man/man1/db.1 - plan9 - Git at Google

 .TH DB 1
 .SH NAME
 db, stack \- debugger
 .SH SYNOPSIS
 .B db
 [
 .I option ...
 ]
 [
 .I pid
 |
 .I corefile
 ]
 [
 .I textfile
 ]
 .PP
 .B stack
 [
 .I pid
 |
 .I corefile
 |
 .I name
 ]
 [
 .I textfile
 ]
 .SH DESCRIPTION
 .I Db
 is a general purpose debugging program.
 It may be used to examine files and to provide
 a controlled environment for the execution
 of programs.
 .PP
 A
 .I textfile
 is a file containing the text and initialized
 data of an executable program.
 A
 .I pid
 or
 .I corefile
 specifies the memory image of a process.
 A
 .I pid
 gives the id of an executing process to be accessed via
 .IR ptrace (2).
 A
 .I corefile
 specifies the name of a core dump (see
 .IR core (5)
 on your system of choice) containing the
 memory image of a terminated process.
 This manual refers to the memory image specified by
 .I pid
 or
 .I corefile
 as a
 .IR memfile .
 .PP
 A
 .I map
 associated with each
 .I textfile
 or
 .I memfile
 supports accesses to instructions and data in the file;
 see `Addresses'.
 .PP
 An argument consisting entirely of digits is assumed
 to be a process id; otherwise, it is the name of a
 .I textfile
 or
 .IR corefile .
 When a
 .I textfile
 is given, the textfile map
 is associated with it.
 If only a
 .I memfile
 is given, the textfile map is
 derived from the corresponding
 .IR textfile ,
 if it can be determined
 (this varies from system to system).
 When a
 .I memfile
 is given, the memfile map is associated with it;
 otherwise the map is undefined and accesses to it
 are not permitted.
 .PP
 .I Stack
 takes the same arguments as
 .IR db .
 It prints a stack trace (see the
 .B $c
 command below) and then exits.
 If the first argument is a process name,
 then
 .I stack
 prints the stack trace of every running process
 with the given name
 that is
 owned by the current user.
 .PP
 Commands to
 .I db
 are read from the standard input and
 responses are to the standard output.
 The options are
 .TP
 .B -q
 Quiet mode:
 suppress informational prints at startup.
 .TP
 .B -w
 Open
 .I textfile
 and
 .I memfile
 for writing as well as reading.
 .TP
 .BI -I path
 Directory in which to look for relative path names in
 .B $<
 and
 .B $<<
 commands.
 .TP
 .BI -m machine
 Assume instructions are for the given CPU type
 (possible names include
 .B 386
 and
 .BR powerpc ;
 adding
 the suffix
 .B -co
 as in
 .B 386-co
 and
 .B powerpc-co
 selects disassembly in the manufacturer's syntax, if
 available,
 rather than the default Plan 9 syntax).
 .PP
 Most
 .I db
 commands have the following form:
 .IP
 .RI [ address ]
 .RB [ ,
 .IR count ]
 .RI [ command ]
 .PP
 If
 .I address
 is present then the current position, called `dot',
 is set to
 .IR address .
 Initially dot
 is set to 0.
 Most commands are repeated
 .I count
 times with
 dot advancing between repetitions.
 The default
 .I count
 is 1.
 .I Address
 and
 .I count
 are expressions.
 Multiple commands on one line must be separated by
 .LR ; .
 .SS Expressions
 Expressions are evaluated as long
 .IR ints .
 .TP 7.2n
 .B .
 The value of dot.
 .TP 7.2n
 .B +
 The value of dot
 incremented by the current increment.
 .TP 7.2n
 .B ^
 The value of dot
 decremented by the current increment.
 .TP 7.2n
 .B \&"
 The last
 .I address
 typed.
 .TP 7.2n
 .I integer
 A number, in decimal radix by default.
 The prefixes
 .L 0
 and
 .L 0o
 and
 .L 0O
 (zero oh) force interpretation
 in octal radix; the prefixes
 .L 0t
 and
 .L 0T
 force interpretation in
 decimal radix; the prefixes
 .LR 0x ,
 .LR 0X ,
 and
 .L #
 force interpretation in
 hexadecimal radix.
 Thus
 .LR 020 ,
 .LR 0o20 ,
 .LR 0t16 ,
 and
 .L #10
 all represent sixteen.
 .TP 7.2n
 .IB integer . fraction
 A single-precision floating point number.
 .TP 7.2n
 .BI \' c\| \'
 The
 16-bit
 value of a character.
 .L \e
 may be used to escape a
 .LR \' .
 .TP 7.2n
 .BI < name
 The value of
 .IR name ,
 which is a register name.
 The register names are
 those printed by the
 .B $r
 command.
 .TP 7.2n
 .I symbol
 A
 .I symbol
 is a sequence
 of upper or lower case letters, underscores or
 digits, not starting with a digit.
 .L \e
 may be used to escape other characters.
 The location of the
 .I symbol
 is calculated from the symbol table
 in
 .IR textfile .
 .TP 7.2n
 .IB routine . name
 The address of the variable
 .I name
 in the specified
 C routine.
 Both
 .I routine
 and
 .I name
 are
 .IR symbols .
