// generateAffineMasks creates the random external masks for the construction.
func generateAffineMasks(rs *random.Source) (inputMask, outputMask encoding.BlockAffine) {
var inputLinear, outputLinear matrix.Matrix
common.GenerateMasks(rs, common.IndependentMasks{common.RandomMask, common.RandomMask}, &inputLinear, &outputLinear)
reader := rs.Stream(make([]byte, 16))
var inputConstant, outputConstant [16]byte
reader.Read(inputConstant[:])
reader.Read(outputConstant[:])
inputMask = encoding.NewBlockAffine(inputLinear, inputConstant)
outputMask = encoding.NewBlockAffine(outputLinear, outputConstant)
return
}
// generateAffineMasks creates the random external masks for the construction.
func generateAffineMasks(rs *random.Source) (inputMask, outputMask *blockAffine) {
var inputLinear, outputLinear matrix.Matrix
common.GenerateMasks(rs, common.IndependentMasks{common.RandomMask, common.RandomMask}, &inputLinear, &outputLinear)
reader := rs.Stream(make([]byte, 16))
inputConstant, outputConstant := matrix.NewRow(128), matrix.NewRow(128)
reader.Read(inputConstant[:])
reader.Read(outputConstant[:])
inputMask = &blockAffine{linear: inputLinear, constant: inputConstant}
outputMask = &blockAffine{linear: outputLinear, constant: outputConstant}
return
}
// GenerateDecryptionKeys creates a white-boxed version of the AES key `key` for decryption, with any non-determinism
// generated by `seed`.
func GenerateDecryptionKeys(key, seed []byte, opts common.KeyGenerationOpts) (out Construction, inputMask, outputMask matrix.Matrix) {
rs := random.NewSource("Xiao Decryption", seed)
constr := saes.Construction{key}
roundKeys := constr.StretchedKey()
// Apply UnShiftRows to round keys 10.
constr.UnShiftRows(roundKeys[10])
hidden := func(round, pos int) table.DoubleToWord {
if round == 0 {
return tBoxMixCol{
[2]table.Byte{
common.InvTBox{constr, roundKeys[10][pos+0], roundKeys[9][pos+0]},
common.InvTBox{constr, roundKeys[10][pos+1], roundKeys[9][pos+1]},
},
unMixColumns,
sideFromPos(pos),
}
} else if 0 < round && round < 9 {
return tBoxMixCol{
[2]table.Byte{
common.InvTBox{constr, 0x00, roundKeys[9-round][pos+0]},
common.InvTBox{constr, 0x00, roundKeys[9-round][pos+1]},
},
unMixColumns,
sideFromPos(pos),
}
} else {
return tBox{
[2]table.Byte{
common.InvTBox{constr, 0x00, roundKeys[0][pos+0]},
common.InvTBox{constr, 0x00, roundKeys[0][pos+1]},
},
sideFromPos(pos),
}
}
}
common.GenerateMasks(&rs, opts, &inputMask, &outputMask)
generateRoundMaterial(&rs, &out, hidden)
generateBarriers(&rs, &out, &inputMask, &outputMask, &unShiftRows)
return out, inputMask, outputMask
}
// GenerateEncryptionKeys creates a white-boxed version of the AES key `key` for encryption, with any non-determinism
// generated by `seed`.
func GenerateEncryptionKeys(key, seed []byte, opts common.KeyGenerationOpts) (out Construction, inputMask, outputMask matrix.Matrix) {
rs := random.NewSource("Xiao Encryption", seed)
constr := saes.Construction{key}
roundKeys := constr.StretchedKey()
// Apply ShiftRows to round keys 0 to 9.
