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interactive-bootstrapping.py
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245 lines (167 loc) · 9.26 KB
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from openfhe import *
def main():
# the scaling technigue can be changed to FIXEDMANUAL, FIXEDAUTO, or FLEXIBLEAUTOEXT
ThresholdFHE(FLEXIBLEAUTO)
Chebyshev(FLEXIBLEAUTO)
def ThresholdFHE(scaleTech):
# if scaleTech not in [FIXEDMANUAL, FIXEDAUTO, FLEXIBLEAUTOEXT]:
# errMsg = "ERROR: Scaling technique is not supported!"
# raise Exception(errMsg)
print(f"Threshold FHE example with Scaling Technique {scaleTech}")
parameters = CCParamsCKKSRNS()
# 1 extra level needs to be added for FIXED* modes (2 extra levels for FLEXIBLE* modes) to the multiplicative depth
# to support 2-party interactive bootstrapping
depth = 7
parameters.SetMultiplicativeDepth(depth)
parameters.SetScalingModSize(50)
parameters.SetBatchSize(16)
parameters.SetScalingTechnique(scaleTech)
cc = GenCryptoContext(parameters)
cc.Enable(PKE)
cc.Enable(LEVELEDSHE)
cc.Enable(ADVANCEDSHE)
cc.Enable(MULTIPARTY)
#############################################################
# Perform Key Generation Operation
#############################################################
print("Running key generation (used for source data)...")
print("Round 1 (party A) started.")
kp1 = cc.KeyGen()
evalMultKey = cc.KeySwitchGen(kp1.secretKey, kp1.secretKey)
print("Round 1 of key generation completed.")
#############################################################
print("Round 2 (party B) started.")
print("Joint public key for (s_a + s_b) is generated...")
kp2 = cc.MultipartyKeyGen(kp1.publicKey)
input = [-0.9, -0.8, -0.6, -0.4, -0.2, 0., 0.2, 0.4, 0.6, 0.8, 0.9]
# This plaintext only has 3 RNS limbs, the minimum needed to perform 2-party interactive bootstrapping for FLEXIBLEAUTO
plaintext1 = cc.MakeCKKSPackedPlaintext(input, 1, depth - 2)
ciphertext1 = cc.Encrypt(kp2.publicKey, plaintext1)
# INTERACTIVE BOOTSTRAPPING STARTS
# under the hood it reduces to two towers
ciphertext1 = cc.IntBootAdjustScale(ciphertext1)
print("IntBootAdjustScale Succeeded")
# masked decryption on the server: c0 = b + a*s0
ciphertextOutput1 = cc.IntBootDecrypt(kp1.secretKey, ciphertext1)
print("IntBootDecrypt on Server Succeeded")
ciphertext2 = ciphertext1.Clone()
ciphertext2.SetElements([ciphertext2.GetElements()[1]])
# masked decryption on the client: c1 = a*s1
ciphertextOutput2 = cc.IntBootDecrypt(kp2.secretKey, ciphertext2)
print("IntBootDecrypt on Client Succeeded")
# Encryption of masked decryption c1 = a*s1
ciphertextOutput2 = cc.IntBootEncrypt(kp2.publicKey, ciphertextOutput2)
print("IntBootEncrypt on Client Succeeded")
# Compute Enc(c1) + c0
ciphertextOutput = cc.IntBootAdd(ciphertextOutput2, ciphertextOutput1)
print("IntBootAdd on Server Succeeded")
# INTERACTIVE BOOTSTRAPPING ENDS
# distributed decryption
ciphertextPartial1 = cc.MultipartyDecryptLead([ciphertextOutput], kp1.secretKey)
ciphertextPartial2 = cc.MultipartyDecryptMain([ciphertextOutput], kp2.secretKey)
partialCiphertextVec = [ciphertextPartial1[0], ciphertextPartial2[0]]
plaintextMultiparty = cc.MultipartyDecryptFusion(partialCiphertextVec)
plaintextMultiparty.SetLength(len(input))
print(f"Original plaintext \n\t {plaintext1.GetCKKSPackedValue()}")
print(f"Result after bootstrapping \n\t {plaintextMultiparty.GetCKKSPackedValue()}")
def Chebyshev(scaleTech):
# if scaleTech not in [FIXEDMANUAL, FIXEDAUTO, FLEXIBLEAUTOEXT]:
# errMsg = "ERROR: Scaling technique is not supported!"
# raise Exception(errMsg)
print(f"Threshold FHE example with Scaling Technique {scaleTech}")
parameters = CCParamsCKKSRNS()
# 1 extra level needs to be added for FIXED* modes (2 extra levels for FLEXIBLE* modes) to the multiplicative depth
# to support 2-party interactive bootstrapping
parameters.SetMultiplicativeDepth(8)
parameters.SetScalingModSize(50)
parameters.SetBatchSize(16)
parameters.SetScalingTechnique(scaleTech)
cc = GenCryptoContext(parameters)
# enable features that you wish to use
cc.Enable(PKE)
cc.Enable(LEVELEDSHE)
cc.Enable(ADVANCEDSHE)
cc.Enable(MULTIPARTY)
############################################################
# Perform Key Generation Operation
############################################################
print("Running key generation (used for source data)...")
print("Round 1 (party A) started.")
kp1 = cc.KeyGen()
evalMultKey = cc.KeySwitchGen(kp1.secretKey, kp1.secretKey)
cc.EvalSumKeyGen(kp1.secretKey)
evalSumKeys = cc.GetEvalSumKeyMap(kp1.secretKey.GetKeyTag())
print("Round 1 of key generation completed.")
