# GBNF Guide GBNF (GGML BNF) is a format for defining [formal grammars](https://en.wikipedia.org/wiki/Formal_grammar) to constrain model outputs in `llama.cpp`. For example, you can use it to force the model to generate valid JSON, or speak only in emojis. GBNF grammars are supported in various ways in `examples/main` and `examples/server`. ## Background [Backus-Naur Form (BNF)](https://en.wikipedia.org/wiki/Backus%E2%80%93Naur_form) is a notation for describing the syntax of formal languages like programming languages, file formats, and protocols. GBNF is an extension of BNF that primarily adds a few modern regex-like features. ## Basics In GBNF, we define *production rules* that specify how a *non-terminal* (rule name) can be replaced with sequences of *terminals* (characters, specifically Unicode [code points](https://en.wikipedia.org/wiki/Code_point)) and other non-terminals. The basic format of a production rule is `nonterminal ::= sequence...`. ## Example Before going deeper, let's look at some of the features demonstrated in `grammars/chess.gbnf`, a small chess notation grammar: ``` # `root` specifies the pattern for the overall output root ::= ( # it must start with the characters "1. " followed by a sequence # of characters that match the `move` rule, followed by a space, followed # by another move, and then a newline "1. " move " " move "\n" # it's followed by one or more subsequent moves, numbered with one or two digits ([1-9] [0-9]? ". " move " " move "\n")+ ) # `move` is an abstract representation, which can be a pawn, nonpawn, or castle. # The `[+#]?` denotes the possibility of checking or mate signs after moves move ::= (pawn | nonpawn | castle) [+#]? pawn ::= ... nonpawn ::= ... castle ::= ... ``` ## Non-Terminals and Terminals Non-terminal symbols (rule names) stand for a pattern of terminals and other non-terminals. They are required to be a dashed lowercase word, like `move`, `castle`, or `check-mate`. Terminals are actual characters ([code points](https://en.wikipedia.org/wiki/Code_point)). They can be specified as a sequence like `"1"` or `"O-O"` or as ranges like `[1-9]` or `[NBKQR]`. ## Characters and character ranges Terminals support the full range of Unicode. Unicode characters can be specified directly in the grammar, for example `hiragana ::= [ぁ-ゟ]`, or with escapes: 8-bit (`\xXX`), 16-bit (`\uXXXX`) or 32-bit (`\UXXXXXXXX`). Character ranges can be negated with `^`: ``` single-line ::= [^\n]+ "\n"` ``` ## Sequences and Alternatives The order of symbols in a sequence matters. For example, in `"1. " move " " move "\n"`, the `"1. "` must come before the first `move`, etc. Alternatives, denoted by `|`, give different sequences that are acceptable. For example, in `move ::= pawn | nonpawn | castle`, `move` can be a `pawn` move, a `nonpawn` move, or a `castle`. Parentheses `()` can be used to group sequences, which allows for embedding alternatives in a larger rule or applying repetition and optional symbols (below) to a sequence. ## Repetition and Optional Symbols - `*` after a symbol or sequence means that it can be repeated zero or more times (equivalent to `{0,}`). - `+` denotes that the symbol or sequence should appear one or more times (equivalent to `{1,}`). - `?` makes the preceding symbol or sequence optional (equivalent to `{0,1}`). - `{m}` repeats the precedent symbol or sequence exactly `m` times - `{m,}` repeats the precedent symbol or sequence at least `m` times - `{m,n}` repeats the precedent symbol or sequence at between `m` and `n` times (included) - `{0,n}` repeats the precedent symbol or sequence at most `n` times (included) ## Comments and newlines Comments can be specified with `#`: ``` # defines optional whitespace ws ::= [ \t\n]+ ``` Newlines are allowed between rules and between symbols or sequences nested inside parentheses. Additionally, a newline after an alternate marker `|` will continue the current rule, even outside of parentheses. ## The root rule In a full grammar, the `root` rule always defines the starting point of the grammar. In other words, it specifies what the entire output must match. ``` # a grammar for lists root ::= ("- " item)+ item ::= [^\n]+ "\n" ``` ## Next steps This guide provides a brief overview. Check out the GBNF files in this directory (`grammars/`) for examples of full grammars. You can try them out with: ``` ./llama-cli -m --grammar-file grammars/some-grammar.gbnf -p 'Some prompt' ``` `llama.cpp` can also convert JSON schemas to grammars either ahead of time or at each request, see below. ## Troubleshooting Grammars currently have performance gotchas (see https://github.com/ggerganov/llama.cpp/issues/4218). ### Efficient optional repetitions A common pattern is to allow repetitions of a pattern `x` up to N times. While semantically correct, the syntax `x? x? x?.... x?` (with N repetitions) may result in extremely slow sampling. Instead, you can write `x{0,N}` (or `(x (x (x ... (x)?...)?)?)?` w/ N-deep nesting in earlier llama.cpp versions). ## Using GBNF grammars You can use GBNF grammars: - In [llama-server](../examples/server)'s completion endpoints, passed as the `grammar` body field - In [llama-cli](../examples/main), passed as the `--grammar` & `--grammar-file` flags - With [llama-gbnf-validator](../examples/gbnf-validator) tool, to test them against strings. ## JSON Schemas → GBNF `llama.cpp` supports converting a subset of https://json-schema.org/ to GBNF grammars: - In [llama-server](../examples/server): - For any completion endpoints, passed as the `json_schema` body field - For the `/chat/completions` endpoint, passed inside the `response_format` body field (e.g. `{"type", "json_object", "schema": {"items": {}}}` or `{ type: "json_schema", json_schema: {"schema": ...} }`) - In [llama-cli](../examples/main), passed as the `--json` / `-j` flag - To convert to a grammar ahead of time: - in CLI, with [examples/json_schema_to_grammar.py](../examples/json_schema_to_grammar.py) - in JavaScript with [json-schema-to-grammar.mjs](../examples/server/public/json-schema-to-grammar.mjs) (this is used by the [server](../examples/server)'s Web UI) Take a look at [tests](../tests/test-json-schema-to-grammar.cpp) to see which features are likely supported (you'll also find usage examples in https://github.com/ggerganov/llama.cpp/pull/5978, https://github.com/ggerganov/llama.cpp/pull/6659 & https://github.com/ggerganov/llama.cpp/pull/6555). ```bash llama-cli \ -hfr bartowski/Phi-3-medium-128k-instruct-GGUF \ -hff Phi-3-medium-128k-instruct-Q8_0.gguf \ -j '{ "type": "array", "items": { "type": "object", "properties": { "name": { "type": "string", "minLength": 1, "maxLength": 100 }, "age": { "type": "integer", "minimum": 0, "maximum": 150 } }, "required": ["name", "age"], "additionalProperties": false }, "minItems": 10, "maxItems": 100 }' \ -p 'Generate a {name, age}[] JSON array with famous actors of all ages.' ```
Show grammar You can convert any schema in command-line with: ```bash examples/json_schema_to_grammar.py name-age-schema.json ``` ``` char ::= [^"\\\x7F\x00-\x1F] | [\\] (["\\bfnrt] | "u" [0-9a-fA-F]{4}) item ::= "{" space item-name-kv "," space item-age-kv "}" space item-age ::= ([0-9] | ([1-8] [0-9] | [9] [0-9]) | "1" ([0-4] [0-9] | [5] "0")) space item-age-kv ::= "\"age\"" space ":" space item-age item-name ::= "\"" char{1,100} "\"" space item-name-kv ::= "\"name\"" space ":" space item-name root ::= "[" space item ("," space item){9,99} "]" space space ::= | " " | "\n" [ \t]{0,20} ```
