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Biscuit, a bearer token with offline attenuation and decentralized verification

Introduction

Biscuit is a bearer token that supports offline attenuation, can be verified by any system that knows the root public key, and provides a flexible authorization language based on logic programming. It is serialized as Protocol Buffers 1, and designed to be small enough for storage in HTTP cookies.

Vocabulary

  • Datalog: a declarative logic language that works on facts defining data relationship, rules creating more facts if conditions are met, and queries to test such conditions
  • check: a restriction on the kind of operation that can be performed with the token that contains it, represented as a datalog query in biscuit. For the operation to be valid, all of the checks defined in the token and the authorizer must succeed
  • allow/deny policies: a list of datalog queries that are tested in a sequence until one of them matches. They can only be defined in the authorizer
  • block: a list of datalog facts, rules and checks. The first block is the authority block, used to define the basic rights of a token
  • (Verified) Biscuit: a completely parsed biscuit, whose signatures and final proof have been successfully verified
  • Unverified Biscuit: a completely parsed biscuit, whose signatures and final proof have not been verified yet. Manipulating unverified biscuits can be useful for generic tooling (eg inspecting a biscuit without knowing its public key)
  • Authorized Biscuit: a completely parsed biscuit, whose signatures and final proof have been successfully verified and that was authorized in a given context, by running checks and policies.
    An authorized biscuit may carry informations about the successful authorization such as the allow query that matched and the facts generated in the process
  • Authorizer: the context in which a biscuit is evaluated. An authorizer may carry facts, rules, checks and policies.

Overview

A Biscuit token is defined as a series of blocks. The first one, named "authority block", contains rights given to the token holder. The following blocks contain checks that reduce the token's scope, in the form of logic queries that must succeed. The holder of a biscuit token can at any time create a new token by adding a block with more checks, thus restricting the rights of the new token, but they cannot remove existing blocks without invalidating the signature.

The token is protected by public key cryptography operations: the initial creator of a token holds a secret key, and any verifier for the token needs only to know the corresponding public key. Any attenuation operation will employ ephemeral key pairs that are meant to be destroyed as soon as they are used.

There is also a sealed version of that token that prevents further attenuation.

The logic language used to design rights, checks, and operation data is a variant of datalog that accepts expressions on some data types.

Semantics

A biscuit is structured as an append-only list of blocks, containing checks, and describing authorization properties. As with Macaroons2, an operation must comply with all checks in order to be allowed by the biscuit.

Checks are written as queries defined in a flavor of Datalog that supports expressions on some data types3, without support for negation. This simplifies its implementation and makes the check more precise.

Logic language

Terminology

A Biscuit Datalog program contains facts and rules, which are made of predicates over the following types:

  • variable
  • integer
  • string
  • byte array
  • date
  • boolean
  • set a deduplicated list of values of any type, except variable or set

While a Biscuit token does not use a textual representation for storage, we use one for parsing and pretty printing of Datalog elements.

A predicate has the form Predicate(v0, v1, ..., vn).

A fact is a predicate that does not contain any variable.

A rule has the form: Pr(r0, r1, ..., rk) <- P0(t0_1, t0_2, ..., t0_m1), ..., Pn(tn_1, tn_2, ..., tn_mn), E0(v0, ..., vi), ..., Ex(vx, ..., vy). The part of the left of the arrow is called the head and on the right, the body. In a rule, each of the ri or ti_j terms can be of any type. A rule is safe if all of the variables in the head appear somewhere in the body. We also define an expression Ex over the variables v0 to vi. Expressions define a test of variable values when applying the rule. If the expression returns false, the rule application fails.

A query is a type of rule that has no head. It has the following form: ?- P0(t1_1, t1_2, ..., t1_m1), ..., Pn(tn_1, tn_2, ..., tn_mn), C0(v0), ..., Cx(vx). When applying a rule, if there is a combination of facts that matches the body's predicates, we generate a new fact corresponding to the head (with the variables bound to the corresponding values).

A check is a list of query for which the token validation will fail if it cannot produce any fact. A single query needs to match for the fact to succeed. If any of the cheks fails, the entire verification fails.

