woop/block/interface/header.go

package blockif

import (
	"math/big"

	"github.com/ethereum/go-ethereum/common"
	"github.com/ethereum/go-ethereum/core/types"
	"github.com/rs/zerolog"

	"github.com/harmony-one/harmony/shard"
)

// Header defines the block header interface.
type Header interface {
	// ParentHash is the header hash of the parent block.  For the genesis block
	// which has no parent by definition, this field is zeroed out.
	ParentHash() common.Hash

	// SetParentHash sets the parent hash field.
	SetParentHash(newParentHash common.Hash)

	// Coinbase is the address of the node that proposed this block and all
	// transactions in it.
	Coinbase() common.Address

	// SetCoinbase sets the coinbase address field.
	SetCoinbase(newCoinbase common.Address)

	// Root is the state (account) trie root hash.
	Root() common.Hash

	// SetRoot sets the state trie root hash field.
	SetRoot(newRoot common.Hash)

	// TxHash is the transaction trie root hash.
	TxHash() common.Hash

	// SetTxHash sets the transaction trie root hash field.
	SetTxHash(newTxHash common.Hash)

	// ReceiptHash is the same-shard transaction receipt trie hash.
	ReceiptHash() common.Hash

	// SetReceiptHash sets the same-shard transaction receipt trie hash.
	SetReceiptHash(newReceiptHash common.Hash)

	// OutgoingReceiptHash is the egress transaction receipt trie hash.
	OutgoingReceiptHash() common.Hash

	// SetOutgoingReceiptHash sets the egress transaction receipt trie hash.
	SetOutgoingReceiptHash(newOutgoingReceiptHash common.Hash)

	// IncomingReceiptHash is the ingress transaction receipt trie hash.
	IncomingReceiptHash() common.Hash

	// SetIncomingReceiptHash sets the ingress transaction receipt trie hash.
	SetIncomingReceiptHash(newIncomingReceiptHash common.Hash)

	// Bloom is the Bloom filter that indexes accounts and topics logged by smart
	// contract transactions (executions) in this block.
	Bloom() types.Bloom

	// SetBloom sets the smart contract log Bloom filter for this block.
	SetBloom(newBloom types.Bloom)

	// Number is the block number.
	//
	// The returned instance is a copy; the caller may do anything with it.
	Number() *big.Int

	// SetNumber sets the block number.
	//
	// It stores a copy; the caller may freely modify the original.
	SetNumber(newNumber *big.Int)

	// GasLimit is the gas limit for transactions in this block.
	GasLimit() uint64

	// SetGasLimit sets the gas limit for transactions in this block.
	SetGasLimit(newGasLimit uint64)

	// GasUsed is the amount of gas used by transactions in this block.
	GasUsed() uint64

	// SetGasUsed sets the amount of gas used by transactions in this block.
	SetGasUsed(newGasUsed uint64)

	// Time is the UNIX timestamp of this block.
	//
	// The returned instance is a copy; the caller may do anything with it.
	Time() *big.Int

	// SetTime sets the UNIX timestamp of this block.
	//
	// It stores a copy; the caller may freely modify the original.
	SetTime(newTime *big.Int)

	// Extra is the extra data field of this block.
	//
	// The returned slice is a copy; the caller may do anything with it.
	Extra() []byte

	// SetExtra sets the extra data field of this block.
	//
	// It stores a copy; the caller may freely modify the original.
	SetExtra(newExtra []byte)

	// MixDigest is the mixhash.
	//
	// This field is a remnant from Ethereum, and Harmony does not use it and always
	// zeroes it out.
	MixDigest() common.Hash

	// SetMixDigest sets the mixhash of this block.
	SetMixDigest(newMixDigest common.Hash)

	// 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.
	ViewID() *big.Int

	// SetViewID sets the view ID in which the block was originally proposed.
	//
	// It stores a copy; the caller may freely modify the original.
	SetViewID(newViewID *big.Int)

	// Epoch is the epoch number of this block.
	//
	// The returned instance is a copy; the caller may do anything with it.
	Epoch() *big.Int

	// SetEpoch sets the epoch number of this block.
	//
	// It stores a copy; the caller may freely modify the original.
	SetEpoch(newEpoch *big.Int)

	// ShardID is the shard ID to which this block belongs.
	ShardID() uint32

	// SetShardID sets the shard ID to which this block belongs.
	SetShardID(newShardID uint32)

