#! /usr/local/bin/perl # NCR 53c810 script assembler # Sponsored by # iX Multiuser Multitasking Magazine # # Copyright 1993, Drew Eckhardt # Visionary Computing # (Unix and Linux consulting and custom programming) # drew@Colorado.EDU # +1 (303) 786-7975 # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 2 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program; if not, write to the Free Software # Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. # # TolerANT and SCSI SCRIPTS are registered trademarks of NCR Corporation. # # # Basically, I follow the NCR syntax documented in the NCR53c710 # Programmer's guide, with the new instructions, registers, etc. # from the NCR53c810. # # Differences between this assembler and NCR's are that # 1. PASS, REL (data, JUMPs work fine), and the option to start a new # script, are unimplemented, since I didn't use them in my scripts. # # 2. I also emit a script_u.h file, which will undefine all of # the A_*, E_*, etc. symbols defined in the script. This # makes including multiple scripts in one program easier # # 3. This is a single pass assembler, which only emits # .h files. # # XXX - set these with command line options $debug = 0; # Print general debugging messages $debug_external = 0; # Print external/forward reference messages $list_in_array = 1; # Emit original SCRIPTS assembler in comments in # script.h $prefix = ''; # define all arrays having this prefix so we # don't have name space collisions after # assembling this file in different ways for # different host adapters # Constants # Table of the SCSI phase encodings %scsi_phases = ( 'DATA_OUT', 0x00_00_00_00, 'DATA_IN', 0x01_00_00_00, 'CMD', 0x02_00_00_00, 'STATUS', 0x03_00_00_00, 'MSG_OUT', 0x06_00_00_00, 'MSG_IN', 0x07_00_00_00 ); # XXX - replace references to the *_810 constants with general constants # assigned at compile time based on chip type. # Table of operator encodings # XXX - NCR53c710 only implements # move (nop) = 0x00_00_00_00 # or = 0x02_00_00_00 # and = 0x04_00_00_00 # add = 0x06_00_00_00 %operators_810 = ( 'SHL', 0x01_00_00_00, '|', 0x02_00_00_00, 'OR', 0x02_00_00_00, 'XOR', 0x03_00_00_00, '&', 0x04_00_00_00, 'AND', 0x04_00_00_00, 'SHR', 0x05_00_00_00, # Note : low bit of the operator bit should be set for add with # carry. '+', 0x06_00_00_00 ); # Table of register addresses %registers_810 = ( 'SCNTL0', 0, 'SCNTL1', 1, 'SCNTL2', 2, 'SCNTL3', 3, 'SCID', 4, 'SXFER', 5, 'SDID', 6, 'GPREG', 7, 'SFBR', 8, 'SOCL', 9, 'SSID', 10, 'SBCL', 11, 'DSTAT', 12, 'SSTAT0', 13, 'SSTAT1', 14, 'SSTAT2', 15, 'DSA0', 16, 'DSA1', 17, 'DSA2', 18, 'DSA3', 19, 'ISTAT', 20, 'CTEST0', 24, 'CTEST1', 25, 'CTEST2', 26, 'CTEST3', 27, 'TEMP0', 28, 'TEMP1', 29, 'TEMP2', 30, 'TEMP3', 31, 'DFIFO', 32, 'CTEST4', 33, 'CTEST5', 34, 'CTEST6', 35, 'DBC0', 36, 'DBC1', 37, 'DBC2', 38, 'DCMD', 39, 'DNAD0', 40, 'DNAD1', 41, 'DNAD2', 42, 'DNAD3', 43, 'DSP0', 44, 'DSP1', 45, 'DSP2', 46, 'DSP3', 47, 'DSPS0', 48, 'DSPS1', 49, 'DSPS2', 50, 'DSPS3', 51, 'SCRATCH0', 52, 'SCRATCH1', 53, 'SCRATCH2', 54, 'SCRATCH3', 55, 'SCRATCHA0', 52, 'SCRATCHA1', 53, 'SCRATCHA2', 54, 'SCRATCHA3', 55, 'DMODE', 