An allow policy or deny policy is a list of query. If any of the queries produces something, the policy matches, and we stop there, otherwise we test the next one. If an allow policy succeeds, the token verification succeeds, while if a deny policy succeeds, the token verification fails. Those policies are tested after all of the checks have passed.

We will represent the various types as follows:

  • variable: $variable (the variable name is converted to an integer id through the symbol table)
  • integer: 12
  • string: "hello" (strings are converted to integer ids through the symbol table)
  • byte array: hex:01A2
  • date in RFC 3339 format: 1985-04-12T23:20:50.52Z
  • boolean: true or false
  • set: [ "a", "b", "c"]

As an example, assuming we have the following facts: parent("a", "b"), parent("b", "c"), parent("c", "d"). If we apply the rule grandparent($x, $z) <- parent($x, $y), parent($y, $z), we will try to replace the predicates in the body by matching facts. We will get the following combinations:

  • grandparent("a", "c") <- parent("a", "b"), parent("b", "c")
  • grandparent("b", "d") <- parent("b", "c"), parent("c", "d")

The system will now contain the two new facts grandparent("a", "c") and grandparent("b", "d"). Whenever we generate new facts, we have to reapply all of the system's rules on the facts, because some rules might give a new result. Once rules application does not generate any new facts, we can stop.

Data types

An integer is a signed 64 bits integer. It supports the following operations: lower than, greater than, lower than or equal, greater than or equal, equal, not equal, set inclusion, addition, subtraction, mutiplication, division, bitwise and, bitwise or, bitwise xor.

A string is a suite of UTF-8 characters. It supports the following operations: prefix, suffix, equal, not equal, set inclusion, regular expression, concatenation (with +), substring test (with .contains()).

A byte array is a suite of bytes. It supports the following operations: equal, not equal, set inclusion.

A date is a 64 bit unsigned integer representing a UTC unix timestamp (number of seconds since 1970-01-01T00:00:00Z). It supports the following operations: <, <= (before), >, >= (after), equal, not equal, set inclusion.

A boolean is true or false. It supports the following operations: ==, !=, ||, &&, set inclusion.

A set is a deduplicated list of terms of the same type. It cannot contain variables or other sets. It supports equal, not equal, , intersection, union, set inclusion.

Grammar

The logic language is described by the following EBNF grammar:

<origin_clause> ::= <sp>? "trusting " <origin_element> <sp>? ("," <sp>? <origin_element> <sp>?)*
<origin_element> ::= "authority" | "previous" | <signature_alg>  "/" <bytes>
<signature_alg> ::= "ed25519"

<block> ::= (<origin_clause> ";" <sp>?)? (<block_element> | <comment> )*
<block_element> ::= <sp>? ( <check> | <fact> | <rule> ) <sp>? ";" <sp>?
<authorizer> ::= (<authorizer_element> | <comment> )*
<authorizer_element> ::= <sp>? ( <policy> | <check> | <fact> | <rule> ) <sp>? ";" <sp>?

<comment> ::= "//" ([a-z] | [A-Z] ) ([a-z] | [A-Z] | [0-9] | "_" | ":" | " " | "\t" | "(" | ")" | "$" | "[" | "]" )* "\n"

<fact> ::= <name> "(" <sp>? <fact_term> (<sp>? "," <sp>? <fact_term> )* <sp>? ")"
<rule> ::= <predicate> <sp>? "<-" <sp>? <rule_body>
<check> ::= "check" <sp> ( "if" | "all" ) <sp> <rule_body> (<sp>? " or " <sp>? <rule_body>)* <sp>?
<policy> ::= ("allow" | "deny") <sp> "if" <sp> <rule_body> (<sp>? " or " <sp>? <rule_body>)* <sp>?