	// LastCommitSignature is the FBFT commit group signature for the last block.
	LastCommitSignature() [96]byte

	// SetLastCommitSignature sets the FBFT commit group signature for the last
	// block.
	SetLastCommitSignature(newLastCommitSignature [96]byte)

	// 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.
	LastCommitBitmap() []byte

	// SetLastCommitBitmap sets the signatory bitmap of the previous block.
	//
	// It stores a copy; the caller may freely modify the original.
	SetLastCommitBitmap(newLastCommitBitmap []byte)

	// ShardStateHash is the shard state hash.
	ShardStateHash() common.Hash

	// SetShardStateHash sets the shard state hash.
	SetShardStateHash(newShardStateHash common.Hash)

	// Vrf is the output of the VRF for the epoch.
	//
	// The returned slice is a copy; the caller may do anything with it.
	Vrf() []byte

	// SetVrf sets the output of the VRF for the epoch.
	//
	// It stores a copy; the caller may freely modify the original.
	SetVrf(newVrf []byte)

	// Vdf is the output of the VDF for the epoch.
	//
	// The returned slice is a copy; the caller may do anything with it.
	Vdf() []byte

	// SetVdf sets the output of the VDF for the epoch.
	//
	// It stores a copy; the caller may freely modify the original.
	SetVdf(newVdf []byte)

	// 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.
	ShardState() []byte

	// SetShardState sets the RLP-encoded form of shard state
	//
	// It stores a copy; the caller may freely modify the original.
	SetShardState(newShardState []byte)

	// 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.
	CrossLinks() []byte

	// 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.
	SetCrossLinks(newCrossLinks []byte)

	// Hash returns the block hash of the header, which is simply the legacy
	// Keccak256 hash of its RLP encoding.
	Hash() common.Hash

	// Size returns the approximate memory used by all internal contents. It is
	// used to approximate and limit the memory consumption of various caches.
	Size() common.StorageSize

	// Logger returns a sub-logger with block contexts added.
	Logger(logger *zerolog.Logger) *zerolog.Logger

	// GetShardState returns the deserialized shard state object.
	GetShardState() (shard.State, error)

	// Copy returns a copy of the header.
	Copy() Header
}
Move block.HeaderInterface → blockif.Header This is to make it possible to use the Header interface from implementations without causing cyclic imports. 5 years ago			`package blockif`
Version headers block.Header is now a lightweight wrapper around an embedded HeaderInterface value, which is implemented by both v0 and v1 headers. It inherits all methods from the wrapped HeaderInterface, except it overrides EncodeRLP, DecodeRLP, and Hash to handle tagged-RLP encoding/decoding. (block.HeaderRegistry is the tagged RLP registry for versioned headers.) A ripple effect is that header instance creation now requires knowledge of epoch. This logic is handled by blockfactory. blockfactory.Factory is the interface, implemented by blockfactory.factory type. It uses a chain config to pull in the right epoch for the right type. As a convenience, blockfactory.NewTestHeader creates a new test-purpose headers. Use this in contexts where the implied chain config is TestChainConfig or the chain config does not matter. Miscellaneous changes: - block.HeaderFieldSetter now lives in its own file. - The functionality of block.NewHeaderWith has been replaced by the (block.Header).With method. The accompanying unit tests for (block.Header).EncodeRLP and (*block.Header).DecodeRLP() are the cross-sectional unit tests for the functionality added by this. They make sure that v0 header is encoded/decoded without tagged RLP envelope (compatibility mode), and v1 header is encoded/decoded with one. See comments of the RLP byte sequence for differences. 5 years ago
			`import (`
			`"math/big"`

			`"github.com/ethereum/go-ethereum/common"`
			`"github.com/ethereum/go-ethereum/core/types"`
			`"github.com/rs/zerolog"`

