@c -*- Texinfo -*- @c Copyright (c) 1990 1991 1992 1993 Free Software Foundation, Inc. @c This file is part of the source for the GDB manual. @c This text diverted to "Remote Debugging" section in general case; @c however, if we're doing a manual specifically for one of these, it @c belongs up front (in "Getting In and Out" chapter). @ifset REMOTESTUB @node Remote Serial @subsection The @value{GDBN} remote serial protocol @cindex remote serial debugging, overview To debug a program running on another machine (the debugging @dfn{target} machine), you must first arrange for all the usual prerequisites for the program to run by itself. For example, for a C program, you need @enumerate @item A startup routine to set up the C runtime environment; these usually have a name like @file{crt0}. The startup routine may be supplied by your hardware supplier, or you may have to write your own. @item You probably need a C subroutine library to support your program's subroutine calls, notably managing input and output. @item A way of getting your program to the other machine---for example, a download program. These are often supplied by the hardware manufacturer, but you may have to write your own from hardware documentation. @end enumerate The next step is to arrange for your program to use a serial port to communicate with the machine where @value{GDBN} is running (the @dfn{host} machine). In general terms, the scheme looks like this: @table @emph @item On the host, @value{GDBN} already understands how to use this protocol; when everything else is set up, you can simply use the @samp{target remote} command (@pxref{Targets,,Specifying a Debugging Target}). @item On the target, you must link with your program a few special-purpose subroutines that implement the @value{GDBN} remote serial protocol. The file containing these subroutines is called a @dfn{debugging stub}. @end table The debugging stub is specific to the architecture of the remote machine; for example, use @file{sparc-stub.c} to debug programs on @sc{sparc} boards. @cindex remote serial stub list These working remote stubs are distributed with @value{GDBN}: @c FIXME! verify these... @table @code @item sparc-stub.c @kindex sparc-stub.c For @sc{sparc} architectures. @item m68k-stub.c @kindex m68-stub.c For Motorola 680x0 architectures. @item i386-stub.c @kindex i36-stub.c For Intel 386 and compatible architectures. @end table The @file{README} file in the @value{GDBN} distribution may list other recently added stubs. @menu * Stub Contents:: What the stub can do for you * Bootstrapping:: What you must do for the stub * Debug Session:: Putting it all together * Protocol:: Outline of the communication protocol @end menu @node Stub Contents @subsubsection What the stub can do for you @cindex remote serial stub The debugging stub for your architecture supplies these three subroutines: @table @code @item set_debug_traps @kindex set_debug_traps @cindex remote serial stub, initialization This routine arranges to transfer control to @code{handle_exception} when your program stops. You must call this subroutine explicitly near the beginning of your program. @item handle_exception @kindex handle_exception @cindex remote serial stub, main routine This is the central workhorse, but your program never calls it explicitly---the setup code arranges for @code{handle_exception} to run when a trap is triggered. @code{handle_exception} takes control when your program stops during execution (for example, on a breakpoint), and mediates communications with @value{GDBN} on the host machine. This is where the communications protocol is implemented; @code{handle_exception} acts as the @value{GDBN} representative on the target machine; it begins by sending summary information on the state of your program, then continues to execute, retrieving and transmitting any information @value{GDBN} needs, until you execute a @value{GDBN} command that makes your program resume; at that point, @code{handle_exception} returns control to your own code on the target machine. @item breakpoint @cindex @code{breakpoint} subroutine, remote Use this auxiliary subroutine to make your program contain a breakpoint. Depending on the particular situation, this may be the only way for @value{GDBN} to get control. For instance, if your target machine has some sort of interrupt button, you won't need to call this; pressing the interrupt button will transfer control to @code{handle_exception}---in efect, to @value{GDBN}. On some machines, simply receiving characters on the serial port may also trigger a trap; again, in that situation, you don't need to call @code{breakpoint} from your own program---simply running @samp{target remote} from the host @value{GDBN} session will get control. Call @code{breakpoint} if none of these is true, or if you simply want to make certain your program stops at a predetermined point for the start of your debugging session. @end table @node Bootstrapping @subsubsection What you must do for the stub @cindex remote stub, support routines The debugging stubs that come with @value{GDBN} are set up for a particular chip architecture, but they have no information about the rest of your debugging target machine. To allow the stub to work, you must supply these special low-level subroutines: @table @code @item