#!/usr/bin/awk -f # $NetBSD: genreadme.awk,v 1.27 2007/05/28 11:07:00 martti Exp $ # # Copyright (c) 2002, 2003, 2005, 2006 The NetBSD Foundation, Inc. # All rights reserved. # # This code is derived from software contributed to The NetBSD Foundation # by Dan McMahill. # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions # are met: # 1. Redistributions of source code must retain the above copyright # notice, this list of conditions and the following disclaimer. # 2. Redistributions in binary form must reproduce the above copyright # notice, this list of conditions and the following disclaimer in the # documentation and/or other materials provided with the distribution. # 3. All advertising materials mentioning features or use of this software # must display the following acknowledgement: # This product includes software developed by the NetBSD # Foundation, Inc. and its contributors. # 4. Neither the name of The NetBSD Foundation nor the names of its # contributors may be used to endorse or promote products derived # from this software without specific prior written permission. # # THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS # ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED # TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR # PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS # BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR # CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF # SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS # INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN # CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) # ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE # POSSIBILITY OF SUCH DAMAGE. # # Global variables #----------------- # The following associative arrays are used for storing the dependency # information and other information for the packages # # topdepends[] : index=pkgdir (math/scilab) # List of explicitly listed depencencies by name. # I.e. "xless-[0-9]* pvm-3.4.3" # # alldepends[] : index=pkgdir (math/scilab) # Flattened dependency list by name. # BEGIN { do_pkg_readme=1; # set to 1 to use "README-new.html" as the name use_readme_new=0; if (use_readme_new) { readme_name = "README-new.html"; } else { readme_name = "README.html"; } printf("Reading database file\n"); } #conflicts /usr/pkgsrc/math/scilab #depends /usr/pkgsrc/math/scilab xless-[0-9]*:../../x11/xless pvm-3.4.3:../../parallel/pvm3 # /^(build_)?depends / { # # Read in the entire depends tree # These lines look like: # #depends /usr/pkgsrc/math/scilab xless-[0-9]*:../../x11/xless pvm-3.4.3:../../parallel/pvm3 #build_depends /usr/pkgsrc/math/scilab libtool-base>=1.4.20010614nb9:../../devel/libtool-base # deptype=$1; # pkg=fulldir2pkgdir($2); pkg = $2; if (pkg in topdepends) {} else {topdepends[pkg] = "";} if (pkg in topbuilddepends) {} else {topbuilddepends[pkg] = "";} for (i = 3; i <= NF; i++) { split($i, a,":"); pkgpat = a[1]; pkgdir = a[2]; sub(/[\.\/]*/, "", pkgdir); if (pkgdir !~ /\//) { pkgcat = pkg; gsub(/\/.*/, "", pkgcat); pkgdir=pkgcat "/" pkgdir; if (debug) printf("Corrected missing category directory to get \"%s\"\n", pkgdir); } if (debug){ printf("package in directory %s %s on:\n", pkg, deptype); printf("\tpkgpat = %s\n", pkgpat); printf("\tpkgdir = %s\n", pkgdir); } # # store the package directory in a associative array with the wildcard # pattern as the index since we will need to be able to look this up later # pat2dir[pkgpat] = pkgdir; if (deptype == "depends") { topdepends[pkg] = topdepends[pkg] " " pkgpat " " ; if (debug) { printf("Appending %s to topdepends[%s] (%s)\n", pkgpat, pkg, topdepends[pkg]); } } else { if (debug) { printf("Appending %s to topbuilddepends[%s] (%s)\n", pkgpat, pkg, topbuilddepends[pkg]); } topbuilddepends[pkg] = topbuilddepends[pkg] " " pkgpat " " ; } } next; } /^comment /{ dir = $2; gsub(/^comment[ \t]*/, ""); tmp = substr($0, length($1) + 1); gsub(/^[ \t]*/, "", tmp); gsub(/&/, "\\\\\\&", tmp); comment[dir] = tmp; next; } /^homepage /{ homepage[$2] = $3; gsub(/&/, "\\\\&", homepage[$2]); next; } /^htmlname / { # # read lines like: # htmlname /usr/pkgsrc/archivers/arc arc-5.21e # # dir=fulldir2pkgdir($2); dir = $2; htmlname = $3; for (i = 4; i <= NF; i++){ htmlname = htmlname " " $i; } # If we are using a name other than README.html, change it # here. This avoids having to process a huge line later which # makes lesser awks puke. gsub(/README.html/, readme_name, htmlname); dir2htmlname[dir] = htmlname; if (debug) printf("added dir2htmlname[%s]=%s\n", dir, htmlname); next; } /^index / { # # read lines like: #index /usr/pkgsrc/math/scilab scilab-2.6nb3 # and store the directory name in a associative array where the index # is the package name and in a associative array that lets us lookup # name from directory. We use fuldir2pkgdir to get "math/scilab" # and drop the /usr/pkgsrc part. # # pkgname2dir[$3] = fulldir2pkgdir($2); # pkgdir2name[fulldir2pkgdir($2)] = $3; pkgname2dir[$3] = $2; pkgdir2name[$2] = $3; next; } /^license /{ license[$2] = $3; next; } /^wildcard /{ wildcard[$2] = $3; } # # Now recurse the tree to give a flattened depends list for each pkg # END { readme = TMPDIR "/" readme_name; if ( dependsfile == "" ) dependsfile = "/dev/stdout"; if ( builddependsfile == "" ) builddependsfile = "/dev/stdout"; printf("Making sure binary package cache file is up to date...\n"); cmd = sprintf("%s AWK=%s CMP=%s FIND=%s GREP=%s GZIP_CMD=\"%s\" PKG_INFO=\"%s\" PKG_SUFX=%s SED=%s SORT=%s %s/mk/scripts/binpkg-cache %s --packages %s", SETENV, AWK, CMP, FIND, GREP, GZIP_CMD, PKG_INFO, PKG_SUFX, SED, SORT, PKGSRCDIR, summary, PACKAGES); if (debug) printf("\nExecute: %s\n",cmd); rc = system(cmd); if (rc != 0 && rc != 2) { printf("\n**** WARNING ****\n") > "/dev/stderr"; printf("Command: %s\nfailed.", cmd) > "/dev/stderr"; printf("**** ------- ****\n") > "/dev/stderr"; exit(1); } if (rc == 2) { printf("\n**** WARNING ****\n") > "/dev/stderr"; printf("* No binary packages directory found\n") > "/dev/stderr"; printf("* List of binary packages will not be generated\n") > "/dev/stderr"; printf("**** ------- ****\n") > "/dev/stderr"; } else { printf("Loading binary package cache file...\n"); load_cache_file( PACKAGES "/.pkgcache" ); if(pkg_count["unknown"] > 0 ) { printf(" Loaded %d binary packages with unknown PKGPATH\n", pkg_count["unknown"]); } } printf("Flattening dependencies\n"); printf("") > dependsfile; for (toppkg in topdepends){ if (debug) printf("calling find_all_depends(%s, run)\n", toppkg); find_all_depends(toppkg, "run"); if (debug) printf("%s depends on: %s, topdepends on %s\n", toppkg, alldepends[toppkg], topdepends[toppkg]); printf("%s depends on: %s\n", toppkg, alldepends[toppkg]) >> dependsfile; flatdepends[toppkg] = alldepends[toppkg]; } close(dependsfile); # clear out the flattened depends list and repeat for the build depends for( key in alldepends ) { delete alldepends[key]; } printf("Flattening build dependencies\n"); printf("") > builddependsfile; for (toppkg in topbuilddepends){ find_all_depends(toppkg, "build"); printf("%s build_depends on: %s\n", toppkg, alldepends[toppkg]) >> builddependsfile; } close(builddependsfile); vfile = PVDIR "/pkg-vulnerabilities"; # extract date for vulnerabilities file cmd = "ls -l " vfile; if ((cmd | getline) > 0) { vuldate = sprintf("at %s %s %s\n",$6,$7,$8); # read the vulnerabilities file printf("Reading vulnerability file \"%s\"\n which was updated %s\n", vfile, vuldate); i = 1; vul_major = 0; vul_minor = 0; vul_teeny = 0; while((getline < vfile) > 0) { if( $0 ~ /#FORMAT/ ) { split($2, vul_format, "."); vul_major = vul_format[1]; vul_minor = vul_format[2]; vul_teeny = vul_format[3]; } if ( $0 ~ /^-----BEGIN PGP SIGNATURE-----.