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threshold-fhe-5p.py
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from openfhe import *
from math import log2
def main():
print("\n=================RUNNING FOR BFVrns======================\n")
RunBFVrns()
def RunBFVrns():
plaintextModulus = 65537
sigma = 3.2
securityLevel = SecurityLevel.HEStd_128_classic
batchSize = 16
multDepth = 4
digitSize = 30
dcrtBits = 60
parameters = CCParamsBFVRNS()
parameters.SetPlaintextModulus(plaintextModulus)
parameters.SetSecurityLevel(securityLevel)
parameters.SetStandardDeviation(sigma)
parameters.SetSecretKeyDist(UNIFORM_TERNARY)
parameters.SetMultiplicativeDepth(multDepth)
parameters.SetBatchSize(batchSize)
parameters.SetDigitSize(digitSize)
parameters.SetScalingModSize(dcrtBits)
parameters.SetThresholdNumOfParties(5)
parameters.SetMultiplicationTechnique(HPSPOVERQLEVELED)
cc = GenCryptoContext(parameters)
# Enable features you wish to use
cc.Enable(PKE)
cc.Enable(KEYSWITCH)
cc.Enable(LEVELEDSHE)
cc.Enable(ADVANCEDSHE)
cc.Enable(MULTIPARTY)
##########################################################
# Set-up of parameters
##########################################################
# Output the generated parameters
print(f"p = {cc.GetPlaintextModulus()}")
print(f"n = {cc.GetCyclotomicOrder() / 2}")
print(f"log2 q = {log2(cc.GetModulus())}")
############################################################
## Perform Key Generation Operation
############################################################
print("Running key generation (used for source data)...")
# Round 1 (party A)
print("Round 1 (party A) started.")
kp1 = cc.KeyGen()
kp2 = cc.MultipartyKeyGen(kp1.publicKey)
kp3 = cc.MultipartyKeyGen(kp2.publicKey)
kp4 = cc.MultipartyKeyGen(kp3.publicKey)
kp5 = cc.MultipartyKeyGen(kp4.publicKey)
# Generate evalmult key part for A
evalMultKey = cc.KeySwitchGen(kp1.secretKey, kp1.secretKey)
evalMultKey2 = cc.MultiKeySwitchGen(kp2.secretKey, kp2.secretKey, evalMultKey)
evalMultKey3 = cc.MultiKeySwitchGen(kp3.secretKey, kp3.secretKey, evalMultKey)
evalMultKey4 = cc.MultiKeySwitchGen(kp4.secretKey, kp4.secretKey, evalMultKey)
evalMultKey5 = cc.MultiKeySwitchGen(kp5.secretKey, kp5.secretKey, evalMultKey)
evalMultAB = cc.MultiAddEvalKeys(evalMultKey, evalMultKey2, kp2.publicKey.GetKeyTag())
evalMultABC = cc.MultiAddEvalKeys(evalMultAB, evalMultKey3, kp3.publicKey.GetKeyTag())
evalMultABCD = cc.MultiAddEvalKeys(evalMultABC, evalMultKey4, kp4.publicKey.GetKeyTag())
evalMultABCDE = cc.MultiAddEvalKeys(evalMultABCD, evalMultKey5, kp5.publicKey.GetKeyTag())
evalMultEABCDE = cc.MultiMultEvalKey(kp5.secretKey, evalMultABCDE, kp5.publicKey.GetKeyTag())
evalMultDABCDE = cc.MultiMultEvalKey(kp4.secretKey, evalMultABCDE, kp5.publicKey.GetKeyTag())
evalMultCABCDE = cc.MultiMultEvalKey(kp3.secretKey, evalMultABCDE, kp5.publicKey.GetKeyTag())
evalMultBABCDE = cc.MultiMultEvalKey(kp2.secretKey, evalMultABCDE, kp5.publicKey.GetKeyTag())
evalMultAABCDE = cc.MultiMultEvalKey(kp1.secretKey, evalMultABCDE, kp5.publicKey.GetKeyTag())
evalMultDEABCDE = cc.MultiAddEvalMultKeys(evalMultEABCDE, evalMultDABCDE, evalMultEABCDE.GetKeyTag())
evalMultCDEABCDE = cc.MultiAddEvalMultKeys(evalMultCABCDE, evalMultDEABCDE, evalMultCABCDE.GetKeyTag())
evalMultBCDEABCDE = cc.MultiAddEvalMultKeys(evalMultBABCDE, evalMultCDEABCDE, evalMultBABCDE.GetKeyTag())
evalMultFinal = cc.MultiAddEvalMultKeys(evalMultAABCDE, evalMultBCDEABCDE, kp5.publicKey.GetKeyTag())
cc.InsertEvalMultKey([evalMultFinal])
print("Round 1 of key generation completed.")
