#!/usr/local/bin/gawk -f
# @(#) memuse.gawk 2.0 96/04/23
# 96/01/21 John H. DuBois III (john@armory.com)
# 96/04/23 Added assorted extra information, and all options.

# swap -l output:
#path               dev  swaplo blocks   free
#/dev/swap          1,105     0 196608 119992
BEGIN {
    Name = "memuse"
    Usage = "Usage: " Name " [-h] [-s<seconds>] [-r<num>]"
    ARGC = Opts(Name,Usage,"hs>r>",0)
    if ("h" in Options) {
	printf \
"%s: show memory usage statistics.\n"\
"%s\n"\
"Options:\n"\
"-s<seconds>: Print values subject to change every <seconds> seconds.\n"\
"    If -r is not also given, values are printed until %s is interrupted.\n"\
"-r<num>: Print values subject to change <num> times.\n"\
"    If -s is not also given, they are printed about once per second.\n",
Name,Usage,Name
	exit 0
    }
    if ("s" in Options)
	Seconds = " -s" Options["s"]
    if ("r" in Options && Options["r"] > 1)
	Repeat = " -r" Options["r"]
    print "Swap space:"
    cmd = "exec swap -l"
    format = "    %-9.9s %6s %5s %5s\n"
    printf format,"Device","Total","Free","Used"
    cmd | getline
    while ((cmd | getline) == 1) {
	numSwap++
	if (NF != 5) {
	    print "Strange line from swap -l: " $0
	    continue
	}
	blocksT += $4
	freeT += $5
	printSwap($1,$4,$5)
    }
    close(cmd)
    if (numSwap > 1)
	printSwap("Total",blocksT,freeT)
    CmdReadLine("exec /etc/memsize 2>/dev/null")
    # If memsize works, we're probably root so can use crash.
    Cmd = "exec kvar -VRSnt' '" Seconds Repeat
    if ($1 > 0) {
	# memsize reports in bytes; convert to KB.
	memSize = $1/1024
	printLine(memSize,"Real memory (RAM)")
	vmem = blocksT/2 + memSize
	printLine(vmem,"Total virtual memory (RAM + swap)")
	while ((Cmd | getline) == 1) {
	    if (DoNewline)
		print ""
	    else
		DoNewline = 1
	    PrintVarStats($1,$2,$3)
	}
    }
}

function PrintVarStats(availsmem,freemem,freeSwap,
realUsed,allocated,inUse,allocUnused) {
    printLine(availsmem,
    "Available (unallocated) virtual memory (availsmem)")
    printLine(freemem,"Available (unused) real memory (freemem)")
    realUsed = memSize - freemem
    printLine(realUsed,"Real memory in use (real memory - freemem)")
    allocated = vmem - availsmem
    printLine(allocated,"Allocated virtual memory (vmem - availsmem)")
    inUse = blocksT/2-freeSwap + realUsed
    printLine(inUse,"Virtual memory in use (real memory used + swap used)")
    allocUnused = allocated - inUse
    printLine(allocUnused,
    "Allocated but unused vmem (allocated vmem - vmem in use)")
}

function printLine(Val,S) {
    # Print negative numbers as 0.  Negative numbers can result because
    # discrepancies will arise since the various binaries used to gather
    # information don't provide an instantaneous snapshot of the system,
    # and also affect the numbers themselves.
    printf "%7dK %4dM %s\n",max(Val,0),max((Val+512)/1024,0),S
}

function printSwap(dev,blocks,free) {
    printf format,dev,f(blocks),f(free),f(blocks-free)
}