Here is also a list of known limitations (contributions welcome): - `additionalProperties` defaults to `false` (produces faster grammars + reduces hallucinations). - `"additionalProperties": true` may produce keys that contain unescaped newlines. - Unsupported features are skipped silently. It is currently advised to use the command-line Python converter (see above) to see any warnings, and to inspect the resulting grammar / test it w/ [llama-gbnf-validator](../examples/gbnf-validator/gbnf-validator.cpp). - Can't mix `properties` w/ `anyOf` / `oneOf` in the same type (https://github.com/ggerganov/llama.cpp/issues/7703) - [prefixItems](https://json-schema.org/draft/2020-12/json-schema-core#name-prefixitems) is broken (but [items](https://json-schema.org/draft/2020-12/json-schema-core#name-items) works) - `minimum`, `exclusiveMinimum`, `maximum`, `exclusiveMaximum`: only supported for `"type": "integer"` for now, not `number` - Nested `$ref`s are broken (https://github.com/ggerganov/llama.cpp/issues/8073) - [pattern](https://json-schema.org/draft/2020-12/json-schema-validation#name-pattern)s must start with `^` and end with `$` - Remote `$ref`s not supported in the C++ version (Python & JavaScript versions fetch https refs) - `string` [formats](https://json-schema.org/draft/2020-12/json-schema-validation#name-defined-formats) lack `uri`, `email` - No [`patternProperties`](https://json-schema.org/draft/2020-12/json-schema-core#name-patternproperties) And a non-exhaustive list of other unsupported features that are unlikely to be implemented (hard and/or too slow to support w/ stateless grammars): - [`uniqueItems`](https://json-schema.org/draft/2020-12/json-schema-validation#name-uniqueitems) - [`contains`](https://json-schema.org/draft/2020-12/json-schema-core#name-contains) / `minContains` - `$anchor` (cf. [dereferencing](https://json-schema.org/draft/2020-12/json-schema-core#name-dereferencing)) - [`not`](https://json-schema.org/draft/2020-12/json-schema-core#name-not) - [Conditionals](https://json-schema.org/draft/2020-12/json-schema-core#name-keywords-for-applying-subsche) `if` / `then` / `else` / `dependentSchemas` ### A word about additionalProperties > [!WARNING] > The JSON schemas spec states `object`s accept [additional properties](https://json-schema.org/understanding-json-schema/reference/object#additionalproperties) by default. > Since this is slow and seems prone to hallucinations, we default to no additional properties. > You can set `"additionalProperties": true` in the the schema of any object to explicitly allow additional properties. If you're using [Pydantic](https://pydantic.dev/) to generate schemas, you can enable additional properties with the `extra` config on each model class: ```python # pip install pydantic import json from typing import Annotated, List from pydantic import BaseModel, Extra, Field class QAPair(BaseModel): class Config: extra = 'allow' # triggers additionalProperties: true in the JSON schema question: str concise_answer: str justification: str class Summary(BaseModel): class Config: extra = 'allow' key_facts: List[Annotated[str, Field(pattern='- .{5,}')]] question_answers: List[Annotated[List[QAPair], Field(min_items=5)]] print(json.dumps(Summary.model_json_schema(), indent=2)) ```
Show JSON schema & grammar ```json { "$defs": { "QAPair": { "additionalProperties": true, "properties": { "question": { "title": "Question", "type": "string" }, "concise_answer": { "title": "Concise Answer", "type": "string" }, "justification": { "title": "Justification", "type": "string" } }, "required": [ "question", "concise_answer", "justification" ], "title": "QAPair", "type": "object" } }, "additionalProperties": true, "properties": { "key_facts": { "items": { "pattern": "^- .{5,}$", "type": "string" }, "title": "Key Facts", "type": "array" }, "question_answers": { "items": { "items": { "$ref": "#/$defs/QAPair" }, "minItems": 5, "type": "array" }, "title": "Question Answers", "type": "array" } }, "required": [ "key_facts", "question_answers" ], "title": "Summary", "type": "object" } ``` ``` QAPair ::= "{" space QAPair-question-kv "," space QAPair-concise-answer-kv "," space QAPair-justification-kv ( "," space ( QAPair-additional-kv ( "," space QAPair-additional-kv )* ) )? "}" space QAPair-additional-k ::= ["] ( [c] ([o] ([n] ([c] ([i] ([s] ([e] ([_] ([a] ([n] ([s] ([w] ([e] ([r] char+ | [^"r] char*) | [^"e] char*) | [^"w] char*) | [^"s] char*) | [^"n] char*) | [^"a] char*) | [^"_] char*) | [^"e] char*) | [^"s] char*) | [^"i] char*) | [^"c] char*) | [^"n] char*) | [^"o] char*) | [j] ([u] ([s] ([t] ([i] ([f] ([i] ([c] ([a] ([t] ([i] ([o] ([n] char+ | [^"n] char*) | [^"o] char*) | [^"i] char*) | [^"t] char*) | [^"a] char*) | [^"c] char*) | [^"i] char*) | [^"f] char*) | [^"i] char*) | [^"t] char*) | [^"s] char*) | [^"u] char*) | [q] ([u] ([e] ([s] ([t] ([i] ([o] ([n] char+ | [^"n] char*) | [^"o] char*) | [^"i] char*) | [^"t] char*) | [^"s] char*) | [^"e] char*) | [^"u] char*) | [^"cjq] char* )? ["] space QAPair-additional-kv ::= QAPair-additional-k ":" space value QAPair-concise-answer-kv ::= "\"concise_answer\"" space ":" space string QAPair-justification-kv ::= "\"justification\"" space ":" space string QAPair-question-kv ::= "\"question\"" space ":" space string additional-k ::= ["] ( [k] ([e] ([y] ([_] ([f] ([a] ([c] ([t] ([s] char+ | [^"s] char*) | [^"t] char*) | [^"c] char*) | [^"a] char*) | [^"f] char*) | [^"_] char*) | [^"y] char*) | [^"e] char*) | [q] ([u] ([e] ([s] ([t] ([i] ([o] ([n] ([_] ([a] ([n] ([s] ([w] ([e] ([r] ([s] char+ | [^"s] char*) | [^"r] char*) | [^"e] char*) | [^"w] char*) | [^"s] char*) | [^"n] char*) | [^"a] char*) | [^"_] char*) | [^"n] char*) | [^"o] char*) | [^"i] char*) | [^"t] char*) | [^"s] char*) | [^"e] char*) | [^"u] char*) | [^"kq] char* )? ["] space additional-kv ::= additional-k ":" space value array ::= "[" space ( value ("," space value)* )? "]" space boolean ::= ("true" | "false") space char ::= [^"\\\x7F\x00-\x1F] | [\\] (["\\bfnrt] | "u" [0-9a-fA-F]{4}) decimal-part ::= [0-9]{1,16} dot ::= [^\x0A\x0D] integral-part ::= [0] | [1-9] [0-9]{0,15} key-facts ::= "[" space (key-facts-item ("," space key-facts-item)*)? "]" space key-facts-item ::= "\"" "- " key-facts-item-1{5,} "\"" space key-facts-item-1 ::= dot key-facts-kv ::= "\"key_facts\"" space ":" space key-facts null ::= "null" space number ::= ("-"? integral-part) ("." decimal-part)? ([eE] [-+]? integral-part)? space object ::= "{" space ( string ":" space value ("," space string ":" space value)* )? "}" space question-answers ::= "[" space (question-answers-item ("," space question-answers-item)*)? "]" space question-answers-item ::= "[" space question-answers-item-item ("," space question-answers-item-item){4,} "]" space question-answers-item-item ::= QAPair question-answers-kv ::= "\"question_answers\"" space ":" space question-answers root ::= "{" space key-facts-kv "," space question-answers-kv ( "," space ( additional-kv ( "," space additional-kv )* ) )? "}" space space ::= | " " | "\n" [ \t]{0,20} string ::= "\"" char* "\"" space value ::= object | array | string | number | boolean | null ```
If you're using [Zod](https://zod.dev/), you can make your objects to explicitly allow extra properties w/ `nonstrict()` / `passthrough()` (or explicitly no extra props w/ `z.object(...).strict()` or `z.strictObject(...)`) but note that [zod-to-json-schema](https://github.com/StefanTerdell/zod-to-json-schema) currently always sets `"additionalProperties": false` anyway. ```js import { z } from 'zod'; import { zodToJsonSchema } from 'zod-to-json-schema'; const Foo = z.object({ age: z.number().positive(), email: z.string().email(), }).strict(); console.log(zodToJsonSchema(Foo)); ```
Show JSON schema & grammar ```json { "type": "object", "properties": { "age": { "type": "number", "exclusiveMinimum": 0 }, "email": { "type": "string", "format": "email" } }, "required": [ "age", "email" ], "additionalProperties": false, "$schema": "http://json-schema.org/draft-07/schema#" } ``` ``` age-kv ::= "\"age\"" space ":" space number char ::= [^"\\\x7F\x00-\x1F] | [\\] (["\\bfnrt] | "u" [0-9a-fA-F]{4}) decimal-part ::= [0-9]{1,16} email-kv ::= "\"email\"" space ":" space string integral-part ::= [0] | [1-9] [0-9]{0,15} number ::= ("-"? integral-part) ("." decimal-part)? ([eE] [-+]? integral-part)? space root ::= "{" space age-kv "," space email-kv "}" space space ::= | " " | "\n" [ \t]{0,20} string ::= "\"" char* "\"" space ```