arnaucube
/
derosuite
mirror of https://github.com/arnaucube/derosuite.git


								// Copyright 2017-2018 DERO Project. All rights reserved.

								// Use of this source code in any form is governed by RESEARCH license.

								// license can be found in the LICENSE file.

								// GPG: 0F39 E425 8C65 3947 702A  8234 08B2 0360 A03A 9DE8

								//

								//

								// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY

								// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF

								// MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL

								// THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,

								// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,

								// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS

								// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,

								// STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF

								// THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.


								package difficulty


								import "fmt"

								import "math/big"


								import "github.com/deroproject/derosuite/config"

								import "github.com/deroproject/derosuite/crypto"


								var (

									// bigZero is 0 represented as a big.Int.  It is defined here to avoid

									// the overhead of creating it multiple times.

									bigZero = big.NewInt(0)


									// bigOne is 1 represented as a big.Int.  It is defined here to avoid

									// the overhead of creating it multiple times.

									bigOne = big.NewInt(1)


									// oneLsh256 is 1 shifted left 256 bits.  It is defined here to avoid

									// the overhead of creating it multiple times.

									oneLsh256 = new(big.Int).Lsh(bigOne, 256)


									// enabling this will simulation mode with hard coded difficulty set to 1

									// the variable is knowingly not exported, so no one can tinker with it

									simulation = false // simulation mode is disabled

								)


								// HashToBig converts a PoW has into a big.Int that can be used to

								// perform math comparisons.

								func HashToBig(buf crypto.Hash) *big.Int {

									// A Hash is in little-endian, but the big package wants the bytes in

									// big-endian, so reverse them.

									blen := len(buf) // its hardcoded 32 bytes, so why do len but lets do it

									for i := 0; i < blen/2; i++ {

										buf[i], buf[blen-1-i] = buf[blen-1-i], buf[i]

									}


									return new(big.Int).SetBytes(buf[:])

								}


								// this function calculates the difficulty in big num form

								func ConvertDifficultyToBig(difficultyi uint64) *big.Int {

									if difficultyi == 0 {

										panic("difficulty can never be zero")

									}

									// (1 << 256) / (difficultyNum )

									difficulty := new(big.Int).SetUint64(difficultyi)

									denominator := new(big.Int).Add(difficulty, bigZero) // above 2 lines can be merged

									return new(big.Int).Div(oneLsh256, denominator)

								}


								// this function check whether the pow hash meets difficulty criteria

								func CheckPowHash(pow_hash crypto.Hash, difficulty uint64) bool {

									big_difficulty := ConvertDifficultyToBig(difficulty)

									big_pow_hash := HashToBig(pow_hash)


									if big_pow_hash.Cmp(big_difficulty) <= 0 { // if work_pow is less than difficulty

										return true

									}

									return false

								}


								/* this function calculates difficulty on the basis of previous timestamps and cumulative_difficulty */

								func Next_Difficulty(timestamps []uint64, cumulative_difficulty []uint64, target_seconds uint64) (difficulty uint64) {


									difficulty = 1 // default difficulty is 1 // for genesis block


									if simulation == true { // simulation mode has difficulty set to 1

										return 1

									}


									if len(timestamps) > config.DIFFICULTY_BLOCKS_COUNT_V2 {

										panic("More timestamps provided than required")

									}

									if len(timestamps) != len(cumulative_difficulty) {

										panic("Number of timestamps != Number of cumulative_difficulty")

									}


									if len(timestamps) <= 1 {

										return difficulty // return 1

									}


									length := uint64(len(timestamps))


									weighted_timespans := uint64(0)

									for i := uint64(1); i < length; i++ {

										timespan := uint64(0)

										if timestamps[i-1] >= timestamps[i] {

											timespan = 1

										} else {

											timespan = timestamps[i] - timestamps[i-1]

										}

										if timespan > (10 * target_seconds) {

											timespan = 10 * target_seconds

										}

										weighted_timespans += i * timespan

									}


									minimum_timespan := (target_seconds * length) / 2

									if weighted_timespans < minimum_timespan { // fix startup weirdness

										weighted_timespans = minimum_timespan

									}


									total_work := cumulative_difficulty[length-1] - cumulative_difficulty[0]


									// convert input for 128 bit multiply

									var big_total_work, big_target, big_result big.Int

									big_total_work.SetUint64(total_work)


									target := (((length + 1) / 2) * target_seconds * 3) / 2

									big_target.SetUint64(target)


									big_result.Mul(&big_total_work, &big_target)


									if big_result.IsUint64() {

										if big_result.Uint64() > 0x000fffffffffffff { // this will give us atleast 1 year to fix the difficulty algorithm

											fmt.Printf("Total work per target_time  will soon cross 2^64, please fix the difficulty algorithm\n")

										}

										difficulty = big_result.Uint64() / weighted_timespans

									} else {

										panic("Total work per target_time crossing 2^64 , please fix the above")

									}


									return difficulty

								}