function f(i) {
    return i2met(int(i/2),4,1,1) "B"
}

# @(#) i2met.awk 1.0 96/01/14
# jhdiii 96/01/14
# Convert positive integer value Value to a string at most MaxLen characters
# long.  This is done by converting the integer to a string of the form n*m,
# where m is a metric suffix from: K M G
# If Pow2 is true, then each factor of 1K is taken to be 1024; if it is false,
# it is taken to be 1000.
# MaxLen must be between 4 and 9. 
# Value may be any integer from 0..maxint
# If Units is given, it is the units that Value is passed in, where
# Units=1 means Value is in K; Units=2 means Value is in M, etc.
function i2met(Value,MaxLen,Pow2,Units,  Len,Div) {
    if (!(1 in Suf))
	split("K,M,G,T,P,E,Z,Y",Suf,",")
    # In both awk & gawk, integer values that can be represented as
    # machine integers will be printed as integers.
    # If value can be printed without modification, return it as it,
    # but with a multiplier suffix if reqd.
    if ((Len = length(Value Suf[Units])) <= MaxLen)
	return Value Suf[Units]
    MaxLen -= 1		# Leave space for suffix
    Div = Pow2 ? 1024 : 1000
    for (Units += 1; Units in Suf; Units++)
	if (length(int(Value /= Div)) <= MaxLen)
	    break
    Value = substr(sprintf("%." MaxLen "f",Value),1,MaxLen)
    if (substr(Value,MaxLen,1) == ".")
	Value = substr(Value,1,MaxLen-1)
    return Value Suf[Units]
}

# @(#) CmdReadLine 95/09/04
# Run Command, read a single line of output from it, then close it.
# If Verbose is true, a complaint is issued if the read fails.
# Output is returned in $*
# The return value from getline is returned.  It will be 1 on a successful
# read; 0 if no lines were read due because the command produced no output
# or could not be run.  ERRNO is never set since pipes are run by a shell.
function CmdReadLine(Command,Verbose,  ret) {
    if (Debug) {
	print "* Issuing command: " Command "\n"\
	      "* Waiting for single line of output..." > "/dev/stderr"
    }
    ret = Command | getline
    if (Verbose && ret != 1)
	printf "Read from pipe '%s' failed\n",Command
    # close doesn't return a value under awk, only gawk
    close(Command)
    if (Debug)
	print "* Output: " $0 > "/dev/stderr"
    return ret
}

### Begin min,max,In routines

function min(a,b) {
    if (a < b)
	return a
    else
	return b
}

function max(a,b) {
    if (a > b)
	return a
    else
	return b
}

function In(Val,Min,Max) {
    return (Min <= Val && Val <= Max)
}

# Return (in Ind) the indices of the elements with the smallest value in A.
# The smallest value is returned as the function value.
# If there are no elements in A, null is returned.
function arrMin(A,Ind,  i,min) {
    for (i in A)
	if (min == "" || A[i] < min) {
	    DeleteAll(Ind)
	    min = A[i]
	    Ind[i]
	}
	else if (A[i] == min)
	    Ind[i]
    return min
}

### End min,max,In routines

### Start of ProcArgs library
# @(#) ProcArgs 1.11 96/12/08
# 92/02/29 john h. dubois iii (john@armory.com)
# 93/07/18 Added "#" arg type
# 93/09/26 Do not count -h against MinArgs
# 94/01/01 Stop scanning at first non-option arg.  Added ">" option type.
#          Removed meaning of "+" or "-" by itself.
# 94/03/08 Added & option and *()< option types.
# 94/04/02 Added NoRCopt to Opts()
# 94/06/11 Mark numeric variables as such.
# 94/07/08 Opts(): Do not require any args if h option is given.
# 95/01/22 Record options given more than once.  Record option num in argv.
# 95/06/08 Added ExclusiveOptions().
# 96/01/20 Let rcfiles be a colon-separated list of filenames.
#          Expand $VARNAME at the start of its filenames.
#          Let varname=0 and -option- turn off an option.
# 96/05/05 Changed meaning of 7th arg to Opts; now can specify exactly how many
#          of the vars should be searched for in the environment.
#          Check for duplicate rcfiles.
# 96/05/13 Return more specific error values.  Note: ProcArgs() and InitOpts()
#          now return various negatives values on error, not just -1, and
#          Opts() may set Err to various positive values, not just 1.
#          Added AllowUnrecOpt.
# 96/05/23 Check type given for & option
# 96/06/15 Re-port to awk
# 96/10/01 Moved file-reading code into ReadConfFile(), so that it can be
#          used by other functions.
# 96/10/15 Added OptChars
# 96/11/01 Added exOpts arg to Opts()
# 96/11/16 Added ; type
# 96/12/08 Added Opt2Set() & Opt2Sets()
# 96/12/27 Added CmdLineOpt()

# optlist is a string which contains all of the possible command line options.
# A character followed by certain characters indicates that the option takes
# an argument, with type as follows:
# :	String argument
# ;	Non-empty string argument
# *	Floating point argument
# (	Non-negative floating point argument
# )	Positive floating point argument
# #	Integer argument
# <	Non-negative integer argument
# >	Positive integer argument
# The only difference the type of argument makes is in the runtime argument
# error checking that is done.

