# cryptofun [![Go Report Card](https://goreportcard.com/badge/github.com/arnaucube/cryptofun)](https://goreportcard.com/report/github.com/arnaucube/cryptofun) Crypto algorithms from scratch. Academic purposes only. - [RSA cryptosystem & Blind signature & Homomorphic Multiplication](#rsa-cryptosystem--blind-signature--homomorphic-multiplication) - [Paillier cryptosystem & Homomorphic Addition](#paillier-cryptosystem--homomorphic-addition) - [Shamir Secret Sharing](#shamir-secret-sharing) - [Diffie-Hellman](#diffie-hellman) - [ECC](#ecc) - [ECC ElGamal](#ecc-elgamal) - [ECC ECDSA](#ecc-ecdsa) - [Schnorr signature](#schnorr-signature) - [Bn128](#bn128) --- ## RSA cryptosystem & Blind signature & Homomorphic Multiplication - https://en.wikipedia.org/wiki/RSA_(cryptosystem)# - https://en.wikipedia.org/wiki/Blind_signature - https://en.wikipedia.org/wiki/Homomorphic_encryption - [x] GenerateKeyPair - [x] Encrypt - [x] Decrypt - [x] Blind - [x] Blind Signature - [x] Unblind Signature - [x] Verify Signature - [x] Homomorphic Multiplication #### Usage - Key generation, Encryption, Decryption ```go // generate key pair key, err := GenerateKeyPair() if err!=nil { fmt.Println(err) } mBytes := []byte("Hi") m := new(big.Int).SetBytes(mBytes) // encrypt message c := Encrypt(m, key.PubK) // decrypt ciphertext d := Decrypt(c, key.PrivK) if m == d { fmt.Println("correctly decrypted") } ``` - Blind signatures ```go // key generation [Alice] key, err := GenerateKeyPair() if err!=nil { fmt.Println(err) } // create new message [Alice] mBytes := []byte("Hi") m := new(big.Int).SetBytes(mBytes) // define r value [Alice] rVal := big.NewInt(int64(101)) // blind message [Alice] mBlinded := Blind(m, rVal, key.PubK) // Blind Sign the blinded message [Bob] sigma := BlindSign(mBlinded, key.PrivK) // unblind the blinded signed message, and get the signature of the message [Alice] mSigned := Unblind(sigma, rVal, key.PubK) // verify the signature [Alice/Bob/Trudy] verified := Verify(m, mSigned, key.PubK) if !verified { fmt.Println("signature could not be verified") } ``` - Homomorphic Multiplication ```go // key generation [Alice] key, err := GenerateKeyPair() if err!=nil { fmt.Println(err) } // define values [Alice] n1 := big.NewInt(int64(11)) n2 := big.NewInt(int64(15)) // encrypt the values [Alice] c1 := Encrypt(n1, key.PubK) c2 := Encrypt(n2, key.PubK) // compute homomorphic multiplication with the encrypted values [Bob] c3c4 := HomomorphicMul(c1, c2, key.PubK) // decrypt the result [Alice] d := Decrypt(c3c4, key.PrivK) // check that the result is the expected if !bytes.Equal(new(big.Int).Mul(n1, n2).Bytes(), d.Bytes()) { fmt.Println("decrypted result not equal to expected result") } ``` ## Paillier cryptosystem & Homomorphic Addition - https://en.wikipedia.org/wiki/Paillier_cryptosystem - https://en.wikipedia.org/wiki/Homomorphic_encryption - [x] GenerateKeyPair - [x] Encrypt - [x] Decrypt - [x] Homomorphic Addition #### Usage - Encrypt, Decrypt ```go // key generation key, err := GenerateKeyPair() if err!=nil { fmt.Println(err) } mBytes := []byte("Hi") m := new(big.Int).SetBytes(mBytes) // encryption c := Encrypt(m, key.PubK) // decryption d := Decrypt(c, key.PubK, key.PrivK) if m == d { fmt.Println("ciphertext decrypted correctly") } ``` - Homomorphic Addition ```go // key generation [Alice] key, err := GenerateKeyPair() if err!