package merkle_tree import ( "encoding/binary" "errors" "fmt" "reflect" "unsafe" "github.com/ledgerwatch/erigon-lib/common" "github.com/ledgerwatch/erigon-lib/common/length" "github.com/ledgerwatch/erigon-lib/types/ssz" "github.com/prysmaticlabs/gohashtree" ) // HashTreeRoot returns the hash for a given schema of objects. // IMPORTANT: DATA TYPE MUST IMPLEMENT HASHABLE // SUPPORTED PRIMITIVES: uint64, *uint64 and []byte func HashTreeRoot(schema ...interface{}) ([32]byte, error) { // Calculate the total number of leaves needed based on the schema length leaves := make([]byte, NextPowerOfTwo(uint64(len(schema)*length.Hash))) pos := 0 // Iterate over each element in the schema for i, element := range schema { switch obj := element.(type) { case uint64: // If the element is a uint64, encode it as little-endian and store it in the leaves binary.LittleEndian.PutUint64(leaves[pos:], obj) case *uint64: // If the element is a pointer to uint64, dereference it, encode it as little-endian, and store it in the leaves binary.LittleEndian.PutUint64(leaves[pos:], *obj) case []byte: // If the element is a byte slice if len(obj) < length.Hash { // If the slice is shorter than the length of a hash, copy the slice into the leaves copy(leaves[pos:], obj) } else { // If the slice is longer or equal to the length of a hash, calculate the hash of the slice and store it in the leaves root, err := BytesRoot(obj) if err != nil { return [32]byte{}, err } copy(leaves[pos:], root[:]) } case ssz.HashableSSZ: // If the element implements the HashableSSZ interface, calculate the SSZ hash and store it in the leaves root, err := obj.HashSSZ() if err != nil { return [32]byte{}, err } copy(leaves[pos:], root[:]) default: // If the element does not match any supported types, panic with an error message panic(fmt.Sprintf("get it out of my face, u put a bad component in the schema. index %d", i)) } // Move the position pointer to the next leaf pos += length.Hash } // Calculate the Merkle root from the flat leaves if err := MerkleRootFromFlatLeaves(leaves, leaves); err != nil { return [32]byte{}, err } // Convert the bytes of the resulting hash into a [32]byte and return it return common.BytesToHash(leaves[:length.Hash]), nil } // HashByteSlice is gohashtree HashBytSlice but using our hopefully safer header converstion func HashByteSlice(out, in []byte) error { if len(in) == 0 { return errors.New("zero leaves provided") } if len(out)%32 != 0 { return errors.New("output must be multple of 32") } if len(in)%64 != 0 { return errors.New("input must be multple of 64") } c_in := convertHeader(in) c_out := convertHeader(out) err := gohashtree.Hash(c_out, c_in) if err != nil { return err } return nil } func convertHeader(xs []byte) [][32]byte { // i wont pretend to understand, but my solution for the problem is as so // first i grab the slice header of the input header := (*reflect.SliceHeader)(unsafe.Pointer(&xs)) // then i allocate a new result slice of no size - this should make the escape analyzer happy i think? dat := make([][32]byte, 0) // we then get the header of our output to modify chunkedHeader := (*reflect.SliceHeader)(unsafe.Pointer(&dat)) // then we move over the values chunkedHeader.Len = header.Len / 32 chunkedHeader.Cap = header.Cap / 32 chunkedHeader.Data = header.Data return dat } func MerkleRootFromFlatLeaves(leaves []byte, out []byte) (err error) { if len(leaves) <= 32 { copy(out, leaves) return } return globalHasher.merkleizeTrieLeavesFlat(leaves, out, NextPowerOfTwo(uint64((len(leaves)+31)/32))) } func MerkleRootFromFlatLeavesWithLimit(leaves []byte, out []byte, limit uint64) (err error) { return globalHasher.merkleizeTrieLeavesFlat(leaves, out, limit) }