// Copyright 2017 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package ethash import ( "bytes" "errors" "fmt" "math/big" "runtime" "time" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/common/math" "github.com/ethereum/go-ethereum/consensus" "github.com/ethereum/go-ethereum/consensus/misc" "github.com/ethereum/go-ethereum/core/state" "github.com/ethereum/go-ethereum/core/types" "github.com/ethereum/go-ethereum/params" set "gopkg.in/fatih/set.v0" ) // Ethash proof-of-work protocol constants. var ( blockReward *big.Int = big.NewInt(5e+18) // Block reward in wei for successfully mining a block maxUncles = 2 // Maximum number of uncles allowed in a single block ) // Various error messages to mark blocks invalid. These should be private to // prevent engine specific errors from being referenced in the remainder of the // codebase, inherently breaking if the engine is swapped out. Please put common // error types into the consensus package. var ( errLargeBlockTime = errors.New("timestamp too big") errZeroBlockTime = errors.New("timestamp equals parent's") errTooManyUncles = errors.New("too many uncles") errDuplicateUncle = errors.New("duplicate uncle") errUncleIsAncestor = errors.New("uncle is ancestor") errDanglingUncle = errors.New("uncle's parent is not ancestor") errNonceOutOfRange = errors.New("nonce out of range") errInvalidDifficulty = errors.New("non-positive difficulty") errInvalidMixDigest = errors.New("invalid mix digest") errInvalidPoW = errors.New("invalid proof-of-work") ) // Author implements consensus.Engine, returning the header's coinbase as the // proof-of-work verified author of the block. func (ethash *Ethash) Author(header *types.Header) (common.Address, error) { return header.Coinbase, nil } // VerifyHeader checks whether a header conforms to the consensus rules of the // stock Ethereum ethash engine. func (ethash *Ethash) VerifyHeader(chain consensus.ChainReader, header *types.Header, seal bool) error { // If we're running a full engine faking, accept any input as valid if ethash.fakeFull { return nil } // Short circuit if the header is known, or it's parent not number := header.Number.Uint64() if chain.GetHeader(header.Hash(), number) != nil { return nil } parent := chain.GetHeader(header.ParentHash, number-1) if parent == nil { return consensus.ErrUnknownAncestor } // Sanity checks passed, do a proper verification return ethash.verifyHeader(chain, header, parent, false, seal) } // VerifyHeaders is similar to VerifyHeader, but verifies a batch of headers // concurrently. The method returns a quit channel to abort the operations and // a results channel to retrieve the async verifications. func (ethash *Ethash) VerifyHeaders(chain consensus.ChainReader, headers []*types.Header, seals []bool) (chan<- struct{}, <-chan error) { // If we're running a full engine faking, accept any input as valid if ethash.fakeFull || len(headers) == 0 { abort, results := make(chan struct{}), make(chan error, len(headers)) for i := 0; i < len(headers); i++ { results <- nil } return abort, results } // Spawn as many workers as allowed threads workers := runtime.GOMAXPROCS(0) if len(headers) < workers { workers = len(headers) } // Create a task channel and spawn the verifiers var ( inputs = make(chan int) done = make(chan int, workers) errors = make([]error, len(headers)) abort = make(chan struct{}) ) for i := 0; i < workers; i++ { go func() { for index := range inputs { errors[index] = ethash.verifyHeaderWorker(chain, headers, seals, index) done <- index } }() } errorsOut := make(chan error, len(headers)) go func() { defer close(inputs) var ( in, out = 0, 0 checked = make([]bool, len(headers)) inputs = inputs ) for { select { case inputs <- in: if in++; in == len(headers) { // Reached end of headers. Stop sending to workers. inputs = nil } case index := <-done: for checked[index] = true; checked[out]; out++ { errorsOut <- errors[out] if out == len(headers)-1 { return } } case <-abort: return } } }() return abort, errorsOut } func (ethash *Ethash) verifyHeaderWorker(chain consensus.ChainReader, headers []*types.Header, seals []bool, index int) error { var parent *types.Header if index == 0 { parent = chain.GetHeader(headers[0].ParentHash, headers[0].Number.Uint64()-1) } else if headers[index-1].Hash() == headers[index].ParentHash { parent = headers[index-1] } if parent == nil { return consensus.ErrUnknownAncestor } if chain.GetHeader(headers[index].Hash(), headers[index].Number.Uint64()) != nil { return nil // known block } return ethash.verifyHeader(chain, headers[index], parent, false, seals[index]) } // VerifyUncles verifies that the given block's uncles conform to the consensus // rules of the stock Ethereum ethash engine. func (ethash *Ethash) VerifyUncles(chain consensus.ChainReader, block *types.Block) error { // If we're running a full engine faking, accept any input as valid if ethash.fakeFull { return nil } // Verify that there are at most 2 uncles included in this block if len(block.Uncles()) > maxUncles { return errTooManyUncles } // Gather the set of past uncles and ancestors uncles, ancestors := set.New(), make(map[common.Hash]*types.Header) number, parent := block.NumberU64()-1, block.ParentHash() for i := 0; i < 7; i++ { ancestor := chain.GetBlock(parent, number) if ancestor == nil { break } ancestors[ancestor.Hash()] = ancestor.Header() for _, uncle := range ancestor.Uncles() { uncles.Add(uncle.Hash()) } parent, number = ancestor.ParentHash(), number-1 } ancestors[block.Hash()] = block.Header() uncles.Add(block.Hash()) // Verify each of the uncles that it's recent, but not an ancestor for _, uncle := range block.Uncles() { // Make sure every uncle is rewarded only once hash := uncle.Hash() if uncles.Has(hash) { return errDuplicateUncle } uncles.Add(hash) // Make sure the uncle has a valid ancestry if ancestors[hash] != nil { return errUncleIsAncestor } if ancestors[uncle.ParentHash] == nil || uncle.ParentHash == block.ParentHash() { return errDanglingUncle } if err := ethash.verifyHeader(chain, uncle, ancestors[uncle.ParentHash], true, true); err != nil { return err } } return nil } // verifyHeader checks whether a header conforms to the consensus rules of the // stock Ethereum ethash engine. // // See YP section 4.3.4. "Block Header Validity" func (ethash *Ethash) verifyHeader(chain consensus.ChainReader, header, parent *types.Header, uncle bool, seal bool) error { // Ensure that the header's extra-data section is of a reasonable size if uint64(len(header.Extra)) > params.MaximumExtraDataSize { return fmt.Errorf("extra-data too long: %d > %d", len(header.Extra), params.MaximumExtraDataSize) } // Verify the header's timestamp if uncle { if header.Time.Cmp(math.MaxBig256) > 0 { return errLargeBlockTime } } else { if header.Time.Cmp(big.NewInt(time.Now().Unix())) > 0 { return consensus.ErrFutureBlock } } if header.Time.Cmp(parent.Time) <= 0 { return errZeroBlockTime } // Verify the block's difficulty based in it's timestamp and parent's difficulty expected := CalcDifficulty(chain.Config(), header.Time.Uint64(), parent.Time.Uint64(), parent.Number, parent.Difficulty) if expected.Cmp(header.Difficulty) != 0 { return fmt.Errorf("invalid difficulty: have %v, want %v", header.Difficulty, expected) } // Verify that the gas limit is <= 2^63-1 if header.GasLimit.Cmp(math.MaxBig63) > 0 { return fmt.Errorf("invalid gasLimit: have %v, max %v", header.GasLimit, math.MaxBig63) } // Verify that the gasUsed is <= gasLimit if header.GasUsed.Cmp(header.GasLimit) > 0 { return fmt.Errorf("invalid gasUsed: have %v, gasLimit %v", header.GasUsed, header.GasLimit) } // Verify that the gas limit remains within allowed bounds diff := new(big.Int).Set(parent.GasLimit) diff = diff.Sub(diff, header.GasLimit) diff.Abs(diff) limit := new(big.Int).Set(parent.GasLimit) limit = limit.Div(limit, params.GasLimitBoundDivisor) if diff.Cmp(limit) >= 0 || header.GasLimit.Cmp(params.MinGasLimit) < 0 { return fmt.Errorf("invalid gas limit: have %v, want %v += %v", header.GasLimit, parent.GasLimit, limit) } // Verify that the block number is parent's +1 if diff := new(big.Int).Sub(header.Number, parent.Number); diff.Cmp(big.NewInt(1)) != 0 { return consensus.ErrInvalidNumber } // Verify the engine specific seal securing the block if seal { if err := ethash.VerifySeal(chain, header); err != nil { return err } } // If all checks passed, validate any special fields for hard forks if err := misc.VerifyDAOHeaderExtraData(chain.Config(), header); err != nil { return err } if err := misc.VerifyForkHashes(chain.Config(), header, uncle); err != nil { return err } return nil } // CalcDifficulty is the difficulty adjustment algorithm. It returns the difficulty // that a new block should have when created at time given the parent block's time // and difficulty. // // TODO (karalabe): Move the chain maker into this package and make this private! func CalcDifficulty(config *params.ChainConfig, time, parentTime uint64, parentNumber, parentDiff *big.Int) *big.Int { if config.IsHomestead(new(big.Int).Add(parentNumber, common.Big1)) { return calcDifficultyHomestead(time, parentTime, parentNumber, parentDiff) } return calcDifficultyFrontier(time, parentTime, parentNumber, parentDiff) } // Some weird constants to avoid constant memory allocs for them. var ( expDiffPeriod = big.NewInt(100000) big10 = big.NewInt(10) bigMinus99 = big.NewInt(-99) ) // calcDifficultyHomestead is the difficulty adjustment algorithm. It returns // the difficulty that a new block should have when created at time given the // parent block's time and difficulty. The calculation uses the Homestead rules. func calcDifficultyHomestead(time, parentTime uint64, parentNumber, parentDiff *big.Int) *big.Int { // https://github.com/ethereum/EIPs/blob/master/EIPS/eip-2.mediawiki // algorithm: // diff = (parent_diff + // (parent_diff / 2048 * max(1 - (block_timestamp - parent_timestamp) // 10, -99)) // ) + 2^(periodCount - 2) bigTime := new(big.Int).SetUint64(time) bigParentTime := new(big.Int).SetUint64(parentTime) // holds intermediate values to make the algo easier to read & audit x := new(big.Int) y := new(big.Int) // 1 - (block_timestamp -parent_timestamp) // 10 x.Sub(bigTime, bigParentTime) x.Div(x, big10) x.Sub(common.Big1, x) // max(1 - (block_timestamp - parent_timestamp) // 10, -99))) if x.Cmp(bigMinus99) < 0 { x.Set(bigMinus99) } // (parent_diff + parent_diff // 2048 * max(1 - (block_timestamp - parent_timestamp) // 10, -99)) y.Div(parentDiff, params.DifficultyBoundDivisor) x.Mul(y, x) x.Add(parentDiff, x) // minimum difficulty can ever be (before exponential factor) if x.Cmp(params.MinimumDifficulty) < 0 { x.Set(params.MinimumDifficulty) } // for the exponential factor periodCount := new(big.Int).Add(parentNumber, common.Big1) periodCount.Div(periodCount, expDiffPeriod) // the exponential factor, commonly referred to as "the bomb" // diff = diff + 2^(periodCount - 2) if periodCount.Cmp(common.Big1) > 0 { y.Sub(periodCount, common.Big2) y.Exp(common.Big2, y, nil) x.Add(x, y) } return x } // calcDifficultyFrontier is the difficulty adjustment algorithm. It returns the // difficulty that a new block should have when created at time given the parent // block's time and difficulty. The calculation uses the Frontier rules. func calcDifficultyFrontier(time, parentTime uint64, parentNumber, parentDiff *big.Int) *big.Int { diff := new(big.Int) adjust := new(big.Int).Div(parentDiff, params.DifficultyBoundDivisor) bigTime := new(big.Int) bigParentTime := new(big.Int) bigTime.SetUint64(time) bigParentTime.SetUint64(parentTime) if bigTime.Sub(bigTime, bigParentTime).Cmp(params.DurationLimit) < 0 { diff.Add(parentDiff, adjust) } else { diff.Sub(parentDiff, adjust) } if diff.Cmp(params.MinimumDifficulty) < 0 { diff.Set(params.MinimumDifficulty) } periodCount := new(big.Int).Add(parentNumber, common.Big1) periodCount.Div(periodCount, expDiffPeriod) if periodCount.Cmp(common.Big1) > 0 { // diff = diff + 2^(periodCount - 2) expDiff := periodCount.Sub(periodCount, common.Big2) expDiff.Exp(common.Big2, expDiff, nil) diff.Add(diff, expDiff) diff = math.BigMax(diff, params.MinimumDifficulty) } return diff } // VerifySeal implements consensus.Engine, checking whether the given block satisfies // the PoW difficulty requirements. func (ethash *Ethash) VerifySeal(chain consensus.ChainReader, header *types.Header) error { // If we're running a fake PoW, accept any seal as valid if ethash.fakeMode { time.Sleep(ethash.fakeDelay) if ethash.fakeFail == header.Number.Uint64() { return errInvalidPoW } return nil } // If we're running a shared PoW, delegate verification to it if ethash.shared != nil { return ethash.shared.VerifySeal(chain, header) } // Sanity check that the block number is below the lookup table size (60M blocks) number := header.Number.Uint64() if number/epochLength >= uint64(len(cacheSizes)) { // Go < 1.7 cannot calculate new cache/dataset sizes (no fast prime check) return errNonceOutOfRange } // Ensure that we have a valid difficulty for the block if header.Difficulty.Sign() <= 0 { return errInvalidDifficulty } // Recompute the digest and PoW value and verify against the header cache := ethash.cache(number) size := datasetSize(number) if ethash.tester { size = 32 * 1024 } digest, result := hashimotoLight(size, cache, header.HashNoNonce().Bytes(), header.Nonce.Uint64()) if !bytes.Equal(header.MixDigest[:], digest) { return errInvalidMixDigest } target := new(big.Int).Div(maxUint256, header.Difficulty) if new(big.Int).SetBytes(result).Cmp(target) > 0 { return errInvalidPoW } return nil } // Prepare implements consensus.Engine, initializing the difficulty field of a // header to conform to the ethash protocol. The changes are done inline. func (ethash *Ethash) Prepare(chain consensus.ChainReader, header *types.Header) error { parent := chain.GetHeader(header.ParentHash, header.Number.Uint64()-1) if parent == nil { return consensus.ErrUnknownAncestor } header.Difficulty = CalcDifficulty(chain.Config(), header.Time.Uint64(), parent.Time.Uint64(), parent.Number, parent.Difficulty) return nil } // Finalize implements consensus.Engine, accumulating the block and uncle rewards, // setting the final state and assembling the block. func (ethash *Ethash) Finalize(chain consensus.ChainReader, header *types.Header, state *state.StateDB, txs []*types.Transaction, uncles []*types.Header, receipts []*types.Receipt) (*types.Block, error) { // Accumulate any block and uncle rewards and commit the final state root AccumulateRewards(state, header, uncles) header.Root = state.IntermediateRoot(chain.Config().IsEIP158(header.Number)) // Header seems complete, assemble into a block and return return types.NewBlock(header, txs, uncles, receipts), nil } // Some weird constants to avoid constant memory allocs for them. var ( big8 = big.NewInt(8) big32 = big.NewInt(32) ) // AccumulateRewards credits the coinbase of the given block with the mining // reward. The total reward consists of the static block reward and rewards for // included uncles. The coinbase of each uncle block is also rewarded. // // TODO (karalabe): Move the chain maker into this package and make this private! func AccumulateRewards(state *state.StateDB, header *types.Header, uncles []*types.Header) { reward := new(big.Int).Set(blockReward) r := new(big.Int) for _, uncle := range uncles { r.Add(uncle.Number, big8) r.Sub(r, header.Number) r.Mul(r, blockReward) r.Div(r, big8) state.AddBalance(uncle.Coinbase, r) r.Div(blockReward, big32) reward.Add(reward, r) } state.AddBalance(header.Coinbase, reward) }