56, 'DIEN', 57, 'DWT', 58, 'DCNTL', 59, 'ADDER0', 60, 'ADDER1', 61, 'ADDER2', 62, 'ADDER3', 63, 'SIEN0', 64, 'SIEN1', 65, 'SIST0', 66, 'SIST1', 67, 'SLPAR', 68, 'MACNTL', 70, 'GPCNTL', 71, 'STIME0', 72, 'STIME1', 73, 'RESPID', 74, 'STEST0', 76, 'STEST1', 77, 'STEST2', 78, 'STEST3', 79, 'SIDL', 80, 'SODL', 84, 'SBDL', 88, 'SCRATCHB0', 92, 'SCRATCHB1', 93, 'SCRATCHB2', 94, 'SCRATCHB3', 95 ); # Parsing regular expressions $identifier = '[A-Za-z_][A-Za-z_0-9]*'; $decnum = '-?\\d+'; $hexnum = '0[xX][0-9A-Fa-f]+'; $constant = "$hexnum|$decnum"; # yucky - since we can't control grouping of # $constant, we need to # expand out each alternative for $value. $value = "$identifier|$identifier\\s*[+\-]\\s*$decnum|". "$identifier\\s*[+-]\s*$hexnum|$constant"; print STDERR "value regex = $value\n" if ($debug); $phase = join ('|', keys %scsi_phases); print STDERR "phase regex = $phase\n" if ($debug); $register = join ('|', keys %registers_810); # yucky - since %operators_810 includes meta-characters which must # be escaped, I can't use the join() trick I used for the register # regex $operator = '\||OR|AND|XOR|\&|\+'; # Global variables %symbol_values = (%registers_810) ; # Traditional symbol table %symbol_references = () ; # Table of symbol references, where # the index is the symbol name, # and the contents a white space # delimited list of address,size # tuples where size is in bytes. @code = (); # Array of 32 bit words for SIOP @entry = (); # Array of entry point names @label = (); # Array of label names @absolute = (); # Array of absolute names @relative = (); # Array of relative names @external = (); # Array of external names $address = 0; # Address of current instruction $lineno = 0; # Line number we are parsing $output = 'script.h'; # Output file $outputu = 'scriptu.h'; # &patch ($address, $offset, $length, $value) patches $code[$address] # so that the $length bytes at $offset have $value added to # them. @inverted_masks = (0x00_00_00_00, 0x00_00_00_ff, 0x00_00_ff_ff, 0x00_ff_ff_ff, 0xff_ff_ff_ff); sub patch { local ($address, $offset, $length, $value) = @_; if ($debug) { print STDERR "Patching $address at offset $offset, length $length to $value\n"; printf STDERR "Old code : %08x\n", $code[$address]; } $mask = ($inverted_masks[$length] << ($offset * 8)); $code[$address] = ($code[$address] & ~$mask) | (($code[$address] & $mask) + ($value << ($offset * 8)) & $mask); printf STDERR "New code : %08x\n", $code[$address] if ($debug); } # &parse_value($value, $word, $offset, $length) where $value is # an identifier or constant, $word is the word offset relative to # $address, $offset is the starting byte within that word, and # $length is the length of the field in bytes. # # Side effects are that the bytes are combined into the @code array # relative to $address, and that the %symbol_references table is # updated as appropriate. sub parse_value { local ($value, $word, $offset, $length) = @_; local ($tmp); $symbol = ''; if ($value =~ /^REL\s*\(\s*($identifier)\s*\)\s*(.*)/i) { $relative = 'REL'; $symbol = $1; $value = $2; print STDERR "Relative reference $symbol\n" if ($debug); } elsif ($value =~ /^($identifier)\s*(.