*/ ) { break; } if ( ( $0 !~ /^\#/ ) && ( $0 !~ /^Hash:.*/ ) && ( $0 !~ /^-----BEGIN PGP SIGNED.*/ ) && ( $0 != "" ) ) { vulpkg[i] = $1; vultype[i] = $2; vulref[i] = $3; i = i + 1; } } if( (vul_major > 1) || (vul_minor > 1) || (vul_teeny > 0) ) { printf("Version %d.%d.%d of the vulnerability file is out of sync with", vul_major, vul_minor, vul_teeny); printf("the genreadme.awk script\n"); } printf(" Loaded %d vulnerabilities\n", i - 1); close(vfile); have_vfile = 1; } else { vuldate="(no vulnerabilities list available)"; printf("No vulnerability file found (%s).\n", vfile); have_vfile = 0; } close(cmd); if (SINGLEPKG != "" ) { printf("Only creating README for %s\n",SINGLEPKG); for( key in topdepends ) { delete topdepends[key]; } topdepends[SINGLEPKG] = "yes"; } printf("Generating README.html files\n"); pkgcnt = 0; if (do_pkg_readme) { templatefile = PKGSRCDIR "/templates/README.pkg"; fatal_check_file(templatefile); for (toppkg in topdepends){ pkgcnt++; pkgdir = PKGSRCDIR "/" toppkg; readmenew=pkgdir "/" readme_name; if (debug) printf("Creating %s for %s\n", readme, readmenew); printf("."); if ((pkgcnt % 100) == 0) { printf("\n%d\n", pkgcnt); } printf("") > readme; htmldeps = ""; for( key in dpkgs ) { delete dpkgs[key]; } split(alldepends[toppkg], dpkgs); i = 1; htmldeps_file = TMPDIR "/htmldep"; printf("") > htmldeps_file; while(i in dpkgs){ if (debug) { printf("\tdpkg=%s, pat2dir[%s] = %s\n", dpkgs[i], dpkgs[i], pat2dir[dpkgs[i]]); } nm=dpkgs[i]; gsub(/&/, "\\&", nm); gsub(//, "\\>", nm); # htmldeps=sprintf("%s%s\n", # htmldeps, # pat2dir[dpkgs[i]], # readme_name, nm); # We use a temp file to hold the html dependencies because for # packages like gnome, this list can get very very large and # become larger than what some awk implementations can deal # with. The nawk shipped with solaris 9 is an example of # such a limited awk. printf("%s%s\n", htmldeps, pat2dir[dpkgs[i]], readme_name, nm) >> htmldeps_file; i = i + 1; } if ( i == 1 ) { printf("none") >> htmldeps_file; } close(htmldeps_file); if (debug) printf("wrote = %d entries to \"%s\"\n", i-1, htmldeps_file); vul = ""; if (have_vfile) { i = 1; pkgbase = pkgdir2name[toppkg]; gsub(/-[^-]*$/, "", pkgbase); if (debug) { printf("Checking for %s (%s) vulnerabilities\n", toppkg, pkgbase); } while(i in vulpkg) { if (vulpkg[i] ~ "^" pkgbase"[-<>=]+[0-9]") { nm = vulpkg[i]; gsub(/&/, "\\\\\\&", nm); gsub(//, "\\\\\\>", nm); url = vulref[i]; gsub(/&/, "\\\\\\&", url); printurl = vulref[i]; gsub(/&/, "\\\\\\&", printurl); gsub(//, "\\\\\\>", printurl); vul = sprintf("%s
  • %s has a %s vulnerability
  • \n", vul, nm, url, vultype[i]); } i = i + 1; } if ( vul == "" ){ vul="(no vulnerabilities known)"; } } if (debug) { printf("Checking for binary package with lookup_cache( %s)\n", toppkg); } # lookup_cache( wildcard ) will produce HTML for the packages which are found lookup_cache( toppkg ); if ( flatdepends[toppkg] ~ /^[ \t]*$/ ) { rundeps = "none"; } else { rundeps = flatdepends[toppkg]; } while((getline < templatefile) > 0){ gsub(/%%PORT%%/, toppkg); gsub(/%%PKG%%/, pkgdir2name[toppkg]); gsub(/%%COMMENT%%/, comment[toppkg]); if (homepage[toppkg] == "") { gsub(/%%HOMEPAGE%%/, ""); } else { gsub(/%%HOMEPAGE%%/, "

    This package has a home page at " homepage[toppkg] ".

