JSON unmarshalling often has to consider separately whether an attribute is absent, false, zero, null, or the empty string, but this was never quite semantically ambiguous enough for my tastes, so adding that void-ish values may also now be serialised as a tuple of length [0] seems to me an excellent additional obfuscation.
The use case here is to reduce the token usage with LLMs, such as an agent that outputs a list of commands eg. Tuples with files to write and their new contents.
Supporting this use case doesn’t require perfectly marshaling every data structure ever.
But to your point the tool could have wider use cases without the limitations.
If one trains a model to understand it then that model will inevitably emit it, which means in turn one shall have to parse it, and now the application supports TOON for anything, and good luck telling the users/customers any different.
What if there’s a simple converter back to json after the model output? Is that possible?
Arrays of length 0 also exist in json?
Yes, this is valid JSON: []
I’ll be interested to see benchmarks. My expectation is that accuracy will take a hit on mid or longer context prompts: I’d bet that the heavy use of JSON in fine tuning will end up impacting quality of a more terse (less reasoning space) novel encoding.
That said: I like the idea!
FWIW, I ran a test comparing LLM accuracy with TOON versus JSON, CSV and a variety of other formats when using them to represent tabular data: https://www.improvingagents.com/blog/is-toon-good-for-table-...
I've only looked at one model (gpt-4.1-nano) so far. I'm hoping to run similar tests on some other models but it gets challenging to discern statistically significant differences with better models as their accuracy tends to be a lot better across the board.
There are a very light benchmarks in the Readme, or are you looking for more?
Do you mean the [0] Token Benchmarks section? I only see token count numbers.
Which doesn't address the question: do LLMs understand TOON the same as they would JSON? It's quite likely that this notation is not interpreted the same by most LLM, as they would JSON. So benchmarks on, say, data processing tasks, would be warranted.
[0] https://github.com/johannschopplich/toon?tab=readme-ov-file#...
I think they're talking about these sections:
1. Retrieval Accuracy - https://github.com/johannschopplich/toon?tab=readme-ov-file#...
2. Performance by dataset - https://github.com/johannschopplich/toon?tab=readme-ov-file#...
I would assume the next iterations/fine-tuned variants of current models would reach similar accuracy for TOON as they do for JSON.
The current models unfortunately do not have TOON in their training set, so they would probably require additional input tokens to grok the notation, and even then probably won’t have the same accuracy as they do for JSON.
LLMs read
> users[2]{id,name,role}: 1,Alice,admin 2,Bob,user
differently than me, i guess. I would read that as "at index value of two, i.e. the third element of an array, the values 1aliceadmin and 2bobuser are stored, or not, since we want to destructure these values and a pair value of a tuple of three is given. and would be confused and think wtf is that, dear user, did you omit or misformat values?
I have this: https://github.com/7mind/sick , a binary deduplicating storage for JSON-like data structures with efficient direct access (no parsing required). It's even more efficient in terms of space and access speed (but not manually editable).
If you instead put parentheses around the lexical sequences, then you wouldn't need syntax like `[3]` to denote length.
You also wouldn't need indentation levels to be syntactically meaningful.
You could also get rid of LLM tokens like square brackets, curly braces, colons, and commas.
And you could have objects nested to arbitrary depth.
In near the same character count as TOON (sometimes more, sometimes less).
(I was telling someone over the weekend that there are only a few small wins for Lisps in most AI work right now. I hadn't considered that the printed syntax itself might have a use with these LLM huge black boxes.)
have you tried it? models struggle keeping track of opening/closing braces, which is exactly why xml/csv (or toon) tends to work better than json
What is the reason that the current LLMs work better with XML than with JSON? Is it the names in the element tags?
I don’t know what I’m talking about (pure fantasy), but what if you train a model on compressed data and then perform inference on compressed data as well? Could this work? With the output also being compressed and then decompressed by the client?
The tokenizer is already a form of (somewhat lossy) compression of a string of plaintext to a stream of token identifiers. You can reason about Tokenizers/"embedding spaces" as a sort of massive "Dictionary Table/Dictionary Function" like you might use in a zip/gzip stream.
Starting with already compressed data doesn't necessarily mean fewer tokens, you can probably assume similar entropy (or probably worse entropy) in expanding "Dictionary words" in a compressed stream versus "tokens" from a plaintext stream.
Since all input is run through a tokenizer, I would expect the tokenizer space doesn't change a lot between one trained on uncompressed vs one trained on compressed data.
Similar to YAML? Also do consider ancient formats like fixed width - in which case you don’t even need delimiter characters. Are LLMs clever enough to parse these if given a code book or old-school INPUT statement? Cheers
Neat. I did a similar thing with CSV (instead of JSON) a year back. Great that there are measurements, but I think the really interesting measure would have it run against the actual "Structured Output Format" endpoints of LLM providers, e.g. those fine-tuned to return valid JSON.
Hello, it's probably better to add leading spaces before all of the words rather than none of them
I wonder how many tokens will be saved compared to real JSON if we use a special version where property names don't require quotes, like in JavaScript.
It would be interesting to compare this to BAML and TOML.
Definitely is a core feature of BAML. My main complaint with BAML is that it’s all or nothing. It’s very opinionated and we can’t get the benefits without the DX and vice versa. Separating this feature without requiring a DSL of model definition is a great add.