int getDebugChar() @kindex getDebugChar Write this subroutine to read a single character from the serial port. It may be identical to @code{getchar} for your target system; a different name is used to allow you to distinguish the two if you wish. @item void putDebugChar(int) @kindex putDebugChar Write this subroutine to write a single character to the serial port. It may be identical to @code{putchar} for your target system; a different name is used to allow you to distinguish the two if you wish. @item void flush_i_cache() @kindex flush_i_cache Write this subroutine to flush the instruction cache, if any, on your target machine. If there is no instruction cache, this subroutine may be a no-op. On target machines that have instruction caches, @value{GDBN} requires this function to make certain that the state of your program is stable. @end table @noindent You must also make sure this library routine is available: @table @code @item void *memset(void *, int, int) @kindex memset This is the standard library function @code{memset} that sets an area of memory to a known value. If you have one of the free versions of @code{libc.a}, @code{memset} can be found there; otherwise, you must either obtain it from your hardware manufacturer, or write your own. @end table If you do not use the GNU C compiler, you may need other standard library subroutines as well; this will vary from one stub to another, but in general the stubs are likely to use any of the common library subroutines which @code{gcc} generates as inline code. @node Debug Session @subsubsection Putting it all together @cindex remote serial debugging summary In summary, when your program is ready to debug, you must follow these steps. @enumerate @item Make sure you have the supporting low-level routines: @code{getDebugChar}, @code{putDebugChar}, @code{flush_i_cache}, @code{memset}. @item Insert these lines near the top of your program: @example set_debug_traps(); breakpoint(); @end example @item Compile and link together: your program, the @value{GDBN} debugging stub for your target architecture, and the supporting subroutines. @item Make sure you have a serial connection between your target machine and the @value{GDBN} host, and identify the serial port used for this on the host. @item Download your program to your target machine (or get it there by whatever means the manufacturer provides), and start it. @item To start remote debugging, run @value{GDBN} on the host machine, and specify as an executable file the program that is running in the remote machine. This tells @value{GDBN} how to find your program's symbols and the contents of its pure text. Then establish communication using the @code{target remote} command. Its argument is the name of the device you're using to control the target machine. For example: @example target remote /dev/ttyb @end example @noindent if the serial line is connected to the device named @file{/dev/ttyb}. @ignore @c this is from the old text, but it doesn't seem to make sense now that I've @c seen an example... pesch 4sep1992 This will stop the remote machine if it is not already stopped. @end ignore @end enumerate Now you can use all the usual commands to examine and change data and to step and continue the remote program. To resume the remote program and stop debugging it, use the @code{detach} command. @node Protocol @subsubsection Outline of the communication protocol @cindex debugging stub, example @cindex remote stub, example @cindex stub example, remote debugging The stub files provided with @value{GDBN} implement the target side of the communication protocol, and the @value{GDBN} side is implemented in the @value{GDBN} source file @file{remote.c}. Normally, you can simply allow these subroutines to communicate, and ignore the details. (If you're implementing your own stub file, you can still ignore the details: start with one of the existing stub files. @file{sparc-stub.c} is the best organized, and therefore the easiest to read.) However, there may be occasions when you need to know something about the protocol---for example, if there is only one serial port to your target machine, you might want your program to do something special if it recognizes a packet meant for @value{GDBN}. @cindex protocol, @value{GDBN} remote serial @cindex serial protocol, @value{GDBN} remote @cindex remote serial protocol All @value{GDBN} commands and responses (other than acknowledgements, which are single characters) are sent as a packet which includes a checksum. A packet is introduced with the character @samp{$}, and ends with the character @samp{#} followed by a two-digit checksum: @example $@var{packet info}#@var{checksum} @end example @cindex checksum, for @value{GDBN} remote @noindent @var{checksum} is computed as the modulo 256 sum of the @var{packet info} characters. When either the host or the target machine receives a packet, the first response expected is an acknowledgement: a single character, either @samp{+} (to indicate the package was received correctly) or @samp{-} (to request retransmission). The host (@value{GDBN}) sends commands, and the target (the debugging stub incorporated in your program) sends data in response. The target also sends data when your program stops. Command packets are distinguished by their first character, which