for k := 0; k < 10; k++ {
constr.ShiftRows(roundKeys[k])
}
hidden := func(round, pos int) table.DoubleToWord {
if round == 9 {
return tBox{
[2]table.Byte{
common.TBox{constr, roundKeys[9][pos+0], roundKeys[10][pos+0]},
common.TBox{constr, roundKeys[9][pos+1], roundKeys[10][pos+1]},
},
sideFromPos(pos),
}
} else {
return tBoxMixCol{
[2]table.Byte{
common.TBox{constr, roundKeys[round][pos+0], 0x00},
common.TBox{constr, roundKeys[round][pos+1], 0x00},
},
mixColumns,
sideFromPos(pos),
}
}
}
common.GenerateMasks(&rs, opts, &inputMask, &outputMask)
generateRoundMaterial(&rs, &out, hidden)
generateBarriers(&rs, &out, &inputMask, &outputMask, &shiftRows)
return out, inputMask, outputMask
}
func generateKeys(rs *random.Source, opts common.KeyGenerationOpts, out *Construction, inputMask, outputMask *matrix.Matrix, shift func(int) int, skinny func(int) table.Byte, wide func(int, int) table.Word) {
// Generate input and output encodings.
common.GenerateMasks(rs, opts, inputMask, outputMask)
// Generate the Input Mask slices and XOR tables.
for pos := 0; pos < 16; pos++ {
out.InputMask[pos] = encoding.BlockTable{
encoding.IdentityByte{},
blockMaskEncoding(rs, pos, common.Inside, shift),
common.BlockMatrix{Linear: *inputMask, Position: pos},
}
}
out.InputXORTables = common.BlockNibbleXORTables(
maskEncoding(rs, common.Inside),
xorEncoding(rs, 10, common.Inside),
roundEncoding(rs, -1, common.Outside, shift),
)
// Generate round material.
for round := 0; round < 9; round++ {
for pos := 0; pos < 16; pos++ {
// Generate a word-sized mixing bijection and stick it on the end of the T-Box/Tyi Table.
mb := common.MixingBijection(rs, 32, round, pos/4)
// Build the T-Box and Tyi Table for this round and position in the state matrix.
out.TBoxTyiTable[round][pos] = encoding.WordTable{
encoding.ComposedBytes{
encoding.NewByteLinear(common.MixingBijection(rs, 8, round-1, pos)),
byteRoundEncoding(rs, round-1, pos, common.Outside, common.NoShift),
},
encoding.ComposedWords{
encoding.ConcatenatedWord{
encoding.NewByteLinear(common.MixingBijection(rs, 8, round, shift(pos/4*4+0))),
encoding.NewByteLinear(common.MixingBijection(rs, 8, round, shift(pos/4*4+1))),
encoding.NewByteLinear(common.MixingBijection(rs, 8, round, shift(pos/4*4+2))),
encoding.NewByteLinear(common.MixingBijection(rs, 8, round, shift(pos/4*4+3))),
},
encoding.NewWordLinear(mb),
wordStepEncoding(rs, round, pos, common.Inside),
},
wide(round, pos),
}
// Encode the inverse of the mixing bijection from above in the MB^(-1) table for this round and position.
mbInv, _ := mb.Invert()
out.MBInverseTable[round][pos] = encoding.WordTable{
byteRoundEncoding(rs, round, pos, common.Inside, common.NoShift),
wordStepEncoding(rs, round, pos, common.Outside),
mbInverseTable{mbInv, uint(pos) % 4},
}
}
}
// Generate the High and Low XOR Tables for reach round.
out.HighXORTable = xorTables(rs, common.Inside, common.NoShift)
out.LowXORTable = xorTables(rs, common.Outside, shift)
// Generate the 10th T-Box/Output Mask slices and XOR tables.
for pos := 0; pos < 16; pos++ {
out.TBoxOutputMask[pos] = encoding.BlockTable{
encoding.ComposedBytes{
encoding.NewByteLinear(common.MixingBijection(rs, 8, 8, pos)),
byteRoundEncoding(rs, 8, pos, common.Outside, common.NoShift),
},
blockMaskEncoding(rs, pos, common.Outside, shift),
table.ComposedToBlock{
Heads: skinny(pos),
Tails: common.BlockMatrix{Linear: *outputMask, Position: pos},
},
}
}
out.OutputXORTables = common.BlockNibbleXORTables(
maskEncoding(rs, common.Outside),
xorEncoding(rs, 10, common.Outside),
func(position int) encoding.Nibble { return encoding.IdentityByte{} },
)
}