*)/) { $relative = 'ABS'; $symbol = $1; $value = $2; print STDERR "Absolute reference $symbol\n" if ($debug); } if ($symbol ne '') { print STDERR "Referencing symbol $1, length = $length in $_\n" if ($debug); $tmp = ($address + $word) * 4 + $offset; if ($symbol_references{$symbol} ne undef) { $symbol_references{$symbol} = "$symbol_references{$symbol} $relative,$tmp,$length"; } else { if (!defined($symbol_values{$symbol})) { print STDERR "forward $1\n" if ($debug_external); $forward{$symbol} = "line $lineno : $_"; } $symbol_references{$symbol} = "$relative,$tmp,$length"; } } $value = eval $value; &patch ($address + $word, $offset, $length, $value); } # &parse_conditional ($conditional) where $conditional is the conditional # clause from a transfer control instruction (RETURN, CALL, JUMP, INT). sub parse_conditional { local ($conditional) = @_; if ($conditional =~ /^\s*(IF|WHEN)\s*(.*)/i) { $if = $1; $conditional = $2; if ($if =~ /WHEN/i) { $allow_atn = 0; $code[$address] |= 0x00_01_00_00; $allow_atn = 0; print STDERR "$0 : parsed WHEN\n" if ($debug); } else { $allow_atn = 1; print STDERR "$0 : parsed IF\n" if ($debug); } } else { die "$0 : syntax error in line $lineno : $_ expected IF or WHEN "; } if ($conditional =~ /^NOT\s+(.*)$/i) { $not = 'NOT '; $other = 'OR'; $conditional = $1; print STDERR "$0 : parsed NOT\n" if ($debug); } else { $code[$address] |= 0x00_08_00_00; $not = ''; $other = 'AND' } $need_data = 0; if ($conditional =~ /^ATN\s*(.*)/i) {# die "$0 : syntax error in line $lineno : $_ WHEN conditional is incompatible with ATN " if (!$allow_atn); $code[$address] |= 0x00_02_00_00; $conditional = $1; print STDERR "$0 : parsed ATN\n" if ($debug); } elsif ($conditional =~ /^($phase)\s*(.*)/i) { $phase_index = "\U$1\E"; $p = $scsi_phases{$phase_index}; $code[$address] |= $p | 0x00_02_00_00; $conditional = $2; print STDERR "$0 : parsed phase $phase_index\n" if ($debug); } else { $other = ''; $need_data = 1; } print STDERR "Parsing conjunction, expecting $other\n" if ($debug); if ($conditional =~ /^(AND|OR)\s*(.*)/i) { $conjunction = $1; $conditional = $2; $need_data = 1; die "$0 : syntax error in line $lineno : $_ Illegal use of $1. Valid uses are ".$not."<phase> $1 data ".$not."ATN $1 data " if ($other eq ''); die "$0 : syntax error in line $lineno : $_ Illegal use of $conjunction. Valid syntaxes are NOT <phase>|ATN OR data <phase>|ATN AND data " if ($conjunction !~ /\s*$other\s*/i); print STDERR "$0 : parsed $1\n" if ($debug); } if ($need_data) { print STDERR "looking for data in $conditional\n" if ($debug); if ($conditional=~ /^($value)\s*(.*)/i) { $code[$address] |= 0x00_04_00_00; $conditional = $2; &parse_value($1, 0, 0, 1); print STDERR "$0 : parsed data\n" if ($debug); } else { die "$0 : syntax error in line $lineno : $_ expected <data>. "; } } if ($conditional =~ /^\s*,\s*(.*)/) { $conditional = $1; if ($conditional =~ /^AND\s\s*MASK\s\s*($value)\s*(.*)/i) { &parse_value ($1, 0, 1, 1); print STDERR "$0 parsed AND MASK $1\n" if ($debug); die "$0 : syntax error in line $lineno : $_ expected end of line, not \"$2\" " if ($2 ne ''); } else { die "$0 : syntax error in line $lineno : $_ expected \",AND MASK <data>\", not \"$2\" "; } } elsif ($conditional !