			`"github.com/harmony-one/harmony/shard"`
			`)`

Move block.HeaderInterface → blockif.Header This is to make it possible to use the Header interface from implementations without causing cyclic imports. 5 years ago			`// Header defines the block header interface.`
			`type Header interface {`
Version headers block.Header is now a lightweight wrapper around an embedded HeaderInterface value, which is implemented by both v0 and v1 headers. It inherits all methods from the wrapped HeaderInterface, except it overrides EncodeRLP, DecodeRLP, and Hash to handle tagged-RLP encoding/decoding. (block.HeaderRegistry is the tagged RLP registry for versioned headers.) A ripple effect is that header instance creation now requires knowledge of epoch. This logic is handled by blockfactory. blockfactory.Factory is the interface, implemented by blockfactory.factory type. It uses a chain config to pull in the right epoch for the right type. As a convenience, blockfactory.NewTestHeader creates a new test-purpose headers. Use this in contexts where the implied chain config is TestChainConfig or the chain config does not matter. Miscellaneous changes: - block.HeaderFieldSetter now lives in its own file. - The functionality of block.NewHeaderWith has been replaced by the (block.Header).With method. The accompanying unit tests for (block.Header).EncodeRLP and (*block.Header).DecodeRLP() are the cross-sectional unit tests for the functionality added by this. They make sure that v0 header is encoded/decoded without tagged RLP envelope (compatibility mode), and v1 header is encoded/decoded with one. See comments of the RLP byte sequence for differences. 5 years ago			`// ParentHash is the header hash of the parent block. For the genesis block`
			`// which has no parent by definition, this field is zeroed out.`
			`ParentHash() common.Hash`

			`// SetParentHash sets the parent hash field.`
			`SetParentHash(newParentHash common.Hash)`

			`// Coinbase is the address of the node that proposed this block and all`
			`// transactions in it.`
			`Coinbase() common.Address`

			`// SetCoinbase sets the coinbase address field.`
			`SetCoinbase(newCoinbase common.Address)`

			`// Root is the state (account) trie root hash.`
			`Root() common.Hash`

			`// SetRoot sets the state trie root hash field.`
			`SetRoot(newRoot common.Hash)`

			`// TxHash is the transaction trie root hash.`
			`TxHash() common.Hash`

			`// SetTxHash sets the transaction trie root hash field.`
			`SetTxHash(newTxHash common.Hash)`

			`// ReceiptHash is the same-shard transaction receipt trie hash.`
			`ReceiptHash() common.Hash`

			`// SetReceiptHash sets the same-shard transaction receipt trie hash.`
			`SetReceiptHash(newReceiptHash common.Hash)`

			`// OutgoingReceiptHash is the egress transaction receipt trie hash.`
			`OutgoingReceiptHash() common.Hash`

			`// SetOutgoingReceiptHash sets the egress transaction receipt trie hash.`
			`SetOutgoingReceiptHash(newOutgoingReceiptHash common.Hash)`

			`// IncomingReceiptHash is the ingress transaction receipt trie hash.`
			`IncomingReceiptHash() common.Hash`

			`// SetIncomingReceiptHash sets the ingress transaction receipt trie hash.`
			`SetIncomingReceiptHash(newIncomingReceiptHash common.Hash)`

			`// Bloom is the Bloom filter that indexes accounts and topics logged by smart`
			`// contract transactions (executions) in this block.`
			`Bloom() types.Bloom`

			`// SetBloom sets the smart contract log Bloom filter for this block.`
			`SetBloom(newBloom types.Bloom)`

			`// Number is the block number.`
			`//`
			`// The returned instance is a copy; the caller may do anything with it.`
			`Number() *big.Int`

			`// SetNumber sets the block number.`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetNumber(newNumber *big.Int)`

			`// GasLimit is the gas limit for transactions in this block.`
			`GasLimit() uint64`

			`// SetGasLimit sets the gas limit for transactions in this block.`
			`SetGasLimit(newGasLimit uint64)`

			`// GasUsed is the amount of gas used by transactions in this block.`
			`GasUsed() uint64`

			`// SetGasUsed sets the amount of gas used by transactions in this block.`
			`SetGasUsed(newGasUsed uint64)`

			`// Time is the UNIX timestamp of this block.`
			`//`
			`// The returned instance is a copy; the caller may do anything with it.`
			`Time() *big.Int`

			`// SetTime sets the UNIX timestamp of this block.`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetTime(newTime *big.Int)`

			`// Extra is the extra data field of this block.`
			`//`
			`// The returned slice is a copy; the caller may do anything with it.`
			`Extra() []byte`

			`// SetExtra sets the extra data field of this block.`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetExtra(newExtra []byte)`

			`// MixDigest is the mixhash.`
			`//`
			`// This field is a remnant from Ethereum, and Harmony does not use it and always`
			`// zeroes it out.`
			`MixDigest() common.Hash`

