This file is indexed.

/usr/bin/sw2asc is in geda-utils 1:1.8.2-4.

This file is owned by root:root, with mode 0o755.

The actual contents of the file can be viewed below.

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#!/usr/bin/mawk -f
#
# gEDA - GPL Electronic Design Automation
#
# Copyright (C) 2003-2010 Dan McMahill
#
# 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., 51 Franklin Street, Fifth Floor, Boston,
# MA 02111-1301 USA.


#
# This is a script to extract out PRINT data from a SWITCAP simulation 
# and write it to a format which gwave can read
#

BEGIN {
  state_wait = 0;
  state_skip_blank = 1;
  state_read_data = 2;
  state = state_wait;

  analysis_none = 0;
  analysis_SSS = 1;
  analysis_SPECTRUM = 2;
  analysis_FREQCOMP = 3;
  analysis_TRAN = 4;
  analysis = analysis_none;

  progn = "sw2asc";

  pat = "none";

  variable_offset = 0;
  nvars = 0;

  for(i=1; i<ARGC; i=i+1) {
    if(ARGV[i] ~ /^(-c)|(--copyright)$/) {
      copyright();
      exit 0;
    } else if(ARGV[i] ~ /^((-h)|(--help))$/) {
      usage();
      exit 0;
    } else if(ARGV[i] ~ /^((-v)|(--version))$/) {
      copyright();
      exit 0;
    } else if(ARGV[i] ~ /^-.*/) {
      printf("Unknown option: ""%s""\n", ARGV[i]) > "/dev/stderr";
      usage();
      close("/dev/stderr");
      exit 1;
    } 
    printf("ARGV[%d] = %s\n", i, ARGV[i]);
  }
  infile = ARGV[ARGC-1];
  
  copyright();

  printf("Loading SWITCAP output file [%s]\n", infile);
}

/^ Sinusoidal Steady State/ {
  if( debug ) { printf("Start of SSS analysis\n"); }
  analysis = analysis_SSS;
  cnt_SSS = cnt_SSS + 1;
  fileid = ".SSS." cnt_SSS;
  pat = "^[ \t]*frequency";
}

/^ Spectral Analysis$/ {
  if( debug ) { printf("Start of SPECTRUM analysis\n"); }
  analysis = analysis_SPECTRUM;
  cnt_SPECTRUM = cnt_SPECTRUM + 1;
  fileid = ".SPECTRUM." cnt_SPECTRUM;
  pat = "^not_implemented_yet$";
  printf("Ignoring data from SPECTRUM analysis.\n");
  printf("I haven't fully worked out how to always parse this\n");
  printf("correctly.  Please write code to do this!!!\n\n");
}

/^ Spectral Analysis by Components$/ {
  if( debug ) { printf("Start of FREQCOMP analysis\n"); }
  analysis = analysis_FREQCOMP;
  cnt_FREQCOMP = cnt_FREQCOMP + 1;
  fileid = ".FREQCOMP." cnt_FREQCOMP;
  pat = "^not_implemented_yet$";
  printf("Ignoring data from FREQCOMP analysis.\n");
  printf("I haven't fully worked out how to always parse this\n");
  printf("correctly.  Please write code to do this!!!\n\n");
}

/^ Transient Analysis$/ {
  if( debug ) { printf("Start of TRAN analysis\n"); }
  analysis = analysis_TRAN;
  cnt_TRAN = cnt_TRAN + 1;
  fileid = ".TRAN." cnt_TRAN;
  pat = "^[ \t]*time";
}

/^ Run Report$/ {
  if( debug ) { printf("Start of Run Report\n"); }
  analysis = analysis_none;
  fileid = "none";
  pat = "^this_is_the_run_report$";
}