~ /^\s*$/) { die "$0 : syntax error in line $lineno : $_ expected end of line" . (($need_data) ? " or \"AND MASK <data>\"" : "") . " not \"$conditional\" "; } } # Parse command line foreach $arg (@argv) { if ($arg =~ /^-prefix\s*=\s*([_a-zA-Z][_a-zA-Z0-9]*)$/i) { $prefix = $1 } } # Main loop while (<STDIN>) { $lineno = $lineno + 1; $list[$address] = $list[$address].$_; s/;.*$//; # Strip comments chop; # Leave new line out of error messages # Handle symbol definitions of the form label: if (/^\s*($identifier)\s*:(.*)/) { if (!defined($symbol_values{$1})) { $symbol_values{$1} = $address * 4; # Address is an index into delete $forward{$1}; # an array of longs push (@label, $1); $_ = $2; } else { die "$0 : redefinition of symbol $1 in line $lineno : $_\n"; } } # Handle symbol definitions of the form ABSOLUTE or RELATIVE identifier = # value if (/^\s*(ABSOLUTE|RELATIVE)\s+(.*)/i) { $is_absolute = $1; $rest = $2; foreach $rest (split (/\s*,\s*/, $rest)) { if ($rest =~ /^($identifier)\s*=\s*($constant)\s*$/) { local ($id, $cnst) = ($1, $2); if ($symbol_values{$id} eq undef) { $symbol_values{$id} = eval $cnst; delete $forward{$id}; if ($is_absolute =~ /ABSOLUTE/i) { push (@absolute , $id); } else { push (@relative, $id); } } else { die "$0 : redefinition of symbol $id in line $lineno : $_\n"; } } else { die "$0 : syntax error in line $lineno : $_ expected <identifier> = <value> "; } } } elsif (/^\s*EXTERNAL\s+(.*)/i) { $externals = $1; foreach $external (split (/,/,$externals)) { if ($external =~ /\s*($identifier)\s*$/) { $external = $1; push (@external, $external); delete $forward{$external}; if (defined($symbol_values{$external})) { die "$0 : redefinition of symbol $1 in line $lineno : $_\n"; } $symbol_values{$external} = $external; print STDERR "defined external $1 to $external\n" if ($debug_external); } else { die "$0 : syntax error in line $lineno : $_ expected <identifier>, got $external "; } } # Process ENTRY identifier declarations } elsif (/^\s*ENTRY\s+(.*)/i) { if ($1 =~ /^($identifier)\s*$/) { push (@entry, $1); } else { "$0 : syntax error in line $lineno : $_ expected ENTRY <identifier> "; } # Process MOVE length, address, WITH|WHEN phase instruction } elsif (/^\s*MOVE\s+(.*)/i) { $rest = $1; if ($rest =~ /^FROM\s+($value)\s*,\s*(WITH|WHEN)\s+($phase)\s*$/i) { $transfer_addr = $1; $with_when = $2; $scsi_phase = $3; print STDERR "Parsing MOVE FROM $transfer_addr, $with_when $3\n" if ($debug); $code[$address] = 0x18_00_00_00 | (($with_when =~ /WITH/i) ? 0x00_00_00_00 : 0x08_00_00_00) | $scsi_phases{$scsi_phase}; &parse_value ($transfer_addr, 1, 0, 4); $address += 2; } elsif ($rest =~ /^($value)\s*,\s*(PTR\s+|)($value)\s*,\s*(WITH|WHEN)\s+($phase)\s*$/i) { $transfer_len = $1; $ptr = $2; $transfer_addr = $3; $with_when = $4; $scsi_phase = $5; $code[$address] = (($with_when =~ /WITH/i) ? 0x00_00_00_00 : 0x08_00_00_00) | (($ptr =~ /PTR/i) ? (1 << 29) : 0) | $scsi_phases{$scsi_phase}; &parse_value ($transfer_len, 0, 0, 3); &parse_value ($transfer_addr, 1, 0, 4); $address += 2; } elsif ($rest =~ /^MEMORY\s+(.