			`// SetMixDigest sets the mixhash of this block.`
			`SetMixDigest(newMixDigest common.Hash)`

			`// 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.`
			`ViewID() *big.Int`

			`// SetViewID sets the view ID in which the block was originally proposed.`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetViewID(newViewID *big.Int)`

			`// Epoch is the epoch number of this block.`
			`//`
			`// The returned instance is a copy; the caller may do anything with it.`
			`Epoch() *big.Int`

			`// SetEpoch sets the epoch number of this block.`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetEpoch(newEpoch *big.Int)`

			`// ShardID is the shard ID to which this block belongs.`
			`ShardID() uint32`

			`// SetShardID sets the shard ID to which this block belongs.`
			`SetShardID(newShardID uint32)`

			`// LastCommitSignature is the FBFT commit group signature for the last block.`
			`LastCommitSignature() [96]byte`

			`// SetLastCommitSignature sets the FBFT commit group signature for the last`
			`// block.`
			`SetLastCommitSignature(newLastCommitSignature [96]byte)`

			`// 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.`
			`LastCommitBitmap() []byte`

			`// SetLastCommitBitmap sets the signatory bitmap of the previous block.`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetLastCommitBitmap(newLastCommitBitmap []byte)`

			`// ShardStateHash is the shard state hash.`
			`ShardStateHash() common.Hash`

			`// SetShardStateHash sets the shard state hash.`
			`SetShardStateHash(newShardStateHash common.Hash)`

			`// Vrf is the output of the VRF for the epoch.`
			`//`
			`// The returned slice is a copy; the caller may do anything with it.`
			`Vrf() []byte`

			`// SetVrf sets the output of the VRF for the epoch.`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetVrf(newVrf []byte)`

			`// Vdf is the output of the VDF for the epoch.`
			`//`
			`// The returned slice is a copy; the caller may do anything with it.`
			`Vdf() []byte`

			`// SetVdf sets the output of the VDF for the epoch.`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetVdf(newVdf []byte)`

			`// 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.`
			`ShardState() []byte`

			`// SetShardState sets the RLP-encoded form of shard state`
			`//`
			`// It stores a copy; the caller may freely modify the original.`
			`SetShardState(newShardState []byte)`

			`// 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.`
			`CrossLinks() []byte`

			`// 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.`
			`SetCrossLinks(newCrossLinks []byte)`

			`// Hash returns the block hash of the header, which is simply the legacy`
			`// Keccak256 hash of its RLP encoding.`
			`Hash() common.Hash`

			`// Size returns the approximate memory used by all internal contents. It is`
			`// used to approximate and limit the memory consumption of various caches.`
			`Size() common.StorageSize`

			`// Logger returns a sub-logger with block contexts added.`
			`Logger(logger zerolog.Logger) zerolog.Logger`

			`// GetShardState returns the deserialized shard state object.`
			`GetShardState() (shard.State, error)`
Add Copy method to the Header interface 5 years ago
			`// Copy returns a copy of the header.`
			`Copy() Header`
Version headers block.Header is now a lightweight wrapper around an embedded HeaderInterface value, which is implemented by both v0 and v1 headers. It inherits all methods from the wrapped HeaderInterface, except it overrides EncodeRLP, DecodeRLP, and Hash to handle tagged-RLP encoding/decoding. (block.HeaderRegistry is the tagged RLP registry for versioned headers.) A ripple effect is that header instance creation now requires knowledge of epoch. This logic is handled by blockfactory. blockfactory.Factory is the interface, implemented by blockfactory.factory type. It uses a chain config to pull in the right epoch for the right type. As a convenience, blockfactory.NewTestHeader creates a new test-purpose headers. Use this in contexts where the implied chain config is TestChainConfig or the chain config does not matter. Miscellaneous changes: - block.HeaderFieldSetter now lives in its own file. - The functionality of block.NewHeaderWith has been replaced by the (block.Header).With method. The accompanying unit tests for (block.Header).EncodeRLP and (*block.Header).DecodeRLP() are the cross-sectional unit tests for the functionality added by this. They make sure that v0 header is encoded/decoded without tagged RLP envelope (compatibility mode), and v1 header is encoded/decoded with one. See comments of the RLP byte sequence for differences. 5 years ago			`}`