package v3 import ( "io" "math/big" "unsafe" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/common/hexutil" ethtypes "github.com/ethereum/go-ethereum/core/types" "github.com/ethereum/go-ethereum/rlp" "github.com/rs/zerolog" blockif "github.com/harmony-one/harmony/block/interface" "github.com/harmony-one/harmony/crypto/hash" "github.com/harmony-one/harmony/shard" ) // Header is the V3 block header. // V3 block header is exactly the same // we copy the code instead of embedded v2 header into v3 // when we do type checking in NewBodyForMatchingHeader // the embedded structure will return v2 header type instead of v3 type type Header struct { fields headerFields } // EncodeRLP encodes the header fields into RLP format. func (h *Header) EncodeRLP(w io.Writer) error { return rlp.Encode(w, &h.fields) } // DecodeRLP decodes the given RLP decode stream into the header fields. func (h *Header) DecodeRLP(s *rlp.Stream) error { return s.Decode(&h.fields) } // NewHeader creates a new header object. func NewHeader() *Header { return &Header{headerFields{ Number: new(big.Int), Time: new(big.Int), ViewID: new(big.Int), Epoch: new(big.Int), }} } type headerFields struct { ParentHash common.Hash `json:"parentHash" gencodec:"required"` Coinbase common.Address `json:"miner" gencodec:"required"` Root common.Hash `json:"stateRoot" gencodec:"required"` TxHash common.Hash `json:"transactionsRoot" gencodec:"required"` ReceiptHash common.Hash `json:"receiptsRoot" gencodec:"required"` OutgoingReceiptHash common.Hash `json:"outgoingReceiptsRoot" gencodec:"required"` IncomingReceiptHash common.Hash `json:"incomingReceiptsRoot" gencodec:"required"` Bloom ethtypes.Bloom `json:"logsBloom" gencodec:"required"` Number *big.Int `json:"number" gencodec:"required"` GasLimit uint64 `json:"gasLimit" gencodec:"required"` GasUsed uint64 `json:"gasUsed" gencodec:"required"` Time *big.Int `json:"timestamp" gencodec:"required"` Extra []byte `json:"extraData" gencodec:"required"` MixDigest common.Hash `json:"mixHash" gencodec:"required"` // Additional Fields ViewID *big.Int `json:"viewID" gencodec:"required"` Epoch *big.Int `json:"epoch" gencodec:"required"` ShardID uint32 `json:"shardID" gencodec:"required"` LastCommitSignature [96]byte `json:"lastCommitSignature" gencodec:"required"` LastCommitBitmap []byte `json:"lastCommitBitmap" gencodec:"required"` // Contains which validator signed ShardStateHash common.Hash `json:"shardStateRoot"` Vrf []byte `json:"vrf"` Vdf []byte `json:"vdf"` ShardState []byte `json:"shardState"` CrossLinks []byte `json:"crossLink"` } // ParentHash is the header hash of the parent block. For the genesis block // which has no parent by definition, this field is zeroed out. func (h *Header) ParentHash() common.Hash { return h.fields.ParentHash } // SetParentHash sets the parent hash field. func (h *Header) SetParentHash(newParentHash common.Hash) { h.fields.ParentHash = newParentHash } // Coinbase is the address of the node that proposed this block and all // transactions in it. func (h *Header) Coinbase() common.Address { return h.fields.Coinbase } // SetCoinbase sets the coinbase address field. func (h *Header) SetCoinbase(newCoinbase common.Address) { h.fields.Coinbase = newCoinbase } // Root is the state (account) trie root hash. func (h *Header) Root() common.Hash { return h.fields.Root } // SetRoot sets the state trie root hash field. func (h *Header) SetRoot(newRoot common.Hash) { h.fields.Root = newRoot } // TxHash is the transaction trie root hash. func (h *Header) TxHash() common.Hash { return h.fields.TxHash } // SetTxHash sets the transaction trie root hash field. func (h *Header) SetTxHash(newTxHash common.Hash) { h.fields.TxHash = newTxHash } // ReceiptHash is the same-shard transaction receipt trie hash. func (h *Header) ReceiptHash() common.Hash { return h.fields.ReceiptHash } // SetReceiptHash sets the same-shard transaction receipt trie hash. func (h *Header) SetReceiptHash(newReceiptHash common.Hash) { h.fields.ReceiptHash = newReceiptHash } // OutgoingReceiptHash is the egress transaction receipt trie hash. func (h *Header) OutgoingReceiptHash() common.Hash { return h.fields.OutgoingReceiptHash } // SetOutgoingReceiptHash sets the egress transaction receipt trie hash. func (h *Header) SetOutgoingReceiptHash(newOutgoingReceiptHash