| # A kind of clone of dc geared towards binary operations. |
| # by Paolo Bonzini |
| # |
| # commands available: |
| # conversion commands |
| # b convert decimal to binary |
| # d convert binary to decimal |
| # |
| # arithmetic commands |
| # < shift left binary by decimal number of bits (11 3< gives 11000) |
| # > shift right binary by decimal number of bits (1011 2> gives 10) |
| # & binary AND (between two binary operands) |
| # | binary OR (between two binary operands) |
| # ^ binary XOR (between two binary operands) |
| # ~ binary NOT (between one binary operand) |
| # |
| # stack manipulation commands |
| # c clear stack |
| # P pop stack top |
| # D duplicate stack top |
| # x exchange top two elements |
| # r rotate stack counter-clockwise (second element becomes first) |
| # R rotate stack clockwise (last element becomes first) |
| # |
| # other commands |
| # l print stack (stack top is first) |
| # p print stack top |
| # q quit, print stack top if any (cq is quiet quit) |
| # |
| # The only shortcoming is that you'd better not attempt conversions of |
| # values above 1000 or so. |
| # |
| # This version keeps the stack in hold space and the command in pattern |
| # space; it is the fastest one (though the gap with binary3.sed is small). |
| # -------------------------------------------------------------------------- |
| # This was actually used in a one-disk distribution of Linux to compute |
| # netmasks as follows (1 parameter => compute netmask e.g. 24 becomes |
| # 255.255.255.0; 2 parameters => given host address and netmask compute |
| # network and broadcast addresses): |
| # |
| # if [ $# = 1 ]; then |
| # OUTPUT='$1.$2.$3.$4' |
| # set 255.255.255.255 $1 |
| # else |
| # OUTPUT='$1.$2.$3.$4 $5.$6.$7.$8' |
| # fi |
| # |
| # if [ `expr $2 : ".*\\."` -gt 0 ]; then |
| # MASK="$2 br b8<r b16<r b24< R|R|R|" |
| # else |
| # MASK="$2b 31b ^d D |
| # 11111111111111111111111111111111 x>1> x<1<" |
| # fi |
| # |
| # set `echo "$1 br b8<r b16<r b24< R|R|R| D # Load address |
| # $MASK D ~r # Load mask |
| # |
| # & DDD 24>dpP 16>11111111& dpP 8>11111111& dpP 11111111& dpP |
| # | DDD 24>dpP 16>11111111& dpP 8>11111111& dpP 11111111& dpP |
| # " | sed -f binary.sed` |
| # |
| # eval echo $OUTPUT |
| # -------------------------------------------------------------------------- |
| |
| :cmd |
| s/^[\n\t ]*// |
| s/^#.*// |
| /^$/ { |
| $b quit |
| N |
| t cmd |
| } |
| /^[0-9][0-9]*/ { |
| G |
| h |
| s/^[0-9][0-9]* *\([^\n]*\).*/\1/ |
| x |
| s/^\([0-9][0-9]*\)[^\n]*/\1/ |
| x |
| t cmd |
| } |
| |
| /^[^DPxrRcplqbd&|^~<>]/b bad |
| |
| /^D/ { |
| x |
| s/^[^\n]*\n/&&/ |
| } |
| /^P/ { |
| x |
| s/^[^\n]*\n// |
| } |
| /^x/ { |
| x |
| s/^\([^\n]*\n\)\([^\n]*\n\)/\2\1/ |
| } |
| /^r/ { |
| x |