 If
 .I name
 is omitted the value is the address of the
 most recently activated stack frame
 corresponding to
 .IR routine ;
 if
 .I routine
 is omitted,
 the active procedure
 is assumed.
 .TP 7.2n
 .IB file : integer
 The address of the instruction corresponding
 to the source statement at the indicated
 line number of the file.  If the source line contains
 no executable statement, the address of the
 instruction associated with the nearest
 executable source line is returned.  Files
 begin at line 1.  If multiple files of the same
 name are loaded, an expression of this form resolves
 to the first file encountered in the symbol table.
 .TP 7.2n
 .BI ( exp )
 The value of the expression
 .IR exp .
 .LP
 .I  Monadic operators
 .RS
 .TP 7.2n
 .BI * exp
 The contents of the location addressed
 by
 .I exp
 in
 .IR memfile .
 .TP 7.2n
 .BI @ exp
 The contents of the location addressed by
 .I exp
 in
 .IR textfile .
 .TP 7.2n
 .BI - exp
 Integer negation.
 .TP 7.2n
 .BI ~ exp
 Bitwise complement.
 .TP 7.2n
 .BI % exp
 When used as an
 .IR address ,
 .I exp
 is an offset into the segment named
 .IR ublock ;
 see `Addresses'.
 .RE
 .LP
 .I "Dyadic\ operators"
 are left-associative
 and are less binding than monadic operators.
 .RS
 .TP 7.2n
 .IB e1 + e2
 Integer addition.
 .TP 7.2n
 .IB e1 - e2
 Integer subtraction.
 .TP 7.2n
 .IB e1 * e2
 Integer multiplication.
 .TP 7.2n
 .IB e1 % e2
 Integer division.
 .TP 7.2n
 .IB e1 & e2
 Bitwise conjunction.
 .TP 7.2n
 .IB e1 | e2
 Bitwise disjunction.
 .TP 7.2n
 .IB e1 # e2
 .I E1
 rounded up to the next multiple of
 .IR e2 .
 .RE
 .DT
 .SS Commands
 Most commands have the following syntax:
 .TP .5i
 .BI ? f
 Locations starting at
 .I address
 in
 .I  textfile
 are printed according to the format
 .IR f .
 .TP
 .BI / f
 Locations starting at
 .I address
 in
 .I  memfile
 are printed according to the format
 .IR f .
 .TP
 .BI = f
 The value of
 .I address
 itself is printed according to the format
 .IR f .
 .PP
 A
 .I format
 consists of one or more characters that specify a style
 of printing.
 Each format character may be preceded by a decimal integer
 that is a repeat count for the format character.
 If no format is given then the last format is used.
 .PP
 Most format letters fetch some data,
 print it,
 and advance (a local copy of) dot
 by the number of bytes fetched.
 The total number of bytes in a format becomes the
 .IR current increment .
 .ta 2.5n .5i
 .RS
 .TP
 .PD 0
 .B o
 Print two-byte integer in octal.
 .TP
 .B O
 Print four-byte integer in octal.
 .TP
 .B q
 Print two-byte integer in signed octal.
 .TP
 .B Q
 Print four-byte integer in signed octal.
 .TP
 .B d
 Print two-byte integer in decimal.
 .TP
 .B D
 Print four-byte integer in decimal.
 .TP
 .B V
 Print eight-byte integer in decimal.
 .TP
 .B Z
 Print eight-byte integer in unsigned decimal.
 .TP
 .B x
 Print two-byte integer in hexadecimal.
 .TP
 .B X
 Print four-byte integer in hexadecimal.
 .TP
 .B Y
 Print eight-byte integer in hexadecimal.
 .TP
 .B u
 Print two-byte integer in unsigned decimal.
 .TP
 .B U
 Print four-byte integer in unsigned decimal.
 .TP
 .B f
 Print
 as a single-precision floating point number.
 .TP
 .B F
 Print double-precision floating point.
 .TP
 .B b
 Print the addressed byte in hexadecimal.
 .TP
 .B c
 Print the addressed byte as an
 .SM ASCII
 character.
 .TP
 .B C
 Print the addressed byte as a character.
 Printable
 .SM ASCII
 characters
 are represented normally; others
 are printed in the form
 .BR \exnn .
 .TP
 .B s
 Print the addressed characters, as a
 .SM UTF
 string, until a zero byte
 is reached.
 Advance dot
 by the length of the string,
 including the zero terminator.
 .TP
 .B S
 Print a string using
 the escape convention (see
 .B C
 above).
 .TP
 .B r
 Print as
 .SM UTF
 the addressed two-byte integer (rune).
 .TP
 .B R
 Print as
 .SM UTF
 the addressed two-byte integers as runes
 until a zero rune is reached.
 Advance dot
 by the length of the string,
 including the zero terminator.
 .TP
 .B i
 Print as machine instructions.  Dot is
 incremented by the size of the instruction.
 .TP
 .B I
 As
 .B i
 above, but print the machine instructions in
 an alternate form if possible.
 .TP
 .B M
 Print the addressed machine instruction in a
 machine-dependent hexadecimal form.
 .TP
 .B a
 Print the value of dot
 in symbolic form.