<rule_body> ::= <rule_body_element> <sp>? ("," <sp>? <rule_body_element> <sp>?)* (<sp> <origin_clause>)?
<rule_body_element> ::= <predicate> | <expression>

<predicate> ::= <name> "(" <sp>? <term> (<sp>? "," <sp>? <term> )* <sp>? ")"
<term> ::= <fact_term> | <variable>
<fact_term> ::= <boolean> | <string> | <number> | ("hex:" <bytes>) | <date> | <set>
<set_term> ::= <boolean> | <string> | <number> | <bytes> | <date>


<number> ::= "-"? [0-9]+
<bytes> ::= ([a-z] | [0-9])+
<boolean> ::= "true" | "false"
<date> ::= [0-9]* "-" [0-9] [0-9] "-" [0-9] [0-9] "T" [0-9] [0-9] ":" [0-9] [0-9] ":" [0-9] [0-9] ( "Z" | ( ("+" | "-") [0-9] [0-9] ":" [0-9] [0-9] ))
<set> ::= "[" <sp>? ( <set_term> ( <sp>? "," <sp>? <set_term>)* <sp>? )? "]"

<expression> ::= <expression_element> (<sp>? <operator> <sp>? <expression_element>)*
<expression_element> ::= <expression_unary> | (<expression_term> <expression_method>? )
<expression_unary> ::= "!" <sp>? <expression>
<expression_method> ::= "." <method_name> "(" <sp>? (<term> ( <sp>? "," <sp>? <term>)* )? <sp>? ")"
<method_name> ::= ([a-z] | [A-Z] ) ([a-z] | [A-Z] | [0-9] | "_" )*

<expression_term> ::= <term> | ("(" <sp>? <expression> <sp>? ")")
<operator> ::= "<" | ">" | "<=" | ">=" | "==" | "!=" | "&&" | "||" | "+" | "-" | "*" | "/" | "&" | "|" | "^"

<sp> ::= (" " | "\t" | "\n")+

The name, variable and string rules are defined as:

  • name:
    • first character is any UTF-8 letter character
    • following characters are any UTF-8 letter character, numbers, _ or :
  • variable:
    • first character is $
    • following characters are any UTF-8 letter character, numbers, _ or :
  • string:
    • first character is "
    • any printable UTF-8 character except " which must be escaped as \"
    • last character is "

The order of operations in expressions is the following:

  • parentheses;
  • methods;
  • * / (left associative)
  • + - (left associative)
  • & (left associative)
  • | (left associative)
  • ^ (left associative)
  • <= >= < > == (not associative: they have to be combined with parentheses)
  • && (left associative)
  • || (left associative)

Scopes

Since the first block defines the token's rights through facts and rules, and later blocks can define their own facts and rules, we must ensure the token cannot increase its rights with later blocks.

This is done through execution scopes: by default, a block's rules and checks can only apply on facts created in the authority, in the current block or in the authorizer. Rules, checks and policies defined in the authorizer can only apply on facts created in the authority or in the authorizer.

Example:

  • the token contains right("file1", "read") in the first block
  • the token holder adds a block with the fact right("file2", "read")
  • the verifier adds:
    • resource("file2")
    • operation("read")
    • check if resource($res), operation($op), right($res, $op)

The verifier's check will fail because when it is evaluated, it only sees right("file1", "read") from the authority block.

Scope annotations

Rules (and blocks) can specify trusted origins through a special trusting annotation. By default, only the current block, the authority block and the verifier are trusted. This default can be overriden:

  • at the block level
  • at the rule level (which takes precedence over block-level annotations)

The scope annotation can be a combination of either:

  • authority (default behaviour): the authorizer, the current block and the authority one are trusted;
  • previous (only available in blocks): the authorizer, the current block and the previous blocks (including the authority) are trusted;
  • a public key: the authorizer, the current block and the blocks carrying an external signature verified by the provided public key are trusted.

previous is only available in blocks, and is ignored when used in the authorizer.

When there are multiple scope annotations, the trusted origins are added. Note that the current block and the authorizer are always trusted.

This scope annotation is then turned into a set of block ids before evaluation. Authorizer facts and rules are assigned a dedicated block id that's distinct from the authority and from the extra blocks.

Only facts which origin is a subset of these trusted origins are matched. The authorizer block id and the current block id are always part of these trusted origins.

Checks

Checks are logic queries evaluating conditions on facts. To validate an operation, all of a token's checks must succeed.

One block can contain one or more checks.