    "); } if (license[toppkg] == "") { gsub(/%%LICENSE%%/, ""); } else { gsub(/%%LICENSE%%/, "

    Please note that this package has a " license[toppkg] " license.

    "); } gsub(/%%VULNERABILITIES%%/, ""vul""); gsub(/%%VULDATE%%/, ""vuldate""); gsub(/%%RUN_DEPENDS%%/, ""rundeps""); line = $0; if( line ~/%%BIN_PKGS%%/ ) { gsub(/%%BIN_PKGS%%/, "", line); while((getline < binpkgs_file) > 0) { print >> readme; } close( binpkgs_file ); } if( line ~/%%BUILD_DEPENDS%%/ ) { gsub(/%%BUILD_DEPENDS%%/, "", line); while((getline < htmldeps_file) > 0) { print >> readme; } close( htmldeps_file ); } print line >> readme; } close(readme); close(templatefile); cmd = "if [ ! -d " pkgdir " ]; then exit 1 ; fi"; if (debug) printf("Execute: %s\n",cmd); rc = system(cmd); if (rc != 0) { printf("\n**** WARNING ****\nPackage directory %s\n", pkgdir) > "/dev/stderr"; printf("Does not exist. This is probably ") > "/dev/stderr"; printf("due to an incorrect DEPENDS line.\n") > "/dev/stderr"; printf("Try running: grep %s */*/Makefile\n", fulldir2pkgdir(pkgdir)) > "/dev/stderr"; printf("or: grep %s */*/buildlink3.mk\n", fulldir2pkgdir(pkgdir)) > "/dev/stderr"; printf("to find the problem\n", pkgdir) > "/dev/stderr"; printf("**** ------- ****\n") > "/dev/stderr"; } else { copy_readme(readmenew, readme); } } printf("\n"); } # if (do_pkg_readme) printf("\n"); if (SINGLEPKG != "" ) { close("/dev/stderr"); exit 0; } printf("Generating category readmes\n"); templatefile = PKGSRCDIR "/templates/README.category"; fatal_check_file(templatefile); # string with URLs for all categories (used by the top README.html) allcat = ""; # string with URLs for all pkgs (used by the top README-all.html) tot_numpkg = 0; top_make = PKGSRCDIR"/Makefile"; while((getline < top_make) > 0){ if ($0 ~ /^[ \t]*SUBDIR.*=[^\$]*$/) { category = $0; gsub(/^[ \t]*SUBDIR.*=[ \t]*/, "", category); catdir = PKGSRCDIR"/"category; readmenew = catdir"/"readme_name; printf("Category = %s\n", category); cat_make = catdir"/Makefile"; pkgs = ""; pkgs_file = TMPDIR "/pkgs_file"; printf("") > pkgs_file; numpkg = 0; print "" > readme; while((getline < cat_make) > 0){ if ($0 ~ /^[ \t]*SUBDIR.*=[^\$]*$/) { pkg = $0; gsub(/^[ \t]*SUBDIR.*=[ \t]*/, "", pkg); dir = category"/"pkg; numpkg++; tot_numpkg++; if (debug) { printf("\tAdding %s (%s : %s)\n", dir, pkgdir2name[dir], comment[dir]); } # pkgs = sprintf("%s%s: %s\n", # pkgs, pkg, readme_name, # pkgdir2name[dir], # comment[dir]); # We use a temp file to hold the list of all packages because # this list can get very very large and # become larger than what some awk implementations can deal # with. The nawk shipped with solaris 9 is an example of # such a limited awk. printf("%s: %s\n", pkg, readme_name, pkgdir2name[dir], comment[dir]) >> pkgs_file; allpkg[tot_numpkg] = sprintf("%s: (%s) %s\n", pkgdir2name[dir], category, pkg, readme_name, pkgdir2name[dir], category, readme_name, category, comment[dir]); # we need slightly fewer escapes here since we are not gsub()-ing # allpkg[] into the output files but just printf()-ing it. gsub(/\\&/, "\\&", allpkg[tot_numpkg]); } else if ($0 ~ /^[ \t]*COMMENT/) { descr = $0; gsub(/^[ \t]*COMMENT.