*)/i) { $rest = $1; $code[$address] = 0xc0_00_00_00; if ($rest =~ /^($value)\s*,\s*($value)\s*,\s*($value)\s*$/) { $count = $1; $source = $2; $dest = $3; print STDERR "Parsing MOVE MEMORY $count, $source, $dest\n" if ($debug); &parse_value ($count, 0, 0, 3); &parse_value ($source, 1, 0, 4); &parse_value ($dest, 2, 0, 4); printf STDERR "Move memory instruction = %08x,%08x,%08x\n", $code[$address], $code[$address+1], $code[$address +2] if ($debug); $address += 3; } else { die "$0 : syntax error in line $lineno : $_ expected <count>, <source>, <destination> " } } elsif ($1 =~ /^(.*)\s+(TO|SHL|SHR)\s+(.*)/i) { print STDERR "Parsing register to register move\n" if ($debug); $src = $1; $op = "\U$2\E"; $rest = $3; $code[$address] = 0x40_00_00_00; $force = ($op !~ /TO/i); print STDERR "Forcing register source \n" if ($force && $debug); if (!$force && $src =~ /^($register)\s+(-|$operator)\s+($value)\s*$/i) { print STDERR "register operand data8 source\n" if ($debug); $src_reg = "\U$1\E"; $op = "\U$2\E"; if ($op ne '-') { $data8 = $3; } else { die "- is not implemented yet.\n" } } elsif ($src =~ /^($register)\s*$/i) { print STDERR "register source\n" if ($debug); $src_reg = "\U$1\E"; # Encode register to register move as a register | 0 # move to register. if (!$force) { $op = '|'; } $data8 = 0; } elsif (!$force && $src =~ /^($value)\s*$/i) { print STDERR "data8 source\n" if ($debug); $src_reg = undef; $op = 'NONE'; $data8 = $1; } else { if (!$force) { die "$0 : syntax error in line $lineno : $_ expected <register> <data8> <register> <operand> <data8> "; } else { die "$0 : syntax error in line $lineno : $_ expected <register> "; } } if ($rest =~ /^($register)\s*(.*)$/i) { $dst_reg = "\U$1\E"; $rest = $2; } else { die "$0 : syntax error in $lineno : $_ expected <register>, got $rest "; } if ($rest =~ /^WITH\s+CARRY\s*(.*)/i) { $rest = $1; if ($op eq '+') { $code[$address] |= 0x01_00_00_00; } else { die "$0 : syntax error in $lineno : $_ WITH CARRY option is incompatible with the $op operator. "; } } if ($rest !~ /^\s*$/) { die "$0 : syntax error in $lineno : $_ Expected end of line, got $rest "; } print STDERR "source = $src_reg, data = $data8 , destination = $dst_reg\n" if ($debug); # Note that Move data8 to reg is encoded as a read-modify-write # instruction. if (($src_reg eq undef) || ($src_reg eq $dst_reg)) { $code[$address] |= 0x38_00_00_00 | ($registers_810{$dst_reg} << 16); } elsif ($dst_reg =~ /SFBR/i) { $code[$address] |= 0x30_00_00_00 | ($registers_810{$src_reg} << 16); } elsif ($src_reg =~ /SFBR/i) { $code[$address] |= 0x28_00_00_00 | ($registers_810{$dst_reg} << 16); } else { die "$0 : Illegal combination of registers in line $lineno : $_ Either source and destination registers must be the same, or either source or destination register must be SFBR. "; } $code[$address] |= $operators_810{$op}; &parse_value ($data8, 0, 1, 1); $code[$address] |= $operators_810{$op}; $code[$address + 1] = 0x00_00_00_00;# Reserved $address += 2; } else { die "$0 : syntax error in line $lineno : $_ expected (initiator) <length>, <address>, WHEN <phase> (target) <length>, <address>, WITH <phase> MEMORY <length>, <source>, <destination> <expression> TO <register> "; } # Process SELECT {ATN|} id, fail_address } elsif (/^\s*(SELECT|RESELECT)\s+(.