de

235 shares · 21 trendiness

If vibecoding is what people say it is, the world should be drowning in vibecoded artifacts right now. Two years of access. Millions of people with the tools. The barrier supposedly fell, right? RIGHT? So where is everything?

Show me the evidence

Where is the vibecoded Photoshop. The vibecoded Excel. The vibecoded Maya. The vibecoded Blender. The vibecoded compiler that compiles itself. The vibecoded database, the vibecoded OS, the vibecoded anything-that-requires-architectural-judgment-to-hold-together. Huh?

I am not asking for slop. Slop exists, slop is easy, slop is not the question. I am asking for the coherent, complex, non-trivial things that vibecoding allegedly makes accessible to anyone who can prompt.

Silence. Every time. The category is empty.

And the accusers never want to address that, because addressing it means admitting the accusation doesn’t hold up.

Accusation without evidence

There are no vibecoded Photoshops because vibecoding does not do what the rhetoric claims it does. The accusation itself is the vibe. The accuser feels that a thing must have been easy because it was made with AI. They post that feeling as if it were a ﬁnding. The ﬁnding never has to be checked, because nobody else checks it either. The accusation travels because it feels right, not because it is right. Big difference.

The accusation that someone produced unveriﬁed output is itself being produced as unveriﬁed output. Or in other words.. The thing they accuse vibecoders of is the very thing they are doing: No definition. No test. No falsiﬁcation. Just a claim, shipped fast, never checked. The accusation is the real vibecoded content. The accuser is the vibecoder. They accuse others of the very crime they are committing themselves, and most of them are unaware of doing it.

The line in the sand

Their whole attack vector is built around the premise of defending a gate that doesn’t need defense, and a threat that doesn’t even exist. I can prove it.

There are levels in this work. Level 1 is the typing. Syntax, semicolons, the years memorizing pointer arithmetic and which header ﬁle the function lives in. Level 2 is the verifying. The harness. The test suite. The reﬂex of rejecting the ninety attempts that almost work and shipping the one that does. Level 3 is the deciding. What to build at all. Which architecture survives contact with the real world. The three have never been the same thing. The gate was never at Level 1. The gate was at Levels 2 and 3, where the work that holds together actually happens.

AI lowered the cost of Level 1. It did not touch Levels 2 or 3. The gate is exactly where it always was.

The Level 2 and 3 people can see this. They look at SoulPlayer and ask about the harness. They look at an AI music video and ask about the timing decisions or how consistency was enforced. They are at the gate. They know where the gate is. They recognize when someone else is also at the gate.

The accusers cannot see this. They are not at the gate. They were at Level 1. Level 1 was their identity, their hours, their proof of belonging, their reason to feel at home in this profession. When AI made Level 1 cheap, it did not threaten the gate. It threatened them. Because they bet their self-worth on the layer that just got rented out.

So they call the work vibecoded. They have to. The new artifact cannot be legitimate, because if it is legitimate, then Level 1 was never the gate, and they were never at the gate either. Exactly, and I feel sorry for everyone who is solely operating at Level 1 and with nothing left to contribute. If AI revealed they were never doing the deciding, that they were never doing the verifying, that they were the typist all along, then they are in deep trouble right now.

And they are ﬁnding this out in public. By panicking at the wrong things. By calling other people’s work vibecoded because that is the only move left when the ﬂoor disappears under you.

I do not feel angry at them. I feel sorry for them.

I will not use this accusation

I could. I have receipts.

SoulPlayer has a ninety-test veriﬁcation harness developed in Python that emits the C64 assembly and binary. Four bit-identical reference implementations have to agree before anything ships. I made sixteen AI music videos, weeks of work each, spent months creating our own custom inference toolchain in order to gain a maximum of control over the ﬁnal frame. I have been the person you call when nothing else works, in rooms full of people who would never have called me on a good day. I know where the gate is. I have been at the gate since before this profession called it a gate.

My demoscene background alone would allow me to turn around and call other people’s work vibecoded. I could punch down at every prompt-and-pray app on the internet and land a lot of hits.

I will not.

Because I know what the accusation costs the person on the receiving end. I have been the target of “you don’t really belong here” my whole life. Neurodivergent, Tics. Freelancer-not-by-choice. Demoscene-not-industry. Artist-not-CS. Disabled. The accusation is the same shape every time. It lets the accuser feel superior without doing any work. It makes the target spend their next week defending themselves instead of building the next thing.

I am writing this essay right now instead of ﬁnishing two other projects. The accusation is already winning, even though it has no evidence, no definition, no falsiﬁcation, and no Photoshops to support it. The accusation doesn’t have to be true. It just has to cost the target enough time and morale that the next person stops sharing their work. The accuser wants to harm and they succeed usually.

People are afraid to say they used AI. Not because using AI is shameful. Because the accusation is shameful, and the accusation is cheap to make and hard to refute. The shame economy runs without any actual shameful behavior in the system. It runs on fear. The fear of being the next person targeted.

I will not feed that. I will not call work vibecoded just because someone used AI. I will not punch down on the prompt-and-pray crowd, even though they are wrong, because the form of that punch is the same form that has been used against me my whole life. I recognize the move. I will not run it. And I will not duck away from the accusations either. I deliberately chose to be transparent and vocal about this.

QED

So. Where are the vibecoded Photoshops? WHERE IS THE THREAT YOU MADE UP TO ATTACK ME?

I’m waiting. — gizmo

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Read the original on indiepixel.de →

There Is No ‘Hard Problem Of Consciousness’

www.noemamag.com

226 shares · 20 trendiness

Credits

Carlo Rovelli is a theoretical physicist known for his work on quantum gravity, the foundation of quantum mechanics and the nature of space and time.

A ﬁerce debate is raging around the slippery notion of consciousness. It retraces a trotted pattern of cultural resistance: We humans are often scared by anything that may disturb our image of ourselves.