############################################################
print("Round 2 (party B) started.")
print("Joint public key for (s_a + s_b) is generated...")
kp2 = cc.MultipartyKeyGen(kp1.publicKey)
evalMultKey2 = cc.MultiKeySwitchGen(kp2.secretKey, kp2.secretKey, evalMultKey)
print("Joint evaluation multiplication key for (s_a + s_b) is generated...")
evalMultAB = cc.MultiAddEvalKeys(evalMultKey, evalMultKey2, kp2.publicKey.GetKeyTag())
print("Joint evaluation multiplication key (s_a + s_b) is transformed into s_b*(s_a + s_b)...")
evalMultBAB = cc.MultiMultEvalKey(kp2.secretKey, evalMultAB, kp2.publicKey.GetKeyTag())
evalSumKeysB = cc.MultiEvalSumKeyGen(kp2.secretKey, evalSumKeys, kp2.publicKey.GetKeyTag())
print("Joint evaluation summation key for (s_a + s_b) is generated...")
evalSumKeysJoin = cc.MultiAddEvalSumKeys(evalSumKeys, evalSumKeysB, kp2.publicKey.GetKeyTag())
cc.InsertEvalSumKey(evalSumKeysJoin)
print("Round 2 of key generation completed.")
print("Round 3 (party A) started.")
print("Joint key (s_a + s_b) is transformed into s_a*(s_a + s_b)...")
evalMultAAB = cc.MultiMultEvalKey(kp1.secretKey, evalMultAB, kp2.publicKey.GetKeyTag())
print("Computing the final evaluation multiplication key for (s_a + s_b)*(s_a + s_b)...")
evalMultFinal = cc.MultiAddEvalMultKeys(evalMultAAB, evalMultBAB, evalMultAB.GetKeyTag())
cc.InsertEvalMultKey([evalMultFinal])
print("Round 3 of key generation completed.")
input = [-4.0, -3.0, -2.0, -1.0, 0.0, 1.0, 2.0, 3.0, 4.0]
coefficients = [1.0, 0.558971, 0.0, -0.0943712, 0.0, 0.0215023, 0.0, -0.00505348, 0.0, 0.00119324,
0.0, -0.000281928, 0.0, 0.0000664347, 0.0, -0.0000148709]
a = -4
b = 4
plaintext1 = cc.MakeCKKSPackedPlaintext(input)
ciphertext1 = cc.Encrypt(kp2.publicKey, plaintext1)
# The Chebyshev series interpolation requires 6 levels
ciphertext1 = cc.EvalChebyshevSeries(ciphertext1, coefficients, a, b)
print("Ran Chebyshev interpolation")
# INTERACTIVE BOOTSTRAPPING STARTS
ciphertext1 = cc.IntBootAdjustScale(ciphertext1)
print("IntBootAdjustScale Succeeded")
# masked decryption on the server: c0 = b + a*s0
ciphertextOutput1 = cc.IntBootDecrypt(kp1.secretKey, ciphertext1)
print("IntBootDecrypt on Server Succeeded")
ciphertext2 = ciphertext1.Clone()
ciphertext2.SetElements([ciphertext2.GetElements()[1]])
# masked decryption on the client: c1 = a*s1
ciphertextOutput2 = cc.IntBootDecrypt(kp2.secretKey, ciphertext2)
print("IntBootDecrypt on Client Succeeded")
# Encryption of masked decryption c1 = a*s1
ciphertextOutput2 = cc.IntBootEncrypt(kp2.publicKey, ciphertextOutput2)
print("IntBootEncrypt on Client Succeeded")
# Compute Enc(c1) + c0
ciphertextOutput = cc.IntBootAdd(ciphertextOutput2, ciphertextOutput1)
print("IntBootAdd on Server Succeeded")
# INTERACTIVE BOOTSTRAPPING ENDS
# distributed decryption
ciphertextPartial1 = cc.MultipartyDecryptLead([ciphertextOutput], kp1.secretKey)
ciphertextPartial2 = cc.MultipartyDecryptMain([ciphertextOutput], kp2.secretKey)
partialCiphertextVec = [ciphertextPartial1[0], ciphertextPartial2[0]]
plaintextMultiparty = cc.MultipartyDecryptFusion(partialCiphertextVec)
plaintextMultiparty.SetLength(len(input))
print(f"\n Original Plaintext #1: \n {plaintext1}")
print(f"\n Results of evaluating the polynomial with coefficients {coefficients} \n")
print(f"\n Ciphertext result: {plaintextMultiparty}")
print("\n Plaintext result: ( 0.0179885, 0.0474289, 0.119205, 0.268936, 0.5, 0.731064, 0.880795, 0.952571, 0.982011 ) \n")
print("\n Exact result: ( 0.0179862, 0.0474259, 0.119203, 0.268941, 0.5, 0.731059, 0.880797, 0.952574, 0.982014 ) \n")
print("\n Another round of Chebyshev interpolation after interactive bootstrapping: \n")
ciphertextOutput = cc.EvalChebyshevSeries(ciphertextOutput, coefficients, a, b)
print("Ran Chebyshev interpolation")
# distributed decryption
ciphertextPartial1 = cc.MultipartyDecryptLead([ciphertextOutput], kp1.secretKey)
ciphertextPartial2 = cc.MultipartyDecryptMain([ciphertextOutput], kp2.secretKey)
partialCiphertextVec = [ciphertextPartial1[0], ciphertextPartial2[0]]
plaintextMultiparty = cc.MultipartyDecryptFusion(partialCiphertextVec)
plaintextMultiparty.SetLength(len(input))
print(f"\n Ciphertext result: {plaintextMultiparty}")
print("\n Plaintext result: ( 0.504497, 0.511855, 0.529766, 0.566832, 0.622459, 0.675039, 0.706987, 0.721632, 0.727508 )")
if __name__ == "__main__":
main()