=nil { fmt.Println(err) } // define values [Alice] n1 := big.NewInt(int64(110)) n2 := big.NewInt(int64(150)) // encrypt values [Alice] c1 := Encrypt(n1, key.PubK) c2 := Encrypt(n2, key.PubK) // compute homomorphic addition [Bob] c3c4 := HomomorphicAddition(c1, c2, key.PubK) // decrypt the result [Alice] d := Decrypt(c3c4, key.PubK, key.PrivK) if !bytes.Equal(new(big.Int).Add(n1, n2).Bytes(), d.Bytes()) { fmt.Println("decrypted result not equal to expected result") } ``` ## Shamir Secret Sharing - https://en.wikipedia.org/wiki/Shamir%27s_Secret_Sharing - [x] create secret sharing from number of secrets needed, number of shares, random point p, secret to share - [x] Lagrange Interpolation to restore the secret from the shares #### Usage ```go // define secret to share k := 123456789 // define random prime p, err := rand.Prime(rand.Reader, bits/2) if err!=nil { fmt.Println(err) } // define how many shares want to generate nShares := big.NewInt(int64(6)) // define how many shares are needed to recover the secret nNeededShares := big.NewInt(int64(3)) // create the shares shares, err := Create( nNeededShares, nShares, p, big.NewInt(int64(k))) assert.Nil(t, err) if err!=nil { fmt.Println(err) } // select shares to use var sharesToUse [][]*big.Int sharesToUse = append(sharesToUse, shares[2]) sharesToUse = append(sharesToUse, shares[1]) sharesToUse = append(sharesToUse, shares[0]) // recover the secret using Lagrange Interpolation secr := LagrangeInterpolation(sharesToUse, p) // check that the restored secret matches the original secret if !bytes.Equal(k.Bytes(), secr.Bytes()) { fmt.Println("reconstructed secret not correspond to original secret") } ``` ## Diffie-Hellman - https://en.wikipedia.org/wiki/Diffie%E2%80%93Hellman_key_exchange - [x] key exchange ## ECC - https://en.wikipedia.org/wiki/Elliptic-curve_cryptography - [x] define elliptic curve - [x] get point at X - [x] get order of a Point on the elliptic curve - [x] Add two points on the elliptic curve - [x] Multiply a point n times on the elliptic curve #### Usage - ECC basic operations ```go // define new ec ec := NewEC(big.NewInt(int64(0)), big.NewInt(int64(7)), big.NewInt(int64(11))) // define two points over the curve p1 := Point{big.NewInt(int64(4)), big.NewInt(int64(7))} p2 := Point{big.NewInt(int64(2)), big.NewInt(int64(2))} // add the two points q, err := ec.Add(p1, p2) if err!=nil { fmt.Println(err) } // multiply the two points q, err := ec.Mul(p, big.NewInt(int64(1))) if err!=nil { fmt.Println(err) } // get order of a generator point over the elliptic curve g := Point{big.NewInt(int64(7)), big.NewInt(int64(8))} order, err := ec.Order(g) if err!=nil { fmt.Println(err) } ``` ## ECC ElGamal - https://en.wikipedia.org/wiki/ElGamal_encryption - [x] ECC ElGamal key generation - [x] ECC ElGamal Encrypton - [x] ECC ElGamal Decryption #### Usage - NewEG, Encryption, Decryption ```go // define new elliptic curve ec := ecc.NewEC(big.NewInt(int64(1)), big.NewInt(int64(18)), big.NewInt(int64(19))) // define new point g := ecc.Point{big.NewInt(int64(7)), big.NewInt(int64(11))} // define new ElGamal crypto system with the elliptic curve and the point eg, err := NewEG(ec, g) if err!=nil { fmt.Println(err) } // define privK&pubK over the elliptic curve privK := big.NewInt(int64(5)) pubK, err := eg.PubK(privK) if err!