Famously, Darwin’s realization that we have common ancestors with all living organisms on our planet met ferocious resistance. Many felt confounded or degraded by the idea of sharing a family tree with donkeys. The cultural history of modernity is dotted by similar ideological rearguard battles, wherein old worldviews ﬁght in retreat against novel knowledge to save some concept held dear. Amid the current cultural backlash against progressive ideas, today’s debate on consciousness reﬂects our human fears of belonging to the same family as inanimate matter and losing our dear, transcendent souls.

During the Middle Ages, Western civilization described humans as composed of two distinct entities: body and soul. The body was an interconnected bunch of matter that decayed and died. The soul belonged to a transcendent spiritual world independent from vile matter. Angels were souls without a body and so were people after their material death. The soul, taken to be immortal and created by God, was understood as the repository of memories, emotions and our subjectivity. It could speak and fall in love. It was the agent of our agency; the subject of our freedom; the entity that bore responsibility, culpability, virtue and value; and deserved to be judged, saved or damned.

The current debate on consciousness is inﬂuenced by our entrenched traditional ideas of ourselves and by the long, slow effort to update them with our new understandings of reality developed over the last three centuries.

Despite the arrogant claims of those who say science can “explain everything,” most phenomena, from thunderstorms to protein folding, escape our full understanding. We still can’t cure the ﬂu or accurately predict the weather two weeks ahead. We do not know the basic physical laws of the universe. And even where we are conﬁdent that we know the basic underlying natural laws, we still cannot account for what they imply. I am conﬁdent that my bicycle diligently obeys the laws of particle physics, yet those laws are useless when it breaks down. To ﬁx it, I ask a mechanic, not a particle physicist.

The functioning of our own body and brain is among the phenomena we understand the least and are curious about the most. This is the proper intellectual space where the “problem of consciousness” is located. That is, consciousness is hard to ﬁgure out for precisely the same reason thunderstorms are: not because we have evidence that it is not a natural phenomenon, but because it is a very complicated natural phenomenon.

Updating the understanding of a phenomenon is not to deny it. Sunsets were understood in Antiquity and the Middle Ages as the descent of the sun in its daily motion over the Earth. Today, we understand them as a result of the Earth’s rotation, which turns us toward its shady side, where the sun gradually becomes no longer visible. Such an update in understanding does not make sunsets illusory or unreal.

Similarly, our soul won’t become illusory or unreal if we get a better sense of how our brain functions. We can still call our soul our “soul,” even if we understand ourselves better. I call it so, because this notion — the soul — is dear to my soul.

The ‘Hard Problem Of Consciousness’

The consciousness debate is often formulated in terms used in an inﬂuential talk given by a young David Chalmers in Tucson in 1994. Chalmers, a philosopher, distinguished two separate “problems of consciousness.” The ﬁrst is the very hard problem described above: understanding the processes in the brain that give rise to the many aspects of our visible behavior and our inner behavior that we can report about. Chalmers christened this hard problem as the “easy” problem of consciousness.

Then he declared that there is another distinct problem — why the brain’s behavior is accompanied by experience at all — which he christened the “hard” problem of consciousness. Today, this so-called “hard problem” is mentioned in all debates on consciousness. According to many, it unveils the very limits of current scientiﬁc understanding. Chalmers claimed that even after hypothetically accounting for our entire behavior, and for all our reports about our inner life, there would still be an “explanatory gap” between brain processes and experience.

“In the Renaissance, it was hard to accept that heaven and Earth are of the same nature; after Darwin, it was hard to accept that animals and humans are cousins; after recent advances in biology, it is hard to accept that living beings and inanimate matter are of the same nature.”

The idea of this supposed “explanatory gap” reincarnates in a number of related forms: explaining “qualia,” the hypothetical elementary bits of experience; explaining “subjectivity,” the very fact that some entity is capable of having experience at all; or explaining, as the philosopher Thomas Nagel famously put it, “what is it like” to be the subject of a certain experience.

I fail to make sense of the claim that there is such an “explanatory gap.” It regards what we would understand if we were to understand something that we currently do not understand. Forgive the muddled question, but: How can we know now what we would understand if we were to understand something we do not currently understand?

But this curious claim has been enthusiastically embraced by crowds of thinkers, commentators and writers across many ﬁelds and worldviews, who have all jumped on the bandwagon of the “hard problem.” This widespread embrace is nourished by a strenuous resistance to an idea anticipated centuries ago by the philosopher Baruch Spinoza: that our soul could be a phenomenon of the same basic nature as any other phenomenon in nature.

In the Renaissance, it was hard to accept that heaven and Earth are of the same nature; after Darwin, it was hard to accept that animals and humans are cousins; after recent advances in biology, it is hard to accept that living beings and inanimate matter are of the same nature.

The idea that we will never be able to understand consciousness upholds a worldview in which spirit and nature, subject and object, form distinct domains. Accepting that consciousness may not be separate from the physical world — that our beloved soul could be of the same nature as our body and any other phenomenon of the world — is too much for many.

Seeing The World From Within It

Chalmers claims that experience cannot be accounted for by science. But scientiﬁc understanding is not extraneous to experience; it is entirely about experience. Empiricism, the grounding of knowledge in experience, is not alternative to science; it is a main component of science’s traditional conceptual ground. As the Russian intellectual Alexander Bogdanov put it, science is the historical process of a successful collective organization of our experience.

It is misleading to see science, as often naively portrayed, as a direct account of an absolute and objective world, observed and described from its outside. If we think in this manner, we introduce dualism. No surprise, then, that we ﬁnd dualism down the road: an irreducible gap between subject and object of knowledge. We have introduced it upfront.

