[apple/shell_cmds.git] / sh / TOUR

#	@(#)TOUR	8.1 (Berkeley) 5/31/93
# $FreeBSD: head/bin/sh/TOUR 317882 2017-05-06 13:28:42Z jilles $

NOTE -- This is the original TOUR paper distributed with ash and
does not represent the current state of the shell.  It is provided anyway
since it provides helpful information for how the shell is structured,
but be warned that things have changed -- the current shell is
still under development.

================================================================

                       A Tour through Ash

               Copyright 1989 by Kenneth Almquist.


DIRECTORIES:  The subdirectory bltin contains commands which can
be compiled stand-alone.  The rest of the source is in the main
ash directory.

SOURCE CODE GENERATORS:  Files whose names begin with "mk" are
programs that generate source code.  A complete list of these
programs is:

        program         input files         generates
        -------         -----------         ---------
        mkbuiltins      builtins.def        builtins.h builtins.c
        mknodes         nodetypes           nodes.h nodes.c
        mksyntax            -               syntax.h syntax.c
        mktokens            -               token.h

There are undoubtedly too many of these.

EXCEPTIONS:  Code for dealing with exceptions appears in
exceptions.c.  The C language doesn't include exception handling,
so I implement it using setjmp and longjmp.  The global variable
exception contains the type of exception.  EXERROR is raised by
calling error.  EXINT is an interrupt.

INTERRUPTS:  In an interactive shell, an interrupt will cause an
EXINT exception to return to the main command loop.  (Exception:
EXINT is not raised if the user traps interrupts using the trap
command.)  The INTOFF and INTON macros (defined in exception.h)
provide uninterruptible critical sections.  Between the execution
of INTOFF and the execution of INTON, interrupt signals will be
held for later delivery.  INTOFF and INTON can be nested.

MEMALLOC.C:  Memalloc.c defines versions of malloc and realloc
which call error when there is no memory left.  It also defines a
stack oriented memory allocation scheme.  Allocating off a stack
is probably more efficient than allocation using malloc, but the
big advantage is that when an exception occurs all we have to do
to free up the memory in use at the time of the exception is to
restore the stack pointer.  The stack is implemented using a
linked list of blocks.

STPUTC:  If the stack were contiguous, it would be easy to store
strings on the stack without knowing in advance how long the
string was going to be:
        p = stackptr;
        *p++ = c;       /* repeated as many times as needed */
        stackptr = p;
The following three macros (defined in memalloc.h) perform these
operations, but grow the stack if you run off the end:
        STARTSTACKSTR(p);
        STPUTC(c, p);   /* repeated as many times as needed */
        grabstackstr(p);

We now start a top-down look at the code:

MAIN.C:  The main routine performs some initialization, executes
the user's profile if necessary, and calls cmdloop.  Cmdloop
repeatedly parses and executes commands.

OPTIONS.C:  This file contains the option processing code.  It is
called from main to parse the shell arguments when the shell is
invoked, and it also contains the set builtin.  The -i and -m op-
tions (the latter turns on job control) require changes in signal
handling.  The routines setjobctl (in jobs.c) and setinteractive
(in trap.c) are called to handle changes to these options.

PARSING:  The parser code is all in parser.c.  A recursive des-
cent parser is used.  Syntax tables (generated by mksyntax) are
used to classify characters during lexical analysis.  There are
four tables:  one for normal use, one for use when inside single
quotes and dollar single quotes, one for use when inside double
quotes and one for use in arithmetic.  The tables are machine
dependent because they are indexed by character variables and
the range of a char varies from machine to machine.

PARSE OUTPUT:  The output of the parser consists of a tree of
nodes.  The various types of nodes are defined in the file node-
types.

Nodes of type NARG are used to represent both words and the con-
tents of here documents.  An early version of ash kept the con-
tents of here documents in temporary files, but keeping here do-
cuments in memory typically results in significantly better per-
formance.  It would have been nice to make it an option to use
temporary files for here documents, for the benefit of small
machines, but the code to keep track of when to delete the tem-
porary files was complex and I never fixed all the bugs in it.
(AT&T has been maintaining the Bourne shell for more than ten
years, and to the best of my knowledge they still haven't gotten
it to handle temporary files correctly in obscure cases.)