# The & option is a special case used to get numeric options without the
# user having to give an option character.  It is shorthand for [-+.0-9].
# If & is included in optlist and an option string that begins with one of
# these characters is seen, the value given to "&" will include the first
# char of the option.  & must be followed by a type character other than ":"
# or ";".
# Note that if e.g. &> is given, an option of -.5 will produce an error.

# Strings in argv[] which begin with "-" or "+" are taken to be
# strings of options, except that a string which consists solely of "-"
# or "+" is taken to be a non-option string; like other non-option strings,
# it stops the scanning of argv and is left in argv[].
# An argument of "--" or "++" also stops the scanning of argv[] but is removed.
# If an option takes an argument, the argument may either immediately
# follow it or be given separately.
# "-" and "+" options are treated the same.  "+" is allowed because most awks
# take any -options to be arguments to themselves.  gawk 2.15 was enhanced to
# stop scanning when it encounters an unrecognized option, though until 2.15.5
# this feature had a flaw that caused problems in some cases.  See the OptChars
# parameter to explicitly set the option-specifier characters.

# If an option that does not take an argument is given,
# an index with its name is created in Options and its value is set to the
# number of times it occurs in argv[].

# If an option that does take an argument is given, an index with its name is
# created in Options and its value is set to the value of the argument given
# for it, and Options[option-name,"count"] is (initially) set to the 1.
# If an option that takes an argument is given more than once,
# Options[option-name,"count"] is incremented, and the value is assigned to
# the index (option-name,instance) where instance is 2 for the second occurance
# of the option, etc.
# In other words, the first time an option with a value is encountered, the
# value is assigned to an index consisting only of its name; for any further
# occurances of the option, the value index has an extra (count) dimension.

# The sequence number for each option found in argv[] is stored in
# Options[option-name,"num",instance], where instance is 1 for the first
# occurance of the option, etc.  The sequence number starts at 1 and is
# incremented for each option, both those that have a value and those that
# do not.  Options set from a config file have a value of 0 assigned to this.

# Options and their arguments are deleted from argv.
# Note that this means that there may be gaps left in the indices of argv[].
# If compress is nonzero, argv[] is packed by moving its elements so that
# they have contiguous integer indices starting with 0.
# Option processing will stop with the first unrecognized option, just as
# though -- was given except that unlike -- the unrecognized option will not be
# removed from ARGV[].  Normally, an error value is returned in this case.
# If AllowUnrecOpt is true, it is not an error for an unrecognized option to
# be found, so the number of remaining arguments is returned instead.
# If OptChars is not a null string, it is the set of characters that indicate
# that an argument is an option string if the string begins with one of the
# characters.  A string consisting solely of two of the same option-indicator
# characters stops the scanning of argv[].  The default is "-+".
# argv[0] is not examined.
# The number of arguments left in argc is returned.
# If an error occurs, the global string OptErr is set to an error message
# and a negative value is returned.
# Current error values:
# -1: option that required an argument did not get it.
# -2: argument of incorrect type supplied for an option.
# -3: unrecognized (invalid) option.
function ProcArgs(argc,argv,OptList,Options,compress,AllowUnrecOpt,OptChars,
ArgNum,ArgsLeft,Arg,ArgLen,ArgInd,Option,Pos,NumOpt,Value,HadValue,specGiven,
NeedNextOpt,GotValue,OptionNum,Escape,dest,src,count,c,OptTerm,OptCharSet)
{
# ArgNum is the index of the argument being processed.
# ArgsLeft is the number of arguments left in argv.
# Arg is the argument being processed.
# ArgLen is the length of the argument being processed.
# ArgInd is the position of the character in Arg being processed.
# Option is the character in Arg being processed.
# Pos is the position in OptList of the option being processed.
# NumOpt is true if a numeric option may be given.
    ArgsLeft = argc
    NumOpt = index(OptList,"&")
    OptionNum = 0
    if (OptChars == "")
	OptChars = "-+"
    while (OptChars != "") {
	c = substr(OptChars,1,1)
	OptChars = substr(OptChars,2)
	OptCharSet[c]
	OptTerm[c c]
    }
    for (ArgNum = 1; ArgNum < argc; ArgNum++) {
	Arg = argv[ArgNum]
	if (length(Arg) < 2 || !((specGiven = substr(Arg,1,1)) in OptCharSet))
	    break	# Not an option; quit
	if (Arg in OptTerm) {
	    delete argv[ArgNum]
	    ArgsLeft--
	    break
	}
	ArgLen = length(Arg)
	for (ArgInd = 2; ArgInd <= ArgLen; ArgInd++) {
	    Option = substr(Arg,ArgInd,1)
	    if (NumOpt && Option ~ /[-+.0-9]/) {
		# If this option is a numeric option, make its flag be & and
		# its option string flag position be the position of & in
		# the option string.
		Option = "&"
		Pos = NumOpt
		# Prefix Arg with a char so that ArgInd will point to the
		# first char of the numeric option.
		Arg = "&" Arg
		ArgLen++
	    }
	    # Find position of flag in option string, to get its type (if any).
	    # Disallow & as literal flag.
	    else if (!(Pos = index(OptList,Option)) || Option == "&") {
		if (AllowUnrecOpt) {
		    Escape = 1
		    break
		}
		else {
		    OptErr = "Invalid option: " specGiven Option
		    return -3
		}
	    }