What this view misses is the fact that we, subjects of knowledge and understanding, are not outside the world. We are part of it. Our theories and knowledge are embodied tools to help us navigate the real world, not disembodied views on reality from the outside. They are themselves aspects of the very world they describe. Our understanding, like our feelings, perceptions and experience, is a natural phenomenon. The source of the confusion about consciousness is the initial step: treating knowledge, consciousness and qualia as something to be derived from a scientiﬁc picture understood to be about something else. In fact, the scientiﬁc picture is a story about them.

Experience is not over and above the processes that happen in the brain, as Chalmers assumed upfront. The dualism between a ﬁrst-person description of experience and a third-person (or scientiﬁc) account of the same is a normal perspectival difference: the same brain phenomenon as experienced by that same brain itself, or by another. Experience for both — not evidence of two different kinds of reality.

“Subjective experience,” “qualia” and “consciousness” are names of phenomena that of course appear differently from different perspectives. It would be strange if they didn’t. They affect the body and the brain embodying them differently from how they affect something interacting with them from the exterior. This is not due to a mysterious “explanatory gap.” “Red,” as a qualia, is the name of the process we generally undergo when we see or remember or think about the color red. We do not need to explain why it looks red for the same reason that we do not have to explain why the animal that we call “cat” looks like a cat. Why should we have to explain why “red” looks red?

“The false ‘hard problem of consciousness’ assumes upfront that there exists a metaphysical gap between mind and body. This contradicts everything we have learned about nature.”

We do not have to derive a ﬁrst-person perspective from an objective third-person view. It is the opposite: Any account is perspectival because knowledge is always embodied. Scientiﬁc knowledge is ultimately ﬁrst-personal. The world is real, but any account of it can exist only from within it. Any knowledge is perspectival. Subjectivity is not mysterious; it is just a special case of a perspective. What generates the apparent “metaphysical gap” and “explanatory gap” is mistaking scientiﬁc pictures for direct accounts of an ultimate reality.

‘Philosophical Zombies’

Chalmers asks us to contemplate what he calls a “philosophical zombie.” This is a hypothetical entity that looks and behaves like a human in all respects, including reporting emotions, feelings, dreams and experience, yet it has no consciousness. As Chalmers puts it, “There is nobody home.” This is a rhetorical trick that induces us to distinguish between behavior and a hypothetical reality accessible only by introspection. The very fact that a philosophical zombie could be conceived, Chalmers argues, shows that inner experience is intrinsically distinct from observable natural phenomena.

But the argument is weak. A philosophical zombie would claim to know what subjective experience is; otherwise, it would be empirically distinguishable from a human. Chalmers’s point is that the existence of the hypothetical, irreducible consciousness of which he speaks is something we can be convinced of only by introspection. During introspection, physical processes in my brain convince me of my consciousness. The same would theoretically happen in the zombie brain, convincing it of having consciousness as well. If this is true, can I believe my own conclusion of having this mysterious non-physical experience, knowing that if I were a zombie, I would be convinced of the same without actually having it? The argument is self-defeating.

My hypothetical, physically identical zombie twin would be exactly like me — including in experience. In other words, philosophical zombies are distinguishable from ordinary people only by those who assume upfront what Chalmers seeks to prove: that there is something non-physical going on in the world. They are not proving anything; they are examples of an unconvincing metaphysical possibility and nostalgia for the old notion of the transcendent soul.

The Soul Is Real & Is Part Of Nature

“Consciousness” and “experience” are names we use to denote events that happen inside us, that make us. No argument contradicts the possibility that what happens can be equally described, using other names, by a capable external observer. Today, we do not have an exhaustive external account, but this is not the same as having proof that no such account is possible.

The false “hard problem of consciousness” assumes upfront that there exists a metaphysical gap between mind and body. But this contradicts everything we have learned about nature in the last centuries. The mind is the behavior of the brain, properly described in a high-level language. Neither my own experience of myself nor an external experience of me is primary: They are two distinct perspectives on the same events. We do not need to assume that the circle between epistemology (how we get knowledge) and ontology (what exists) requires a starting point. There is nothing wrong with its circularity: The world I access is the information I have about it, and I am part of that world.

Nor do we need to require that there is any ultimate or fundamental account of reality. Any account is approximate, has blind spots and is realized within reality, so it is embodied in a part of that same reality. There are hinges between a representation and where it is embodied, and this may be a singular point in a representation, but it is not a metaphysical gap. It is not an explanatory gap.

So, there is no “hard problem of consciousness.” Our mental life can very well be of the same nature as any other phenomenon of the universe. The more interesting challenge is not to speculate about a “hard problem,” it is to try hard to understand more about the functioning of our brain and body without postulating that our soul is transcendent or different in kind from the rest of nature.

We have souls. We have an inner self. We can treat ourselves as transcendental subjects in the Kantian sense. We have emotions and spiritual life; we experience qualia. These entities are not obtained by addition to a physical state, but by subtraction from a complete physical account. Mental processes are physical processes described in a way that captures only their salient characteristics.

“It is time to give up the pernicious dualism introduced by the debate on consciousness and embrace the reality that our soul, or our spiritual life, is consistent with our fundamental physics.”

If we do not fall into the error of dualism upfront, we can safely speak of soul and emotions just as we speak of a kitchen table, even if the table is also a collection of atoms. It is time to give up the pernicious dualism introduced by the debate on consciousness and embrace the reality that our soul, or our spiritual life, is consistent with our fundamental physics.

The reason why this picture is more credible than any dualism is not that “science explains everything” — it doesn’t — or because “physics explains everything” — it does so even less. It is because of the hundreds of years of astonishing and unexpected success of the sciences that have convincingly shown that apparent metaphysical gaps are never such.

Earth is not metaphysically different from the heavens, living beings are not metaphysically different from inanimate matter, humans are not metaphysically different from other animals. The soul is not metaphysically different from the body. We are all parts of nature, like anything else in this sweet world.

