132 lines
5.3 KiB
Sed
132 lines
5.3 KiB
Sed
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# Common bitwise operations using regular expressions
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#
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# Copyright (C) 2018 Mike Gerwitz
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#
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# This program is free software: you can redistribute it and/or modify
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# it under the terms of the GNU General Public License as published by
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# the Free Software Foundation, either version 3 of the License, or
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# (at your option) any later version.
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#
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# This program is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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# GNU General Public License for more details.
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#
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# You should have received a copy of the GNU General Public License
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# along with this program. If not, see <http://www.gnu.org/licenses/>.
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#
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# This script implements the most common unary and binary bitwise operations
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# on 8-bit (1-byte) values. The format of the input is:
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#
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# C BYTE[ BYTE]
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#
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# Where C is one of the commands defined below and, BYTE is an 8-bit value
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# represented by 0s and 1s. The square brackets denote an optional
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# value---some operators are unary (require one argument) and others are
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# binary (require two arguments).
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#
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# For example:
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#
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# ^ 11100001 11110000
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#
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# will XOR the two bytes to produce `00010001'. Whereas:
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#
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# < 11111111
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#
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# will perform a logical left shift to produce `11111110'.
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#
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# The regexes below all follow common patterns. To make that pattern clear,
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# some regexes may do useless things (e.g. `.\{0\}') so that they are
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# well-aligned.
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#
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# Transformations use `:' and `.' as intermediate values to represent 1 and
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# 0 respectively. This is necessary to ensure that one regex does not
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# operate on the replacement of another (for example, NOT replacing 0 with 1
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# and then replacing 1 with 0 immediately thereafter; or the dual-use of OR
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# with XOR).
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#
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# Below, A denotes the first byte and B the second. The term ``set'' refers
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# to a bit with a value of 1 and ``clear'' a value of 0.
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#
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# (This could have been implemented more concisely by branching in a loop,
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# but I want to be clear that this is being done with vanilla replacements
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# using regexes and that such loops are not needed.)
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#
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# Note that all regexes operate at a fixed position; this makes them
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# suitable as a template for general-purpose use in larger pattern spaces.
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##
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# Bitwise AND (&). If the value of the bit in A is already clear, then we
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# need not do anything, because the result will always be clear. Otherwise,
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# we need only clear the bit if the respective bit of B is clear.
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s/^\(& .\{0\}\)1\(.\{8\}0\)/\1.\2/
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s/^\(& .\{1\}\)1\(.\{8\}0\)/\1.\2/
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s/^\(& .\{2\}\)1\(.\{8\}0\)/\1.\2/
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s/^\(& .\{3\}\)1\(.\{8\}0\)/\1.\2/
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s/^\(& .\{4\}\)1\(.\{8\}0\)/\1.\2/
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s/^\(& .\{5\}\)1\(.\{8\}0\)/\1.\2/
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s/^\(& .\{6\}\)1\(.\{8\}0\)/\1.\2/
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s/^\(& .\{7\}\)1\(.\{8\}0\)/\1.\2/
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# Bitwise OR (|) or XOR (^). This logic is shared for both operations (see
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# XOR below). If the bit in A is already set, then we need not do anything,
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# because the result will always be set. Otherwise, we need only set the bit
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# if the respective bit in B is set.
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s/^\([|^] .\{0\}\)0\(.\{8\}1\)/\1:\2/
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s/^\([|^] .\{1\}\)0\(.\{8\}1\)/\1:\2/
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s/^\([|^] .\{2\}\)0\(.\{8\}1\)/\1:\2/
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s/^\([|^] .\{3\}\)0\(.\{8\}1\)/\1:\2/
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s/^\([|^] .\{4\}\)0\(.\{8\}1\)/\1:\2/
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s/^\([|^] .\{5\}\)0\(.\{8\}1\)/\1:\2/
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s/^\([|^] .\{6\}\)0\(.\{8\}1\)/\1:\2/
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s/^\([|^] .\{7\}\)0\(.\{8\}1\)/\1:\2/
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# Bitwise XOR (^). We must perform two steps: first, if a bit in A is clear,
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# then it should be set if the respective bit in B is set; this logic
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# is handled above in OR. Otherwise, if A is set, then it should be cleared
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# if the respective bit in B is also set.
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s/^\(\^ .\{0\}\)1\(.\{8\}1\)/\1.\2/
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s/^\(\^ .\{1\}\)1\(.\{8\}1\)/\1.\2/
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s/^\(\^ .\{2\}\)1\(.\{8\}1\)/\1.\2/
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s/^\(\^ .\{3\}\)1\(.\{8\}1\)/\1.\2/
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s/^\(\^ .\{4\}\)1\(.\{8\}1\)/\1.\2/
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s/^\(\^ .\{5\}\)1\(.\{8\}1\)/\1.\2/
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s/^\(\^ .\{6\}\)1\(.\{8\}1\)/\1.\2/
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s/^\(\^ .\{7\}\)1\(.\{8\}1\)/\1.\2/
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# Bitwise NOT (~). This is a unary operation. A bit in A is set if it is
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# clear and vice-versa.
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s/^\(~ .\{0\}\)1/\1./; s/^\(~ .\{0\}\)0/\1:/;
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s/^\(~ .\{1\}\)1/\1./; s/^\(~ .\{1\}\)0/\1:/;
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s/^\(~ .\{2\}\)1/\1./; s/^\(~ .\{2\}\)0/\1:/;
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s/^\(~ .\{3\}\)1/\1./; s/^\(~ .\{3\}\)0/\1:/;
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s/^\(~ .\{4\}\)1/\1./; s/^\(~ .\{4\}\)0/\1:/;
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s/^\(~ .\{5\}\)1/\1./; s/^\(~ .\{5\}\)0/\1:/;
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s/^\(~ .\{6\}\)1/\1./; s/^\(~ .\{6\}\)0/\1:/;
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s/^\(~ .\{7\}\)1/\1./; s/^\(~ .\{7\}\)0/\1:/;
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# Logical left shift (<), right shift (>). For left shifts, the first bit
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# in A is discarded and a 0 is added to the end. For right shifts, the last
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# bit of A is discarded and a 0 is added to the beginning.
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s/^< .\(.\{7\}\)/< \10/
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s/^> \(.\{7\}\)./> 0\1/
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# Arithmetic right shift (a). Similar to a logical right shift, except that
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# instead of shifting in a clear bit, the sign is maintained (in a two's
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# complement system, the most significant bit is the sign bit). An
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# arithmetic left shit is the same as a logical left shift, so we do not
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# provide such an operator.
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s/^a \(.\)\(.\{6\}\)/a \1\1\2/
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# Circular shift (rot8) left (r), right (R). Rather than shifting in a
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# clear bit, the bit that is shifted off of the end is re-added to the other
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# end. This is also called a rotation.
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s/^r \(.\)\(.\{7\}\)/r \2\1/
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s/^R \(.\{7\}\)\(.\)/R \2\1/
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# Prepare the final output by discarding the command and second byte, and
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# then replacing the temporary values `:' and `.' with their respective bits.
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s/^. \(.\{8\}\).*/\1/
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s/:/1/g; s/\./0/g
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