mirror of
https://github.com/GaloisInc/cryptol.git
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44f8bcd310
Note: this is actually Cryptol 1 code. We should port it. I've started the process, but don't have a complete port yet.
132 lines
4.5 KiB
Plaintext
132 lines
4.5 KiB
Plaintext
/*
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* Copyright (c) 2013 David Lazar <lazard@galois.com>
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*
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* Permission is hereby granted, free of charge, to any person obtaining a copy
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* of this software and associated documentation files (the "Software"), to deal
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* in the Software without restriction, including without limitation the rights
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* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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* copies of the Software, and to permit persons to whom the Software is
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* furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in
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* all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
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* THE SOFTWARE.
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*/
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// Specification of the Keccak (SHA-3) hash function
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// Author: David Lazar
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SHA_3_224 M = take(224, Keccak `{r = 1152, c = 448} M);
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SHA_3_256 M = take(256, Keccak `{r = 1088, c = 512} M);
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SHA_3_384 M = take(384, Keccak `{r = 832, c = 768} M);
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SHA_3_512 M = take(512, Keccak `{r = 576, c = 1024} M);
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Keccak : {r c m}
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( fin r, fin c, fin m
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, r >= 0, c >= 0, m >= 0
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, fin ((r + m + 1) / r)
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, (r + m + 1) / r >= 0
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, (r + m + 1) / r * r - m >= 2
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, 64 >= (r + c) / 25
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, 25 * ((r + c) / 25) >= r
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) => [m] -> [inf];
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Keccak M = squeeze `{r = r} (absorb `{w = (r + c) / 25} Ps)
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where Ps = pad `{r = r} M;
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squeeze : {r w} (fin r, fin w, 64 >= w, r >= 0, 25 * w >= r) => [5][5][w] -> [inf];
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squeeze A = take(`r, flatten A) # squeeze `{r = r} (Keccak_f A);
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absorb : {r w n} (fin r, fin w, fin n, 64 >= w, 25 * w >= r) => [n][r] -> [5][5][w];
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absorb Ps = as ! 0
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where {
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as = [zero] # [| Keccak_f `{w = w} (s ^ (unflatten p)) || s <- as || p <- Ps |];
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};
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pad : {r m n}
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( fin r, fin m, fin n
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, n == (r + m + 1) / r
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, r * n - m >= 2
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) => [m] -> [n][r];
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pad M = split (M # [True] # zero # [True]);
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Keccak_f : {b w} (fin w, b == 25 * w, 64 >= w) => [5][5][w] -> [5][5][w];
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Keccak_f A = rounds ! 0
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where {
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rounds = [A] # [| Round RC A || RC <- RCs `{w = w} || A <- rounds |];
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};
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Round : {w} (fin w) => [5][5][w] -> [5][5][w] -> [5][5][w];
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Round RC A = ι RC (χ (π (ρ (θ A))));
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θ : {w} (fin w) => [5][5][w] -> [5][5][w];
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θ A = A'
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where {
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C = [| xor a || a <- A |];
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D = [| C @ x ^ (C @ y <<< 1)
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|| x <- [0 .. 4] >>> 1
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|| y <- [0 .. 4] <<< 1
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|];
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A' = [| [| a ^ (D @ x) || a <- A @ x |] || x <- [0 .. 4] |];
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};
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ρ : {w} (fin w) => [5][5][w] -> [5][5][w];
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ρ A = groupBy(5, [| a <<< r || a <- join(A) || r <- R |])
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where R = [00 36 03 41 18
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01 44 10 45 02
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62 06 43 15 61
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28 55 25 21 56
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27 20 39 08 14];
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π : {w} (fin w) => [5][5][w] -> [5][5][w];
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π A = groupBy(5, [| A @ ((x + (3:[8]) * y) % 5) @ x
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|| x <- [0..4], y <- [0..4]
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|]);
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χ : {w} (fin w) => [5][5][w] -> [5][5][w];
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χ A = groupBy(5, [| (A @ x @ y) ^ (~ A @ ((x + 1) % 5) @ y
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& A @ ((x + 2) % 5) @ y)
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|| x <- [0..4], y <- [0..4]
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|]);
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ι : {w} (fin w) => [5][5][w] -> [5][5][w] -> [5][5][w];
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ι RC A = A ^ RC;
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RCs : {w n} (fin w, fin n, 24 >= n, n == 12 + 2 * (lg2 w)) => [n][5][5][w];
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RCs = [| [([(RC @@ [0 .. `(w - 1)])] # zero)] # zero
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|| RC <- RCs64
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|| _ <- [1 .. `n]
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|];
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RCs64 : [24][64];
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RCs64 = join (transpose [
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[0x0000000000000001 0x000000008000808B]
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[0x0000000000008082 0x800000000000008B]
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[0x800000000000808A 0x8000000000008089]
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[0x8000000080008000 0x8000000000008003]
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[0x000000000000808B 0x8000000000008002]
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[0x0000000080000001 0x8000000000000080]
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[0x8000000080008081 0x000000000000800A]
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[0x8000000000008009 0x800000008000000A]
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[0x000000000000008A 0x8000000080008081]
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[0x0000000000000088 0x8000000000008080]
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[0x0000000080008009 0x0000000080000001]
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[0x000000008000000A 0x8000000080008008]
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]);
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unflatten : {r w} (fin r, 25*w >= r) => [r] -> [5][5][w];
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unflatten p = transpose(groupBy(5, groupBy(`w, p # zero)));
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flatten : {r w} [5][5][w] -> [5 * 5 * w];
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flatten A = join (join (transpose A));
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xor : {a b} (fin a) => [a][b] -> [b];
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xor xs = xors ! 0
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where xors = [0] # [| x ^ z || x <- xs || z <- xors |];
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