	    # Find what the value of the option will be if it takes one.
	    # NeedNextOpt is true if the option specifier is the last char of
	    # this arg, which means that if the option requires a value it is
	    # the next arg.
	    if (NeedNextOpt = (ArgInd >= ArgLen)) { # Value is the next arg
		if (GotValue = ArgNum + 1 < argc)
		    Value = argv[ArgNum+1]
	    }
	    else {	# Value is included with option
		Value = substr(Arg,ArgInd + 1)
		GotValue = 1
	    }

	    if (HadValue = AssignVal(Option,Value,Options,
	    substr(OptList,Pos + 1,1),GotValue,"",++OptionNum,!NeedNextOpt,
	    specGiven)) {
		if (HadValue < 0)	# error occured
		    return HadValue
		if (HadValue == 2)
		    ArgInd++	# Account for the single-char value we used.
		else {
		    if (NeedNextOpt) {	# option took next arg as value
			delete argv[++ArgNum]
			ArgsLeft--
		    }
		    break	# This option has been used up
		}
	    }
	}
	if (Escape)
	    break
	# Do not delete arg until after processing of it, so that if it is not
	# recognized it can be left in ARGV[].
	delete argv[ArgNum]
	ArgsLeft--
    }
    if (compress != 0) {
	dest = 1
	src = argc - ArgsLeft + 1
	for (count = ArgsLeft - 1; count; count--) {
	    ARGV[dest] = ARGV[src]
	    dest++
	    src++
	}
    }
    return ArgsLeft
}

# Assignment to values in Options[] occurs only in this function.
# Option: Option specifier character.
# Value: Value to be assigned to option, if it takes a value.
# Options[]: Options array to return values in.
# ArgType: Argument type specifier character.
# GotValue: Whether any value is available to be assigned to this option.
# Name: Name of option being processed.
# OptionNum: Number of this option (starting with 1) if set in argv[],
#     or 0 if it was given in a config file or in the environment.
# SingleOpt: true if the value (if any) that is available for this option was
#     given as part of the same command line arg as the option.  Used only for
#     options from the command line.
# specGiven is the option specifier character use, if any (e.g. - or +),
# for use in error messages.
# Global variables: OptErr
# Return value: negative value on error, 0 if option did not require an
# argument, 1 if it did & used the whole arg, 2 if it required just one char of
# the arg.
# Current error values:
# -1: Option that required an argument did not get it.
# -2: Value of incorrect type supplied for option.
# -3: Bad type given for option &
function AssignVal(Option,Value,Options,ArgType,GotValue,Name,OptionNum,
SingleOpt,specGiven,  UsedValue,Err,NumTypes) {
    # If option takes a value...    [
    NumTypes = "*()#<>]"
    if (Option == "&" && ArgType !~ "[" NumTypes) {	# ]
	OptErr = "Bad type given for & option"
	return -3
    }