Their text representation is check if or check all followed by the body of the query. There can be multiple queries inside of a check, it will succeed if any of them succeeds. They are separated by a or token.

  • a check if query succeeds if it finds one set of facts that matches the body and expressions
  • a check all query succeeds if all the sets of facts that match the body also succeed the expression. check all can only be used starting from block version 4

Here are some examples of writing checks:

Basic token

This first token defines a list of authority facts giving read and write rights on file1, read on file2. The first caveat checks that the operation is read (and will not allow any other operation fact), and then that we have the read right over the resource. The second caveat checks that the resource is file1.

authority:
  right("file1", "read");
  right("file2", "read");
  right("file1", "write");
----------
Block 1:
check if
  resource($0),
  operation("read"),
  right($0, "read")  // restrict to read operations
----------
Block 2:
check if
  resource("file1")  // restrict to file1 resource

The verifier side provides the resource and operation facts with information from the request.

If the verifier provided the facts resource("file2") and operation("read"), the rule application of the first check would see resource("file2"), operation("read"), right("file2", "read") with X = "file2", so it would succeed, but the second check would fail because it expects resource("file1").

If the verifier provided the facts resource("file1") and operation("read"), both checks would succeed.

Broad authority rules

In this example, we have a token with very large rights, that will be attenuated before giving to a user. The authority block can define rules that will generate facts depending on data provided by the verifier. This helps reduce the size of the token.

authority:

// if there is an ambient resource and we own it, we can read it
right($0, "read") <- resource($0), owner($1, $0);
// if there is an ambient resource and we own it, we can write to it
right($0, "write") <- resource($0), owner($1, $0);
----------
Block 1:

check if
  right($0, $1),
  resource($0),
  operation($1)
----------
Block 2:

check if
  resource($0),
  owner("alice", $0) // defines a token only usable by alice

These rules will define authority facts depending on verifier data. If we had the facts resource("file1") and owner("alice", "file1"), the authority rules will define right("file1", "read") and right("file1", "write"), which will allow check 1 and check 2 to succeed.

If the owner ambient fact does not match the restriction in the second check, the token verification will fail.

Allow/deny policies

Allow and deny policies are queries that are tested one by one, after all of the checks have succeeded. If one of them succeeds, we stop there, otherwise we test the next one. If an allow policy succeeds, token verification succeeds, while if a deny policy succeeds, the token verification fails. If none of these policies are present, the verification will fail.

They are written as allow if or deny if followed by the body of the query. Same as for checks, the body of a policy can contain multiple queries, separated by "or". A single query needs to match for the policy to match.

Expressions

We can define queries or rules with expressions on some predicate values, and restrict usage based on ambient values:

authority:

right("/folder/file1", "read");
right("/folder/file2", "read");
right("/folder2/file3", "read");
----------
check if resource($0), right($0, $1)
----------
check if time($0), $0 < 2019-02-05T23:00:00Z // expiration date
----------
check if source_IP($0), ["1.2.3.4", "5.6.7.8"].contains($0) // set membership
----------
check if resource($0), $0.starts_with("/folder/") // prefix operation on strings

Executing an expression must always return a boolean, and all variables appearing in an expression must also appear in other predicates of the rule.

Execution

Expressions are internally represented as a series of opcodes for a stack based virtual machine. There are three kinds of opcodes:

  • value: a raw value of any type. If it is a variable, the variable must also appear in a predicate, so the variable gets a real value for execution. When encountering a value opcode, we push it onto the stack
  • unary operation: an operation that applies on one argument. When executed, it pops a value from the stack, applies the operation, then pushes the result
  • binary operation: an operation that applies on two arguments. When executed, it pops two values from the stack, applies the operation, then pushes the result

After executing, the stack must contain only one value, of the boolean type.