 Dot is unaffected.
 .TP
 .B A
 Print the value of dot
 in hexadecimal.
 Dot is unaffected.
 .TP
 .B z
 Print the function name, source file, and line number
 corresponding to dot (textfile only). Dot is unaffected.
 .TP
 .B p
 Print the addressed value in symbolic form.
 Dot is advanced by the size of a machine address.
 .TP
 .B t
 When preceded by an integer, tabs to the next
 appropriate tab stop.
 For example,
 .B 8t
 moves to the next 8-space tab stop.
 Dot is unaffected.
 .TP
 .B n
 Print a newline.
 Dot is unaffected.
 .tr '"
 .TP
 .BR ' ... '
 Print the enclosed string.
 Dot is unaffected.
 .br
 .tr ''
 .TP
 .B ^
 Dot is decremented by the current increment.
 Nothing is printed.
 .TP
 .B +
 Dot is incremented by 1.
 Nothing is printed.
 .TP
 .B -
 Dot is decremented by 1.
 Nothing is printed.
 .RE
 .PD
 .LP
 Other commands include:
 .TP
 newline
 Update dot by the current increment.
 Repeat the previous command with a
 .I count
 of 1.
 .TP
 .RB [ ?/ ] l "\fI value mask\fR"
 Words starting at dot
 are masked with
 .I mask
 and compared with
 .I value
 until
 a match is found.
 If
 .B l
 is used,
 the match is for a two-byte integer;
 .B L
 matches four bytes.
 If no match is found then dot
 is unchanged; otherwise dot
 is set to the matched location.
 If
 .I mask
 is omitted then ~0 is used.
 .TP
 .RB [ ?/ ] w "\fI value ...\fR"
 Write the two-byte
 .I value
 into the addressed
 location.
 If the command is
 .BR W ,
 write four bytes.
 .TP
 .RB [ ?/ ] "m\fI s b e f \fP" [ ?\fR]
 .br
 New values for
 .RI ( b,\ e,\ f )
 in the segment named
 .I s
 are recorded.  Valid segment names are
 .IR text ,
 .IR data ,
 or
 .IR ublock .
 If less than three address expressions are given,
 the remaining parameters are left unchanged.
 If the list is terminated by
 .L ?
 or
 .L /
 then the file
 .RI ( textfile
 or
 .I memfile
 respectively) is used
 for subsequent requests.
 For example,
 .L /m?
 causes
 .L /
 to refer to
 .IR textfile .
 .TP
 .BI > name
 Dot is assigned to the variable or register named.
 .TP
 .B !
 The rest of the line is passed to
 .IR rc (1)
 for execution.
 .TP
 .BI $ modifier
 Miscellaneous commands.
 The available
 .I modifiers
 are:
 .RS
 .TP
 .PD 0
 .BI < f
 Read commands from the file
 .IR f .
 If this command is executed in a file, further commands
 in the file are not seen.
 If
 .I f
 is omitted, the current input stream is terminated.
 If a
 .I count
 is given, and is zero, the command is ignored.
 .TP
 .BI << f
 Similar to
 .B <
 except it can be used in a file of commands without
 causing the file to be closed.
 There is a (small) limit to the number of
 .B <<
 files that can be open at once.
 .br
 .ns
 .TP
 .BI > f
 Append output to the file
 .IR f ,
 which is created if it does not exist.
 If
 .I f
 is omitted, output is returned to the terminal.
 .TP
 .B ?
 Print process id, the condition which caused stopping or termination,
 the registers and the instruction addressed by
 .BR pc .
 This is the default if
 .I modifier
 is omitted.
 .TP
 .B r
 Print the general registers and
 the instruction addressed by
 .BR pc .
 Dot is set to
 .BR pc .
 .TP
 .B R
 Like
 .BR $r ,
 but include miscellaneous processor control registers
 and floating point registers.
 .TP
 .B f
 Print floating-point register values as
 single-precision floating point numbers.
 .TP
 .B F
 Print floating-point register values as
 double-precision floating point numbers.
 .TP
 .B b
 Print all breakpoints
 and their associated counts and commands.  `B' produces the same results.
 .TP
 .B c
 Stack backtrace.
 If
 .I address
 is given, it specifies the address of a pair of 32-bit
 values containing the
 .B sp
 and
 .B pc
 of an active process.  This allows selecting
 among various contexts of a multi-threaded
 process.
 If
 .B C
 is used, the names and (long) values of all
 parameters,
 automatic
 and static variables are printed for each active function.
 If
 .I count
 is given, only the first
 .I count
 frames are printed.
 .TP
 .B a
 Attach to the running process whose pid
 is contained in
 .IR address .
 .TP
 .B e
 The names and values of all
 external variables are printed.
 .TP
 .B w
 Set the page width for output to
 .I address
 (default 80).
 .TP
 .B q
 Exit from
 .IR db .
 .TP
 .B m
 Print the address maps.
 .TP
 .B k
 Simulate kernel memory management.
 .TP
 .BI M machine
 Set the
 .I machine
 type used for disassembling instructions.
 .PD
 .RE
 .TP
 .BI : modifier
 Manage a subprocess.
