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BFV-addition
In HomomorphicEncryption: BFV, BGV, CKKS Schema for Fully Homomorphic Encryption
knitr::opts_chunk$set(
collapse = TRUE,
comment = "#>"
)
Load libraries that will be used.
library(HomomorphicEncryption)
library(polynom)
Set some parameters.
d = 4
n = 2^d
p = (n/2)-1
q = 424242
pm = GenPolyMod(n)
Set a working seed for random numbers
set.seed(123)
Create the secret key and the polynomials a and e, which will go into the public key
# generate a secret key
s = GenSecretKey(n)
# generate a
a = GenA(n, q)
# generate the error
e = GenError(n)
Generate the public key.
# generate the public key
pk0 = GenPubKey0(a, s, e, pm, q)
pk1 = GenPubKey1(a)
Create polynomials for the encryption
# polynomials for encryption
e1 = GenError(n)
e2 = GenError(n)
u = GenU(n)
Now create to messages to add.
m1 = polynomial(c(1, 1, 1))
m2 = polynomial(c(0, 1 ))
Encrypt the messages.
m1_ct0 = EncryptPoly0(m1, pk0, u, e1, p, pm, q)
m1_ct1 = EncryptPoly1( pk1, u, e2, pm, q)
m2_ct0 = EncryptPoly0(m2, pk0, u, e1, p, pm, q)
m2_ct1 = EncryptPoly1( pk1, u, e2, pm, q)
Sum the encrypted messages.
sum_ct0 = m1_ct0 + m2_ct0
sum_ct1 = m1_ct1 + m2_ct1
sum_ct0 = sum_ct0 %% pm
sum_ct0 = CoefMod(sum_ct0, q)
sum_ct1 = sum_ct1 %% pm
sum_ct1 = CoefMod(sum_ct1, q)
Decrypt the sum
decrypt = (sum_ct1 * s) + sum_ct0
decrypt = decrypt %% pm
decrypt = CoefMod(decrypt, q)
# rescale
decrypt = decrypt * p/q
# round then mod p
decrypt = CoefMod(round(decrypt), p)
print(decrypt)
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HomomorphicEncryption documentation built on May 29, 2024, 9:59 a.m.
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knitr::opts_chunk$set( collapse = TRUE, comment = "#>" )
Load libraries that will be used.
library(HomomorphicEncryption) library(polynom)
Set some parameters.
d = 4 n = 2^d p = (n/2)-1 q = 424242 pm = GenPolyMod(n)
Set a working seed for random numbers
set.seed(123)
Create the secret key and the polynomials a and e, which will go into the public key
# generate a secret key s = GenSecretKey(n) # generate a a = GenA(n, q) # generate the error e = GenError(n)
Generate the public key.
# generate the public key pk0 = GenPubKey0(a, s, e, pm, q) pk1 = GenPubKey1(a)
Create polynomials for the encryption
# polynomials for encryption e1 = GenError(n) e2 = GenError(n) u = GenU(n)
Now create to messages to add.
m1 = polynomial(c(1, 1, 1)) m2 = polynomial(c(0, 1 ))
Encrypt the messages.
m1_ct0 = EncryptPoly0(m1, pk0, u, e1, p, pm, q) m1_ct1 = EncryptPoly1( pk1, u, e2, pm, q) m2_ct0 = EncryptPoly0(m2, pk0, u, e1, p, pm, q) m2_ct1 = EncryptPoly1( pk1, u, e2, pm, q)
Sum the encrypted messages.
sum_ct0 = m1_ct0 + m2_ct0 sum_ct1 = m1_ct1 + m2_ct1 sum_ct0 = sum_ct0 %% pm sum_ct0 = CoefMod(sum_ct0, q) sum_ct1 = sum_ct1 %% pm sum_ct1 = CoefMod(sum_ct1, q)
Decrypt the sum
decrypt = (sum_ct1 * s) + sum_ct0 decrypt = decrypt %% pm decrypt = CoefMod(decrypt, q) # rescale decrypt = decrypt * p/q # round then mod p decrypt = CoefMod(round(decrypt), p) print(decrypt)
Try the HomomorphicEncryption package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
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We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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