*)/i) { $rest = $2; if ($rest =~ /^(ATN|)\s*($value)\s*,\s*($identifier)\s*$/i) { $atn = $1; $id = $2; $alt_addr = $3; $code[$address] = 0x40_00_00_00 | (($atn =~ /ATN/i) ? 0x01_00_00_00 : 0); $code[$address + 1] = 0x00_00_00_00; &parse_value($id, 0, 2, 1); &parse_value($alt_addr, 1, 0, 4); $address += 2; } elsif ($rest =~ /^(ATN|)\s*FROM\s+($value)\s*,\s*($identifier)\s*$/i) { $atn = $1; $addr = $2; $alt_addr = $3; $code[$address] = 0x42_00_00_00 | (($atn =~ /ATN/i) ? 0x01_00_00_00 : 0); $code[$address + 1] = 0x00_00_00_00; &parse_value($addr, 0, 0, 3); &parse_value($alt_addr, 1, 0, 4); $address += 2; } else { die "$0 : syntax error in line $lineno : $_ expected SELECT id, alternate_address or SELECT FROM address, alternate_address or RESELECT id, alternate_address or RESELECT FROM address, alternate_address "; } } elsif (/^\s*WAIT\s+(.*)/i) { $rest = $1; print STDERR "Parsing WAIT $rest\n" if ($debug); if ($rest =~ /^DISCONNECT\s*$/i) { $code[$address] = 0x48_00_00_00; $code[$address + 1] = 0x00_00_00_00; $address += 2; } elsif ($rest =~ /^(RESELECT|SELECT)\s+($identifier)\s*$/i) { $alt_addr = $2; $code[$address] = 0x50_00_00_00; &parse_value ($alt_addr, 1, 0, 4); $address += 2; } else { die "$0 : syntax error in line $lineno : $_ expected (initiator) WAIT DISCONNECT or (initiator) WAIT RESELECT alternate_address or (target) WAIT SELECT alternate_address "; } # Handle SET and CLEAR instructions. Note that we should also do something # with this syntax to set target mode. } elsif (/^\s*(SET|CLEAR)\s+(.*)/i) { $set = $1; $list = $2; $code[$address] = ($set =~ /SET/i) ? 0x58_00_00_00 : 0x60_00_00_00; foreach $arg (split (/\s+AND\s+/i,$list)) { if ($arg =~ /ATN/i) { $code[$address] |= 0x00_00_00_08; } elsif ($arg =~ /ACK/i) { $code[$address] |= 0x00_00_00_40; } elsif ($arg =~ /TARGET/i) { $code[$address] |= 0x00_00_02_00; } elsif ($arg =~ /CARRY/i) { $code[$address] |= 0x00_00_04_00; } else { die "$0 : syntax error in line $lineno : $_ expected $set followed by a AND delimited list of one or more strings from the list ACK, ATN, CARRY, TARGET. "; } } $code[$address + 1] = 0x00_00_00_00; $address += 2; } elsif (/^\s*(JUMP|CALL|INT)\s+(.*)/i) { $instruction = $1; $rest = $2; if ($instruction =~ /JUMP/i) { $code[$address] = 0x80_00_00_00; } elsif ($instruction =~ /CALL/i) { $code[$address] = 0x88_00_00_00; } else { $code[$address] = 0x98_00_00_00; } print STDERR "parsing JUMP, rest = $rest\n" if ($debug); # Relative jump. if ($rest =~ /^(REL\s*\(\s*$identifier\s*\))\s*(.*)/i) { $addr = $1; $rest = $2; print STDERR "parsing JUMP REL, addr = $addr, rest = $rest\n" if ($debug); $code[$address] |= 0x00_80_00_00; &parse_value($addr, 1, 0, 4); # Absolute jump, requires no more gunk } elsif ($rest =~ /^($value)\s*(.*)/) { $addr = $1; $rest = $2; &parse_value($addr, 1, 0, 4); } else { die "$0 : syntax error in line $lineno : $_ expected <address> or REL (address) "; } if ($rest =~ /^,\s*(.