Read more Read the original on www.noemamag.com →

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Mercurial, 20 years and counting: how are we still alive and kicking?

fosdem.org

203 shares · 8 trendiness

Track: Main Track

Room: Janson

Day: Saturday

Start (UTC+1): 12:00

End (UTC+1): 12:50

Chat: Join the conversation!

Mercurial is a Distributed Version Control System created in 2005.

The project has been constantly active since then, fostering modern tooling, introducing new ideas, spawning multiple recent tools from its community, keeping itself competitive, and with sustained funding for its development. However nowadays, most people we encounter remember Mercurial for losing the popularity battle to its sibling Git in the 2010s and think the project dead.

This talk confronts this paradox. How did Mercurial get itself in such a situation? What can everyone learn from it? What does this mean for the future of version control?

Using our ﬁrst hand knowledge of Mercurial’s history, we look at a selection of events, contributor proﬁles, technical and community aspects, to see how they’ve affected the project’s course.

We will focus on topics that we have been asked about most frequently, such as: * How has Mercurial weathered the Git storm? * Which impacts has Mercurial had on your life, unbeknownst to you? * How has the involvement from behemoth companies reshaped the project? * What brings people to Mercurial in 2025?

Finally, we leverage the knowledge extracted from our past, to assess the present state of version control, try to predict its future, and highlight how community-based open-source remains as relevant as ever.

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jank now has its own custom IR

jank-lang.org

201 shares · 10 trendiness

Good news, everyone! jank has a new custom intermediate representation (IR) and we’re using it to optimize jank to compete with the JVM. We’ll dive into more of that today, but ﬁrst I want to say thank you to my Github sponsors and to Clojurists Together for sponsoring me this whole year. You all are helping a great deal. I am still searching for a way to continue working on jank full-time with an income which will cover rent and groceries, so if you’ve not yet chipped in a sponsorship, now’s a great time!

What is an intermediate representation (IR)?

Compilers often represent programs as a more abstract set of instructions than a target CPU instruction set can afford. This has a few added beneﬁts. Firstly, the program can be represented in a way which could later be lowered to different CPU architectures, such as x86_64 or arm64. Since intermediate representations are often higher level than CPU architectures, they can generally be more portable. Secondly, IRs can be specifically designed to represent the program in a way which makes writing certain optimizations easier, such as single static assigment (SSA) form. Finally, IR designers get to choose the level of abstraction of the IR to match the semantics they’re aiming to represent, which can either make an IR more general or more speciﬁc to a certain language.

There are many common popular IRs, such as the JVM’s bytecode, the CLR’s common intermediate language (CIL), GCC’s GIMPLE, LLVM’s IR, and so on. Some compilers may move the program through multiple IRs during compilation.

Custom IR rationale

Historically, jank has not been an optimizing compiler. We’ve delegated basically all of that work to LLVM, based on the C++ or LLVM IR which we would generate. However, LLVM IR works at a very low level, compared to Clojure. It has no concept of Clojure’s vars, transients, persistent data structures, lazy sequences, and so on. Clojure’s dynamism is granted by a great deal of both polymorphism and indirection, but this means LLVM has very few optimization opportunities when it’s dealing with the LLVM IR from jank.

The optimization work done previously on jank helped optimize its runtime, and the compiler itself, but less so the code being compiled by the compiler. In the past two months, I have sought to change this.

I wanted an IR which operated at the level of Clojure’s semantics. This would be much higher level than LLVM IR and even much higher level than JVM’s bytecode. Since I’m not building a general virtual machine (VM) or compiler platform, I don’t need to generalize the IR for different languages. I can make jank’s IR specifically tailored to jank, which gives us even more power for optimizations. As far as I know, no Clojure dialects have taken this step.

Custom IR details

I have written a reference for jank’s IR in the jank book here. This reference is targeted at people who’re working on jank itself, since I’m making no promises on the stability of jank’s IR at this point. However, I will copy some of that here to illustrate jank’s IR and help provide a mental model for what’s to come. Let’s examine this simple Clojure function.

(defn greet [name] (if (= “jeaye” name) (println “Are you me?!“) (println (str “Hello, ” name ”!“))))

jank’s IR is stored in memory as C++ data structures, but it is renderable to Clojure data for debugging and testing. This is not full serialization, since it cannot round-trip back into the jank compiler from the IR, due to all of the Clang AST internal data we have on hand. Let’s take a look at the jank IR module for this function.

{:name user_greet_82687 :lifted-vars {clojure_core_SLASH_str_82694 clojure.core/str clojure_core_SLASH_println_82691 clojure.core/println clojure_core_SLASH__EQ__82689 clojure.core/=} :lifted-constants {const_82693 ”!” const_82692 “Hello, ” const_82690 “Are you me?!” const_82688 “jeaye”} :functions [{:name user_greet_82687_1 :blocks [{:name entry :instructions [{:name greet :op :parameter :type “jank::runtime::object_ref”} {:name name :op :parameter :type “jank::runtime::object_ref”} {:name v3 :op :literal :value “jeaye” :type “jank::runtime::obj::persistent_string_ref”} {:name v4 :op :var-deref :var clojure_core_SLASH__EQ__82689 :type “jank::runtime::object_ref”} {:name v5 :op :dynamic-call :fn v4 :args [v3 name] :type “jank::runtime::object_ref”} {:name v7 :op :truthy :value v5 :type “bool”} {:name v8 :op :branch :condition v7 :then if0 :else else1 :merge nil :shadow nil :type “void”}]} {:name if0 :instructions [{:name v9 :op :literal :value “Are you me?!” :type “jank::runtime::obj::persistent_string_ref”} {:name v10 :op :var-deref :var clojure_core_SLASH_println_82691 :type “jank::runtime::object_ref”} {:name v11 :op :dynamic-call :fn v10 :args [v9] :type “jank::runtime::object_ref”} {:name v12 :op :ret :value v11 :type “jank::runtime::object_ref”}]} {:name else1 :instructions [{:name v13 :op :literal :value “Hello, ” :type “jank::runtime::obj::persistent_string_ref”} {:name v14 :op :literal :value ”!” :type “jank::runtime::obj::persistent_string_ref”} {:name v15 :op :var-deref :var clojure_core_SLASH_str_82694 :type “jank::runtime::object_ref”} {:name v16 :op :dynamic-call :fn v15 :args [v13 name v14] :type “jank::runtime::object_ref”} {:name v17 :op :var-deref :var clojure_core_SLASH_println_82691 :type “jank::runtime::object_ref”} {:name v18 :op :dynamic-call :fn v17 :args [v16] :type “jank::runtime::object_ref”} {:name v19 :op :ret :value v18 :type “jank::runtime::object_ref”}]}]}]}