identifies the kind of command. These are the commands currently supported: @table @code @item g Requests the values of CPU registers. @item G Sets the values of CPU registers. @item m@var{addr},@var{count} Read @var{count} bytes at location @var{addr}. @item M@var{addr},@var{count}:@dots{} Write @var{count} bytes at location @var{addr}. @item c @itemx c@var{addr} Resume execution at the current address (or at @var{addr} if supplied). @item s @itemx s@var{addr} Step the target program for one instruction, from either the current program counter or from @var{addr} if supplied. @item k Kill the target program. @item ? Report the most recent signal. To allow you to take advantage of the @value{GDBN} signal handling commands, one of the functions of the debugging stub is to report CPU traps as the corresponding POSIX signal values. @end table @kindex set remotedebug @kindex show remotedebug @cindex packets, reporting on stdout @cindex serial connections, debugging If you have trouble with the serial connection, you can use the command @code{set remotedebug}. This makes @value{GDBN} report on all packets sent back and forth across the serial line to the remote machine. The packet-debugging information is printed on the @value{GDBN} standard output stream. @code{set remotedebug off} turns it off, and @code{show remotedebug} will show you its current state. @end ifset @ifset Icmlx @node i960-Nindy Remote @subsection @value{GDBN} with a remote i960 (Nindy) @cindex Nindy @cindex i960 @dfn{Nindy} is a ROM Monitor program for Intel 960 target systems. When @value{GDBN} is configured to control a remote Intel 960 using Nindy, you can tell @value{GDBN} how to connect to the 960 in several ways: @itemize @bullet @item Through command line options specifying serial port, version of the Nindy protocol, and communications speed; @item By responding to a prompt on startup; @item By using the @code{target} command at any point during your @value{GDBN} session. @xref{Target Commands, ,Commands for managing targets}. @end itemize @menu * Nindy Startup:: Startup with Nindy * Nindy Options:: Options for Nindy * Nindy Reset:: Nindy reset command @end menu @node Nindy Startup @subsubsection Startup with Nindy If you simply start @code{@value{GDBP}} without using any command-line options, you are prompted for what serial port to use, @emph{before} you reach the ordinary @value{GDBN} prompt: @example Attach /dev/ttyNN -- specify NN, or "quit" to quit: @end example @noindent Respond to the prompt with whatever suffix (after @samp{/dev/tty}) identifies the serial port you want to use. You can, if you choose, simply start up with no Nindy connection by responding to the prompt with an empty line. If you do this and later wish to attach to Nindy, use @code{target} (@pxref{Target Commands, ,Commands for managing targets}). @node Nindy Options @subsubsection Options for Nindy These are the startup options for beginning your @value{GDBN} session with a Nindy-960 board attached: @table @code @item -r @var{port} Specify the serial port name of a serial interface to be used to connect to the target system. This option is only available when @value{GDBN} is configured for the Intel 960 target architecture. You may specify @var{port} as any of: a full pathname (e.g. @samp{-r /dev/ttya}), a device name in @file{/dev} (e.g. @samp{-r ttya}), or simply the unique suffix for a specific @code{tty} (e.g. @samp{-r a}). @item -O (An uppercase letter ``O'', not a zero.) Specify that @value{GDBN} should use the ``old'' Nindy monitor protocol to connect to the target system. This option is only available when @value{GDBN} is configured for the Intel 960 target architecture. @quotation @emph{Warning:} if you specify @samp{-O}, but are actually trying to connect to a target system that expects the newer protocol, the connection will fail, appearing to be a speed mismatch. @value{GDBN} will repeatedly attempt to reconnect at several different line speeds. You can abort this process with an interrupt. @end quotation @item -brk Specify that @value{GDBN} should first send a @code{BREAK} signal to the target system, in an attempt to reset it, before connecting to a Nindy target. @quotation @emph{Warning:} Many target systems do not have the hardware that this requires; it only works with a few boards. @end quotation @end table The standard @samp{-b} option controls the line speed used on the serial port. @c @group @node Nindy Reset @subsubsection Nindy reset command @table @code @item reset @kindex reset For a Nindy target, this command sends a ``break'' to the remote target system; this is only useful if the target has been equipped with a circuit to perform a hard reset (or some other interesting action) when a break is detected. @end table @c @end group @end ifset @ifset AMDxxixK @node UDI29K Remote @subsection @value{GDBN} and the UDI protocol for AMD29K @cindex UDI @cindex AMD29K via UDI @value{GDBN} supports AMD's UDI (``Universal Debugger Interface'') protocol for debugging the 29k processor family. To use this configuration with AMD targets running the MiniMON monitor, you need the program @code{MONTIP}, available from AMD at no charge. You can also use @value{GDBN} with the UDI conformant 29k simulator program @code{ISSTIP}, also available from AMD. @table @code @item