*=[ \t]*/, "", descr); } } while ((getline < templatefile) > 0){ gsub(/%%CATEGORY%%/, category); gsub(/%%NUMITEMS%%/, numpkg); gsub(/%%DESCR%%/, descr); line = $0 if( $0 ~/%%SUBDIR%%/ ) { gsub(/%%SUBDIR%%/, "", line); while((getline < pkgs_file) > 0) { gsub(/README.html/, readme_name); print >> readme; } close( pkgs_file ); } print line >> readme; } close(readme); close(templatefile); copy_readme(readmenew, readme); gsub(/href=\"/, "href=\""category"/", pkgs); allcat = sprintf("%s%s: %s\n", allcat, category, readme_name, category, descr); close(cat_make); } } close(top_make); printf("Generating toplevel readmes:\n"); templatefile = PKGSRCDIR "/templates/README.top"; fatal_check_file(templatefile); readmenew = PKGSRCDIR "/"readme_name; printf("\t%s\n", readmenew); print "" > readme; while((getline < templatefile) > 0){ gsub(/%%DESCR%%/, ""); gsub(/%%SUBDIR%%/, allcat); gsub(/README.html/, readme_name); print >> readme; } close(readme); close(templatefile); copy_readme(readmenew, readme); templatefile = PKGSRCDIR "/templates/README.all"; fatal_check_file(templatefile); readmenew = PKGSRCDIR "/README-all.html"; printf("\t%s\n", readmenew); # sort the pkgs sfile = TMPDIR"/unsorted"; spipe = "sort " sfile; i = 1; print "" >sfile; while(i in allpkg) { printf("%s",allpkg[i]) >> sfile; i++; } close(sfile); print "" > readme; while((getline < templatefile) > 0){ line = $0; if ($0 ~ /%%PKGS%%/) { while((spipe | getline) > 0) { print >> readme; } close(spipe); } else { gsub(/%%DESCR%%/, "", line); gsub(/%%NPKGS%%/, tot_numpkg, line); gsub(/README.html/, readme_name, line); print line >> readme; } } close(readme); close(templatefile); copy_readme(readmenew, readme); close("/dev/stderr"); exit 0; } function find_all_depends(pkg, type, pkgreg, i, deps, depdir, topdep){ # pkg is the package directory, like math/scilab # printf("find_all_depends(%s, %s)\n", pkg, type); # if we find the package already has been fully depended # then return the depends list if (pkg in alldepends){ if (debug) printf("\t%s is allready depended. Returning %s\n", pkg, alldepends[pkg]); return(alldepends[pkg]); } # if this package has no top dependencies, enter an empty flat dependency # list for it. if( type == "run" ) { # we only want DEPENDS topdep = topdepends[pkg]; } else { # we want BUILD_DEPENDS and DEPENDS topdep = topdepends[pkg] " " topbuilddepends[pkg]; } if (topdep ~ "^[ \t]*$") { alldepends[pkg] = " "; if (debug) printf("\t%s has no depends(%s). Returning %s\n", pkg, topdep, alldepends[pkg]); return(alldepends[pkg]); } # recursively gather depends that each of the depends has pkgreg = reg2str(pkg); split(topdep, deps); i = 1; alldepends[pkg] = " "; while ( i in deps ) { # figure out the directory name associated with the package hame # in (wild card/dewey) version form depdir = pat2dir[deps[i]]; if (debug) printf("\tadding dependency #%d on \"%s\" (%s)\n", i, deps[i], depdir); # do not add ourselves to the list (should not happen, but # we would like to not get stuck in a loop if one exists) # if (" "deps[i]" " !