 Available modifiers are:
 .RS
 .TP
 .PD 0
 .BI h
 Halt
 an asynchronously running process to allow breakpointing.
 Unnecessary for processes created under
 .IR db ,
 e.g. by
 .BR :r .
 .TP
 .BI b c
 Set breakpoint at
 .IR address .
 The breakpoint is executed
 .IR count \-1
 times before
 causing a stop.
 Also, if a command
 .I c
 is given it is executed at each
 breakpoint and if it sets dot to zero
 the breakpoint causes a stop.
 .TP
 .B d
 Delete breakpoint at
 .IR address .
 .TP
 .B r
 Run
 .I textfile
 as a subprocess.
 If
 .I address
 is given the
 program is entered at that point; otherwise
 the standard entry point is used.
 .I Count
 specifies how many breakpoints are to be
 ignored before stopping.
 Arguments to the subprocess may be supplied on the
 same line as the command.
 An argument starting with < or > causes the standard
 input or output to be established for the command.
 .TP
 .BI c s
 The subprocess is continued.
 If
 .I s
 is omitted
 or nonzero,
 the subprocess
 is sent the note that caused it to stop.
 If 0
 is specified,
 no note is sent.
 (If the stop was due to a breakpoint or single-step,
 the corresponding note is elided before continuing.)
 Breakpoint skipping is the same
 as for
 .BR r .
 .TP
 .BI s s
 As for
 .B c
 except that
 the subprocess is single stepped for
 .I count
 machine instructions.
 If a note is pending,
 it is received
 before the first instruction is executed.
 If there is no current subprocess then
 .I textfile
 is run
 as a subprocess as for
 .BR r .
 In this case no note can be sent; the remainder of the line
 is treated as arguments to the subprocess.
 .TP
 .BI S s
 Identical to
 .B s
 except the subprocess is single stepped for
 .I count
 lines of C source.  In optimized code, the correspondence
 between C source and the machine instructions is
 approximate at best.
 .TP
 .BI x
 The current subprocess, if any, is released by
 .I db
 and allowed to continue executing normally.
 .TP
 .B k
 The current subprocess, if any, is terminated.
 .TP
 .BI n c
 Display the pending notes for the process.
 If
 .I c
 is specified, first delete
 .I c'th
 pending note.
 .PD
 .RE
 .SS Addresses
 The location in a file or memory image associated with
 an address is calculated from a map
 associated with the file.
 Each map contains one or more quadruples
 .RI ( "t, f, b, e, o" ),
 defining a segment named
 .I t
 (usually,
 .IR text ,
 .IR data ,
 or
 .IR core )
 in file
 .I f
 mapping addresses in the range
 .I b
 through
 .IR e
 to the part of the file
 beginning at
 offset
 .IR o .
 If segments overlap, later segments obscure earlier ones.
 An address
 .I a
 is translated
 to a file address
 by finding the last segment in the list
 for which
 .IR b ≤ a < e ;
 the location in the file
 is then
 .IR address + f \- b .
 .PP
 Usually,
 the text and initialized data of a program
 are mapped by segments called
 .IR text ,
 .IR data ,
 and
 .IR bss .
 Since a program file does not contain stack data,
 this data is
 not mapped.
 The text segment is mapped similarly in
 a normal (i.e., non-kernel)
 .IR memfile .
 However, one or more segments called
 .I data
 provide access to process memory.
 This region contains the program's static data, the bss, the
 heap and the stack.
 .PP
 Sometimes it is useful to define a map with a single segment
 mapping the region from 0 to 0xFFFFFFFF; a map of this type
 allows an entire file to be examined
 without address translation.
 .PP
 The
 .B $m
 command dumps the currently active maps.  The
 .B ?m
 and
 .B /m
 commands modify the segment parameters in the
 .I textfile
 and
 .I memfile
 maps, respectively.
 .SH EXAMPLES
 To set a breakpoint at the beginning of
 .B write()
 in extant process 27:
 .IP
 .EX
 % db 27
 :h
 write:b
 :c
 .EE
 .PP
 To set a breakpoint at the entry of function
 .B parse
 when the local variable
 .B argc
 in
 .B main
 is equal to 1:
 .IP
 .EX
 parse:b *main.argc-1=X
 .EE
 .PP
 This prints the value of
 .B argc-1
 which as a side effect sets dot; when
 .B argc
 is one the breakpoint will fire.
 Beware that local variables may be stored in registers; see the
 BUGS section.
 .SH "SEE ALSO"
 .IR acid (1),
 .IR core (1)
 .SH SOURCE
 .B \*9/src/cmd/db
 .SH DIAGNOSTICS
 Exit status is 0, unless the last command failed or
 returned non-zero status.
 .SH BUGS
 Examining a local variable with
 .I routine.name
 returns the contents of the memory allocated for the variable, but
 with optimization, variables often reside in registers.
 Also, on some architectures, the first argument is always
 passed in a register.
 .PP
 Variables and parameters that have been
 optimized away do not appear in the
 symbol table, returning the error
 .IR "bad local variable"
 when accessed by
 .IR db .
 .PP
 Breakpoints should not be set on instructions scheduled
 in delay slots.  When a program stops on such a breakpoint,
 it is usually impossible to continue its execution.