target udi @var{keyword} @kindex udi Select the UDI interface to a remote 29K board or simulator, where @var{keyword} is an entry in the AMD configuration file @file{udi_soc}. This file contains keyword entries which specify parameters used to connect to 29k targets. If the @file{udi_soc} file is not in your working directory, you must set the environment variable @samp{UDICONF} to its pathname. @end table @node EB29K Remote @subsection @value{GDBN} with a remote EB29K @cindex EB29K board @cindex running 29K programs To use @value{GDBN} from a Unix system to run programs on AMD's EB29K board in a PC, you must first connect a serial cable between the PC and a serial port on the Unix system. In the following, we assume you've hooked the cable between the PC's @file{COM1} port and @file{/dev/ttya} on the Unix system. @menu * Comms (EB29K):: Communications setup * gdb-EB29K:: EB29K cross-debugging * Remote Log:: Remote log @end menu @node Comms (EB29K) @subsubsection Communications setup The next step is to set up the PC's port, by doing something like this in DOS on the PC: @example C:\> MODE com1:9600,n,8,1,none @end example @noindent This example---run on an MS DOS 4.0 system---sets the PC port to 9600 bps, no parity, eight data bits, one stop bit, and no ``retry'' action; you must match the communications parameters when establishing the Unix end of the connection as well. @c FIXME: Who knows what this "no retry action" crud from the DOS manual may @c mean? It's optional; leave it out? ---pesch@cygnus.com, 25feb91 To give control of the PC to the Unix side of the serial line, type the following at the DOS console: @example C:\> CTTY com1 @end example @noindent (Later, if you wish to return control to the DOS console, you can use the command @code{CTTY con}---but you must send it over the device that had control, in our example over the @file{COM1} serial line). From the Unix host, use a communications program such as @code{tip} or @code{cu} to communicate with the PC; for example, @example cu -s 9600 -l /dev/ttya @end example @noindent The @code{cu} options shown specify, respectively, the linespeed and the serial port to use. If you use @code{tip} instead, your command line may look something like the following: @example tip -9600 /dev/ttya @end example @noindent Your system may require a different name where we show @file{/dev/ttya} as the argument to @code{tip}. The communications parameters, including which port to use, are associated with the @code{tip} argument in the ``remote'' descriptions file---normally the system table @file{/etc/remote}. @c FIXME: What if anything needs doing to match the "n,8,1,none" part of @c the DOS side's comms setup? cu can support -o (odd @c parity), -e (even parity)---apparently no settings for no parity or @c for character size. Taken from stty maybe...? John points out tip @c can set these as internal variables, eg ~s parity=none; man stty @c suggests that it *might* work to stty these options with stdin or @c stdout redirected... ---pesch@cygnus.com, 25feb91 @kindex EBMON Using the @code{tip} or @code{cu} connection, change the DOS working directory to the directory containing a copy of your 29K program, then start the PC program @code{EBMON} (an EB29K control program supplied with your board by AMD). You should see an initial display from @code{EBMON} similar to the one that follows, ending with the @code{EBMON} prompt @samp{#}--- @example C:\> G: G:\> CD \usr\joe\work29k G:\USR\JOE\WORK29K> EBMON Am29000 PC Coprocessor Board Monitor, version 3.0-18 Copyright 1990 Advanced Micro Devices, Inc. Written by Gibbons and Associates, Inc. Enter '?' or 'H' for help PC Coprocessor Type = EB29K I/O Base = 0x208 Memory Base = 0xd0000 Data Memory Size = 2048KB Available I-RAM Range = 0x8000 to 0x1fffff Available D-RAM Range = 0x80002000 to 0x801fffff PageSize = 0x400 Register Stack Size = 0x800 Memory Stack Size = 0x1800 CPU PRL = 0x3 Am29027 Available = No Byte Write Available = Yes # ~. @end example Then exit the @code{cu} or @code{tip} program (done in the example by typing @code{~.} at the @code{EBMON} prompt). @code{EBMON} will keep running, ready for @value{GDBN} to take over. For this example, we've assumed what is probably the most convenient way to make sure the same 29K program is on both the PC and the Unix system: a PC/NFS connection that establishes ``drive @code{G:}'' on the PC as a file system on the Unix host. If you do not have PC/NFS or something similar connecting the two systems, you must arrange some other way---perhaps floppy-disk transfer---of getting the 29K program from the Unix system to the PC; @value{GDBN} will @emph{not} download it over the serial line. @node gdb-EB29K @subsubsection EB29K cross-debugging Finally, @code{cd} to the directory containing an image of your 29K program on the Unix system, and start @value{GDBN}---specifying as argument the name of your 29K program: @example cd /usr/joe/work29k @value{GDBP} myfoo @end example Now you can use the @code{target} command: @example target amd-eb /dev/ttya 9600 MYFOO @c FIXME: test above 'target amd-eb' as spelled, with caps! caps are meant to @c emphasize that this is the name as seen by DOS (since I think DOS is @c single-minded about case of letters). ---pesch@cygnus.com, 25feb91 @end example @noindent In