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authorlloyd <[email protected]>2008-11-08 19:46:52 +0000
committerlloyd <[email protected]>2008-11-08 19:46:52 +0000
commitf1c459725da56fd8ed5766e7779300182fa26bcf (patch)
tree32295cec92df1155563ae8a535dc695d6800d7f6 /src/block/square/square.cpp
parent8dba7b5264403e781bbb86ff61850e4377dca7b9 (diff)
Split ciphers into block and stream ciphers. Move base class headers
Diffstat (limited to 'src/block/square/square.cpp')
-rw-r--r--src/block/square/square.cpp185
1 files changed, 185 insertions, 0 deletions
diff --git a/src/block/square/square.cpp b/src/block/square/square.cpp
new file mode 100644
index 000000000..f2b15499b
--- /dev/null
+++ b/src/block/square/square.cpp
@@ -0,0 +1,185 @@
+/*************************************************
+* Square Source File *
+* (C) 1999-2007 Jack Lloyd *
+*************************************************/
+
+#include <botan/square.h>
+#include <botan/loadstor.h>
+#include <botan/bit_ops.h>
+
+namespace Botan {
+
+/*************************************************
+* Square Encryption *
+*************************************************/
+void Square::enc(const byte in[], byte out[]) const
+ {
+ u32bit T0, T1, T2, T3, B0, B1, B2, B3;
+ B0 = TE0[in[ 0] ^ ME[ 0]] ^ TE1[in[ 4] ^ ME[ 4]] ^
+ TE2[in[ 8] ^ ME[ 8]] ^ TE3[in[12] ^ ME[12]] ^ EK[0];
+ B1 = TE0[in[ 1] ^ ME[ 1]] ^ TE1[in[ 5] ^ ME[ 5]] ^
+ TE2[in[ 9] ^ ME[ 9]] ^ TE3[in[13] ^ ME[13]] ^ EK[1];
+ B2 = TE0[in[ 2] ^ ME[ 2]] ^ TE1[in[ 6] ^ ME[ 6]] ^
+ TE2[in[10] ^ ME[10]] ^ TE3[in[14] ^ ME[14]] ^ EK[2];
+ B3 = TE0[in[ 3] ^ ME[ 3]] ^ TE1[in[ 7] ^ ME[ 7]] ^
+ TE2[in[11] ^ ME[11]] ^ TE3[in[15] ^ ME[15]] ^ EK[3];
+ for(u32bit j = 1; j != 7; j += 2)
+ {
+ T0 = TE0[get_byte(0, B0)] ^ TE1[get_byte(0, B1)] ^
+ TE2[get_byte(0, B2)] ^ TE3[get_byte(0, B3)] ^ EK[4*j+0];
+ T1 = TE0[get_byte(1, B0)] ^ TE1[get_byte(1, B1)] ^
+ TE2[get_byte(1, B2)] ^ TE3[get_byte(1, B3)] ^ EK[4*j+1];
+ T2 = TE0[get_byte(2, B0)] ^ TE1[get_byte(2, B1)] ^
+ TE2[get_byte(2, B2)] ^ TE3[get_byte(2, B3)] ^ EK[4*j+2];
+ T3 = TE0[get_byte(3, B0)] ^ TE1[get_byte(3, B1)] ^
+ TE2[get_byte(3, B2)] ^ TE3[get_byte(3, B3)] ^ EK[4*j+3];
+ B0 = TE0[get_byte(0, T0)] ^ TE1[get_byte(0, T1)] ^
+ TE2[get_byte(0, T2)] ^ TE3[get_byte(0, T3)] ^ EK[4*j+4];
+ B1 = TE0[get_byte(1, T0)] ^ TE1[get_byte(1, T1)] ^
+ TE2[get_byte(1, T2)] ^ TE3[get_byte(1, T3)] ^ EK[4*j+5];
+ B2 = TE0[get_byte(2, T0)] ^ TE1[get_byte(2, T1)] ^