The text field of a NARG structure points to the text of the
word.  The text consists of ordinary characters and a number of
special codes defined in parser.h.  The special codes are:

        CTLVAR              Parameter expansion
        CTLENDVAR           End of parameter expansion
        CTLBACKQ            Command substitution
        CTLBACKQ|CTLQUOTE   Command substitution inside double quotes
        CTLARI              Arithmetic expansion
        CTLENDARI           End of arithmetic expansion
        CTLESC              Escape next character

A variable substitution contains the following elements:

        CTLVAR type name '=' [ alternative-text CTLENDVAR ]

The type field is a single character specifying the type of sub-
stitution.  The possible types are:

        VSNORMAL            $var
        VSMINUS             ${var-text}
        VSMINUS|VSNUL       ${var:-text}
        VSPLUS              ${var+text}
        VSPLUS|VSNUL        ${var:+text}
        VSQUESTION          ${var?text}
        VSQUESTION|VSNUL    ${var:?text}
        VSASSIGN            ${var=text}
        VSASSIGN|VSNUL      ${var:=text}
        VSTRIMLEFT          ${var#text}
        VSTRIMLEFTMAX       ${var##text}
        VSTRIMRIGHT         ${var%text}
        VSTRIMRIGHTMAX      ${var%%text}
        VSLENGTH            ${#var}
        VSERROR             delayed error

In addition, the type field will have the VSQUOTE flag set if the
variable is enclosed in double quotes and the VSLINENO flag if
LINENO is being expanded (the parameter name is the decimal line
number).  The parameter's name comes next, terminated by an equals
sign.  If the type is not VSNORMAL (including when it is VSLENGTH),
then the text field in the substitution follows, terminated by a
CTLENDVAR byte.

The type VSERROR is used to allow parsing bad substitutions like
${var[7]} and generate an error when they are expanded.

Commands in back quotes are parsed and stored in a linked list.
The locations of these commands in the string are indicated by
CTLBACKQ and CTLBACKQ+CTLQUOTE characters, depending upon whether
the back quotes were enclosed in double quotes.

Arithmetic expansion starts with CTLARI and ends with CTLENDARI.

The character CTLESC escapes the next character, so that in case
any of the CTL characters mentioned above appear in the input,
they can be passed through transparently.  CTLESC is also used to
escape '*', '?', '[', and '!' characters which were quoted by the
user and thus should not be used for file name generation.

CTLESC characters have proved to be particularly tricky to get
right.  In the case of here documents which are not subject to
variable and command substitution, the parser doesn't insert any
CTLESC characters to begin with (so the contents of the text
field can be written without any processing).  Other here docu-
ments, and words which are not subject to file name generation,
have the CTLESC characters removed during the variable and command
substitution phase.  Words which are subject to file name
generation have the CTLESC characters removed as part of the file
name phase.

EXECUTION:  Command execution is handled by the following files:
        eval.c     The top level routines.
        redir.c    Code to handle redirection of input and output.
        jobs.c     Code to handle forking, waiting, and job control.
        exec.c     Code to do path searches and the actual exec sys call.
        expand.c   Code to evaluate arguments.
        var.c      Maintains the variable symbol table.  Called from expand.c.

EVAL.C:  Evaltree recursively executes a parse tree.  The exit
status is returned in the global variable exitstatus.  The alter-
native entry evalbackcmd is called to evaluate commands in back
quotes.  It saves the result in memory if the command is a buil-
tin; otherwise it forks off a child to execute the command and
connects the standard output of the child to a pipe.

JOBS.C:  To create a process, you call makejob to return a job
structure, and then call forkshell (passing the job structure as
an argument) to create the process.  Waitforjob waits for a job
to complete.  These routines take care of process groups if job
control is defined.

REDIR.C:  Ash allows file descriptors to be redirected and then
restored without forking off a child process.  This is accom-
plished by duplicating the original file descriptors.  The redir-
tab structure records where the file descriptors have been dupli-
cated to.

EXEC.C:  The routine find_command locates a command, and enters
the command in the hash table if it is not already there.  The
third argument specifies whether it is to print an error message
if the command is not found.  (When a pipeline is set up,
find_command is called for all the commands in the pipeline be-
fore any forking is done, so to get the commands into the hash
table of the parent process.  But to make command hashing as
transparent as possible, we silently ignore errors at that point
and only print error messages if the command cannot be found
later.)

The routine shellexec is the interface to the exec system call.

EXPAND.C:  As the routine argstr generates words by parameter
expansion, command substitution and arithmetic expansion, it
performs word splitting on the result.  As each word is output,
the routine expandmeta performs file name generation (if enabled).

