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@@ -14,12 +14,21 @@ func p1(X uint32) uint32 { |
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return X ^ rotl32(15, X) ^ rotl32(23, X) |
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} |
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func ff1(X uint32, Y uint32, Z uint32) uint32 { |
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return (X & Y) | ((X | Y) & Z) |
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// Choose bitwise between A or B controlled by C (gg1). A if C=1 otherwise B |
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// Optimized as per, "Hackers Delight" (7-1, MUX operation), can be used |
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// to reduce number of operations. |
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func ch(M uint32, A uint32, B uint32) uint32 { |
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return ((A ^ B) & M) ^ B |
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} |
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func gg1(X uint32, Y uint32, Z uint32) uint32 { |
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return (X & Y) ^ ((^X) & Z) // Can be also (Z ^ (X & (Y ^ Z))) |
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// Majority function (ff1) - takes the majority value as the final result. If two |
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// or three of the variables are 1, then the result is 1, otherwise 0. |
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func maj(X uint32, Y uint32, Z uint32) uint32 { |
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// Y^Z works as a mask. If mask is 0, then majority is dictated by |
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// value of either Y or Z (doesn't matter, as they are the same, but we |
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// don't know if result is 0 or 1). Otherwise Y!=Z and results is |
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// going to dicated by X. |
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return ch(Y^Z, X, Y) |
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} |
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func r1( |
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@@ -43,8 +52,8 @@ func r2( |
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A12 := rotl32(12, A) |
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SS1 := rotl32(7, A12+E+TJ) |
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TT1 := ff1(A, *B, C) + *D + (SS1 ^ A12) + Wj |
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TT2 := gg1(E, *F, G) + *H + SS1 + Wi |
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TT1 := maj(A, *B, C) + *D + (SS1 ^ A12) + Wj |
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TT2 := ch(E, *F, G) + *H + SS1 + Wi |
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*B = rotl32(9, *B) |
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*D = TT1 |
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