    if (UsedValue = (ArgType ~ "[:;" NumTypes)) {	# ]
	if (!GotValue) {
	    if (Name != "")
		OptErr = "Variable requires a value -- " Name
	    else
		OptErr = "option requires an argument -- " Option
	    return -1
	}
	if ((Err = CheckType(ArgType,Value,Option,Name,specGiven)) != "") {
	    OptErr = Err
	    return -2
	}
	# Mark this as a numeric variable; will be propogated to Options[] val.
	if (ArgType != ":" && ArgType != ";")
	    Value += 0
	if ((Instance = ++Options[Option,"count"]) > 1)
	    Options[Option,Instance] = Value
	else
	    Options[Option] = Value
    }
    # If this is an environ or rcfile assignment & it was given a value...
    else if (!OptionNum && Value != "") {
	UsedValue = 1
	# If the value is "0" or "-" and this is the first instance of it,
	# do not set Options[Option]; this allows an assignment in an rcfile to
	# turn off an option (for the simple "Option in Options" test) in such
	# a way that it cannot be turned on in a later file.
	if (!(Option in Options) && (Value == "0" || Value == "-"))
	    Instance = 1
	else
	    Instance = ++Options[Option]
	# Save the value even though this is a flag
	Options[Option,Instance] = Value
    }
    # If this is a command line flag and has a - following it in the same arg,
    # it is being turned off.
    else if (OptionNum && SingleOpt && substr(Value,1,1) == "-") {
	UsedValue = 2
	if (Option in Options)
	    Instance = ++Options[Option]
	else
	    Instance = 1
	Options[Option,Instance]
    }
    # If this is a flag assignment without a value, increment the count for the
    # flag unless it was turned off.  The indicator for a flag being turned off
    # is that the flag index has not been set in Options[] but it has an
    # instance count.
    else if (Option in Options || !((Option,1) in Options))
	# Increment number of times this flag seen; will inc null value to 1
	Instance = ++Options[Option]
    Options[Option,"num",Instance] = OptionNum
    return UsedValue
}

# Option is the option letter
# Value is the value being assigned
# Name is the var name of the option, if any
# ArgType is one of:
# :	String argument
# ;	Non-null string argument
# *	Floating point argument
# (	Non-negative floating point argument
# )	Positive floating point argument
# #	Integer argument
# <	Non-negative integer argument
# >	Positive integer argument
# specGiven is the option specifier character use, if any (e.g. - or +),
# for use in error messages.
# Returns null on success, err string on error
function CheckType(ArgType,Value,Option,Name,specGiven,  Err,ErrStr) {
    if (ArgType == ":")
	return ""
    if (ArgType == ";") {
	if (Value == "")
	    Err = "must be a non-empty string"
    }
    # A number begins with optional + or -, and is followed by a string of
    # digits or a decimal with digits before it, after it, or both
    else if (Value !~ /^[-+]?([0-9]+|[0-9]*\.[0-9]+|[0-9]+\.)$/)
	Err = "must be a number"
    else if (ArgType ~ "[#<>]" && Value ~ /\./)
	Err = "may not include a fraction"
    else if (ArgType ~ "[()<>]" && Value < 0)
	Err = "may not be negative"
    # (
    else if (ArgType ~ "[)>]" && Value == 0)
	Err = "must be a positive number"
    if (Err != "") {
	ErrStr = "Bad value \"" Value "\".  Value assigned to "
	if (Name != "")
	    return ErrStr "variable " substr(Name,1,1) " " Err
	else {
	    if (Option == "&")
		Option = Value
	    return ErrStr "option " specGiven substr(Option,1,1) " " Err
	}
    }
    else
	return ""
}

# Note: only the above functions are needed by ProcArgs.
# The rest of these functions call ProcArgs() and also do other
# option-processing stuff.

