zolfa
/
tendermint


								package merkle


								import (

									"bytes"

									"errors"

									"fmt"

								)


								//----------------------------------------

								// ProofOp gets converted to an instance of ProofOperator:


								// ProofOperator is a layer for calculating intermediate Merkle roots

								// when a series of Merkle trees are chained together.

								// Run() takes leaf values from a tree and returns the Merkle

								// root for the corresponding tree. It takes and returns a list of bytes

								// to allow multiple leaves to be part of a single proof, for instance in a range proof.

								// ProofOp() encodes the ProofOperator in a generic way so it can later be

								// decoded with OpDecoder.

								type ProofOperator interface {

									Run([][]byte) ([][]byte, error)

									GetKey() []byte

									ProofOp() ProofOp

								}


								//----------------------------------------

								// Operations on a list of ProofOperators


								// ProofOperators is a slice of ProofOperator(s).

								// Each operator will be applied to the input value sequentially

								// and the last Merkle root will be verified with already known data

								type ProofOperators []ProofOperator


								func (poz ProofOperators) VerifyValue(root []byte, keypath string, value []byte) (err error) {

									return poz.Verify(root, keypath, [][]byte{value})

								}


								func (poz ProofOperators) Verify(root []byte, keypath string, args [][]byte) (err error) {

									keys, err := KeyPathToKeys(keypath)

									if err != nil {

										return

									}


									for i, op := range poz {

										key := op.GetKey()

										if len(key) != 0 {

											if len(keys) == 0 {

												return fmt.Errorf("key path has insufficient # of parts: expected no more keys but got %+v", string(key))

											}

											lastKey := keys[len(keys)-1]

											if !bytes.Equal(lastKey, key) {

												return fmt.Errorf("key mismatch on operation #%d: expected %+v but got %+v", i, string(lastKey), string(key))

											}

											keys = keys[:len(keys)-1]

										}

										args, err = op.Run(args)

										if err != nil {

											return

										}

									}

									if !bytes.Equal(root, args[0]) {

										return fmt.Errorf("calculated root hash is invalid: expected %+v but got %+v", root, args[0])

									}

									if len(keys) != 0 {

										return errors.New("keypath not consumed all")

									}

									return nil

								}


								//----------------------------------------

								// ProofRuntime - main entrypoint


								type OpDecoder func(ProofOp) (ProofOperator, error)


								type ProofRuntime struct {

									decoders map[string]OpDecoder

								}


								func NewProofRuntime() *ProofRuntime {

									return &ProofRuntime{

										decoders: make(map[string]OpDecoder),

									}

								}


								func (prt *ProofRuntime) RegisterOpDecoder(typ string, dec OpDecoder) {

									_, ok := prt.decoders[typ]

									if ok {

										panic("already registered for type " + typ)

									}

									prt.decoders[typ] = dec

								}


								func (prt *ProofRuntime) Decode(pop ProofOp) (ProofOperator, error) {

									decoder := prt.decoders[pop.Type]

									if decoder == nil {

										return nil, fmt.Errorf("unrecognized proof type %v", pop.Type)

									}

									return decoder(pop)

								}


								func (prt *ProofRuntime) DecodeProof(proof *Proof) (ProofOperators, error) {

									poz := make(ProofOperators, 0, len(proof.Ops))

									for _, pop := range proof.Ops {

										operator, err := prt.Decode(pop)

										if err != nil {

											return nil, fmt.Errorf("decoding a proof operator: %w", err)

										}

										poz = append(poz, operator)

									}

									return poz, nil

								}


								func (prt *ProofRuntime) VerifyValue(proof *Proof, root []byte, keypath string, value []byte) (err error) {

									return prt.Verify(proof, root, keypath, [][]byte{value})

								}


								// TODO In the long run we'll need a method of classifcation of ops,

								// whether existence or absence or perhaps a third?

								func (prt *ProofRuntime) VerifyAbsence(proof *Proof, root []byte, keypath string) (err error) {

									return prt.Verify(proof, root, keypath, nil)

								}


								func (prt *ProofRuntime) Verify(proof *Proof, root []byte, keypath string, args [][]byte) (err error) {

									poz, err := prt.DecodeProof(proof)

									if err != nil {

										return fmt.Errorf("decoding proof: %w", err)

									}

									return poz.Verify(root, keypath, args)

								}


								// DefaultProofRuntime only knows about Simple value

								// proofs.

								// To use e.g. IAVL proofs, register op-decoders as

								// defined in the IAVL package.

								func DefaultProofRuntime() (prt *ProofRuntime) {

									prt = NewProofRuntime()

									prt.RegisterOpDecoder(ProofOpSimpleValue, SimpleValueOpDecoder)

									return

								}