*)/) { &parse_conditional($1); } elsif ($rest =~ /^\s*$/) { $code[$address] |= (1 << 19); } else { die "$0 : syntax error in line $lineno : $_ expected , <conditional> or end of line, got $1 "; } $address += 2; } elsif (/^\s*(RETURN|INTFLY)\s*(.*)/i) { $instruction = $1; $conditional = $2; print STDERR "Parsing $instruction\n" if ($debug); $code[$address] = ($instruction =~ /RETURN/i) ? 0x90_00_00_00 : 0x98_10_00_00; if ($conditional =~ /^,\s*(.*)/) { $conditional = $1; &parse_conditional ($conditional); } elsif ($conditional !~ /^\s*$/) { die "$0 : syntax error in line $lineno : $_ expected , <conditional> "; } else { $code[$address] |= 0x00_08_00_00; } $code[$address + 1] = 0x00_00_00_00; $address += 2; } elsif (/^\s*DISCONNECT\s*$/) { $code[$address] = 0x48_00_00_00; $code[$address + 1] = 0x00_00_00_00; $address += 2; # I'm not sure that I should be including this extension, but # what the hell? } elsif (/^\s*NOP\s*$/i) { $code[$address] = 0x80_88_00_00; $code[$address + 1] = 0x00_00_00_00; $address += 2; # Ignore lines consisting entirely of white space } elsif (/^\s*$/) { } else { die "$0 : syntax error in line $lineno: $_ expected label:, ABSOLUTE, CLEAR, DISCONNECT, EXTERNAL, MOVE, RESELECT, SELECT SET, or WAIT "; } } # Fill in label references @undefined = keys %forward; if ($#undefined >= 0) { print STDERR "Undefined symbols : \n"; foreach $undef (@undefined) { print STDERR "$undef in $forward{$undef}\n"; } exit 1; } @label_patches = (); @external_patches = (); @absolute = sort @absolute; foreach $i (@absolute) { foreach $j (split (/\s+/,$symbol_references{$i})) { $j =~ /(REL|ABS),(.*),(.*)/; $type = $1; $address = $2; $length = $3; die "$0 : $symbol $i has illegal relative reference at address $address, size $length\n" if ($type eq 'REL'); &patch ($address / 4, $address % 4, $length, $symbol_values{$i}); } } foreach $external (@external) { print STDERR "checking external $external \n" if ($debug_external); if ($symbol_references{$external} ne undef) { for $reference (split(/\s+/,$symbol_references{$external})) { $reference =~ /(REL|ABS),(.*),(.*)/; $type = $1; $address = $2; $length = $3; die "$0 : symbol $label is external, has illegal relative reference at $address, size $length\n" if ($type eq 'REL'); die "$0 : symbol $label has illegal reference at $address, size $length\n" if ((($address % 4) !=0) || ($length != 4)); $symbol = $symbol_values{$external}; $add = $code[$address / 4]; if ($add eq 0) { $code[$address / 4] = $symbol; } else { $add = sprintf ("0x%08x", $add); $code[$address / 4] = "$symbol + $add"; } print STDERR "referenced external $external at $1\n" if ($debug_external); } } } foreach $label (@label) { if ($symbol_references{$label} ne undef) { for $reference (split(/\s+/,$symbol_references{$label})) { $reference =~ /(REL|ABS),(.*),(.*)/; $type = $1; $address = $2; $length = $3; if ((($address % 4) !