VAR.C:  Variables are stored in a hash table.  Probably we should
switch to extensible hashing.  The variable name is stored in the
same string as the value (using the format "name=value") so that
no string copying is needed to create the environment of a com-
mand.  Variables which the shell references internally are preal-
located so that the shell can reference the values of these vari-
ables without doing a lookup.

When a program is run, the code in eval.c sticks any environment
variables which precede the command (as in "PATH=xxx command") in
the variable table as the simplest way to strip duplicates, and
then calls "environment" to get the value of the environment.

BUILTIN COMMANDS:  The procedures for handling these are scat-
tered throughout the code, depending on which location appears
most appropriate.  They can be recognized because their names al-
ways end in "cmd".  The mapping from names to procedures is
specified in the file builtins.def, which is processed by the
mkbuiltins command.

A builtin command is invoked with argc and argv set up like a
normal program.  A builtin command is allowed to overwrite its
arguments.  Builtin routines can call nextopt to do option pars-
ing.  This is kind of like getopt, but you don't pass argc and
argv to it.  Builtin routines can also call error.  This routine
normally terminates the shell (or returns to the main command
loop if the shell is interactive), but when called from a non-
special builtin command it causes the builtin command to
terminate with an exit status of 2.

The directory bltins contains commands which can be compiled in-
dependently but can also be built into the shell for efficiency
reasons.  The header file bltin.h takes care of most of the
differences between the ash and the stand-alone environment.
The user should call the main routine "main", and #define main to
be the name of the routine to use when the program is linked into
ash.  This #define should appear before bltin.h is included;
bltin.h will #undef main if the program is to be compiled
stand-alone. A similar approach is used for a few utilities from
bin and usr.bin.

CD.C:  This file defines the cd and pwd builtins.

SIGNALS:  Trap.c implements the trap command.  The routine set-
signal figures out what action should be taken when a signal is
received and invokes the signal system call to set the signal ac-
tion appropriately.  When a signal that a user has set a trap for
is caught, the routine "onsig" sets a flag.  The routine dotrap
is called at appropriate points to actually handle the signal.
When an interrupt is caught and no trap has been set for that
signal, the routine "onint" in error.c is called.

OUTPUT:  Ash uses its own output routines.  There are three out-
put structures allocated.  "Output" represents the standard out-
put, "errout" the standard error, and "memout" contains output
which is to be stored in memory.  This last is used when a buil-
tin command appears in backquotes, to allow its output to be col-
lected without doing any I/O through the UNIX operating system.
The variables out1 and out2 normally point to output and errout,
respectively, but they are set to point to memout when appropri-
ate inside backquotes.

INPUT:  The basic input routine is pgetc, which reads from the
current input file.  There is a stack of input files; the current
input file is the top file on this stack.  The code allows the
input to come from a string rather than a file.  (This is for the
-c option and the "." and eval builtin commands.)  The global
variable plinno is saved and restored when files are pushed and
popped from the stack.  The parser routines store the number of
the current line in this variable.