# Opts: Process command line arguments.
# Opts processes command line arguments using ProcArgs()
# and checks for errors.  If an error occurs, a message is printed
# and the program is exited.
#
# Input variables:
# Name is the name of the program, for error messages.
# Usage is a usage message, for error messages.
# OptList the option description string, as used by ProcArgs().
# MinArgs is the minimum number of non-option arguments that this
# program should have, non including ARGV[0] and +h.
# If the program does not require any non-option arguments,
# MinArgs should be omitted or given as 0.
# rcFiles, if given, is a colon-seprated list of filenames to read for
# variable initialization.  If a filename begins with ~/, the ~ is replaced
# by the value of the environment variable HOME.  If a filename begins with
# $, the part from the character after the $ up until (but not including)
# the first character not in [a-zA-Z0-9_] will be searched for in the
# environment; if found its value will be substituted, if not the filename will
# be discarded.
# rcfiles are read in the order given.
# Values given in them will not override values given on the command line,
# and values given in later files will not override those set in earlier
# files, because AssignVal() will store each with a different instance index.
# The first instance of each variable, either on the command line or in an
# rcfile, will be stored with no instance index, and this is the value
# normally used by programs that call this function.
# VarNames is a comma-separated list of variable names to map to options,
# in the same order as the options are given in OptList.
# If EnvSearch is given and nonzero, the first EnvSearch variables will also be
# searched for in the environment.  If set to -1, all values will be searched
# for in the environment.  Values given in the environment will override
# those given in the rcfiles but not those given on the command line.
# NoRCopt, if given, is an additional letter option that if given on the
# command line prevents the rcfiles from being read.
# See ProcArgs() for a description of AllowUnRecOpt and optChars, and
# ExclusiveOptions() for a description of exOpts.
# Special options:
# If x is made an option and is given, some debugging info is output.
# h is assumed to be the help option.

# Global variables:
# The command line arguments are taken from ARGV[].
# The arguments that are option specifiers and values are removed from
# ARGV[], leaving only ARGV[0] and the non-option arguments.
# The number of elements in ARGV[] should be in ARGC.
# After processing, ARGC is set to the number of elements left in ARGV[].
# The option values are put in Options[].
# On error, Err is set to a positive integer value so it can be checked for in
# an END block.
# Return value: The number of elements left in ARGV is returned.
# Must keep OptErr global since it may be set by InitOpts().
function Opts(Name,Usage,OptList,MinArgs,rcFiles,VarNames,EnvSearch,NoRCopt,
AllowUnrecOpt,optChars,exOpts,  ArgsLeft,e) {
    if (MinArgs == "")
	MinArgs = 0
    ArgsLeft = ProcArgs(ARGC,ARGV,OptList NoRCopt,Options,1,AllowUnrecOpt,
    optChars)
    if (ArgsLeft < (MinArgs+1) && !("h" in Options)) {
	if (ArgsLeft >= 0) {
	    OptErr = "Not enough arguments"
	    Err = 4
	}
	else
	    Err = -ArgsLeft
	printf "%s: %s.\nUse -h for help.\n%s\n",
	Name,OptErr,Usage > "/dev/stderr"
	exit 1
    }
    if (rcFiles != "" && (NoRCopt == "" || !(NoRCopt in Options)) &&
    (e = InitOpts(rcFiles,Options,OptList,VarNames,EnvSearch)) < 0)
    {
	print Name ": " OptErr ".\nUse -h for help." > "/dev/stderr"
	Err = -e
	exit 1
    }
    if ((exOpts != "") && ((OptErr = ExclusiveOptions(exOpts,Options)) != ""))
    {
	printf "%s: Error: %s\n",Name,OptErr > "/dev/stderr"
	Err = 1
	exit 1
    }
    return ArgsLeft
}