=0) || ($length != 4)) { die "$0 : symbol $label has illegal reference at $1, size $2\n"; } if ($type eq 'ABS') { $code[$address / 4] += $symbol_values{$label}; push (@label_patches, $address / 4); } else { # # - The address of the reference should be in the second and last word # of an instruction # - Relative jumps, etc. are relative to the DSP of the _next_ instruction # # So, we need to add four to the address of the reference, to get # the address of the next instruction, when computing the reference. $tmp = $symbol_values{$label} - ($address + 4); die # Relative addressing is limited to 24 bits. "$0 : symbol $label is too far ($tmp) from $address to reference as relative/\n" if (($tmp >= 0x80_00_00) || ($tmp < -0x80_00_00)); $code[$address / 4] = $tmp & 0x00_ff_ff_ff; } } } } # Output SCRIPT[] array, one instruction per line. Optionally # print the original code too. open (OUTPUT, ">$output") || die "$0 : can't open $output for writing\n"; open (OUTPUTU, ">$outputu") || die "$0 : can't open $outputu for writing\n"; print OUTPUT "u32 ".$prefix."SCRIPT[] = {\n"; $instructions = 0; for ($i = 0; $i < $#code; ) { if ($list_in_array) { printf OUTPUT "/*\n$list[$i]\nat 0x%08x : */", $i; } printf OUTPUT "\t0x%08x,", $code[$i]; printf STDERR "Address $i = %x\n", $code[$i] if ($debug); if ($code[$i + 1] =~ /\s*($identifier)(.*)$/) { push (@external_patches, $i+1, $1); printf OUTPUT "0%s,", $2 } else { printf OUTPUT "0x%08x,",$code[$i+1]; } if (($code[$i] & 0xff_00_00_00) == 0xc0_00_00_00) { if ($code[$i + 2] =~ /$identifier/) { push (@external_patches, $i+2, $code[$i+2]); printf OUTPUT "0,\n"; } else { printf OUTPUT "0x%08x,\n",$code[$i+2]; } $i += 3; } else { printf OUTPUT "\n"; $i += 2; } $instructions += 1; } print OUTPUT "};\n\n"; foreach $i (@absolute) { printf OUTPUT "#define A_$i\t0x%08x\n", $symbol_values{$i}; if (defined($prefix) && $prefix ne '') { printf OUTPUT "#define A_".$i."_used ".$prefix."A_".$i."_used\n"; printf OUTPUTU "#undef A_".$i."_used\n"; } printf OUTPUTU "#undef A_$i\n"; printf OUTPUT "u32 A_".$i."_used\[\] = {\n"; printf STDERR "$i is used $symbol_references{$i}\n" if ($debug); foreach $j (split (/\s+/,$symbol_references{$i})) { $j =~ /(ABS|REL),(.*),(.*)/; if ($1 eq 'ABS') { $address = $2; $length = $3; printf OUTPUT "\t0x%08x,\n", $address / 4; } } printf OUTPUT "};\n\n"; } foreach $i (sort @entry) { printf OUTPUT "#define Ent_$i\t0x%08x\n", $symbol_values{$i}; printf OUTPUTU "#undef Ent_$i\n", $symbol_values{$i}; } # # NCR assembler outputs label patches in the form of indices into # the code. # printf OUTPUT "u32 ".$prefix."LABELPATCHES[] = {\n"; for $patch (sort {$a <=> $b} @label_patches) { printf OUTPUT "\t0x%08x,\n", $patch; } printf OUTPUT "};\n\n"; $num_external_patches = 0; printf OUTPUT "struct {\n\tu32\toffset;\n\tvoid\t\t*address;\n". "} ".$prefix."EXTERNAL_PATCHES[] = {\n"; while ($ident = pop(@external_patches)) { $off = pop(@external_patches); printf OUTPUT "\t{0x%08x, &%s},\n", $off, $ident; ++$num_external_patches; } printf OUTPUT "};\n\n"; printf OUTPUT "u32 ".$prefix."INSTRUCTIONS\t= %d;\n", $instructions; printf OUTPUT "u32 ".$prefix."PATCHES\t= %d;\n", $#label_patches+1; printf OUTPUT "u32 ".$prefix."EXTERNAL_PATCHES_LEN\t= %d;\n", $num_external_patches; close OUTPUT; close OUTPUTU;