| s/^\([^\n]*\n\)\(.*\)/\2\1/ |
| } |
| /^R/ { |
| x |
| s/^\(.*\n\)\([^\n]*\n\)/\2\1/ |
| } |
| /^c/ { |
| x |
| s/.*// |
| } |
| /^p/ { |
| x |
| P |
| } |
| |
| /^l/ { |
| x |
| p |
| } |
| |
| /^q/ { |
| :quit |
| x |
| /./P |
| d |
| } |
| |
| /^b/ { |
| # Decimal to binary via analog form |
| x |
| s/^\([^\n]*\)/-&;9876543210aaaaaaaaa/ |
| :d2bloop1 |
| s/\(a*\)-\(.\)\([^;]*;[0-9]*\2.\{9\}\(a*\)\)/\1\1\1\1\1\1\1\1\1\1\4-\3/ |
| t d2bloop1 |
| s/-;9876543210aaaaaaaaa/;a01!/ |
| :d2bloop2 |
| s/\(a*\)\1\(a\{0,1\}\)\(;\2.\(.\)[^!]*!\)/\1\3\4/ |
| /^a/b d2bloop2 |
| s/[^!]*!// |
| } |
| |
| /^d/ { |
| # Binary to decimal via analog form |
| x |
| s/^\([^\n]*\)/-&;10a/ |
| :b2dloop1 |
| s/\(a*\)-\(.\)\([^;]*;[0-9]*\2.\(a*\)\)/\1\1\4-\3/ |
| t b2dloop1 |
| s/-;10a/;aaaaaaaaa0123456789!/ |
| :b2dloop2 |
| s/\(a*\)\1\1\1\1\1\1\1\1\1\(a\{0,9\}\)\(;\2.\{9\}\(.\)[^!]*!\)/\1\3\4/ |
| /^a/b b2dloop2 |
| s/[^!]*!// |
| } |
| |
| /^&/ { |
| # Binary AND |
| x |
| s/\([^\n]*\)\n\([^\n]*\)/-\1-\2-111 01000/ |
| :andloop |
| s/\([^-]*\)-\([^-]*\)\([^-]\)-\([^-]*\)\([^-]\)-\([01 ]*\3\5\([01]\)\)/\7\1-\2-\4-\6/ |
| t andloop |
| s/^0*\([^-]*\)-[^\n]*/\1/ |
| s/^\n/0&/ |
| } |
| |
| /^\^/ { |
| # Binary XOR |
| x |
| s/\([^\n]*\)\n\([^\n]*\)/-\1-\2-000 01101/ |
| b orloop |
| } |
| |
| /^|/ { |
| # Binary OR |
| x |
| s/\([^\n]*\)\n\([^\n]*\)/-\1-\2-000 10111/ |
| :orloop |
| s/\([^-]*\)-\([^-]*\)\([^-]\)-\([^-]*\)\([^-]\)-\([01 ]*\3\5\([01]\)\)/\7\1-\2-\4-\6/ |
| t orloop |
| s/\([^-]*\)-\([^-]*\)-\([^-]*\)-[^\n]*/\2\3\1/ |
| } |
| |
| /^~/ { |
| # Binary NOT |
| x |
| s/^\(.\)\([^\n]*\n\)/\1-010-\2/ |
| :notloop |
| s/\(.\)-0\{0,1\}\1\(.\)0\{0,1\}-\([01\n]\)/\2\3-010-/ |
| t notloop |
| |
| # If result is 00001..., \3 does not match (it looks for -10) and we just |
| # remove the table and leading zeros. If result is 0000...0, \3 matches |
| # (it looks for -0), \4 is a zero and we leave a lone zero as top of the |
| # stack. |
| |
| s/0*\(1\{0,1\}\)\([^-]*\)-\(\1\(0\)\)\{0,1\}[^-]*-/\4\1\2/ |
| } |
| |
| /^</ { |
| # Left shift, convert to analog and add a binary digit for each analog digit |
| x |
| s/^\([^\n]*\)/-&;9876543210aaaaaaaaa/ |
| :lshloop1 |
| s/\(a*\)-\(.\)\([^;]*;[0-9]*\2.\{9\}\(a*\)\)/\1\1\1\1\1\1\1\1\1\1\4-\3/ |
| t lshloop1 |
| s/^\(a*\)-;9876543210aaaaaaaaa\n\([^\n]*\)/\2\1/ |
| s/a/0/g |
| } |
| |
| /^>/ { |
| # Right shift, convert to analog and remove a binary digit for each analog digit |
| x |
| s/^\([^\n]*\)/-&;9876543210aaaaaaaaa/ |
| :rshloop1 |
| s/\(a*\)-\(.\)\([^;]*;[0-9]*\2.\{9\}\(a*\)\)/\1\1\1\1\1\1\1\1\1\1\4-\3/ |
| t rshloop1 |
| s/^\(a*\)-;9876543210aaaaaaaaa\n\([^\n]*\)/\2\1/ |
| :rshloop2 |
| s/.a// |
| s/^aa*/0/ |
| /a\n/b rshloop2 |
| } |
| |
| x |
| :bad |
| s/^.// |
| tcmd |