DEBUGGING:  If DEBUG is defined in shell.h, then the shell will
write debugging information to the file $HOME/trace.  Most of
this is done using the TRACE macro, which takes a set of printf
arguments inside two sets of parenthesis.  Example:
"TRACE(("n=%d0, n))".  The double parenthesis are necessary be-
cause the preprocessor can't handle functions with a variable
number of arguments.  Defining DEBUG also causes the shell to
generate a core dump if it is sent a quit signal.  The tracing
code is in show.c.
Commit	Line	Data
71aad674	1	# @(#)TOUR 8.1 (Berkeley) 5/31/93
254f12f7	2	# $FreeBSD: head/bin/sh/TOUR 317882 2017-05-06 13:28:42Z jilles $
71aad674 A	3
	4	NOTE -- This is the original TOUR paper distributed with ash and
	5	does not represent the current state of the shell. It is provided anyway
	6	since it provides helpful information for how the shell is structured,
	7	but be warned that things have changed -- the current shell is
	8	still under development.
	9
	10	================================================================
	11
	12	A Tour through Ash
	13
	14	Copyright 1989 by Kenneth Almquist.
	15
	16
	17	DIRECTORIES: The subdirectory bltin contains commands which can
	18	be compiled stand-alone. The rest of the source is in the main
	19	ash directory.
	20
	21	SOURCE CODE GENERATORS: Files whose names begin with "mk" are
	22	programs that generate source code. A complete list of these
	23	programs is:
	24
	25	program input files generates
	26	------- ----------- ---------
254f12f7	27	mkbuiltins builtins.def builtins.h builtins.c
71aad674 A	28	mknodes nodetypes nodes.h nodes.c
	29	mksyntax - syntax.h syntax.c
	30	mktokens - token.h
	31
	32	There are undoubtedly too many of these.
	33
	34	EXCEPTIONS: Code for dealing with exceptions appears in
	35	exceptions.c. The C language doesn't include exception handling,
	36	so I implement it using setjmp and longjmp. The global variable
	37	exception contains the type of exception. EXERROR is raised by
	38	calling error. EXINT is an interrupt.
	39
	40	INTERRUPTS: In an interactive shell, an interrupt will cause an
	41	EXINT exception to return to the main command loop. (Exception:
	42	EXINT is not raised if the user traps interrupts using the trap
	43	command.) The INTOFF and INTON macros (defined in exception.h)
	44	provide uninterruptible critical sections. Between the execution
	45	of INTOFF and the execution of INTON, interrupt signals will be
	46	held for later delivery. INTOFF and INTON can be nested.
	47
	48	MEMALLOC.C: Memalloc.c defines versions of malloc and realloc
	49	which call error when there is no memory left. It also defines a
	50	stack oriented memory allocation scheme. Allocating off a stack
	51	is probably more efficient than allocation using malloc, but the
	52	big advantage is that when an exception occurs all we have to do
	53	to free up the memory in use at the time of the exception is to
	54	restore the stack pointer. The stack is implemented using a
	55	linked list of blocks.
	56
	57	STPUTC: If the stack were contiguous, it would be easy to store
	58	strings on the stack without knowing in advance how long the
	59	string was going to be:
	60	p = stackptr;
	61	p++ = c; / repeated as many times as needed */
	62	stackptr = p;
	63	The following three macros (defined in memalloc.h) perform these
	64	operations, but grow the stack if you run off the end:
	65	STARTSTACKSTR(p);
	66	STPUTC(c, p); /* repeated as many times as needed */
	67	grabstackstr(p);
	68
	69	We now start a top-down look at the code:
	70
	71	MAIN.C: The main routine performs some initialization, executes
	72	the user's profile if necessary, and calls cmdloop. Cmdloop
	73	repeatedly parses and executes commands.
	74
	75	OPTIONS.C: This file contains the option processing code. It is
	76	called from main to parse the shell arguments when the shell is
	77	invoked, and it also contains the set builtin. The -i and -m op-
	78	tions (the latter turns on job control) require changes in signal
	79	handling. The routines setjobctl (in jobs.c) and setinteractive
	80	(in trap.c) are called to handle changes to these options.
	81
	82	PARSING: The parser code is all in parser.c. A recursive des-
	83	cent parser is used. Syntax tables (generated by mksyntax) are
	84	used to classify characters during lexical analysis. There are
	85	four tables: one for normal use, one for use when inside single
	86	quotes and dollar single quotes, one for use when inside double
	87	quotes and one for use in arithmetic. The tables are machine
	88	dependent because they are indexed by character variables and
	89	the range of a char varies from machine to machine.
	90
	91	PARSE OUTPUT: The output of the parser consists of a tree of
92	nodes. The various types of nodes are defined in the file node-
93	types.
94
95	Nodes of type NARG are used to represent both words and the con-
96	tents of here documents. An early version of ash kept the con-
97	tents of here documents in temporary files, but keeping here do-
98	cuments in memory typically results in significantly better per-
99	formance. It would have been nice to make it an option to use
100	temporary files for here documents, for the benefit of small
101	machines, but the code to keep track of when to delete the tem-
