This is kind of just a measurement of how representative a language is in the distribution of the tokenizer training. You could have a single token equal to “public static void main”.
I'm biased by my preferred style of programming languages but I think that pure statically typed functional languages are incredibly well suited for LLMs. The purity gives you referential transparency and static analysis powers that the LLM can leverage to stay correctly on task.
The high level declarative nature and type driven development style of languages like Haskell also make it really easy for an experienced developer to review and validate the output of the LLM.
Early on in the GPT era I had really bad experiences generating Haskell code with LLMs but I think that the combination of improved models, increased context size, and agentic tooling has allowed LLMs to really take advantage of functional programming.
Realistically, it’s also a function of how many iterations it takes for an AI agent to correctly solve a problem with a given language. I’d imagine most AI agents would frequently have to redo J or F# code, as they are fairly uncommon languages with much smaller training set than JavaScript or Python.
I can say that for F# this has been mostly true up until quite recently. We use F# at work and were mostly unable to use agents like Claude Code up until the release of Opus 4.5, which seems to know F# quite well.
This is interesting research; thank you for doing it.
I am not sure token efficiency is an interesting problem in the long term, though.
And in the short term I wonder if prompts could be pre-compiled to “compressed tokens”; the idea would be to use a smaller number of tokens to represent a frequently needed concept; kind of like LZ compression. Or maybe token compression becomes a feature of future models optimized for specific tasks.
I was wondering last year if it would be worthwhile trying to create a language that was especially LLM-friendly, eg that embedded more context in the language structure. The idea is to make more of the program and the thinking behind it, explicit to the LLM but in a programming language style to eliminate the ambiguity of natural language (one could just use comments).
Then it occurred to me that with current LLM training methodology that there’s a chicken-and-egg problem; it doesn’t start to show rewards until there is a critical mass of good code in the language for LLMs to train on.
It strikes me that more tokens likely give the LLM more time/space to "think". Also that more redundant tokens, like local type declarations instead of type inference from far away, likely often reduce the portion of the code LLMs (and humans) have to read.
So I'm not convinced this is either the right metric, or even if you got the right metric that it's a metric you want to minimize.
I would expect that we’ll end up compressing (or whatever term you would use) this at some point so many of those syntactical differences will not be as significant.
But I would love for more expressive and compact languages to do better, selfish as I am. But I think training data size is more of a factor, and we won’t be all moving up Clojure any time soon.
I suspect DB queries will also benefit from token-efficient query languages as RAG queries grow exponentially. I've been working on one such language that is emitted in a token-efficient IR and compiles to SQL. https://memelang.net/
I knew it without the reading. But having each system call in 2 versions not even closely related to each other (monadic/diadic) requires me to have a hard time doing learning. I very appreciate this language for shortness but this kind of shortness might annoy.
I guess it also depends on which dataset LLM was trained on. Rare or niche languages get fragmented into more tokens even if the code itself is short. So two languages with the same number of characters can produce very different token counts because one aligns with what the model has seen millions of times and the other does not.
I don't think context size is really the limit for larger codebases - it's more about how you use that context.
Claude Code makes some efforts to reduce context size, but at the end of the day is loading entire source files into context (then keeping them there until told to remove them, or context is compacted). One of the major wins is to run subagents for some tasks, that use their own context rather than loading more into CCs own context.
Cursor makes more efficient use of context by building a vector database of code chunks, then only loading matching chunks into context (I believe it does this for Composer/agentic use as well as for tab/autocomplete).
One of the more obvious ways to reduce context use in a larger multi-module codebase would be to take advantage of the split between small module definition (e.g. C++ .h files) and large module implementations (.cpp files). Generally you'd only need to load module interfaces/definitions into context if you are working on code that uses the module, and Cursor's chunked approach can reduce that further.
For whole codebase overview a language server can help locate things, and one could use the AI to itself generate shortish summaries/overviews of source files and the codebase and structure, similar to what a human developer might keep in their head, rather than repeatedly reading entire source files for code that isn't actually being modified.
It seems we're really in the early days of agentic coding tools, and they have a lot of room to get better and more efficient.
The approaches used by Claude Code and Cursor are inefficient. It's possible to calculate a covering set for a piece of code and provide that to an agent directly via a tool, and it turns out that this can reduce context usage in SWE-bench style tasks by >90% over RAG and grep/read.
`public` might have a token by itself, even though you can have `pub` occurring in other contexts, too.
The high level declarative nature and type driven development style of languages like Haskell also make it really easy for an experienced developer to review and validate the output of the LLM.
Early on in the GPT era I had really bad experiences generating Haskell code with LLMs but I think that the combination of improved models, increased context size, and agentic tooling has allowed LLMs to really take advantage of functional programming.
But had never considered that a programming language might be created thats less human readable/auditable to enable LLMs.
Scares me a bit.
I am not sure token efficiency is an interesting problem in the long term, though.
And in the short term I wonder if prompts could be pre-compiled to “compressed tokens”; the idea would be to use a smaller number of tokens to represent a frequently needed concept; kind of like LZ compression. Or maybe token compression becomes a feature of future models optimized for specific tasks.
I was wondering last year if it would be worthwhile trying to create a language that was especially LLM-friendly, eg that embedded more context in the language structure. The idea is to make more of the program and the thinking behind it, explicit to the LLM but in a programming language style to eliminate the ambiguity of natural language (one could just use comments).
Then it occurred to me that with current LLM training methodology that there’s a chicken-and-egg problem; it doesn’t start to show rewards until there is a critical mass of good code in the language for LLMs to train on.
So I'm not convinced this is either the right metric, or even if you got the right metric that it's a metric you want to minimize.
But I would love for more expressive and compact languages to do better, selfish as I am. But I think training data size is more of a factor, and we won’t be all moving up Clojure any time soon.
Because that’s what happened in the real world when generating a bunch of untyped Python code.
[1] https://www.jsoftware.com/
E.g. when it comes to authoring code, C, which comes language, is by far one of the languages that LLMs excel most at.
Claude Code makes some efforts to reduce context size, but at the end of the day is loading entire source files into context (then keeping them there until told to remove them, or context is compacted). One of the major wins is to run subagents for some tasks, that use their own context rather than loading more into CCs own context.
Cursor makes more efficient use of context by building a vector database of code chunks, then only loading matching chunks into context (I believe it does this for Composer/agentic use as well as for tab/autocomplete).
One of the more obvious ways to reduce context use in a larger multi-module codebase would be to take advantage of the split between small module definition (e.g. C++ .h files) and large module implementations (.cpp files). Generally you'd only need to load module interfaces/definitions into context if you are working on code that uses the module, and Cursor's chunked approach can reduce that further.
For whole codebase overview a language server can help locate things, and one could use the AI to itself generate shortish summaries/overviews of source files and the codebase and structure, similar to what a human developer might keep in their head, rather than repeatedly reading entire source files for code that isn't actually being modified.
It seems we're really in the early days of agentic coding tools, and they have a lot of room to get better and more efficient.
If you're interested in learning more, https://github.com/sibyllinesoft/scribe