jank’s IR is SSA-based, meaning that each name is only assigned once. This makes entire categories of optimizations much easier to reason about. jank’s IR is also represented as a control ﬂow graph (CFG), which is composed of one or more basic blocks, each with exactly one terminating instruction (branch, jump, throw, ret, etc).

As we can see from the IR module, jank handles the lifting of vars and constants, and it has instructions at the level of Clojure’s semantics, for dereferencing vars, calling functions, and so on. Let’s take a look at the generated C++ from this IR.

extern “C” jank::runtime::object_ref user_greet_19_1(jank::runtime::object_ref const greet, jank::runtime::object_ref name) { auto const v3(const_33); auto const v4(clojure_core_SLASH__EQ__34->deref()); auto const v5(jank::runtime::dynamic_call(v4, v3, name)); auto const v7(jank::runtime::truthy(v5)); if(v7) { auto const v9(const_35); auto const v10(clojure_core_SLASH_println_36->deref()); auto const v11(jank::runtime::dynamic_call(v10, v9)); return v11; } else { auto const v13(const_37); auto const v14(const_38); auto const v15(clojure_core_SLASH_str_39->deref()); auto const v16(jank::runtime::dynamic_call(v15, v13, name, v14)); auto const v17(clojure_core_SLASH_println_36->deref()); auto const v18(jank::runtime::dynamic_call(v17, v16)); return v18; } }

If you compare the C++ to the IR, you can immediately see the correlation. The C++ variables are named to match the IR variables. A var dereference just becomes a call to ->deref() on the var. A dynamic call just becomes a jank::runtime::dynamic_call. This is intentional.

Optimizing the IR

It took about six weeks to design and implement the IR, including reworking our C++ code generation to generate from the IR instead of from jank’s AST. At this point, we’re not yet running any optimization passes on the IR. However, we have everything we need to start doing that. I wanted to prioritize getting the new IR pipeline merged, rather than building it out as much as possible, since six weeks is already a long time to be branched from main. Now that the IR is merged in, my approach will be to pick up one benchmark at a time and optimize it as needed until I’m satistiﬁed and/or cannot optimize it any further. Some of those optimizations will involve the IR directly, while others will not.

If you’re interested in more of the technical development side of this IR, there are a few videos on the jank TV YouTube channel from the various Twitch streams I did while working on the IR. These videos go way into the weeds of implementing things.

With the new IR introduced, let’s jump into optimizing our ﬁrst benchmark: recursive ﬁbonacci.

Interlude

Before we proceed, please consider subscribing to jank’s mailing list. This is going to be the best way to make sure you stay up to date with jank’s releases, jank-related talks, workshops, and so on. It’s very low trafﬁc.

Optimizing recursive ﬁbonacci

Our ﬁrst benchmark for this round of optimization is a recursive ﬁbonacci implementation. It’s just ﬁve lines long. Our goal is to have jank be at least as fast as Clojure JVM, if not faster, but we have to earn it.

(defn ﬁbonacci [n] (if (<= n 1) n (+ (ﬁbonacci (- n 1)) (ﬁbonacci (- n 2)))))

This may seem like a trivial benchmark to optimize. You might wonder why would this be representative of a real world application. In reality, this benchmark covers some essential aspects of the compiler and runtime.

Polymorphic arithmetic and relational predicates. Basically every program crunches numbers and needs to do so quickly.

Recursion. Many popular algorithms, especially in Lisps, are recursive. Being able to handle these patterns efﬁciently is important.

Garbage creation and collection. The trash truck may come every week, but that doesn’t mean we should be generating as much garbage as we can.

In general, the ability for the language runtime to get out of the way. If we’re trying to calculate ﬁbonacci numbers, we don’t want anything showing up in the proﬁler which is unrelated to ﬁbonacci numbers.

As we optimize, throughout this post, consider these four categories and how each optimization we do can be categorized.

Baseline ﬁbonacci timing

We’re going to use Clojure JVM to get our baseline benchmark numbers and then we’ll aim to beat those numbers with jank.

Note that all numbers in this post are measured on my ﬁve year old x86_64 desktop with an AMD Ryzen Threadripper 2950X on NixOS with OpenJDK 21. When I say “JVM” in this post, I mean OpenJDK 21.

❯ clojure -Sdeps ‘{:deps {criterium/criterium {:mvn/version “0.4.6”}}}’ Clojure 1.12.4 user=> (require ’[criterium.core :refer [quick-bench]]) nil

user=> (defn ﬁbonacci [n] (if (<= n 1) n (+ (ﬁbonacci (- n 1)) (ﬁbonacci (- n 2))))) #’user/ﬁbonacci

user=> (quick-bench (ﬁbonacci 35))

Clojure takes about 200 milliseconds to calculate (ﬁbonacci 35). This is our baseline!