	.TH DB 1
	.SH NAME
	db, stack \- debugger
	.SH SYNOPSIS
	.B db
	[
	.I option ...
	]
	[
	.I pid
	\|
	.I corefile
	]
	[
	.I textfile
	]
	.PP
	.B stack
	[
	.I pid
	\|
	.I corefile
	\|
	.I name
	]
	[
	.I textfile
	]
	.SH DESCRIPTION
	.I Db
	is a general purpose debugging program.
	It may be used to examine files and to provide
	a controlled environment for the execution
	of programs.
	.PP
	A
	.I textfile
	is a file containing the text and initialized
	data of an executable program.
	A
	.I pid
	or
	.I corefile
	specifies the memory image of a process.
	A
	.I pid
	gives the id of an executing process to be accessed via
	.IR ptrace (2).
	A
	.I corefile
	specifies the name of a core dump (see
	.IR core (5)
	on your system of choice) containing the
	memory image of a terminated process.
	This manual refers to the memory image specified by
	.I pid
	or
	.I corefile
	as a
	.IR memfile .
	.PP
	A
	.I map
	associated with each
	.I textfile
	or
	.I memfile
	supports accesses to instructions and data in the file;
	see `Addresses'.
	.PP
	An argument consisting entirely of digits is assumed
	to be a process id; otherwise, it is the name of a
	.I textfile
	or
	.IR corefile .
	When a
	.I textfile
	is given, the textfile map
	is associated with it.
	If only a
	.I memfile
	is given, the textfile map is
	derived from the corresponding
	.IR textfile ,
	if it can be determined
	(this varies from system to system).
	When a
	.I memfile
	is given, the memfile map is associated with it;
	otherwise the map is undefined and accesses to it
	are not permitted.
	.PP
	.I Stack
	takes the same arguments as
	.IR db .
	It prints a stack trace (see the
	.B $c
	command below) and then exits.
	If the first argument is a process name,
	then
	.I stack
	prints the stack trace of every running process
	with the given name
	that is
	owned by the current user.
	.PP
	Commands to
	.I db
	are read from the standard input and
	responses are to the standard output.
	The options are
	.TP
	.B -q
	Quiet mode:
	suppress informational prints at startup.
	.TP
	.B -w
	Open
	.I textfile
	and
	.I memfile
	for writing as well as reading.
	.TP
	.BI -I path
	Directory in which to look for relative path names in
	.B $<
	and
	.B $<<
	commands.
	.TP
	.BI -m machine
	Assume instructions are for the given CPU type
	(possible names include
	.B 386
	and
	.BR powerpc ;
	adding
	the suffix
	.B -co
	as in
	.B 386-co
	and
	.B powerpc-co
	selects disassembly in the manufacturer's syntax, if
	available,
	rather than the default Plan 9 syntax).
	.PP
	Most
	.I db
	commands have the following form:
	.IP
	.RI [ address ]
	.RB [ ,
	.IR count ]
	.RI [ command ]
	.PP
	If
	.I address
	is present then the current position, called `dot',
	is set to
	.IR address .
	Initially dot
	is set to 0.
	Most commands are repeated
	.I count
	times with
	dot advancing between repetitions.
	The default
	.I count
	is 1.
	.I Address
	and
	.I count
	are expressions.
	Multiple commands on one line must be separated by
	.LR ; .
	.SS Expressions
	Expressions are evaluated as long
	.IR ints .
	.TP 7.2n
	.B .
	The value of dot.
	.TP 7.2n
	.B +
	The value of dot
	incremented by the current increment.
	.TP 7.2n
	.B ^
	The value of dot
	decremented by the current increment.
	.TP 7.2n
	.B \&"
	The last
	.I address
	typed.
	.TP 7.2n
	.I integer
	A number, in decimal radix by default.
	The prefixes
	.L 0
	and
	.L 0o
	and
	.L 0O
	(zero oh) force interpretation
	in octal radix; the prefixes
	.L 0t
	and
	.L 0T
	force interpretation in
	decimal radix; the prefixes
	.LR 0x ,
	.LR 0X ,
	and
	.L #
	force interpretation in
	hexadecimal radix.
	Thus
	.LR 020 ,
	.LR 0o20 ,
	.LR 0t16 ,
	and
	.L #10
	all represent sixteen.
	.TP 7.2n
	.IB integer . fraction
	A single-precision floating point number.
	.TP 7.2n
	.BI \' c\\| \'
	The
	16-bit
	value of a character.
	.L \e
	may be used to escape a
	.LR \' .
	.TP 7.2n
	.BI < name
	The value of
	.IR name ,
	which is a register name.
	The register names are
	those printed by the
	.B $r
	command.
	.TP 7.2n
	.I symbol
	A
	.I symbol
	is a sequence
	of upper or lower case letters, underscores or
	digits, not starting with a digit.
	.L \e
	may be used to escape other characters.
	The location of the
	.I symbol
	is calculated from the symbol table
	in
	.IR textfile .
	.TP 7.2n
	.IB routine . name
	The address of the variable
	.I name
	in the specified
	C routine.
	Both
	.I routine
	and
	.I name
	are
	.IR symbols .