############################################################
## EvalSum Key Generation
############################################################
print("Running evalsum key generation (used for source data)...")
# Generate evalsum key part for A
cc.EvalSumKeyGen(kp1.secretKey)
evalSumKeys = cc.GetEvalSumKeyMap(kp1.secretKey.GetKeyTag())
evalSumKeysB = cc.MultiEvalSumKeyGen(kp2.secretKey, evalSumKeys, kp2.publicKey.GetKeyTag())
evalSumKeysC = cc.MultiEvalSumKeyGen(kp3.secretKey, evalSumKeys, kp3.publicKey.GetKeyTag())
evalSumKeysD = cc.MultiEvalSumKeyGen(kp4.secretKey, evalSumKeys, kp4.publicKey.GetKeyTag())
evalSumKeysE = cc.MultiEvalSumKeyGen(kp5.secretKey, evalSumKeys, kp5.publicKey.GetKeyTag())
evalSumKeysAB = cc.MultiAddEvalSumKeys(evalSumKeys, evalSumKeysB, kp2.publicKey.GetKeyTag())
evalSumKeysABC = cc.MultiAddEvalSumKeys(evalSumKeysC, evalSumKeysAB, kp3.publicKey.GetKeyTag())
evalSumKeysABCD = cc.MultiAddEvalSumKeys(evalSumKeysABC, evalSumKeysD, kp4.publicKey.GetKeyTag())
evalSumKeysJoin = cc.MultiAddEvalSumKeys(evalSumKeysE, evalSumKeysABCD, kp5.publicKey.GetKeyTag())
cc.InsertEvalSumKey(evalSumKeysJoin)
print("Evalsum key generation completed.")
############################################################
## Encode source data
############################################################
vectorOfInts1 = [1, 2, 3, 4, 5, 6, 5, 4, 3, 2, 1, 0]
vectorOfInts2 = [1, 0, 0, 1, 1, 0, 0, 0, 0, 0, 0, 0]
vectorOfInts3 = [2, 2, 3, 4, 5, 6, 7, 8, 9, 10, 0, 0]
plaintext1 = cc.MakePackedPlaintext(vectorOfInts1)
plaintext2 = cc.MakePackedPlaintext(vectorOfInts2)
plaintext3 = cc.MakePackedPlaintext(vectorOfInts3)
############################################################
## Encryption
############################################################
ciphertext1 = cc.Encrypt(kp5.publicKey, plaintext1)
ciphertext2 = cc.Encrypt(kp5.publicKey, plaintext2)
ciphertext3 = cc.Encrypt(kp5.publicKey, plaintext3)
############################################################
## Homomorphic Operations
############################################################
ciphertextAdd12 = cc.EvalAdd(ciphertext1, ciphertext2)
ciphertextAdd123 = cc.EvalAdd(ciphertextAdd12, ciphertext3)
ciphertextMult1 = cc.EvalMult(ciphertext1, ciphertext1)
ciphertextMult2 = cc.EvalMult(ciphertextMult1, ciphertext1)
ciphertextMult3 = cc.EvalMult(ciphertextMult2, ciphertext1)
ciphertextMult = cc.EvalMult(ciphertextMult3, ciphertext1)
ciphertextEvalSum = cc.EvalSum(ciphertext3, batchSize)
############################################################
## Decryption after Accumulation Operation on Encrypted Data with Multiparty
############################################################