Be careful of lein repl

Note that I originally did my benchmarking for Clojure in lein repl, which gives incredibly different results. On my system, instead of 200 milliseconds, Clojure clocks in around 2,800 milliseconds instead! There are some notes here stating that lein repl disables some JVM optimizations which apparently play a key role here. Thank you to Kyle Cesare for pointing this out.

Initial jank timing

Starting from jank’s main a few weeks ago, we’re going to use the same ﬁbonacci definition, but we don’t have criterium, since that’s a library for the JVM. Instead, jank has its own benchmarking library, shipped along with jank itself.

(defn ﬁbonacci [n] (if (<= n 1) n (+ (ﬁbonacci (- n 1)) (ﬁbonacci (- n 2)))))

(require ’[jank.perf]) (jank.perf/benchmark {:label “ﬁb”} (ﬁbonacci 35))

If we run this with optimizations enabled and eager compilation, we can get our initial numbers.

❯ jank run -O3 –eagerness eager ﬁb.jank

jank clocks in at 5,522 milliseconds. That’s… not fast. Not compared to the JVM’s 200 milliseconds.

Inlining arithmetic

To kick things off, I know that Clojure is inlining math calls and jank used to have a hacky solution to that which was removed. It’s time to do this properly. Clojure handles inlining via metadata, since the body of a function from another namespace is not available. This is not specifically a Clojure problem, since it’s also exactly how C and C++ work. Calls to C or C++ functions across translation units won’t be inlined unless link time optimizations (LTO) are used. The only other option is to move the definition into a header ﬁle and mark the function inline, so that every translation unit has its own copy. In Clojure, we can achieve the same effect of “putting the function in a header” by changing the metadata of the var to include inlining information, since anyone can read var metadata from anywhere. Let’s see an example of this.

(defn ^{:inline (fn [l r] (list ’cpp/jank.runtime.max l r)) :inline-arities #{2}} max ([x] x) ([l r] (cpp/jank.runtime.max l r)) ([l r & args] (let [res (cpp/jank.runtime.max l r)] (if (empty? args) res (recur res (ﬁrst args) (next args))))))

Here, we have clojure.core/max, which deﬁnes some metadata containing two keys: :inline and :inline-arities. The latter is a set of arities to inline. Here, we only care about the [l r] arity. The value of :inline is an actual function to call to get the body for that arity. In the case of max, we just want to inline a C++ call to jank::runtime::max. Later on, we’ll tell Clang to even inline that call.

The inlining is done during analysis, rather than in an IR pass. When we ﬁnd a function call through a var, we check the var’s metadata and call the corresponding :inline function if present. You can think of this as a sister to macro expansion, since it works very similarly.

This style of inlining has some huge beneﬁts. Firstly, we get to remove the var interning and dereference of clojure.core/max. Secondly, since every Clojure function needs boxed parameters, if we’re working with native values, we don’t need to box them before calling max. Thirdly, if max returns an unboxed native value, we don’t need to box it to return from the function. This allows us to avoid boxing and better propagate type information.

After adding inline support to jank’s analyzer and updating the metadata for all arithmetic functions, we can check our new benchmark results. This drops us from 5,522 milliseconds to 2,309 milliseconds. It’s nice to start with a huge win.

Eliminating extra IR instructions

Next, let’s take a look at the IR for our ﬁbonacci function. I love inspecting the IR for jank functions now, since is provides such a nice view into how the jank compiler sees the code.

{:name user_ﬁbonacci_82580 :lifted-vars {} :lifted-constants {const_82598 2 const_82597 1} :functions [{:name user_ﬁbonacci_82580_1 :blocks [{:name entry :instructions [{:name ﬁbonacci :op :parameter :type “jank::runtime::object_ref”} {:name n :op :parameter :type “jank::runtime::object_ref”} {:name v3 :op :literal :value 1 :type “jank::runtime::obj::integer_ref”} {:name v4 :op :cpp/call :value “jank::runtime::lte” :args [n v3] :type “bool”} {:name v5 :op :cpp/into-object :value v4 :type “jank::runtime::object_ref”} {:name v7 :op :truthy :value v5 :type “bool”} {:name v8 :op :branch :condition v7 :then if0 :else else1 :merge nil :shadow nil :type “void”}]} {:name if0 :instructions [{:name v9 :op :ret :value n :type “jank::runtime::object_ref”}]} {:name else1 :instructions [{:name v10 :op :literal :value 1 :type “jank::runtime::obj::integer_ref”} {:name v11 :op :cpp/call :value “jank::runtime::sub” :args [n v10] :type “jank::runtime::object_ref”} {:name v12 :op :named-recursion :fn ﬁbonacci :args [v11] :type “jank::runtime::object_ref”} {:name v13 :op :literal :value 2 :type “jank::runtime::obj::integer_ref”} {:name v14 :op :cpp/call :value “jank::runtime::sub” :args [n v13] :type “jank::runtime::object_ref”} {:name v15 :op :named-recursion :fn ﬁbonacci :args [v14] :type “jank::runtime::object_ref”} {:name v16 :op :cpp/call :value “jank::runtime::add” :args [v12 v15] :type “jank::runtime::object_ref”} {:name v17 :op :ret :value v16 :type “jank::runtime::object_ref”}]}]}]}

So we have three blocks in our function. We start at the entry block. We grab our parameter n and the literal 1 and we do our <= check, which has been inlined as a cpp/call instruction which returns bool.

{:name n :op :parameter :type “jank::runtime::object_ref”} {:name v3 :op :literal :value 1 :type “jank::runtime::obj::integer_ref”} {:name v4 :op :cpp/call :value “jank::runtime::lte” :args [n v3] :type “bool”}

We then convert that bool into a boxed object and check if it’s truthy so we can branch.

{:name v5 :op :cpp/into-object :value v4 :type “jank::runtime::object_ref”} {:name v7 :op :truthy :value v5 :type “bool”} {:name v8 :op :branch :condition v7 :then if0 :else else1 :merge nil :shadow nil :type “void”}

This can be optimized away, since the result of our <= check (v4) was already a bool. We turned it into an object just so we can turn it back into a bool. Ideally, the branch condition can just be v4 instead.