TOML has some readability and compactness benefits over JSON while still being both common enough for models to easily be able to process it relatively reliably and widely supported in most languages. I suspect BAML still performs better but likewise due to the tooling work I haven't integrated it.
indentation-based sounds pretty brittle for a serialization format. I imagine a tabular format that factors out repeating keys could be expressed fairly compactly in json itself.
This is awesome, I saw it on twitter and gave it a star
What is the font used on that README image?
Looks like one of the variations of Iosevka. https://github.com/be5invis/Iosevka
Well done, sir!
I'll say the obvious. A lot of this you can just do in JSON.
Let's take the example:
We can keep it JSON, but use more compact list expressions, as tuples when pragmatic:{ "users": [ { "id": 1, "name": "Alice", "role": "admin" }, { "id": 2, "name": "Bob", "role": "user" } ] } users[2]{id,name,role}: 1,Alice,admin 2,Bob,user
The thing is the game with LLMs is not what's shortest, but what's:["users", [1, "Alice", "admin"], [2, "Bob", "user"] ]1. Mainstream, so they understand it.
2. What they're tuned for, and their tuned for what's mainstream (JSON).
If you want to go extreme compression you can shove it all in JSON strings too and keep the larger structure JSON:
You may say "how is this better". Well it's better because it's still JSON, there's less to explain to the LLM, and to your other devs. Even if we use a weird compact format like "id:role:name" this is still shorter to explain than a completely different syntax with its whole world of rules.["users", "1:admin:Alice", "2:user:Bob", ]If fairness to toon, the alternative json your giving doesn’t include hints on structure.
Not sure LLM are more “tuned” to JSON.
That said, your general point holds that toon maybe unnecessary. Especially in the examples given. But perhaps plan text would suffice. Toon could be useful when automating inputs with many different shapes.
Yea exactly. The LLMs are tuned to natural language. I don't think anything will beat good ol' templating (a.k.a. plain text). In Go I do something like this:
This way you're able to change the formatting to something the LLM understands for each struct. The LLM might understand some structs better as JSON, others as YAML, and others in an arbitrary format. Templating gives you the most flexibility to choose which one will work best.// mytemplate.tmpl Description="The following data is for the users in our application." Format="id,name,role" length=2 Data: {{range .}} {{.ID}}, {{.Name}}, {{.Role}} {{end}}
I don't get it, can't you just use yaml instead of inventing another DSL.
For repeating objects of the same structure, yaml will still require each key on each object, whereas this is a hybrid with csv, so it defines the keys once.
No one forces us to use objects in JSON with repeated keys you know.
Indeed a
could fit.{"header": ["some","column","names"], "values": [[1,2,3],[4,5,6],...]}For sure, but most people aren't thinking intentionally about what they are dumping into their context either ;)
It's more compact than YAML. More like a combination of YAML and CSV.
Norway.
YAML 1.2 has been out for 16 years now, so I would simply not assume that the suggestion to use YAML for a new purpose means “use YAML 1.1”.
I could agree that you would not make poor assumptions.
Your LLM, however, may experience cross-format feature superposition and consequential spurious activation.
It is, also noone uses it:)
This TOON is bound to have the same problem, because strings are not quoted. You can’t differentiate between the number 123 and the string ”123”.
For LLM consumption, this might not matter, don’t use this for anything else.
Since the whole point of this is to limit LLM token consumption, it'd be interesting to see the results of prompts that use it.
I've seen a ton of people who just paste a CSV into a prompt and expect it to work well because they don't know any better, but the results are typically hot garbage. It's too repetitive, it can't memorize and/or process such a big chunk of data. Asking an LLM to use pandas to iteratively analyze some CSV works great, though.
I'm sorry I don't see this adding value over various other formats. I don't really want a new object serialization format, I just want the existing ones to have the features I need. YAML but with static typing and schema. XML but without crazy internet features. TOML but with an object format that doesn't hurt my brain. JSON but with decent multiline strings and comments. NestedText but with a sub-standard that provides static-typing and schema and whatnot.
This isn't really an interchange formula so much as something you'd JIT compile down to when handing things off to an LLM, right?
And on the way out of the LLM. Token savings nice on the way out too, and then also I have to imagine it's better for the LLM to see one format in all of it's context instead of two.
It seems like a nice idea to me if restricted to that. Although I guess I am not sure if it's really intended that way - the array count for example is probably pretty bad for LLM output.
I feel like on the output side you might be working against LLM training? But I don't know.
https://cuelang.org | https://cuetorials.com
CUE can emit the other formats (minus XML because it's a beast of ambiguity, but there are other tools for json->xml i.e.)
It also has modules and imports, a very underrated feature for config languages if you haven't experienced it before
I don't think you even need to care about this as a format. It could exist only during communication and encoded/decoded by middleware, and everything still works.
The benchmarks show it performs better than them, so that's the value - cost savings and improved accuracy. I suppose you could convert JSON to TOON just for the LLM and not actually read it with your own brain.
Obligatory XKCD: https://xkcd.com/927/
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I'm not sure which one would win but its a bit telling that compression isn't mentioned at all.
I guess its about LLMs so the idea is has to be plaintext? But if you can train it on TOON can't you train it on BSON?