# Distributed decryption
# partial decryption by party A
ciphertextPartial1 = cc.MultipartyDecryptLead([ciphertextAdd123], kp1.secretKey)
# partial decryption by party B
ciphertextPartial2 = cc.MultipartyDecryptMain([ciphertextAdd123], kp2.secretKey)
# partial decryption by party C
ciphertextPartial3 = cc.MultipartyDecryptMain([ciphertextAdd123], kp3.secretKey)
# partial decryption by party D
ciphertextPartial4 = cc.MultipartyDecryptMain([ciphertextAdd123], kp4.secretKey)
# partial decryption by party E
ciphertextPartial5 = cc.MultipartyDecryptMain([ciphertextAdd123], kp5.secretKey)
partialCiphertextVec = [ciphertextPartial1[0], ciphertextPartial2[0], ciphertextPartial3[0],
ciphertextPartial4[0], ciphertextPartial5[0]]
plaintextMultipartyNew = cc.MultipartyDecryptFusion(partialCiphertextVec)
print("\n Original Plaintext: \n")
print(plaintext1)
print(plaintext2)
print(plaintext3)
plaintextMultipartyNew.SetLength(plaintext1.GetLength())
print("\n Resulting Fused Plaintext: \n")
print(plaintextMultipartyNew)
print("\n")
ciphertextPartial1 = cc.MultipartyDecryptLead([ciphertextMult], kp1.secretKey)
ciphertextPartial2 = cc.MultipartyDecryptMain([ciphertextMult], kp2.secretKey)
ciphertextPartial3 = cc.MultipartyDecryptMain([ciphertextMult], kp3.secretKey)
ciphertextPartial4 = cc.MultipartyDecryptMain([ciphertextMult], kp4.secretKey)
ciphertextPartial5 = cc.MultipartyDecryptMain([ciphertextMult], kp5.secretKey)
partialCiphertextVecMult = [ciphertextPartial1[0], ciphertextPartial2[0], ciphertextPartial3[0],
ciphertextPartial4[0], ciphertextPartial5[0]]
plaintextMultipartyMult = cc.MultipartyDecryptFusion(partialCiphertextVecMult)
plaintextMultipartyMult.SetLength(plaintext1.GetLength())
print("\n Resulting Fused Plaintext after Multiplication of plaintexts 1 and 3: \n")
print(plaintextMultipartyMult)
print("\n")
ciphertextPartial1 = cc.MultipartyDecryptLead([ciphertextEvalSum], kp1.secretKey)
ciphertextPartial2 = cc.MultipartyDecryptMain([ciphertextEvalSum], kp2.secretKey)
ciphertextPartial3 = cc.MultipartyDecryptMain([ciphertextEvalSum], kp3.secretKey)
ciphertextPartial4 = cc.MultipartyDecryptMain([ciphertextEvalSum], kp4.secretKey)
ciphertextPartial5 = cc.MultipartyDecryptMain([ciphertextEvalSum], kp5.secretKey)
partialCiphertextVecEvalSum = [ciphertextPartial1[0], ciphertextPartial2[0], ciphertextPartial3[0],
ciphertextPartial4[0], ciphertextPartial5[0]]
plaintextMultipartyEvalSum = cc.MultipartyDecryptFusion(partialCiphertextVecEvalSum)
plaintextMultipartyEvalSum.SetLength(plaintext1.GetLength())
print("\n Fused result after the Summation of ciphertext 3: \n")
print(plaintextMultipartyEvalSum)
if __name__ == "__main__":
main()