Before optimizing that, let’s ﬁnish examining our IR. We either branch to if0, which just returns our result, or to else1, which then needs to do the recursion. Our else1 branch happens in three steps.

; 1. Recur with `(- n 1)`. {:name v10 :op :literal :value 1 :type “jank::runtime::obj::integer_ref”} {:name v11 :op :cpp/call :value “jank::runtime::sub” :args [n v10] :type “jank::runtime::object_ref”} {:name v12 :op :named-recursion :fn ﬁbonacci :args [v11] :type “jank::runtime::object_ref”}

; 2. Recur with `(- n 2)`. {:name v13 :op :literal :value 2 :type “jank::runtime::obj::integer_ref”} {:name v14 :op :cpp/call :value “jank::runtime::sub” :args [n v13] :type “jank::runtime::object_ref”} {:name v15 :op :named-recursion :fn ﬁbonacci :args [v14] :type “jank::runtime::object_ref”}

; 3. Return the sum of those. {:name v16 :op :cpp/call :value “jank::runtime::add” :args [v12 v15] :type “jank::runtime::object_ref”} {:name v17 :op :ret :value v16 :type “jank::runtime::object_ref”}

That’s everything! So let’s eliminate those extra :cpp/into-object and :truthy instructions and add support to our IR generation for just using bool values directly. The results are that we drop from 2,309 milliseconds to 2,247 milliseconds. That’s quite marginal, given our overall magnitude. It’s nice that the IR no longer has any extraneous work in it, though. We could lift those two :literal instructions for 1 so there’s just one of them, but that’s not going to affect our performance, so I’ll leave it for now.

{:name entry :instructions [{:name ﬁbonacci :op :parameter :type “jank::runtime::object_ref”} {:name n :op :parameter :type “jank::runtime::object_ref”} {:name v3 :op :literal :value 1 :type “jank::runtime::obj::integer_ref”} {:name v4 :op :cpp/call :value “jank::runtime::lte” :args [n v3] :type “bool”} {:name v6 :op :branch :condition v4 :then if0 :else else1 :merge nil :shadow nil :type “void”}]} {:name if0 :instructions [{:name v7 :op :ret :value n :type “jank::runtime::object_ref”}]} {:name else1 :instructions [{:name v8 :op :literal :value 1 :type “jank::runtime::obj::integer_ref”} {:name v9 :op :cpp/call :value “jank::runtime::sub” :args [n v8] :type “jank::runtime::object_ref”} {:name v10 :op :named-recursion :fn ﬁbonacci :args [v9] :type “jank::runtime::object_ref”} {:name v11 :op :literal :value 2 :type “jank::runtime::obj::integer_ref”} {:name v12 :op :cpp/call :value “jank::runtime::sub” :args [n v11] :type “jank::runtime::object_ref”} {:name v13 :op :named-recursion :fn ﬁbonacci :args [v12] :type “jank::runtime::object_ref”} {:name v14 :op :cpp/call :value “jank::runtime::add” :args [v10 v13] :type “jank::runtime::object_ref”} {:name v15 :op :ret :value v14 :type “jank::runtime::object_ref”}]}

Optimizing nil usage

At this point, the IR looks good and I have no other planned optimizations, so let’s take a look at a ﬂamegraph to see where our time is being spent. You can click this image to open it in a new tab and see the details, if you’d like. I’ll cover the essentials here anyway.

We’re expecting to see arithmetic, and calls to ﬁbonacci, but curiously we see a LOT of time spent in jank_nil and jank_const_nil. As a Clojure dialect, we access nil very often, since we need to check if things are nil, initialize things to nil, and lots of expressions evaluate to nil. However, that shouldn’t show up in the proﬁler! It does because jank currently puts its nil value behind a function for some very in-the-weeds reasons. C++ doesn’t guarantee initialization order for globals across translation units and any translation units jank AOT compiles will be full of globals (lifted constants) which will want to initialize their values to be nil. If nil is deﬁned as a global in another translation unit, as part of the jank runtime, we might try to use it before it’s initialized. So we’ve been working around that by putting nil behind a function called jank_nil, but apparently this has had a heavy performance cost.

jank’s boxed pointer type doesn’t allow initialization with nullptr, since that’s not a valid value. jank separates nil from nullptr since dereferencing nil is well-deﬁned, in Clojure, but dereferencing nullptr is undeﬁned behavior in C++. We simply just can’t do it. But I happen to know that we don’t care about the default construction of the globals we generate for AOT compiled code, since we later re-initialize them when the module is loaded. So let’s add a custom constructor to our boxed pointer type which actually initializes them to nullptr because we know we’ll be re-initializing them with nil later. Then we can just keep jank_nil as a global value instead of a function.

This brings us from 2,247 milliseconds to 1,400 milliseconds!

That’s a big win! This qualiﬁes as the runtime getting in the way of our benchmark, so it’s nice to clear that up. We’re still over 5x slower than Clojure JVM, though, so it’s time to cut off some more huge chunks.

Why are add/sub slow?

If we look at the rest of the ﬂamegraph embedded above, we see the expected suspects. Namely, add and sub. The slowest parts of those functions, the ﬂamegraph tells us, is the GC allocation of new numbers. Every single integer result from adding or subtracting is a new dynamic allocation. At this point, we’re spending basically our entire time just allocating numbers.

You might wonder why we’re not using unboxed numbers for this. Or you might think “Just add a type hint! Clojure supports those!”. But that misses the point of this benchmark. This benchmark is specifically written to challenge the compiler and runtime. Let’s take a look at our Clojure code one more time and I’ll explain why.