Here are the currently defined unary operations:

  • negate: boolean negation
  • parens: returns its argument without modification (this is used when printing the expression, to avoid precedence errors)
  • length: defined on strings, byte arrays and sets (for strings, length is defined as the number of bytes in the UTF-8 encoded string; the alternative of counting grapheme clusters would be inconsistent between languages)

Here are the currently defined binary operations:

  • less than, defined on integers and dates, returns a boolean
  • greater than, defined on integers and dates, returns a boolean
  • less or equal, defined on integers and dates, returns a boolean
  • greater or equal, defined on integers and dates, returns a boolean
  • equal, defined on integers, strings, byte arrays, dates, set, returns a boolean
  • not equal, defined on integers, strings, byte arrays, dates, set, returns a boolean (v4 only)
  • contains takes a set and another value as argument, returns a boolean. Between two sets, indicates if the first set is a superset of the second one. between two strings, indicates a substring test.
  • prefix, defined on strings, returns a boolean
  • suffix, defined on strings, returns a boolean
  • regex, defined on strings, returns a boolean
  • add, defined on integers, returns an integer. Defined on strings, concatenates them.
  • sub, defined on integers, returns an integer
  • mul, defined on integers, returns an integer
  • div, defined on integers, returns an integer
  • and, defined on booleans, returns a boolean
  • or, defined on booleans, returns a boolean
  • intersection, defined on sets, return a set that is the intersection of both arguments
  • union, defined on sets, return a set that is the union of both arguments
  • bitwiseAnd, defined on integers, returns an integer (v4 only)
  • bitwiseOr, defined on integers, returns an integer (v4 only)
  • bitwiseXor, defined on integers, returns an integer (v4 only)

Integer operations must have overflow checks. If it overflows, the expression fails.

Example

The expression 1 + 2 < 4 will translate to the following opcodes: 1, 2, +, 4, <

Here is how it would be executed:

Op | stack
   | [ ]
1  | [ 1 ]
2  | [ 2, 1 ]
+  | [ 3 ]
4  | [ 4, 3 ]
<  | [ true ]

The stack contains only one value, and it is true: the expression succeeds.

Datalog fact generation

Datalog fact generation works by repeatedly extending a Datalog world until no new facts are generated.

A Datalog world is:

  • a set of rules, each one tagged by the block id they were defined in
  • a set of facts, each one tagged by its origin: the block ids that allowed them to exist

Then, for each rule

  • facts are filtered based on their origin, and the scope annotation of the rule
  • available facts are matched on the rule predicates; only fact combinations that match every predicate are kept
  • rules expressions are computed for every matched combination; only fact combinations for which every expression returns true succeed
  • new facts are generated by the rule head, based on the matched variables

A fact defined in a block n has for origin {n} (a set containing only n). A fact generated by a rule defined in block rule_block_id that matched on facts fact_0…, fact_n has for origin Union({rule_block_id}, origin(fact_0) …, origin(fact_n)).

Verifier

The verifier provides information on the operation, such as the type of access ("read", "write", etc), the resource accessed, and more ambient data like the current time, source IP address, revocation lists. The verifier can also provide its own checks. It provides allow and deny policies for the final decision on request validation.

Deserializing the token

The token must first be deserialized according to the protobuf format definition, of Biscuit.

The cryptographic signature must be checked immediately after deserializing. The verifier must check that the public key of the authority block is the root public key it is expecting.

A Biscuit contains in its authority and blocks fields some byte arrays that must be deserialized as a Block.

Authorization process

The authorizer will first create a default symbol table, and will append to that table the values from the symbols field of each block, starting from the authority block and all the following blocks, ordered by their index.

The verifier will create a Datalog "world", and add to this world its own facts and rules: ambient data from the request, lists of users and roles, etc.

  • the facts from the authority block
  • the rules from the authority block
  • for each following block:
    • add the facts from the block.
    • add the rules from the block.
Revocation identifiers

The verifier will generate a list of facts indicating revocation identifiers for the token. The revocation identifier for a block is its signature (as it uniquely identifies the block) serialized to a byte array (as in the Protobuf schema). For each of these if, a fact revocation_id(<index of the block>, <byte array>) will be generated.

Authorizing

From there, the authorizer can start loading data from each block.