102	porary files was complex and I never fixed all the bugs in it.
103	(AT&T has been maintaining the Bourne shell for more than ten
104	years, and to the best of my knowledge they still haven't gotten
105	it to handle temporary files correctly in obscure cases.)
106
107	The text field of a NARG structure points to the text of the
108	word. The text consists of ordinary characters and a number of
109	special codes defined in parser.h. The special codes are:
110
254f12f7 A	111	CTLVAR Parameter expansion
254f12f7 A	112	CTLENDVAR End of parameter expansion
71aad674 A	113	CTLBACKQ Command substitution
71aad674 A	114	CTLBACKQ\|CTLQUOTE Command substitution inside double quotes
254f12f7 A	115	CTLARI Arithmetic expansion
254f12f7 A	116	CTLENDARI End of arithmetic expansion
71aad674 A	117	CTLESC Escape next character
	118
	119	A variable substitution contains the following elements:
	120
	121	CTLVAR type name '=' [ alternative-text CTLENDVAR ]
	122
	123	The type field is a single character specifying the type of sub-
	124	stitution. The possible types are:
	125
	126	VSNORMAL $var
	127	VSMINUS ${var-text}
	128	VSMINUS\|VSNUL ${var:-text}
	129	VSPLUS ${var+text}
	130	VSPLUS\|VSNUL ${var:+text}
	131	VSQUESTION ${var?text}
	132	VSQUESTION\|VSNUL ${var:?text}
	133	VSASSIGN ${var=text}
	134	VSASSIGN\|VSNUL ${var:=text}
254f12f7 A	135	VSTRIMLEFT ${var#text}
	136	VSTRIMLEFTMAX ${var##text}
	137	VSTRIMRIGHT ${var%text}
	138	VSTRIMRIGHTMAX ${var%%text}
	139	VSLENGTH ${#var}
	140	VSERROR delayed error
71aad674 A	141
71aad674 A	142	In addition, the type field will have the VSQUOTE flag set if the
254f12f7 A	143	variable is enclosed in double quotes and the VSLINENO flag if
	144	LINENO is being expanded (the parameter name is the decimal line
	145	number). The parameter's name comes next, terminated by an equals
	146	sign. If the type is not VSNORMAL (including when it is VSLENGTH),
	147	then the text field in the substitution follows, terminated by a
	148	CTLENDVAR byte.
	149
	150	The type VSERROR is used to allow parsing bad substitutions like
	151	${var[7]} and generate an error when they are expanded.
71aad674 A	152
	153	Commands in back quotes are parsed and stored in a linked list.
	154	The locations of these commands in the string are indicated by
	155	CTLBACKQ and CTLBACKQ+CTLQUOTE characters, depending upon whether
	156	the back quotes were enclosed in double quotes.
	157
254f12f7 A	158	Arithmetic expansion starts with CTLARI and ends with CTLENDARI.
254f12f7 A	159
71aad674 A	160	The character CTLESC escapes the next character, so that in case
	161	any of the CTL characters mentioned above appear in the input,
	162	they can be passed through transparently. CTLESC is also used to
	163	escape '*', '?', '[', and '!' characters which were quoted by the
	164	user and thus should not be used for file name generation.
	165
	166	CTLESC characters have proved to be particularly tricky to get
	167	right. In the case of here documents which are not subject to
	168	variable and command substitution, the parser doesn't insert any
	169	CTLESC characters to begin with (so the contents of the text
	170	field can be written without any processing). Other here docu-
254f12f7 A	171	ments, and words which are not subject to file name generation,
	172	have the CTLESC characters removed during the variable and command
	173	substitution phase. Words which are subject to file name
	174	generation have the CTLESC characters removed as part of the file
	175	name phase.
71aad674 A	176
	177	EXECUTION: Command execution is handled by the following files:
	178	eval.c The top level routines.
	179	redir.c Code to handle redirection of input and output.
	180	jobs.c Code to handle forking, waiting, and job control.
	181	exec.c Code to do path searches and the actual exec sys call.
	182	expand.c Code to evaluate arguments.
	183	var.c Maintains the variable symbol table. Called from expand.c.
	184
	185	EVAL.C: Evaltree recursively executes a parse tree. The exit
	186	status is returned in the global variable exitstatus. The alter-
	187	native entry evalbackcmd is called to evaluate commands in back
	188	quotes. It saves the result in memory if the command is a buil-
	189	tin; otherwise it forks off a child to execute the command and
	190	connects the standard output of the child to a pipe.
	191
	192	JOBS.C: To create a process, you call makejob to return a job
	193	structure, and then call forkshell (passing the job structure as
	194	an argument) to create the process. Waitforjob waits for a job
	195	to complete. These routines take care of process groups if job
	196	control is defined.
	197
	198	REDIR.C: Ash allows file descriptors to be redirected and then
	199	restored without forking off a child process. This is accom-
	200	plished by duplicating the original file descriptors. The redir-
	201	tab structure records where the file descriptors have been dupli-
	202	cated to.
	203
	204	EXEC.C: The routine find_command locates a command, and enters
	205	the command in the hash table if it is not already there. The
	206	third argument specifies whether it is to print an error message
	207	if the command is not found. (When a pipeline is set up,
	208	find_command is called for all the commands in the pipeline be-
	209	fore any forking is done, so to get the commands into the hash