	If
	.I name
	is omitted the value is the address of the
	most recently activated stack frame
	corresponding to
	.IR routine ;
	if
	.I routine
	is omitted,
	the active procedure
	is assumed.
	.TP 7.2n
	.IB file : integer
	The address of the instruction corresponding
	to the source statement at the indicated
	line number of the file. If the source line contains
	no executable statement, the address of the
	instruction associated with the nearest
	executable source line is returned. Files
	begin at line 1. If multiple files of the same
	name are loaded, an expression of this form resolves
	to the first file encountered in the symbol table.
	.TP 7.2n
	.BI ( exp )
	The value of the expression
	.IR exp .
	.LP
	.I Monadic operators
	.RS
	.TP 7.2n
	.BI * exp
	The contents of the location addressed
	by
	.I exp
	in
	.IR memfile .
	.TP 7.2n
	.BI @ exp
	The contents of the location addressed by
	.I exp
	in
	.IR textfile .
	.TP 7.2n
	.BI - exp
	Integer negation.
	.TP 7.2n
	.BI ~ exp
	Bitwise complement.
	.TP 7.2n
	.BI % exp
	When used as an
	.IR address ,
	.I exp
	is an offset into the segment named
	.IR ublock ;
	see `Addresses'.
	.RE
	.LP
	.I "Dyadic\ operators"
	are left-associative
	and are less binding than monadic operators.
	.RS
	.TP 7.2n
	.IB e1 + e2
	Integer addition.
	.TP 7.2n
	.IB e1 - e2
	Integer subtraction.
	.TP 7.2n
	.IB e1 * e2
	Integer multiplication.
	.TP 7.2n
	.IB e1 % e2
	Integer division.
	.TP 7.2n
	.IB e1 & e2
	Bitwise conjunction.
	.TP 7.2n
	.IB e1 \| e2
	Bitwise disjunction.
	.TP 7.2n
	.IB e1 # e2
	.I E1
	rounded up to the next multiple of
	.IR e2 .
	.RE
	.DT
	.SS Commands
	Most commands have the following syntax:
	.TP .5i
	.BI ? f
	Locations starting at
	.I address
	in
	.I textfile
	are printed according to the format
	.IR f .
	.TP
	.BI / f
	Locations starting at
	.I address
	in
	.I memfile
	are printed according to the format
	.IR f .
	.TP
	.BI = f
	The value of
	.I address
	itself is printed according to the format
	.IR f .
	.PP
	A
	.I format
	consists of one or more characters that specify a style
	of printing.
	Each format character may be preceded by a decimal integer
	that is a repeat count for the format character.
	If no format is given then the last format is used.
	.PP
	Most format letters fetch some data,
	print it,
	and advance (a local copy of) dot
	by the number of bytes fetched.
	The total number of bytes in a format becomes the
	.IR current increment .
	.ta 2.5n .5i
	.RS
	.TP
	.PD 0
	.B o
	Print two-byte integer in octal.
	.TP
	.B O
	Print four-byte integer in octal.
	.TP
	.B q
	Print two-byte integer in signed octal.
	.TP
	.B Q
	Print four-byte integer in signed octal.
	.TP
	.B d
	Print two-byte integer in decimal.
	.TP
	.B D
	Print four-byte integer in decimal.
	.TP
	.B V
	Print eight-byte integer in decimal.
	.TP
	.B Z
	Print eight-byte integer in unsigned decimal.
	.TP
	.B x
	Print two-byte integer in hexadecimal.
	.TP
	.B X
	Print four-byte integer in hexadecimal.
	.TP
	.B Y
	Print eight-byte integer in hexadecimal.
	.TP
	.B u
	Print two-byte integer in unsigned decimal.
	.TP
	.B U
	Print four-byte integer in unsigned decimal.
	.TP
	.B f
	Print
	as a single-precision floating point number.
	.TP
	.B F
	Print double-precision floating point.
	.TP
	.B b
	Print the addressed byte in hexadecimal.
	.TP
	.B c
	Print the addressed byte as an
	.SM ASCII
	character.
	.TP
	.B C
	Print the addressed byte as a character.
	Printable
	.SM ASCII
	characters
	are represented normally; others
	are printed in the form
	.BR \exnn .
	.TP
	.B s
	Print the addressed characters, as a
	.SM UTF
	string, until a zero byte
	is reached.
	Advance dot
	by the length of the string,
	including the zero terminator.
	.TP
	.B S
	Print a string using
	the escape convention (see
	.B C
	above).
	.TP
	.B r
	Print as
	.SM UTF
	the addressed two-byte integer (rune).
	.TP
	.B R
	Print as
	.SM UTF
	the addressed two-byte integers as runes
	until a zero rune is reached.
	Advance dot
	by the length of the string,
	including the zero terminator.
	.TP
	.B i
	Print as machine instructions. Dot is
	incremented by the size of the instruction.
	.TP
	.B I
	As
	.B i
	above, but print the machine instructions in
	an alternate form if possible.
	.TP
	.B M
	Print the addressed machine instruction in a
	machine-dependent hexadecimal form.
	.TP
	.B a
	Print the value of dot
	in symbolic form.