  • load facts and rules from every block, tagging each fact and rule with the corresponding block id
  • run the Datalog engine on all the facts and rules
  • for each check, validate it. If it fails, add an error to the error list
  • for each allow/deny policy:
    • run the query. If it succeeds:
      • if it is an allow policy, the verification succeeds, store the result and stop here
      • if it is a deny policy, the verification fails, store the result and stop here

Returning the result:

  • if the error list is not empty, return the error list
  • check policy result:
    • if an allow policy matched, the verification succeeds
    • if a deny policy matched, the verification fails
    • if no policy matched, the verification fails

Queries

The verifier can also run queries over the loaded data. A query is a datalog rule, and the query's result is the produced facts.

Appending

Deserializing

Appending a new block to an existing biscuit token requires deserializing blocks to extract symbol tables. Signature verification is not required at this step.

Format

The current version of the format is in schema.proto

The token contains two levels of serialization. The main structure that will be transmitted over the wire is either the normal Biscuit wrapper:

message Biscuit {
  optional uint32 rootKeyId = 1;
  required SignedBlock authority = 2;
  repeated SignedBlock blocks = 3;
  required Proof proof = 4;
}

message SignedBlock {
  required bytes block = 1;
  required PublicKey nextKey = 2;
  required bytes signature = 3;
  optional ExternalSignature externalSignature = 4;
}

message ExternalSignature {
  required bytes signature = 1;
  required PublicKey publicKey = 2;
}

message PublicKey {
  required Algorithm algorithm = 1;

  enum Algorithm {
    Ed25519 = 0;
  }

  required bytes key = 2;
}

message Proof {
  oneof Content {
    bytes nextSecret = 1;
    bytes finalSignature = 2;
  }
}

The rootKeyId is a hint to decide which root public key should be used for signature verification.

Each block contains a serialized byte array of the Datalog data (block), the next public key (nextKey) and the signature of that block and key by the previous key.

The proof field contains either the private key corresponding to the public key in the last block (attenuable tokens) or a signature of the last block by the private key (sealed tokens).

The block field is a byte array, containing a Block structure serialized in Protobuf format as well:

message Block {
  repeated string symbols = 1;
  optional string context = 2;
  optional uint32 version = 3;
  repeated FactV2 facts_v2 = 4;
  repeated RuleV2 rules_v2 = 5;
  repeated CheckV2 checks_v2 = 6;
  repeated Scope scope = 7;
  repeated PublicKey publicKeys = 8;
}

Each block contains a version field, indicating at which format version it was generated. Since a Biscuit implementation at version N can receive a valid token generated at version N-1, new implementations must be able to recognize older formats. Moreover, when appending a new block, they cannot convert the old blocks to the new format (since that would invalidate the signature). So each block must carry its own version.

  • An implementation must refuse a token containing blocks with a newer format than the range they know.

  • An implementation must refuse a token containing blocks with an older format than the range they know.

  • An implementation may generate blocks with older formats to help with backwards compatibility, when possible, especially for biscuit versions that are only additive in terms of features.

  • The lowest supported biscuit version is 3;

  • The highest supported biscuit version is 5;

Version 2

This is the format for the 2.0 version of Biscuit.

It transport expressions as an array of opcodes.

Text format

When transmitted as text, a Biscuit token should be serialized to a URLS safe base 64 string. When the context does not indicate that it is a Biscuit token, that base 64 string should be prefixed with biscuit:.

Cryptography

Biscuit tokens are based on public key cryptography, with a chain of Ed25519 signatures. Each block contains the serialized Datalog, the next public key, and the signature by the previous key. The token also contains the private key corresponding to the last public key, to sign a new block and attenuate the token, or a signature of the last block by the last private key, to seal the token.

Signature (one block)

  • (pk_0, sk_0) the root public and private Ed25519 keys
  • data_0 the serialized Datalog
  • (pk_1, sk_1) the next key pair, generated at random
  • alg_1 the little endian representation of the signature algorithm fr pk1, sk1 (see protobuf schema)
  • sig_0 = sign(sk_0, data_0 + alg_1 + pk_1)

The token will contain:

Token {
  root_key_id: <optional number indicating the root key to use for verification>
  authority: Block {
    data_0,
    pk_1,
    sig_0,
  }
  blocks: [],
  proof: Proof {
    nextSecret: sk_1,
  },
}

Signature (appending)

With a token containing blocks 0 to n:

Block n contains:

  • data_n
  • pk_n+1
  • sig_n

The token also contains sk_n+1.