=nil { fmt.Println(err) } // define point to encrypt m := ecc.Point{big.NewInt(int64(11)), big.NewInt(int64(12))} // encrypt c, err := eg.Encrypt(m, pubK, big.NewInt(int64(15))) if err!=nil { fmt.Println(err) } // decrypt d, err := eg.Decrypt(c, privK) if err!=nil { fmt.Println(err) } // check that decryption is correct if !m.Equal(d) { fmt.Println("decrypted not equal to original") } ``` ## ECC ECDSA - https://en.wikipedia.org/wiki/Elliptic_Curve_Digital_Signature_Algorithm - [x] define ECDSA data structure - [x] ECDSA Sign - [x] ECDSA Verify signature #### Usage ```go // define new elliptic curve ec := ecc.NewEC(big.NewInt(int64(1)), big.NewInt(int64(18)), big.NewInt(int64(19))) // define new point g := ecc.Point{big.NewInt(int64(7)), big.NewInt(int64(11))} // define new ECDSA system dsa, err := NewDSA(ec, g) if err!=nil { fmt.Println(err) } // define privK&pubK over the elliptic curve privK := big.NewInt(int64(5)) pubK, err := dsa.PubK(privK) if err!=nil { fmt.Println(err) } // hash value to sign hashval := big.NewInt(int64(40)) // define r r := big.NewInt(int64(11)) // sign hashed value sig, err := dsa.Sign(hashval, privK, r) if err!=nil { fmt.Println(err) } // verify signature verified, err := dsa.Verify(hashval, sig, pubK) if err!=nil { fmt.Println(err) } if verified { fmt.Println("signature correctly verified") } ``` ## Schnorr signature - https://en.wikipedia.org/wiki/Schnorr_signature - [x] Hash[M || R] (where M is the msg bytes and R is a Point on the ECC, using sha256 hash function) - [x] Generate Schnorr scheme - [x] Sign - [x] Verify signature #### Usage ```go // define new elliptic curve ec := ecc.NewEC(big.NewInt(int64(0)), big.NewInt(int64(7)), big.NewInt(int64(11))) // define new point g := ecc.Point{big.NewInt(int64(11)), big.NewInt(int64(27))} // Generator // define new random r r := big.NewInt(int64(23)) // random r // define new Schnorr crypto system using the values schnorr, sk, err := Gen(ec, g, r) if err!=nil { fmt.println(err) } // define message to sign m := []byte("hola") // also we can hash the message, but it's not mandatory, as it will be done inside the schnorr.Sign, but we can perform it now, just to check the function h := Hash([]byte("hola"), c) if h.String() != "34719153732582497359642109898768696927847420320548121616059449972754491425079") { fmt.Println("not correctly hashed") } s, rPoint, err := schnorr.Sign(sk, m) if err!=nil { fmt.println(err) } // verify Schnorr signature verified, err := Verify(schnorr.EC, sk.PubK, m, s, rPoint) if err!=nil { fmt.println(err) } if verified { fmt.Println("Schnorr signature correctly verified") } ``` ## Bn128 **[not finished]** This is implemented followng the implementations and info from: - https://github.com/iden3/zksnark - https://github.com/zcash/zcash/tree/master/src/snark - https://github.com/ethereum/py_ecc/tree/master/py_ecc/bn128 - `Multiplication and Squaring on Pairing-Friendly Fields`, Augusto Jun Devegili, Colm Ó hÉigeartaigh, Michael Scott, and Ricardo Dahab https://pdfs.semanticscholar.org/3e01/de88d7428076b2547b60072088507d881bf1.pdf - `Optimal Pairings`, Frederik Vercauteren https://www.cosic.esat.kuleuven.be/bcrypt/optimal.pdf - `Double-and-Add with Relative Jacobian Coordinates`, Björn Fay https://eprint.iacr.org/2014/1014.pdf - `Fast and Regular Algorithms for Scalar Multiplication over Elliptic Curves`, Matthieu Rivain https://eprint.iacr.org/2011/338.pdf - [x] Fq, Fq2, Fq6, Fq12 operations - [x] G1, G2 