# ReadConfFile(): Read a file containing var/value assignments, in the form
# <variable-name><assignment-char><value>.
# Whitespace (spaces and tabs) around a variable (leading whitespace on the
# line and whitespace between the variable name and the assignment character) 
# is stripped.  Lines that do not contain an assignment operator or which
# contain a null variable name are ignored, other than possibly being noted in
# the return value.  If more than one assignment is made to a variable, the
# first assignment is used.
# Input variables:
# File is the file to read.
# Comment is the line-comment character.  If it is found as the first non-
#     whitespace character on a line, the line is ignored.
# Assign is the assignment string.  The first instance of Assign on a line
#     separates the variable name from its value.
# If StripWhite is true, whitespace around the value (whitespace between the
#     assignment char and trailing whitespace on the line) is stripped.
# VarPat is a pattern that variable names must match.  
#     Example: "^[a-zA-Z][a-zA-Z0-9]+$"
# If FlagsOK is true, variables are allowed to be "set" by being put alone on
#     a line; no assignment operator is needed.  These variables are set in
#     the output array with a null value.  Lines containing nothing but
#     whitespace are still ignored.
# Output variables:
# Values[] contains the assignments, with the indexes being the variable names
#     and the values being the assigned values.
# Lines[] contains the line number that each variable occured on.  A flag set
#     is record by giving it an index in Lines[] but not in Values[].
# Return value:
# If any errors occur, a string consisting of descriptions of the errors
# separated by newlines is returned.  In no case will the string start with a
# numeric value.  If no errors occur,  the number of lines read is returned.
function ReadConfigFile(Values,Lines,File,Comment,Assign,StripWhite,VarPat,
FlagsOK,
Line,Status,Errs,AssignLen,LineNum,Var,Val) {
    if (Comment != "")
	Comment = "^" Comment
    AssignLen = length(Assign)
    if (VarPat == "")
	VarPat = "."	# null varname not allowed
    while ((Status = (getline Line < File)) == 1) {
	LineNum++
	sub("^[ \t]+","",Line)
	if (Line == "")		# blank line
	    continue
	if (Comment != "" && Line ~ Comment)
	    continue
	if (Pos = index(Line,Assign)) {
	    Var = substr(Line,1,Pos-1)
	    Val = substr(Line,Pos+AssignLen)
	    if (StripWhite) {
		sub("^[ \t]+","",Val)
		sub("[ \t]+$","",Val)
	    }
	}
	else {
	    Var = Line	# If no value, var is entire line
	    Val = ""
	}
	if (!FlagsOK && Val == "") {
	    Errs = Errs \
	    sprintf("\nBad assignment on line %d of file %s: %s",
	    LineNum,File,Line)
	    continue
	}
	sub("[ \t]+$","",Var)
	if (Var !~ VarPat) {
	    Errs = Errs sprintf("\nBad variable name on line %d of file %s: %s",
	    LineNum,File,Var)
	    continue
	}
	if (!(Var in Lines)) {
	    Lines[Var] = LineNum
	    if (Pos)
		Values[Var] = Val
	}
    }
    if (Status)
	Errs = Errs "\nCould not read file " File
    close(File)
    return Errs == "" ? LineNum : substr(Errs,2)	# Skip first newline
}

# Variables:
# Data is stored in Options[].
# rcFiles, OptList, VarNames, and EnvSearch are as as described for Opts().
# Global vars:
# Sets OptErr.  Uses ENVIRON[].
# If anything is read from any of the rcfiles, sets READ_RCFILE to 1.
function InitOpts(rcFiles,Options,OptList,VarNames,EnvSearch,
Line,Var,Pos,Vars,Map,CharOpt,NumVars,TypesInd,Types,Type,Ret,i,rcFile,
fNames,numrcFiles,filesRead,Err,Values,retStr) {
    split("",filesRead,"")	# make awk know this is an array
    NumVars = split(VarNames,Vars,",")
    TypesInd = Ret = 0
    if (EnvSearch == -1)
	EnvSearch = NumVars
    for (i = 1; i <= NumVars; i++) {
	Var = Vars[i]
	CharOpt = substr(OptList,++TypesInd,1)
	if (CharOpt ~ "^[:;*()#<>&]$")
	    CharOpt = substr(OptList,++TypesInd,1)
	Map[Var] = CharOpt
	Types[Var] = Type = substr(OptList,TypesInd+1,1)
	# Do not overwrite entries from environment
	if (i <= EnvSearch && Var in ENVIRON &&
	(Err = AssignVal(CharOpt,ENVIRON[Var],Options,Type,1,Var,0)) < 0)
	    return Err
    }

    numrcFiles = split(rcFiles,fNames,":")
    for (i = 1; i <= numrcFiles; i++) {
	rcFile = fNames[i]
	if (rcFile ~ "^~/")
	    rcFile = ENVIRON["HOME"] substr(rcFile,2)
	else if (rcFile ~ /^\$/) {
	    rcFile = substr(rcFile,2)
	    match(rcFile,"^[a-zA-Z0-9_]*")
	    envvar = substr(rcFile,1,RLENGTH)
	    if (envvar in ENVIRON)
		rcFile = ENVIRON[envvar] substr(rcFile,RLENGTH+1)
	    else
		continue
	}
	if (rcFile in filesRead)
	    continue
	# rcfiles are liable to be given more than once, e.g. UHOME and HOME
	# may be the same
	filesRead[rcFile]
	if ("x" in Options)
	    printf "Reading configuration file %s\n",rcFile > "/dev/stderr"
	retStr = ReadConfigFile(Values,Lines,rcFile,"#","=",0,"",1)
	if (retStr > 0)
	    READ_RCFILE = 1
	else if (ret != "") {
	    OptErr = retStr
	    Ret = -1
	}
	for (Var in Lines)
	    if (Var in Map) {
		if ((Err = AssignVal(Map[Var],
		Var in Values ? Values[Var] : "",Options,Types[Var],
		Var in Values,Var,0)) < 0)
		    return Err
	    }
	    else {
		OptErr = sprintf(\
		"Unknown var \"%s\" assigned to on line %d\nof file %s",Var,
		Lines[Var],rcFile)
		Ret = -1
	    }
    }