	Dot is unaffected.
	.TP
	.B A
	Print the value of dot
	in hexadecimal.
	Dot is unaffected.
	.TP
	.B z
	Print the function name, source file, and line number
	corresponding to dot (textfile only). Dot is unaffected.
	.TP
	.B p
	Print the addressed value in symbolic form.
	Dot is advanced by the size of a machine address.
	.TP
	.B t
	When preceded by an integer, tabs to the next
	appropriate tab stop.
	For example,
	.B 8t
	moves to the next 8-space tab stop.
	Dot is unaffected.
	.TP
	.B n
	Print a newline.
	Dot is unaffected.
	.tr '"
	.TP
	.BR ' ... '
	Print the enclosed string.
	Dot is unaffected.
	.br
	.tr ''
	.TP
	.B ^
	Dot is decremented by the current increment.
	Nothing is printed.
	.TP
	.B +
	Dot is incremented by 1.
	Nothing is printed.
	.TP
	.B -
	Dot is decremented by 1.
	Nothing is printed.
	.RE
	.PD
	.LP
	Other commands include:
	.TP
	newline
	Update dot by the current increment.
	Repeat the previous command with a
	.I count
	of 1.
	.TP
	.RB [ ?/ ] l "\fI value mask\fR"
	Words starting at dot
	are masked with
	.I mask
	and compared with
	.I value
	until
	a match is found.
	If
	.B l
	is used,
	the match is for a two-byte integer;
	.B L
	matches four bytes.
	If no match is found then dot
	is unchanged; otherwise dot
	is set to the matched location.
	If
	.I mask
	is omitted then ~0 is used.
	.TP
	.RB [ ?/ ] w "\fI value ...\fR"
	Write the two-byte
	.I value
	into the addressed
	location.
	If the command is
	.BR W ,
	write four bytes.
	.TP
	.RB [ ?/ ] "m\fI s b e f \fP" [ ?\fR]
	.br
	New values for
	.RI ( b,\ e,\ f )
	in the segment named
	.I s
	are recorded. Valid segment names are
	.IR text ,
	.IR data ,
	or
	.IR ublock .
	If less than three address expressions are given,
	the remaining parameters are left unchanged.
	If the list is terminated by
	.L ?
	or
	.L /
	then the file
	.RI ( textfile
	or
	.I memfile
	respectively) is used
	for subsequent requests.
	For example,
	.L /m?
	causes
	.L /
	to refer to
	.IR textfile .
	.TP
	.BI > name
	Dot is assigned to the variable or register named.
	.TP
	.B !
	The rest of the line is passed to
	.IR rc (1)
	for execution.
	.TP
	.BI $ modifier
	Miscellaneous commands.
	The available
	.I modifiers
	are:
	.RS
	.TP
	.PD 0
	.BI < f
	Read commands from the file
	.IR f .
	If this command is executed in a file, further commands
	in the file are not seen.
	If
	.I f
	is omitted, the current input stream is terminated.
	If a
	.I count
	is given, and is zero, the command is ignored.
	.TP
	.BI << f
	Similar to
	.B <
	except it can be used in a file of commands without
	causing the file to be closed.
	There is a (small) limit to the number of
	.B <<
	files that can be open at once.
	.br
	.ns
	.TP
	.BI > f
	Append output to the file
	.IR f ,
	which is created if it does not exist.
	If
	.I f
	is omitted, output is returned to the terminal.
	.TP
	.B ?
	Print process id, the condition which caused stopping or termination,
	the registers and the instruction addressed by
	.BR pc .
	This is the default if
	.I modifier
	is omitted.
	.TP
	.B r
	Print the general registers and
	the instruction addressed by
	.BR pc .
	Dot is set to
	.BR pc .
	.TP
	.B R
	Like
	.BR $r ,
	but include miscellaneous processor control registers
	and floating point registers.
	.TP
	.B f
	Print floating-point register values as
	single-precision floating point numbers.
	.TP
	.B F
	Print floating-point register values as
	double-precision floating point numbers.
	.TP
	.B b
	Print all breakpoints
	and their associated counts and commands. `B' produces the same results.
	.TP
	.B c
	Stack backtrace.
	If
	.I address
	is given, it specifies the address of a pair of 32-bit
	values containing the
	.B sp
	and
	.B pc
	of an active process. This allows selecting
	among various contexts of a multi-threaded
	process.
	If
	.B C
	is used, the names and (long) values of all
	parameters,
	automatic
	and static variables are printed for each active function.
	If
	.I count
	is given, only the first
	.I count
	frames are printed.
	.TP
	.B a
	Attach to the running process whose pid
	is contained in
	.IR address .
	.TP
	.B e
	The names and values of all
	external variables are printed.
	.TP
	.B w
	Set the page width for output to
	.I address
	(default 80).
	.TP
	.B q
	Exit from
	.IR db .
	.TP
	.B m
	Print the address maps.
	.TP
	.B k
	Simulate kernel memory management.
	.TP
	.BI M machine
	Set the
	.I machine
	type used for disassembling instructions.
	.PD
	.RE
	.TP
	.BI : modifier
	Manage a subprocess.