The new block can optionally be signed by an external keypair (epk, esk) and carry an external signature esig.

We generate at random (pk_n+2, sk_n+2) and the signature sig_n+1 = sign(sk_n+1, data_n+1 + esig? + alg_n+2 + pk_n+2). If the block is not signed by an external keypair, then esig is not part of the signed payload.

The token will contain:

Token {
  root_key_id: <optional number indicating the root key to use for verification>
  authority: Block_0,
  blocks: [Block_1, .., Block_n,
      Block_n+1 {
      data_n+1,
      pk_n+2,
      sig_n+1,
      epk?, esig?
    }]
  proof: Proof {
    nextSecret: sk_n+2,
  },
}
Optional external signature

Blocks generated by a trusted third party can carry an extra signature to provide a proof of their origin. Same as regular signatures, they rely on Ed25519.

The external signature for block n+1, with (external_pk, external_sk) is external_sig_n+1 = sign(external_sk, data_n+1 + alg_n+1 + pk_n+1). It's quite similar to the regular signature, with a crucial difference: the public key appended to the block payload is the one carried by block n (and which is used to verify block n+1). This means that the authority block can't carry an external signature (that would be useless, since the root key is not ephemeral and can be trusted directly).

This is necessary to make sure an external signature can't be used for any other token.

The presence of an external signature affects the regular signature: the external signature is part of the payload signed by the regular signature.

The token will contain:

Token {
  root_key_id: <optional number indicating the root key to use for verification>
  authority: Block_0,
  blocks: [Block_1, .., Block_n,
      Block_n+1 {
      data_n+1,
      pk_n+2,
      sig_n+1,
      external_pk,
      external_sig_n+1
    }]
  proof: Proof {
    nextSecret: sk_n+2,
  },
}

Blocks signed with an external keypair must be at least v5.

Verifying

For each block i from 0 to n:

  • verify(pk_i, sig_i, data_i + alg_i+1 + pk_i+1)

If all signatures are verified, extract pk_n+1 from the last block and sk_n+1 from the proof field, and check that they are from the same key pair.

Verifying external signatures

For each block i from 1 to n, where an external signature is present:

  • verify(external_pk_i, external_sig_i, data_i + alg_i + pk_i)

Signature (sealing)

With a token containing blocks 0 to n:

Block n contains:

  • data_n
  • pk_n+1
  • sig_n

The token also contains sk_n+1

We generate the signature sig_n+1 = sign(sk_n+1, data_n + alg_n+1 + pk_n+1 + sig_n) (we sign the last block and its signature with the last private key).

The token will contain:

Token {
  root_key_id: <optional number indicating the root key to use for verification>
  authority: Block_0,
  blocks: [Block_1, .., Block_n]
  proof: Proof {
    finalSignature: sig_n+1
  },
}

Verifying (sealed)

For each block i from 0 to n:

  • verify(pk_i, sig_i, data_i+alg_i+1+pk_i+1)

If all signatures are verified, extract pk_n+1 from the last block and sig from the proof field, and check verify(pk_n+1, sig_n+1, data_n+alg_n+1+pk_n+1+sig_n)

Blocks

A block is defined as follows in the schema file:

message Block {
  repeated string symbols = 1;
  optional string context = 2;
  optional uint32 version = 3;
  repeated FactV2 facts_v2 = 4;
  repeated RuleV2 rules_v2 = 5;
  repeated CheckV2 checks_v2 = 6;
  repeated Scope scope = 7;
  repeated PublicKey publicKeys = 8;
}

The block index is incremented for each new block. The Block 0 is the authority block.

Each block can provide facts either from its facts list, or generate them with its rules list.

Symbol table

To reduce the token size and improve performance, Biscuit uses a symbol table, a list of strings that any fact or token can refer to by index. While running the logic engine does not need to know the content of that list, pretty printing facts, rules and results will use it.