    if ("x" in Options)
	for (Var in Map)
	    if (Map[Var] in Options)
		printf "(%s) %s=%s\n",Map[Var],Var,Options[Map[Var]] > \
		"/dev/stderr"
	    else
		printf "(%s) %s not set\n",Map[Var],Var > "/dev/stderr"
    return Ret
}

# OptSets is a semicolon-separated list of sets of option sets.
# Within a list of option sets, the option sets are separated by commas.  For
# each set of sets, if any option in one of the sets is in Options[] AND any
# option in one of the other sets is in Options[], an error string is returned.
# If no conflicts are found, nothing is returned.
# Example: if OptSets = "ab,def,g;i,j", an error will be returned due to
# the exclusions presented by the first set of sets (ab,def,g) if:
# (a or b is in Options[]) AND (d, e, or f is in Options[]) OR
# (a or b is in Options[]) AND (g is in Options) OR
# (d, e, or f is in Options[]) AND (g is in Options)
# An error will be returned due to the exclusions presented by the second set
# of sets (i,j) if: (i is in Options[]) AND (j is in Options[]).
# todo: make options given on command line unset options given in config file
# todo: that they conflict with.
function ExclusiveOptions(OptSets,Options,
Sets,SetSet,NumSets,Pos1,Pos2,Len,s1,s2,c1,c2,ErrStr,L1,L2,SetSets,NumSetSets,
SetNum,OSetNum) {
    NumSetSets = split(OptSets,SetSets,";")
    # For each set of sets...
    for (SetSet = 1; SetSet <= NumSetSets; SetSet++) {
	# NumSets is the number of sets in this set of sets.
	NumSets = split(SetSets[SetSet],Sets,",")
	# For each set in a set of sets except the last...
	for (SetNum = 1; SetNum < NumSets; SetNum++) {
	    s1 = Sets[SetNum]
	    L1 = length(s1)
	    for (Pos1 = 1; Pos1 <= L1; Pos1++)
		# If any of the options in this set was given, check whether
		# any of the options in the other sets was given.  Only check
		# later sets since earlier sets will have already been checked
		# against this set.
		if ((c1 = substr(s1,Pos1,1)) in Options)
		    for (OSetNum = SetNum+1; OSetNum <= NumSets; OSetNum++) {
			s2 = Sets[OSetNum]
			L2 = length(s2)
			for (Pos2 = 1; Pos2 <= L2; Pos2++)
			    if ((c2 = substr(s2,Pos2,1)) in Options)
				ErrStr = ErrStr "\n"\
				sprintf("Cannot give both %s and %s options.",
				c1,c2)
		    }
	}
    }
    if (ErrStr != "")
	return substr(ErrStr,2)
    return ""
}

# The value of each instance of option Opt that occurs in Options[] is made an
# index of Set[].
# The return value is the number of instances of Opt in Options.
function Opt2Set(Options,Opt,Set,  count) {
    if (!(Opt in Options))
	return 0
    Set[Options[Opt]]
    count = Options[Opt,"count"]
    for (; count > 1; count--)
	Set[Options[Opt,count]]
    return count
}

# The value of each instance of option Opt that occurs in Options[] that
# begins with "!" is made an index of nSet[] (with the ! stripped from it).
# Other values are made indexes of Set[].
# The return value is the number of instances of Opt in Options.
function Opt2Sets(Options,Opt,Set,nSet,  count,aSet,ret) {
    ret = Opt2Set(Options,Opt,aSet)
    for (value in aSet)
	if (substr(value,1,1) == "!")
	    nSet[substr(value,2)]
	else
	    Set[value]
    return ret
}

# Returns true if option Opt was given on the command line.
function CmdLineOpt(Options,Opt,  i) {
    for (i = 1; (Opt,"num",i) in Options; i++)
	if (Options[Opt,"num",i] != 0)
	    return 1
    return 0
}
### End of ProcArgs library