operations #### Usage First let's define three basic functions to convert integer compositions to big integer compositions: ```go func iToBig(a int) *big.Int { return big.NewInt(int64(a)) } func iiToBig(a, b int) [2]*big.Int { return [2]*big.Int{iToBig(a), iToBig(b)} } func iiiToBig(a, b int) [2]*big.Int { return [2]*big.Int{iToBig(a), iToBig(b)} } ``` - Finite Fields (1, 2, 6, 12) operations ```go // new finite field of order 1 fq1 := NewFq(iToBig(7)) // basic operations of finite field 1 res := fq1.Add(iToBig(4), iToBig(4)) res = fq1.Double(iToBig(5)) res = fq1.Sub(iToBig(5), iToBig(7)) res = fq1.Neg(iToBig(5)) res = fq1.Mul(iToBig(5), iToBig(11)) res = fq1.Inverse(iToBig(4)) res = fq1.Square(iToBig(5)) // new finite field of order 2 nonResidueFq2str := "-1" // i / Beta nonResidueFq2, ok := new(big.Int).SetString(nonResidueFq2str, 10) fq2 := Fq2{fq1, nonResidueFq2} nonResidueFq6 := iiToBig(9, 1) // basic operations of finite field of order 2 res := fq2.Add(iiToBig(4, 4), iiToBig(3, 4)) res = fq2.Double(iiToBig(5, 3)) res = fq2.Sub(iiToBig(5, 3), iiToBig(7, 2)) res = fq2.Neg(iiToBig(4, 4)) res = fq2.Mul(iiToBig(4, 4), iiToBig(3, 4)) res = fq2.Inverse(iiToBig(4, 4)) res = fq2.Div(iiToBig(4, 4), iiToBig(3, 4)) res = fq2.Square(iiToBig(4, 4)) // new finite field of order 6 nonResidueFq6 := iiToBig(9, 1) // TODO fq6 := Fq6{fq2, nonResidueFq6} // define two new values of Finite Field 6, in order to be able to perform the operations a := [3][2]*big.Int{ iiToBig(1, 2), iiToBig(3, 4), iiToBig(5, 6)} b := [3][2]*big.Int{ iiToBig(12, 11), iiToBig(10, 9), iiToBig(8, 7)} // basic operations of finite field order 6 res := fq6.Add(a, b) res = fq6.Sub(a, b) res = fq6.Mul(a, b) divRes := fq6.Div(mulRes, b) // new finite field of order 12 q, ok := new(big.Int).SetString("21888242871839275222246405745257275088696311157297823662689037894645226208583", 10) // i if !ok { fmt.Println("error parsing string to big integer") } fq1 := NewFq(q) nonResidueFq2, ok := new(big.Int).SetString("21888242871839275222246405745257275088696311157297823662689037894645226208582", 10) // i assert.True(t, ok) nonResidueFq6 := iiToBig(9, 1) fq2 := Fq2{fq1, nonResidueFq2} fq6 := Fq6{fq2, nonResidueFq6} fq12 := Fq12{fq6, fq2, nonResidueFq6} ``` - G1 operations ```go bn128, err := NewBn128() assert.Nil(t, err) r1 := big.NewInt(int64(33)) r2 := big.NewInt(int64(44)) gr1 := bn128.G1.MulScalar(bn128.G1.G, bn128.Fq1.Copy(r1)) gr2 := bn128.G1.MulScalar(bn128.G1.G, bn128.Fq1.Copy(r2)) grsum1 := bn128.G1.Add(gr1, gr2) r1r2 := bn128.Fq1.Add(r1, r2) grsum2 := bn128.G1.MulScalar(bn128.G1.G, r1r2) a := bn128.G1.Affine(grsum1) b := bn128.G1.Affine(grsum2) assert.Equal(t, a, b) assert.Equal(t, "0x2f978c0ab89ebaa576866706b14787f360c4d6c3869efe5a72f7c3651a72ff00", utils.BytesToHex(a[0].Bytes())) assert.Equal(t, "0x12e4ba7f0edca8b4fa668fe153aebd908d322dc26ad964d4cd314795844b62b2", utils.BytesToHex(a[1].Bytes())) ``` - G2 operations ```go bn128, err := NewBn128() assert.Nil(t, err) r1 := big.NewInt(int64(33)) r2 := big.NewInt(int64(44)) gr1 := bn128.G2.MulScalar(bn128.G2.G, bn128.Fq1.Copy(r1)) gr2 := bn128.G2.MulScalar(bn128.G2.G, bn128.Fq1.Copy(r2)) grsum1 := bn128.G2.Add(gr1, gr2) r1r2 := bn128.Fq1.Add(r1, r2) grsum2 := bn128.G2.MulScalar(bn128.G2.G, r1r2) a := bn128.G2.Affine(grsum1) b := bn128.G2.Affine(grsum2) assert.Equal(t, a, b) ``` --- To run all tests: ``` go test ./... -v ```