eth2.0-specs/specs/test_formats/ssz_generic
Danny Ryan b09c45ffd2
remove last two references to signing root
2019-12-12 12:34:02 -07:00
..
README.md remove last two references to signing root 2019-12-12 12:34:02 -07:00

README.md

SSZ, generic tests

This set of test-suites provides general testing for SSZ: to decode any container/list/vector/other type from binary data, encode it back, and compute the hash-tree-root.

This test collection for general-purpose SSZ is experimental. The ssz_static suite is the required minimal support for SSZ, and should be prioritized.

The ssz_generic tests are split up into different handler, each specialized into a SSZ type:

  • Vectors
    • basic_vector
    • complex_vector not supported yet
  • List
    • basic_list not supported yet
    • complex_list not supported yet
  • Bitfields
    • bitvector
    • bitlist
  • Basic types
    • boolean
    • uints
  • Containers
    • containers

Format

For each type, a valid and an invalid suite is implemented. The cases have the same format, but those in the invalid suite only declare a subset of the data a test in the valid declares.

Each of the handlers encodes the SSZ type declaration in the file-name. See Type Declarations.

valid

Valid has 3 parts: meta.yaml, serialized.ssz, value.yaml

meta.yaml

Valid ssz objects can have a hash-tree-root. The expected roots are encoded into the metadata yaml:

root: Bytes32             -- Hash-tree-root of the object

The Bytes32 is encoded as a string, hexadecimal encoding, prefixed with 0x.

serialized.ssz

The serialized form of the object, as raw SSZ bytes.

value.yaml

The object, encoded as a YAML structure. Using the same familiar encoding as YAML data in the other test suites.

Conditions

The conditions are the same for each type:

  • Encoding: After encoding the given value object, the output should match serialized.
  • Decoding: After decoding the given serialized bytes, it should match the value object.
  • Hash-tree-root: the root should match the root declared in the metadata.

invalid

Test cases in the invalid suite only include the serialized.ssz

Condition

Unlike the valid suite, invalid encodings do not have any value or hash tree root. The serialized data should simply not be decoded without raising an error.

Note that for some type declarations in the invalid suite, the type itself may technically be invalid. This is a valid way of detecting invalid data too. E.g. a 0-length basic vector.

Type declarations

Most types are not as static, and can reasonably be constructed during test runtime from the test case name. Formats are listed below.

For each test case, an additional _{extra...} may be appended to the name, where {extra...} contains a human readable indication of the test case contents for debugging purposes.

basic_vector

Template:

vec_{element type}_{length}

Data:

{element type}: bool, uint8, uint16, uint32, uint64, uint128, uint256

{length}: an unsigned integer

bitlist

Template:

bitlist_{limit}

Data:

{limit}: the list limit, in bits, of the bitlist. Does not include the length-delimiting bit in the serialized form.

bitvector

Template:

bitvec_{length}

Data:

{length}: the length, in bits, of the bitvector.

boolean

A boolean has no type variations. Instead, file names just plainly describe the contents for debugging.

uints

Template:

uint_{size}

Data:

{size}: the uint size: 8, 16, 32, 64, 128 or 256.

containers

Containers are more complicated than the other types. Instead, a set of pre-defined container structures is referenced:

Template:

{container name}

Data:

{container name}: Any of the container names listed below (exluding the `(Container)` python super type)

class SingleFieldTestStruct(Container):
    A: byte


class SmallTestStruct(Container):
    A: uint16
    B: uint16


class FixedTestStruct(Container):
    A: uint8
    B: uint64
    C: uint32


class VarTestStruct(Container):
    A: uint16
    B: List[uint16, 1024]
    C: uint8


class ComplexTestStruct(Container):
    A: uint16
    B: List[uint16, 128]
    C: uint8
    D: Bytes[256]
    E: VarTestStruct
    F: Vector[FixedTestStruct, 4]
    G: Vector[VarTestStruct, 2]


class BitsStruct(Container):
    A: Bitlist[5]
    B: Bitvector[2]
    C: Bitvector[1]
    D: Bitlist[6]
    E: Bitvector[8]