Documentation ¶
Overview ¶
Package gcs provides an API for building and using a Golomb-coded set filter.
Golomb-Coded Set ¶
A Golomb-coded set is a probabilistic data structure used similarly to a Bloom filter. A filter uses constant-size overhead plus on average n+2 bits per item added to the filter, where 2^-n is the desired false positive (collision) probability.
GCS use in Bitcoin ¶
GCS filters are a proposed mechanism for storing and transmitting per-block filters in Bitcoin. The usage is intended to be the inverse of Bloom filters: a full node would send an SPV node the GCS filter for a block, which the SPV node would check against its list of relevant items. The suggested collision probability for Bitcoin use is 2^-20.
Index ¶
- Constants
- Variables
- type Filter
- func (f *Filter) Bytes() ([]byte, error)
- func (f *Filter) Match(key [KeySize]byte, data []byte) (yn bool, e error)
- func (f *Filter) MatchAny(key [KeySize]byte, data [][]byte) (bool, error)
- func (f *Filter) N() uint32
- func (f *Filter) NBytes() ([]byte, error)
- func (f *Filter) NPBytes() ([]byte, error)
- func (f *Filter) P() uint8
- func (f *Filter) PBytes() ([]byte, error)
Constants ¶
const ( // KeySize is the size of the byte array required for key material for the // SipHash keyed hash function. KeySize = 16 )
Variables ¶
var ( // ErrNTooBig signifies that the filter can't handle N items. ErrNTooBig = fmt.Errorf("N is too big to fit in uint32") // ErrPTooBig signifies that the filter can't handle `1/2**P` collision probability. ErrPTooBig = fmt.Errorf("P is too big to fit in uint32") )
Inspired by https://github.com/rasky/gcs
var F, E, W, I, D, T log.LevelPrinter = log.GetLogPrinterSet(subsystem)
Functions ¶
This section is empty.
Types ¶
type Filter ¶
type Filter struct {
// contains filtered or unexported fields
}
Filter describes an immutable filter that can be built from a set of data elements, serialized, deserialized, and queried in a thread-safe manner. The serialized form is compressed as a Golomb Coded Set (GCS), but does not include N or P to allow the user to encode the metadata separately if necessary. The hash function used is SipHash, a keyed function; the key used in building the filter is required in order to match filter values and is not included in the serialized form.
func BuildGCSFilter ¶
BuildGCSFilter builds a new GCS filter with the collision probability of `1/(2**P)`, key `key`, and including every `[]byte` in `data` as a member of the set.
func FromBytes ¶
FromBytes deserializes a GCS filter from a known N, P, and serialized filter as returned by Hash().
func FromNBytes ¶
FromNBytes deserializes a GCS filter from a known P, and serialized N and filter as returned by NBytes().
func (*Filter) Bytes ¶
Bytes returns the serialized format of the GCS filter, which does not include N or P (returned by separate methods) or the key used by SipHash.
func (*Filter) Match ¶
Match checks whether a []byte value is likely (within collision probability) to be a member of the set represented by the filter.
func (*Filter) MatchAny ¶
MatchAny returns checks whether any []byte value is likely (within collision probability) to be a member of the set represented by the filter faster than calling Match() for each value individually.
func (*Filter) NBytes ¶
NBytes returns the serialized format of the GCS filter with N, which does not include P (returned by a separate method) or the key used by SipHash.
func (*Filter) NPBytes ¶
NPBytes returns the serialized format of the GCS filter with N and P, which does not include the key used by SipHash.