+ TE2[get_byte(2, T2)] ^ TE3[get_byte(2, T3)] ^ EK[4*j+6];
+ B3 = TE0[get_byte(3, T0)] ^ TE1[get_byte(3, T1)] ^
+ TE2[get_byte(3, T2)] ^ TE3[get_byte(3, T3)] ^ EK[4*j+7];
+ }
+ out[ 0] = SE[get_byte(0, B0)] ^ ME[16];
+ out[ 1] = SE[get_byte(0, B1)] ^ ME[17];
+ out[ 2] = SE[get_byte(0, B2)] ^ ME[18];
+ out[ 3] = SE[get_byte(0, B3)] ^ ME[19];
+ out[ 4] = SE[get_byte(1, B0)] ^ ME[20];
+ out[ 5] = SE[get_byte(1, B1)] ^ ME[21];
+ out[ 6] = SE[get_byte(1, B2)] ^ ME[22];
+ out[ 7] = SE[get_byte(1, B3)] ^ ME[23];
+ out[ 8] = SE[get_byte(2, B0)] ^ ME[24];
+ out[ 9] = SE[get_byte(2, B1)] ^ ME[25];
+ out[10] = SE[get_byte(2, B2)] ^ ME[26];
+ out[11] = SE[get_byte(2, B3)] ^ ME[27];
+ out[12] = SE[get_byte(3, B0)] ^ ME[28];
+ out[13] = SE[get_byte(3, B1)] ^ ME[29];
+ out[14] = SE[get_byte(3, B2)] ^ ME[30];
+ out[15] = SE[get_byte(3, B3)] ^ ME[31];
+ }
+
+/*************************************************
+* Square Decryption *
+*************************************************/
+void Square::dec(const byte in[], byte out[]) const
+ {
+ u32bit T0, T1, T2, T3, B0, B1, B2, B3;
+ B0 = TD0[in[ 0] ^ MD[ 0]] ^ TD1[in[ 4] ^ MD[ 4]] ^
+ TD2[in[ 8] ^ MD[ 8]] ^ TD3[in[12] ^ MD[12]] ^ DK[0];
+ B1 = TD0[in[ 1] ^ MD[ 1]] ^ TD1[in[ 5] ^ MD[ 5]] ^
+ TD2[in[ 9] ^ MD[ 9]] ^ TD3[in[13] ^ MD[13]] ^ DK[1];
+ B2 = TD0[in[ 2] ^ MD[ 2]] ^ TD1[in[ 6] ^ MD[ 6]] ^
+ TD2[in[10] ^ MD[10]] ^ TD3[in[14] ^ MD[14]] ^ DK[2];
+ B3 = TD0[in[ 3] ^ MD[ 3]] ^ TD1[in[ 7] ^ MD[ 7]] ^
+ TD2[in[11] ^ MD[11]] ^ TD3[in[15] ^ MD[15]] ^ DK[3];
+ for(u32bit j = 1; j != 7; j += 2)
+ {
+ T0 = TD0[get_byte(0, B0)] ^ TD1[get_byte(0, B1)] ^
+ TD2[get_byte(0, B2)] ^ TD3[get_byte(0, B3)] ^ DK[4*j+0];
+ T1 = TD0[get_byte(1, B0)] ^ TD1[get_byte(1, B1)] ^
+ TD2[get_byte(1, B2)] ^ TD3[get_byte(1, B3)] ^ DK[4*j+1];
+ T2 = TD0[get_byte(2, B0)] ^ TD1[get_byte(2, B1)] ^
+ TD2[get_byte(2, B2)] ^ TD3[get_byte(2, B3)] ^ DK[4*j+2];
+ T3 = TD0[get_byte(3, B0)] ^ TD1[get_byte(3, B1)] ^
+ TD2[get_byte(3, B2)] ^ TD3[get_byte(3, B3)] ^ DK[4*j+3];
+ B0 = TD0[get_byte(0, T0)] ^ TD1[get_byte(0, T1)] ^
+ TD2[get_byte(0, T2)] ^ TD3[get_byte(0, T3)] ^ DK[4*j+4];
+ B1 = TD0[get_byte(1, T0)] ^ TD1[get_byte(1, T1)] ^
+ TD2[get_byte(1, T2)] ^ TD3[get_byte(1, T3)] ^ DK[4*j+5];
+ B2 = TD0[get_byte(2, T0)] ^ TD1[get_byte(2, T1)] ^
+ TD2[get_byte(2, T2)] ^ TD3[get_byte(2, T3)] ^ DK[4*j+6];
+ B3 = TD0[get_byte(3, T0)] ^ TD1[get_byte(3, T1)] ^
+ TD2[get_byte(3, T2)] ^ TD3[get_byte(3, T3)] ^ DK[4*j+7];
+ }