	Available modifiers are:
	.RS
	.TP
	.PD 0
	.BI h
	Halt
	an asynchronously running process to allow breakpointing.
	Unnecessary for processes created under
	.IR db ,
	e.g. by
	.BR :r .
	.TP
	.BI b c
	Set breakpoint at
	.IR address .
	The breakpoint is executed
	.IR count \-1
	times before
	causing a stop.
	Also, if a command
	.I c
	is given it is executed at each
	breakpoint and if it sets dot to zero
	the breakpoint causes a stop.
	.TP
	.B d
	Delete breakpoint at
	.IR address .
	.TP
	.B r
	Run
	.I textfile
	as a subprocess.
	If
	.I address
	is given the
	program is entered at that point; otherwise
	the standard entry point is used.
	.I Count
	specifies how many breakpoints are to be
	ignored before stopping.
	Arguments to the subprocess may be supplied on the
	same line as the command.
	An argument starting with < or > causes the standard
	input or output to be established for the command.
	.TP
	.BI c s
	The subprocess is continued.
	If
	.I s
	is omitted
	or nonzero,
	the subprocess
	is sent the note that caused it to stop.
	If 0
	is specified,
	no note is sent.
	(If the stop was due to a breakpoint or single-step,
	the corresponding note is elided before continuing.)
	Breakpoint skipping is the same
	as for
	.BR r .
	.TP
	.BI s s
	As for
	.B c
	except that
	the subprocess is single stepped for
	.I count
	machine instructions.
	If a note is pending,
	it is received
	before the first instruction is executed.
	If there is no current subprocess then
	.I textfile
	is run
	as a subprocess as for
	.BR r .
	In this case no note can be sent; the remainder of the line
	is treated as arguments to the subprocess.
	.TP
	.BI S s
	Identical to
	.B s
	except the subprocess is single stepped for
	.I count
	lines of C source. In optimized code, the correspondence
	between C source and the machine instructions is
	approximate at best.
	.TP
	.BI x
	The current subprocess, if any, is released by
	.I db
	and allowed to continue executing normally.
	.TP
	.B k
	The current subprocess, if any, is terminated.
	.TP
	.BI n c
	Display the pending notes for the process.
	If
	.I c
	is specified, first delete
	.I c'th
	pending note.
	.PD
	.RE
	.SS Addresses
	The location in a file or memory image associated with
	an address is calculated from a map
	associated with the file.
	Each map contains one or more quadruples
	.RI ( "t, f, b, e, o" ),
	defining a segment named
	.I t
	(usually,
	.IR text ,
	.IR data ,
	or
	.IR core )
	in file
	.I f
	mapping addresses in the range
	.I b
	through
	.IR e
	to the part of the file
	beginning at
	offset
	.IR o .
	If segments overlap, later segments obscure earlier ones.
	An address
	.I a
	is translated
	to a file address
	by finding the last segment in the list
	for which
	.IR b ≤ a < e ;
	the location in the file
	is then
	.IR address + f \- b .
	.PP
	Usually,
	the text and initialized data of a program
	are mapped by segments called
	.IR text ,
	.IR data ,
	and
	.IR bss .
	Since a program file does not contain stack data,
	this data is
	not mapped.
	The text segment is mapped similarly in
	a normal (i.e., non-kernel)
	.IR memfile .
	However, one or more segments called
	.I data
	provide access to process memory.
	This region contains the program's static data, the bss, the
	heap and the stack.
	.PP
	Sometimes it is useful to define a map with a single segment
	mapping the region from 0 to 0xFFFFFFFF; a map of this type
	allows an entire file to be examined
	without address translation.
	.PP
	The
	.B $m
	command dumps the currently active maps. The
	.B ?m
	and
	.B /m
	commands modify the segment parameters in the
	.I textfile
	and
	.I memfile
	maps, respectively.
	.SH EXAMPLES
	To set a breakpoint at the beginning of
	.B write()
	in extant process 27:
	.IP
	.EX
	% db 27
	:h
	write:b
	:c
	.EE
	.PP
	To set a breakpoint at the entry of function
	.B parse
	when the local variable
	.B argc
	in
	.B main
	is equal to 1:
	.IP
	.EX
	parse:b *main.argc-1=X
	.EE
	.PP
	This prints the value of
	.B argc-1
	which as a side effect sets dot; when
	.B argc
	is one the breakpoint will fire.
	Beware that local variables may be stored in registers; see the
	BUGS section.
	.SH "SEE ALSO"
	.IR acid (1),
	.IR core (1)
	.SH SOURCE
	.B \*9/src/cmd/db
	.SH DIAGNOSTICS
	Exit status is 0, unless the last command failed or
	returned non-zero status.
	.SH BUGS
	Examining a local variable with
	.I routine.name
	returns the contents of the memory allocated for the variable, but
	with optimization, variables often reside in registers.
	Also, on some architectures, the first argument is always
	passed in a register.
	.PP
	Variables and parameters that have been
	optimized away do not appear in the
	symbol table, returning the error
	.IR "bad local variable"
	when accessed by
	.IR db .
	.PP
	Breakpoints should not be set on instructions scheduled
	in delay slots. When a program stops on such a breakpoint,
	it is usually impossible to continue its execution.