(defn ﬁbonacci [n] (if (<= n 1) n (+ (ﬁbonacci (- n 1)) (ﬁbonacci (- n 2)))))

Here, the type of n is just going to be a type-erased object. In Clojure JVM, it will be a Java Object. In jank, it’s a jank::runtime::object_ref. Either way, we have no idea what kind of object is in there. When we do (- n 1) and (- n 2), we still don’t know the type of n. It could be a ﬂoat. It could be an integer. It could be a ratio. It could be a big decimal or big integer. It could be something which doesn’t even support arithmetic. So we need to do a whole polymorphic dance to handle arithmetic on n. Fortunately, we know the types of 1 and 2, so we can optimize for that, but it’s not enough to unbox any of this arithmetic. The same thing applies to the + call. We don’t know the return type of ﬁbonacci. We either return n, which we don’t know the type of, or we return the result of + with both inputs being the return from ﬁbonacci, which we still don’t know the type of. So there’s nothing we can do here statically either. This is the key aspect that makes this benchmark difﬁcult. The JVM is doing a much better job of it than we are, currently.

Pointer tagging

To remedy this, let’s just avoid dynamic allocations for integers entirely. There are some well-known tricks used by language runtimes to do exactly that and jank isn’t yet using any of them. We’ll start with the simplest trick and then build to a more complex design in a later benchmark post.

Did you know that, on 64 bit sytems, the bottom three bits of pointers are effectively unused? This is because pointers are aligned to 64 bit machine words. For example, an aligned pointer exists at address 0, 8, 16, 24, and so on. But an aligned pointer will not exist at an address which is not divisible by 8 bytes (64 bits). The bottom three bits of a pointer, 000, are for the 1′s place (lowest bit), 2′s place (middle bit), and 4′s place (highest bit). If all bits are on, 111, we have the value 7 (4 + 2 + 1). If you add one more, we get 8 and all three lowest bits go back to 0.

This is an incredible piece of knowledge, since it means that we can embed extra information in our pointers very easily. For example, if we set the lowest bit to 1, we can convey that the pointer is not actually a pointer. Instead, it’s an encoded integer. We can then use the other 63 bits to store the actual integer value. This way, as long as our integers don’t need to store values higher than what 63 bits can manage, we can store them inline without needing to do a dynamic allocation! In the case where we need all 64 bits, we can just do an allocation like we normally would and we’d get a normal pointer (lowest three bits all 0) to a boxed integer.

To visualize this, a normal 64 bit pointer would look like this. The highest 61 bits are used for pointer data and the lowest three bits are 0.

pppppppp pppppppp pppppppp pppppppp pppppppp pppppppp pppppppp ppppp000

An encoded integer would look like this. The lowest bit is 1 and the rest is reserved for integer data. To get the actual 63 bit integer, we just shift the whole thing to the right once.

xxxxxxxx xxxxxxxx xxxxxxxx xxxxxxxx xxxxxxxx xxxxxxxx xxxxxxxx xxxxxxx1

For our ﬁbonacci benchmark, and indeed for basically every benchmark and real-world application, this is going to effectively eliminate every dynamic allocation for integers. Let’s see how it affects our numbers.

With tagged pointers to optimize for 63 bit integers, jank goes from 1,400 milliseconds to 282 milliseconds. As I said, we were basically spending all of our time allocating integers. Even better, this puts us within reach of Clojure’s 200 milliseconds.

Intense inlining

Let’s take a look at a new ﬂamegraph with our latest changes and see how we can trim off the extra fat. Again, you can click this image to open it in a new tab, if you’d like. Or just take my word for it.

Ideally, what we see here is just ﬁbonacci and nothing more, since everything that matters should have been inlined. Instead, we see jank::runtime::add, jank::runtime::sub, and jank::runtime::lte. This means those calls have not been inlined by Clang. Let’s try to tell Clang to always inline our arithmetic functions. We can do this by putting some attributes on the C++ add, sub, etc functions. Modern C++ syntax makes this easy.

template <typename L, typename R> [[gnu::always_inline, gnu::ﬂatten, gnu::hot]] auto add(L const l, R const r) { … }

Arithmetic is something we always want to be fast, so there’s no better thing to inline than number crunching. Now we can try again. Fortunately, with a sigh of relief, this drops jank from 282 milliseconds to 114 milliseconds. We’re nearly twice as fast as Clojure JVM! Better yet, we’re gone from taking 5,522 milliseconds to taking 114 milliseconds and we’re effectively doing the same work.

I once saw an interview with an artist who does chainsaw sculptures. The interviewer asked him how he approaches sculpting something like a bear out of a huge log. He said “I just remove everything that doesn’t look like a bear”. While that’s not a particularly helpful answer, optimization is quite similar. When we’re proﬁling and taking a look at how the time is being spent, we just need to remove all of the time spent NOT doing the most essential tasks. Generally, that just means ﬁguring out what the essential tasks are and then ﬁguring out how to not do everything else.

What’s next

One benchmark down, many more to go. Next, I will be revisiting a ray tracer I wrote in Clojure a couple of years ago and we will utilize our new IR and optimized runtime to see how fast we can push jank. This post, and this ﬁrst benchmark, is just the start. I will be spending the next couple of months tackling more and more benchmarks, of varying sizes, to ensure jank is reasonably fast in every practical sense. This is all building up to jank’s beta release.

A note about the JVM versus native

Many folks who use jank for the ﬁrst time end up saying something along the lines of “Why is jank slow? Isn’t it written in C++?” So, ﬁrstly, jank is slow because it’s unoptimized. As we can see here, jank can absolutely compete with the JVM in this micro-benchmark and I will show in future posts that we can do so in larger benchmarks, too. Secondly, you know what’s also written in C++? The JVM. jank is indeed a miniature JVM, with some key distinctions.

Read more Read the original on jank-lang.org →

Read the original on jank-lang.org →

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