+ out[ 0] = SD[get_byte(0, B0)] ^ MD[16];
+ out[ 1] = SD[get_byte(0, B1)] ^ MD[17];
+ out[ 2] = SD[get_byte(0, B2)] ^ MD[18];
+ out[ 3] = SD[get_byte(0, B3)] ^ MD[19];
+ out[ 4] = SD[get_byte(1, B0)] ^ MD[20];
+ out[ 5] = SD[get_byte(1, B1)] ^ MD[21];
+ out[ 6] = SD[get_byte(1, B2)] ^ MD[22];
+ out[ 7] = SD[get_byte(1, B3)] ^ MD[23];
+ out[ 8] = SD[get_byte(2, B0)] ^ MD[24];
+ out[ 9] = SD[get_byte(2, B1)] ^ MD[25];
+ out[10] = SD[get_byte(2, B2)] ^ MD[26];
+ out[11] = SD[get_byte(2, B3)] ^ MD[27];
+ out[12] = SD[get_byte(3, B0)] ^ MD[28];
+ out[13] = SD[get_byte(3, B1)] ^ MD[29];
+ out[14] = SD[get_byte(3, B2)] ^ MD[30];
+ out[15] = SD[get_byte(3, B3)] ^ MD[31];
+ }
+
+/*************************************************
+* Square Key Schedule *
+*************************************************/
+void Square::key(const byte key[], u32bit)
+ {
+ SecureBuffer<u32bit, 36> XEK, XDK;
+ for(u32bit j = 0; j != 4; ++j)
+ XEK[j] = load_be<u32bit>(key, j);
+ for(u32bit j = 0; j != 8; ++j)
+ {
+ XEK[4*j+4] = XEK[4*j ] ^ rotate_left(XEK[4*j+3], 8) ^ (0x01000000 << j);
+ XEK[4*j+5] = XEK[4*j+1] ^ XEK[4*j+4];
+ XEK[4*j+6] = XEK[4*j+2] ^ XEK[4*j+5];
+ XEK[4*j+7] = XEK[4*j+3] ^ XEK[4*j+6];
+ XDK.copy(28 - 4*j, XEK + 4*(j+1), 4);
+ transform(XEK + 4*j);
+ }
+ for(u32bit j = 0; j != 4; ++j)
+ for(u32bit k = 0; k != 4; ++k)
+ {
+ ME[4*j+k ] = get_byte(k, XEK[j ]);
+ ME[4*j+k+16] = get_byte(k, XEK[j+32]);
+ MD[4*j+k ] = get_byte(k, XDK[j ]);
+ MD[4*j+k+16] = get_byte(k, XEK[j ]);
+ }
+ EK.copy(XEK + 4, 28);
+ DK.copy(XDK + 4, 28);
+ }
+
+/*************************************************
+* Square's Inverse Linear Transformation *
+*************************************************/
+void Square::transform(u32bit round_key[4])
+ {
+ static const byte G[4][4] = {
+ { 0x02, 0x01, 0x01, 0x03 },
+ { 0x03, 0x02, 0x01, 0x01 },
+ { 0x01, 0x03, 0x02, 0x01 },
+ { 0x01, 0x01, 0x03, 0x02 } };
+
+ for(u32bit j = 0; j != 4; ++j)
+ {
+ SecureBuffer<byte, 4> A, B;
+
+ store_be(round_key[j], A);
+
+ for(u32bit k = 0; k != 4; ++k)
+ for(u32bit l = 0; l != 4; ++l)
+ {
+ const byte a = A[l];
+ const byte b = G[l][k];
+
+ if(a && b)
+ B[k] ^= ALog[(Log[a] + Log[b]) % 255];
+ }
+
+ round_key[j] = load_be<u32bit>(B.begin(), 0);
+ }
+ }
+
+/*************************************************
+* Clear memory of sensitive data *
+*************************************************/
+void Square::clear() throw()
+ {
+ EK.clear();
+ DK.clear();
+ ME.clear();
+ MD.clear();
+ }
+
+}