/\*SWITCAP/ {
  if( debug ) { printf("Saw *SWITCAP line\n"); }

  if( variable_offset > 0 ) {
    outf = infile fileid ".asc";
    printf("Writing data to ""%s""\n", outf);
    printf( "" ) > outf;
    for(i = 1; i <= variable_offset; i = i + 1) {
      printf("%s ", vnames[i]) >> outf;
    }
    printf("\n") >> outf;
    
    for(pt = 1; pt < cnt ; pt = pt + 1) {
      if( debug > 1) { printf("point #%d: ", pt); }
      for(i = 1; i <= variable_offset; i = i + 1) {
	printf("%s ", data[i ":" pt]) >> outf;
      }
      printf("\n") >> outf;
    }
    close(outf);

    variable_offset = 0;
    nvars = 0;
    for(k in data) { delete data[k]; }
    num_analysis = num_analysis + 1;

  } else {
    if( debug ) { printf("No data to output yet\n"); }
  }

  next;
}


state == state_wait {
  if( $0 ~ pat ) {
    if( debug) { printf("state_wait: Variable start line:"); }
    for(i=1; i<=NF; i=i+1) {
      if( debug ) { printf("\tVariable #%d = %s\n", i, $i); }
      vnames[i + variable_offset] = $i;
    }
    
    nvars = NF;
    
    if( debug ) { printf("state_wait:  moving to state_skip_blank\n") };
    state = state_skip_blank;
  }
  next;
}

state == state_skip_blank {
  if( $0 == "" ) {
    if( debug) { printf("state_skip_blank:  skipping blank line\n"); }
    next; 
  }
  
  cnt = 1;
  if( debug ) { printf("state_skip_blank:  moving to state_read_data\n") };
  state = state_read_data;
}

state == state_read_data {
  if( $0 == "" ) {
    variable_offset = variable_offset + nvars;
    nvars = 0;
    if( debug ) { printf("state_read_data:  moving to state_wait\n") };
    state = state_wait;
    next;
  }

  if( debug > 1 ) { printf("state_read_data: data = %s\n", $0); }
  for(i=1; i<=NF; i=i+1) {
    gsub(/d$/, "", $i);
    data[i+variable_offset ":" cnt] = $i;
  }
  cnt = cnt + 1;
  next;
}

END {
  if( debug ) { printf("END.  Processed %d analyses.\n", num_analysis); };
}


function copyright() {
  printf("gEDA/%s version %s\n", progn, "1.8.2");
  printf("gEDA/%s comes with ABSOLUTELY NO WARRANTY; see COPYING for more details.\n", progn);
  printf("This is free software, and you are welcome to redistribute it under certain\n");
  printf("conditions; please see the COPYING file for more details.\n\n");
}

function usage() {
  printf("Usage:\n\n");
  printf("\t%s -- -c|--copyright\n", progn);
  printf("\t%s -- -h|--help\n", progn);
  printf("\t%s -- -v|--version\n", progn);
  printf("\t%s switcap.out\n", progn);
  printf("\n");
  printf("%s process the output file generated by the SWITCAP switched capacitor\n", progn);
  printf("circuit simulator.  Data generated by SWITCAP ""PRINT"" statements is\n");
  printf("extracted and written to an output file in an ASCII format which can be\n");
  printf("directly loaded by the gwave waveform viewer or more easily loaded into\n");
  printf("a tool such as scilab, octave, grace, or matlab.\n");
  printf("\n");
  printf("If multiple analyses are in the SWITCAP output file, then they are written\n");
  printf("to individual files by %s.  The output file names are derived from the input\n", progn);
  printf("file name by appending "".{SSS,TRAN}.#.asc"" to the name of the input file.\n");
  printf("SSS is used for Sinusoidal Steady State analysis output and TRAN is used for.\n");
  printf("TRANsient analysis output.  # corresponds to the analysis number (ie if you \n");
  printf("have 3 SSS analyses in your file, you will end up with .SSS.1.asc, .SSS.2.asc,\n");
  printf("and .SSS.3.asc.\n");
  printf("\n");
  
}