arnaucube
/
go-iden3-crypto
mirror of https://github.com/arnaucube/go-iden3-crypto.git


								package mimc7


								import (

									"errors"

									"fmt"

									"math/big"


									"github.com/ethereum/go-ethereum/crypto"

									_constants "github.com/iden3/go-iden3-crypto/constants"

									"github.com/iden3/go-iden3-crypto/field"

								)


								const SEED = "mimc"


								// RElem is a big.Int of maximum 253 bits

								type RElem *big.Int


								var constants = generateConstantsData()


								type constantsData struct {

									maxFieldVal *big.Int

									seedHash    *big.Int

									iv          *big.Int

									fqR         field.Fq

									nRounds     int

									cts         []*big.Int

								}


								func getIV(seed string) {

								}


								func generateConstantsData() constantsData {

									var constants constantsData


									fqR := field.NewFq(_constants.Q)

									constants.fqR = fqR


									// maxFieldVal is the R value of the Finite Field

									constants.maxFieldVal = constants.fqR.Q


									constants.seedHash = new(big.Int).SetBytes(crypto.Keccak256([]byte(SEED)))

									c := new(big.Int).SetBytes(crypto.Keccak256([]byte(SEED + "_iv")))

									constants.iv = new(big.Int).Mod(c, constants.maxFieldVal)


									constants.nRounds = 91

									cts, err := getConstants(constants.fqR, SEED, constants.nRounds)

									if err != nil {

										panic(err)

									}

									constants.cts = cts

									return constants

								}


								// BigIntToRElem checks if given big.Int fits in a Field R element, and returns the RElem type

								func BigIntToRElem(a *big.Int) (RElem, error) {

									if a.Cmp(constants.maxFieldVal) != -1 {

										return RElem(a), errors.New("Given big.Int don't fits in the Finite Field over R")

									}

									return RElem(a), nil

								}


								//BigIntsToRElems converts from array of *big.Int to array of RElem

								func BigIntsToRElems(arr []*big.Int) ([]RElem, error) {

									o := make([]RElem, len(arr))

									for i, a := range arr {

										e, err := BigIntToRElem(a)

										if err != nil {

											return o, fmt.Errorf("element in position %v don't fits in Finite Field over R", i)

										}

										o[i] = e

									}

									return o, nil

								}


								// RElemsToBigInts converts from array of RElem to array of *big.Int

								func RElemsToBigInts(arr []RElem) []*big.Int {

									o := make([]*big.Int, len(arr))

									for i, a := range arr {

										o[i] = a

									}

									return o

								}


								func getConstants(fqR field.Fq, seed string, nRounds int) ([]*big.Int, error) {

									cts := make([]*big.Int, nRounds)

									cts[0] = big.NewInt(int64(0))

									c := new(big.Int).SetBytes(crypto.Keccak256([]byte(SEED)))

									for i := 1; i < nRounds; i++ {

										c = new(big.Int).SetBytes(crypto.Keccak256(c.Bytes()))


										n := fqR.Affine(c)

										cts[i] = n

									}

									return cts, nil

								}


								// MIMC7HashGeneric performs the MIMC7 hash over a RElem, in a generic way, where it can be specified the Finite Field over R, and the number of rounds

								func MIMC7HashGeneric(fqR field.Fq, xIn, k *big.Int, nRounds int) (*big.Int, error) {

									cts, err := getConstants(fqR, SEED, nRounds)

									if err != nil {

										return &big.Int{}, err

									}

									var r *big.Int

									for i := 0; i < nRounds; i++ {

										var t *big.Int

										if i == 0 {

											t = fqR.Add(xIn, k)

										} else {

											t = fqR.Add(fqR.Add(r, k), cts[i])

										}

										t2 := fqR.Square(t)

										t4 := fqR.Square(t2)

										r = fqR.Mul(fqR.Mul(t4, t2), t)

									}

									return fqR.Affine(fqR.Add(r, k)), nil

								}


								// HashGeneric performs the MIMC7 hash over a RElem array, in a generic way, where it can be specified the Finite Field over R, and the number of rounds

								func HashGeneric(iv *big.Int, arrEl []RElem, fqR field.Fq, nRounds int) (RElem, error) {

									arr := RElemsToBigInts(arrEl)

									r := iv

									var err error

									for i := 0; i < len(arr); i++ {

										r, err = MIMC7HashGeneric(fqR, r, arr[i], nRounds)

										if err != nil {

											return r, err

										}

									}

									return RElem(r), nil

								}


								// MIMC7Hash performs the MIMC7 hash over a RElem, using the Finite Field over R and the number of rounds setted in the `constants` variable

								func MIMC7Hash(xIn, k *big.Int) *big.Int {

									var r *big.Int

									for i := 0; i < constants.nRounds; i++ {

										var t *big.Int

										if i == 0 {

											t = constants.fqR.Add(xIn, k)

										} else {

											t = constants.fqR.Add(constants.fqR.Add(r, k), constants.cts[i])

										}

										t2 := constants.fqR.Square(t)

										t4 := constants.fqR.Square(t2)

										r = constants.fqR.Mul(constants.fqR.Mul(t4, t2), t)

									}

									return constants.fqR.Affine(constants.fqR.Add(r, k))

								}


								// Hash performs the MIMC7 hash over a RElem array

								func Hash(arrEl []RElem, key *big.Int) RElem {

									arr := RElemsToBigInts(arrEl)

									var r *big.Int

									if key == nil {

										r = constants.fqR.Zero()

									} else {

										r = key

									}

									// r := constants.iv

									for i := 0; i < len(arr); i++ {

										r = constants.fqR.Add(

											constants.fqR.Add(

												r,

												arr[i],

											),

											MIMC7Hash(arr[i], r))

									}

									return RElem(r)

								}