~ pkgreg){ # if we do not already have this dependency (deps[i]) listed, then add # it. However, we may have already added it because another package # we depend on may also have depended on # deps[i]. if (alldepends[pkg] !~ reg2str(deps[i])){ alldepends[pkg] = alldepends[pkg] " " deps[i] " " find_all_depends(depdir, type); } else { if (debug) printf("\t%s is already listed in %s\n", deps[i], alldepends[pkg]); } i = i + 1; } # while i if (debug) printf("\tcalling uniq() on alldepends[%s] = %s\n", pkg, alldepends[pkg]); alldepends[pkg] = uniq(alldepends[pkg]); if (debug) printf("\tuniq() output alldepends[%s] = %s\n", pkg, alldepends[pkg]); return(alldepends[pkg]); } # # take a string which has special characters like '+' in it and # escape them. Also put a space before and after since that's how # we'll distinguish things like gnome from gnome-libs # function reg2str(reg){ gsub(/\./, "\\\.", reg); gsub(/\+/, "\\\+", reg); gsub(/\*/, "\\\*", reg); gsub(/\?/, "\\\?", reg); gsub(/\[/, "\\\[", reg); gsub(/\]/, "\\\]", reg); reg = " "reg" "; return(reg); } # # take a string which has a shell glob pattern and turn it into # an awk regular expression. # function glob2reg(reg){ # escape some characters which are special in regular expressions gsub(/\./, "\\\.", reg); gsub(/\+/, "\\\+", reg); # and reformat some others gsub(/\*/, ".*", reg); gsub(/\?/, ".?", reg); # finally, expand {a,b,c} type patterns return(reg); } # # accepts a full path to a package directory, like "/usr/pkgsrc/math/scilab" # and returns just the last 2 directories, like "math/scilab" # function fulldir2pkgdir(d, i){ i = match(d, /\/[^\/]+\/[^\/]+$/); return substr(d, i + 1); } # # take the depends lists and uniq them. # function uniq(list, deps, i, ulist){ # split out the depends split(list, deps); i = 1; ulist = " "; while (i in deps){ # printf("uniq(): Checking \"%s\"\n", ulist); # printf(" for \"%s\"\n", reg2str(deps[i])); if (ulist !~reg2str(deps[i])){ ulist = ulist deps[i]" "; } i++; } return(ulist); } function fatal_check_file(file, cmd){ cmd="test -f " file ; if (debug) printf("Execute: %s\n",cmd); if (system(cmd) != 0) { printf("**** FATAL ****\nRequired file %s does not exist\n", file) > "/dev/stderr"; printf("**** ------- ****\n") > "/dev/stderr"; close("/dev/stderr"); exit(1); } } # 'new' is the newly created README.html file # 'old' is the existing (possibly not present) README.html file # # This function copies over the 'new' file if the 'old' one does # not exist or if they are different. In addition, the 'new' one # which is a temporary file is removed at the end function copy_readme(old, new, cmd, rc) { # if the README.html file does not exist at all then copy over # the one we created cmd = "if [ ! -f "old" ]; then cp " new " " old " ; fi"; if (debug) printf("copy_readme() execute: %s\n",cmd); rc = system(cmd); if (rc != 0) { printf("**** WARNING ****\nThe command\n %s\n", cmd) > "/dev/stderr"; printf("failed with result code %d\n", rc) > "/dev/stderr"; printf("**** ------- ****\n") > "/dev/stderr"; } # Compare the existing README.html file to the one we created. If they are # not the same, then copy over the one we created cmd = sprintf("%s -s %s %s ; if test $? -ne 0 ; then mv -f %s %s ; fi", CMP, new, old, new, old); if (debug) printf("copy_readme() execute: %s\n",cmd); rc = system(cmd); if (rc != 0) { printf("**** WARNING ****\nThe command\n %s\n", cmd) > "/dev/stderr"; printf("failed with result code %d\n", rc) > "/dev/stderr"; printf("**** ------- ****\n") > "/dev/stderr"; } # If the temp file still exists, then delete it cmd = " if [ -f "new" ]; then rm -f "new" ; fi"; if (debug) printf("copy_readme() execute: %s\n",cmd); rc = system(cmd); if (rc != 0) { printf("**** WARNING ****\nThe command\n %s\n", cmd) > "/dev/stderr"; printf("failed with result code %d\n", rc) > "/dev/stderr"; printf("**** ------- ****\n") > "/dev/stderr"; } } function load_cache_file( file, pkgfile, opsys, osver, march, wk, rx ) { printf(" * %s\n", file); fatal_check_file( file ); # read the cache file while( getline < file ) { # if this line points to another cache file, then recursively # load it if( $0 ~ /^pkgcache_cachefile/ ) { if( debug ) printf("\tFound pkgcache_cachefile line.\n"); load_cache_file( $2 ); } else if( $0 ~/^pkgcache_begin /) { pkgfile = $2; if( debug ) printf("\tStarting %s\n", pkgfile); opsys = "unknown"; osver = "unknown"; march = "unknown"; pkgpath = "unknown"; } else if( $0 ~/^PKGPATH=/ ) { pkgpath = $0; gsub(/PKGPATH=[ \t]*/, "", pkgpath); } else if( $0 ~/^OPSYS=/ ) { opsys = $0; gsub(/OPSYS=[ \t]*/, "", opsys); } else if( $0 ~/^OS_VERSION=/ ) { osver = $0; gsub(/OS_VERSION=[ \t]*/, "", osver); } else if( $0 ~/^MACHINE_ARCH=/ ) { march = $0; gsub(/MACHINE_ARCH=[ \t]*/, "", march); } else if( $0 ~/^pkgcache_end /) { if( debug ) printf("\t%s, OPSYS=%s, OS_VERSION=%s, MACHINE_ARCH=%s, PKGPATH=%s\n", pkgfile, opsys, osver, march, pkpath); pkg_count[pkgpath] = pkg_count[pkgpath] + 1; opsys_list[pkgpath, pkg_count[pkgpath]] = opsys; osver_list[pkgpath, pkg_count[pkgpath]] = osver; march_list[pkgpath, pkg_count[pkgpath]] = march; pkgfile_list[pkgpath, pkg_count[pkgpath]] = pkgfile; gsub(/.*\//, "", pkgfile); pkgnm_list[pkgpath, pkg_count[pkgpath]] = pkgfile; } else { # skip this line } } # close the cache file close( file ); } function lookup_cache( d, binpkgs) { if( debug ) printf("lookup_cache( %s ): pkg_count = %d\n", d, pkg_count[d]); binpkgs_file = TMPDIR "/binpkgs"; spipe = SORT " > " binpkgs_file; for(i=1 ; i<=pkg_count[d]; i=i+1) { printf("%s:%s(%s %s)\n", march_list[d, i], PKG_URL, pkgfile_list[d, i], pkgnm_list[d, i], opsys_list[d, i], osver_list[d, i]) | spipe; } if( pkg_count[d] == 0 ) { printf("none\n") | spipe; } close( spipe ); }