The symbol table is created from a default table containing, in order:

  • read
  • write
  • resource
  • operation
  • right
  • time
  • role
  • owner
  • tenant
  • namespace
  • user
  • team
  • service
  • admin
  • email
  • group
  • member
  • ip_address
  • client
  • client_ip
  • domain
  • path
  • version
  • cluster
  • node
  • hostname
  • nonce
  • query

Symbol table indexes from 0 to 1023 are reserved for the default symbols. Symbols defined in a token or authorizer must start from 1024.

Adding content to the symbol table

Regular blocks (no external signature)

When creating a new block, we start from the current symbol table of the token. For each fact or rule that introduces a new symbol, we add the corresponding string to the table, and convert the fact or rule to use its index instead.

Once every fact and rule has been integrated, we set as the block's symbol table (its symbols field) the symbols that were appended to the token's table.

The new token's symbol table is the list from the default table, and for each block in order, the block's symbols.

It is important to verify that different blocks do not contain the same symbol in their list.

3rd party blocks (with an external signature)

Blocks that are signed by an external key don't use the token symbol table and start from the default symbol table. Following blocks ignore the symbols declared in their symbols field.

Similarly such blocks don't use the token public keys table and start from an empty table. Following blocks ignore the public keys defined in the public_keys field.

The reason for this is that the party signing the block is not supposed to have access to the token itself and can't use the token's symbol table or its public keys table.

Public key tables

Public keys carried in SignedBlocks are stored as is, as they are required for verification.

Public keys carried in datalog scope annotations are stored in a table, to reduce token size.

Reading

Building a symbol table for a token can be done this way:

for each block (if it does not have an external signature):

  • add the contents of the publicKeys field of the Block message

Blocks with an external signature use their own table and don't affect the rest of the token.

Appending

Same as for symbols, the publicKeys field should only contain public keys that were not present in the table yet.

Appending a third-party block

Third party blocks are special blocks, that are meant to be signed by a trusted party, to either expand a token or fulfill special checks with dedicated public key constraints.

Unlike first-party blocks, the party signing the token should not have access to the token itself. The third party needs however some context in order to be able to properly sign block contents. Additionally, the third party needs to return both the serialized block and the external signature.

To support this use-case, the protobuf schema defines two message types: ThirdPartyBlockRequest and ThirdPartyBlockContents:

message ThirdPartyBlockRequest {
  required PublicKey previousKey = 1;
  repeated PublicKey legacyPublicKeys = 2;
}

message ThirdPartyBlockContents {
  required bytes payload = 1;
  required ExternalSignature externalSignature = 2;
}

ThirdPartyBlockRequest contains the necessary context for serializing and signing a datalog block:

  • previousKey is needed for the signature (it makes sure that a third-party block can only be used for a specific biscuit token
  • legacyPublicKeys is a legacy field. It must be empty (a non-empty field indicates that the request has been generated by an outdated implementation)

ThirdPartyBlockContents contains both the serialized Block and the external signature.

The expected sequence is

  • the token holder generates a ThirdPartyBlockRequest from their token;
  • they send it, along with domain-specific information, to the third party that's responsible for providing a third-party block;
  • the third party creates a datalog block (based on domain-specific information), serializes it and signs it, and returns a ThirdPartyBlockContents to the token holder
  • the token holder now uses ThirdPartyBlockContents to append a new signed block to the token

An implementation must be able to:

  • generate a ThirdPartyBlockRequest from a token (by extracting its last ephemeral public key)
  • apply a ThirdPartyBlockContents on a token by appending the serialized block like a regular block

Same as biscuit tokens, the ThirdPartyBlockRequest and ThirdPartyBlockContents values can be transfered in text format by encoding them with base64url.

Test cases

We provide sample tokens and the expected result of their verification at https://github.com/biscuit-auth/biscuit/tree/master/samples

References

Footnotes

  1. ProtoBuf https://developers.google.com/protocol-buffers/

  2. "Macaroons: Cookies with Contextual Caveats for Decentralized Authorization in the Cloud" https://ai.google/research/pubs/pub41892

  3. "Datalog with Constraints: A Foundation for Trust Management Languages" http://crypto.stanford.edu/~ninghui/papers/cdatalog_padl03.pdf