common.Hash) { h.fields.OutgoingReceiptHash = newOutgoingReceiptHash } // IncomingReceiptHash is the ingress transaction receipt trie hash. func (h *Header) IncomingReceiptHash() common.Hash { return h.fields.IncomingReceiptHash } // SetIncomingReceiptHash sets the ingress transaction receipt trie hash. func (h *Header) SetIncomingReceiptHash(newIncomingReceiptHash common.Hash) { h.fields.IncomingReceiptHash = newIncomingReceiptHash } // Bloom is the Bloom filter that indexes accounts and topics logged by smart // contract transactions (executions) in this block. func (h *Header) Bloom() ethtypes.Bloom { return h.fields.Bloom } // SetBloom sets the smart contract log Bloom filter for this block. func (h *Header) SetBloom(newBloom ethtypes.Bloom) { h.fields.Bloom = newBloom } // Number is the block number. // // The returned instance is a copy; the caller may do anything with it. func (h *Header) Number() *big.Int { return new(big.Int).Set(h.fields.Number) } // SetNumber sets the block number. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetNumber(newNumber *big.Int) { h.fields.Number = new(big.Int).Set(newNumber) } // GasLimit is the gas limit for transactions in this block. func (h *Header) GasLimit() uint64 { return h.fields.GasLimit } // SetGasLimit sets the gas limit for transactions in this block. func (h *Header) SetGasLimit(newGasLimit uint64) { h.fields.GasLimit = newGasLimit } // GasUsed is the amount of gas used by transactions in this block. func (h *Header) GasUsed() uint64 { return h.fields.GasUsed } // SetGasUsed sets the amount of gas used by transactions in this block. func (h *Header) SetGasUsed(newGasUsed uint64) { h.fields.GasUsed = newGasUsed } // Time is the UNIX timestamp of this block. // // The returned instance is a copy; the caller may do anything with it. func (h *Header) Time() *big.Int { return new(big.Int).Set(h.fields.Time) } // SetTime sets the UNIX timestamp of this block. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetTime(newTime *big.Int) { h.fields.Time = new(big.Int).Set(newTime) } // Extra is the extra data field of this block. // // The returned slice is a copy; the caller may do anything with it. func (h *Header) Extra() []byte { return append(h.fields.Extra[:0:0], h.fields.Extra...) } // SetExtra sets the extra data field of this block. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetExtra(newExtra []byte) { h.fields.Extra = append(newExtra[:0:0], newExtra...) } // MixDigest is the mixhash. // // This field is a remnant from Ethereum, and Harmony does not use it and always // zeroes it out. func (h *Header) MixDigest() common.Hash { return h.fields.MixDigest } // SetMixDigest sets the mixhash of this block. func (h *Header) SetMixDigest(newMixDigest common.Hash) { h.fields.MixDigest = newMixDigest } // ViewID is the ID of the view in which this block was originally proposed. // // It normally increases by one for each subsequent block, or by more than one // if one or more PBFT/FBFT view changes have occurred. // // The returned instance is a copy; the caller may do anything with it. func (h *Header) ViewID() *big.Int { return new(big.Int).Set(h.fields.ViewID) } // SetViewID sets the view ID in which the block was originally proposed. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetViewID(newViewID *big.Int) { h.fields.ViewID = new(big.Int).Set(newViewID) } // Epoch is the epoch number of this block. // // The returned instance is a copy; the caller may do anything with it. func (h *Header) Epoch() *big.Int { return new(big.Int).Set(h.fields.Epoch) } // SetEpoch sets the epoch number of this block. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetEpoch(newEpoch *big.Int) { h.fields.Epoch = new(big.Int).Set(newEpoch) } // ShardID is the shard ID to which this block belongs. func (h *Header) ShardID() uint32 { return h.fields.ShardID } // SetShardID sets the shard ID to which this block belongs. func (h *Header) SetShardID(newShardID uint32) { h.fields.ShardID = newShardID } // LastCommitSignature is the FBFT commit group signature for the last block. func (h *Header) LastCommitSignature() [96]byte { return h.fields.LastCommitSignature } // SetLastCommitSignature sets the FBFT commit group signature for the last // block. func (h *Header) SetLastCommitSignature(newLastCommitSignature [96]byte) { h.fields.LastCommitSignature = newLastCommitSignature } // LastCommitBitmap is the signatory bitmap of the previous block. Bit // positions index into committee member array. // // The returned slice is a copy; the caller may do anything with it. func (h *Header) LastCommitBitmap() []byte { return append(h.fields.LastCommitBitmap[:0:0], h.fields.LastCommitBitmap...) } // SetLastCommitBitmap sets the signatory bitmap of the previous block. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetLastCommitBitmap(newLastCommitBitmap []byte) { h.fields.LastCommitBitmap = append(newLastCommitBitmap[:0:0], newLastCommitBitmap...) } // ShardStateHash is the shard state hash. func (h *Header) ShardStateHash() common.Hash { return h.fields.ShardStateHash } // SetShardStateHash sets the shard state hash. func (h *Header) SetShardStateHash(newShardStateHash common.Hash) { h.fields.ShardStateHash = newShardStateHash } // Vrf is the output of the VRF for the epoch. // // The returned slice is a copy; the caller may do anything with it. func (h *Header) Vrf() []byte { return append(h.fields.Vrf[:0:0], h.fields.Vrf...) } // SetVrf sets the output of the VRF for the epoch. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetVrf(newVrf []byte) { h.fields.Vrf = append(newVrf[:0:0], newVrf...) } // Vdf is the output of the VDF for the epoch. // // The returned slice is a copy; the caller may do anything with it. func (h *Header) Vdf() []byte { return append(h.fields.Vdf[:0:0], h.fields.Vdf...) } // SetVdf sets the output of the VDF for the epoch. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetVdf(newVdf []byte) { h.fields.Vdf = append(newVdf[:0:0], newVdf...) } // ShardState is the RLP-encoded form of shard state (list of committees) for // the next epoch. // // The returned slice is a copy; the caller may do anything with it. func (h *Header) ShardState() []byte { return append(h.fields.ShardState[:0:0], h.fields.ShardState...) } // SetShardState sets the RLP-encoded form of shard state // // It stores a copy; the caller may freely modify the original. func (h *Header) SetShardState(newShardState []byte) { h.fields.ShardState = append(newShardState[:0:0], newShardState...) } // CrossLinks is the RLP-encoded form of non-beacon block headers chosen to be // canonical by the beacon committee. This field is present only on beacon // chain block headers. // // The returned slice is a copy; the caller may do anything with it. func (h *Header) CrossLinks() []byte { return append(h.fields.CrossLinks[:0:0], h.fields.CrossLinks...) } // SetCrossLinks sets the RLP-encoded form of non-beacon block headers chosen to // be canonical by the beacon committee. // // It stores a copy; the caller may freely modify the original. func (h *Header) SetCrossLinks(newCrossLinks []byte) { h.fields.CrossLinks = append(newCrossLinks[:0:0], newCrossLinks...) } // field type overrides for gencodec type headerMarshaling struct { Difficulty *hexutil.Big Number *hexutil.Big GasLimit hexutil.Uint64 GasUsed hexutil.Uint64 Time *hexutil.Big Extra hexutil.Bytes Hash common.Hash `json:"hash"` // adds call to Hash() in MarshalJSON } // Hash returns the block hash of the header, which is simply the keccak256 hash of its // RLP encoding. func (h *Header) Hash() common.Hash { return hash.FromRLP(h) } // Size returns the approximate memory used by all internal contents. It is used // to approximate and limit the memory consumption of various caches. func (h *Header) Size() common.StorageSize { // TODO: update with new fields return common.StorageSize(unsafe.Sizeof(*h)) + common.StorageSize(len(h.Extra())+(h.Number().BitLen()+h.Time().BitLen())/8) } // Logger returns a sub-logger with block contexts added. func (h *Header) Logger(logger *zerolog.Logger) *zerolog.Logger { nlogger := logger. With(). Str("blockHash", h.Hash().Hex()). Uint32("blockShard", h.ShardID()). Uint64("blockEpoch", h.Epoch().Uint64()). Uint64("blockNumber", h.Number().Uint64()). Logger() return &nlogger } // GetShardState returns the deserialized shard state object. func (h *Header) GetShardState() (shard.State, error) { return shard.DecodeWrapper(h.ShardState()) } // Copy returns a copy of the given header. func (h *Header) Copy() blockif.Header { cpy := *h return &cpy }