	210	table of the parent process. But to make command hashing as
	211	transparent as possible, we silently ignore errors at that point
	212	and only print error messages if the command cannot be found
	213	later.)
	214
	215	The routine shellexec is the interface to the exec system call.
	216
254f12f7 A	217	EXPAND.C: As the routine argstr generates words by parameter
	218	expansion, command substitution and arithmetic expansion, it
	219	performs word splitting on the result. As each word is output,
	220	the routine expandmeta performs file name generation (if enabled).
71aad674 A	221
	222	VAR.C: Variables are stored in a hash table. Probably we should
	223	switch to extensible hashing. The variable name is stored in the
	224	same string as the value (using the format "name=value") so that
	225	no string copying is needed to create the environment of a com-
	226	mand. Variables which the shell references internally are preal-
	227	located so that the shell can reference the values of these vari-
	228	ables without doing a lookup.
	229
	230	When a program is run, the code in eval.c sticks any environment
	231	variables which precede the command (as in "PATH=xxx command") in
	232	the variable table as the simplest way to strip duplicates, and
	233	then calls "environment" to get the value of the environment.
	234
	235	BUILTIN COMMANDS: The procedures for handling these are scat-
	236	tered throughout the code, depending on which location appears
	237	most appropriate. They can be recognized because their names al-
	238	ways end in "cmd". The mapping from names to procedures is
254f12f7 A	239	specified in the file builtins.def, which is processed by the
254f12f7 A	240	mkbuiltins command.
71aad674 A	241
	242	A builtin command is invoked with argc and argv set up like a
	243	normal program. A builtin command is allowed to overwrite its
	244	arguments. Builtin routines can call nextopt to do option pars-
	245	ing. This is kind of like getopt, but you don't pass argc and
	246	argv to it. Builtin routines can also call error. This routine
	247	normally terminates the shell (or returns to the main command
254f12f7 A	248	loop if the shell is interactive), but when called from a non-
	249	special builtin command it causes the builtin command to
	250	terminate with an exit status of 2.
71aad674 A	251
	252	The directory bltins contains commands which can be compiled in-
	253	dependently but can also be built into the shell for efficiency
254f12f7 A	254	reasons. The header file bltin.h takes care of most of the
	255	differences between the ash and the stand-alone environment.
	256	The user should call the main routine "main", and #define main to
	257	be the name of the routine to use when the program is linked into
	258	ash. This #define should appear before bltin.h is included;
	259	bltin.h will #undef main if the program is to be compiled
	260	stand-alone. A similar approach is used for a few utilities from
	261	bin and usr.bin.
71aad674 A	262
	263	CD.C: This file defines the cd and pwd builtins.
	264
	265	SIGNALS: Trap.c implements the trap command. The routine set-
	266	signal figures out what action should be taken when a signal is
	267	received and invokes the signal system call to set the signal ac-
	268	tion appropriately. When a signal that a user has set a trap for
	269	is caught, the routine "onsig" sets a flag. The routine dotrap
	270	is called at appropriate points to actually handle the signal.
	271	When an interrupt is caught and no trap has been set for that
	272	signal, the routine "onint" in error.c is called.
	273
254f12f7	274	OUTPUT: Ash uses its own output routines. There are three out-
71aad674 A	275	put structures allocated. "Output" represents the standard out-
	276	put, "errout" the standard error, and "memout" contains output
	277	which is to be stored in memory. This last is used when a buil-
	278	tin command appears in backquotes, to allow its output to be col-
	279	lected without doing any I/O through the UNIX operating system.
	280	The variables out1 and out2 normally point to output and errout,
	281	respectively, but they are set to point to memout when appropri-
	282	ate inside backquotes.
	283
	284	INPUT: The basic input routine is pgetc, which reads from the
	285	current input file. There is a stack of input files; the current
	286	input file is the top file on this stack. The code allows the
	287	input to come from a string rather than a file. (This is for the
	288	-c option and the "." and eval builtin commands.) The global
	289	variable plinno is saved and restored when files are pushed and
	290	popped from the stack. The parser routines store the number of
	291	the current line in this variable.
	292
	293	DEBUGGING: If DEBUG is defined in shell.h, then the shell will
	294	write debugging information to the file $HOME/trace. Most of
	295	this is done using the TRACE macro, which takes a set of printf
	296	arguments inside two sets of parenthesis. Example:
	297	"TRACE(("n=%d0, n))". The double parenthesis are necessary be-
	298	cause the preprocessor can't handle functions with a variable
	299	number of arguments. Defining DEBUG also causes the shell to
	300	generate a core dump if it is sent a quit signal. The tracing
	301	code is in show.c.