this example, we've assumed your program is in a file called @file{myfoo}. Note that the filename given as the last argument to @code{target amd-eb} should be the name of the program as it appears to DOS. In our example this is simply @code{MYFOO}, but in general it can include a DOS path, and depending on your transfer mechanism may not resemble the name on the Unix side. At this point, you can set any breakpoints you wish; when you are ready to see your program run on the 29K board, use the @value{GDBN} command @code{run}. To stop debugging the remote program, use the @value{GDBN} @code{detach} command. To return control of the PC to its console, use @code{tip} or @code{cu} once again, after your @value{GDBN} session has concluded, to attach to @code{EBMON}. You can then type the command @code{q} to shut down @code{EBMON}, returning control to the DOS command-line interpreter. Type @code{CTTY con} to return command input to the main DOS console, and type @kbd{~.} to leave @code{tip} or @code{cu}. @node Remote Log @subsubsection Remote log @kindex eb.log @cindex log file for EB29K The @code{target amd-eb} command creates a file @file{eb.log} in the current working directory, to help debug problems with the connection. @file{eb.log} records all the output from @code{EBMON}, including echoes of the commands sent to it. Running @samp{tail -f} on this file in another window often helps to understand trouble with @code{EBMON}, or unexpected events on the PC side of the connection. @end ifset @ifset STmm @node ST2000 Remote @subsection @value{GDBN} with a Tandem ST2000 To connect your ST2000 to the host system, see the manufacturer's manual. Once the ST2000 is physically attached, you can run @example target st2000 @var{dev} @var{speed} @end example @noindent to establish it as your debugging environment. The @code{load} and @code{attach} commands are @emph{not} defined for this target; you must load your program into the ST2000 as you normally would for standalone operation. @value{GDBN} will read debugging information (such as symbols) from a separate, debugging version of the program available on your host computer. @c FIXME!! This is terribly vague; what little content is here is @c basically hearsay. @cindex ST2000 auxiliary commands These auxiliary @value{GDBN} commands are available to help you with the ST2000 environment: @table @code @item st2000 @var{command} @kindex st2000 @var{cmd} @cindex STDBUG commands (ST2000) @cindex commands to STDBUG (ST2000) Send a @var{command} to the STDBUG monitor. See the manufacturer's manual for available commands. @item connect @cindex connect (to STDBUG) Connect the controlling terminal to the STDBUG command monitor. When you are done interacting with STDBUG, typing either of two character sequences will get you back to the @value{GDBN} command prompt: @kbd{@key{RET}~.} (Return, followed by tilde and period) or @kbd{@key{RET}~@key{C-d}} (Return, followed by tilde and control-D). @end table @end ifset @ifset VXWORKS @node VxWorks Remote @subsection @value{GDBN} and VxWorks @cindex VxWorks @value{GDBN} enables developers to spawn and debug tasks running on networked VxWorks targets from a Unix host. Already-running tasks spawned from the VxWorks shell can also be debugged. @value{GDBN} uses code that runs on both the UNIX host and on the VxWorks target. The program @code{@value{GDBP}} is installed and executed on the UNIX host. The following information on connecting to VxWorks was current when this manual was produced; newer releases of VxWorks may use revised procedures. The remote debugging interface (RDB) routines are installed and executed on the VxWorks target. These routines are included in the VxWorks library @file{rdb.a} and are incorporated into the system image when source-level debugging is enabled in the VxWorks configuration. @kindex INCLUDE_RDB If you wish, you can define @code{INCLUDE_RDB} in the VxWorks configuration file @file{configAll.h} to include the RDB interface routines and spawn the source debugging task @code{tRdbTask} when VxWorks is booted. For more information on configuring and remaking VxWorks, see the manufacturer's manual. @c VxWorks, see the @cite{VxWorks Programmer's Guide}. Once you have included the RDB interface in your VxWorks system image and set your Unix execution search path to find @value{GDBN}, you are ready to run @value{GDBN}. From your UNIX host, type: @example % @value{GDBP} @end example @value{GDBN} will come up showing the prompt: @example (@value{GDBP}) @end example @menu * VxWorks Connection:: Connecting to VxWorks * VxWorks Download:: VxWorks download * VxWorks Attach:: Running tasks @end menu @node VxWorks Connection @subsubsection Connecting to VxWorks The @value{GDBN} command @code{target} lets you connect to a VxWorks target on the network. To connect to a target whose host name is ``@code{tt}'', type: @example (@value{GDBP}) target vxworks tt @end example @value{GDBN} will display a message similar to the following: @smallexample Attaching remote machine across net... Success! @end smallexample @value{GDBN} will then attempt to read the symbol tables of any object modules loaded into the VxWorks target since it was last booted. @value{GDBN} locates these files by searching the directories listed in the command search path (@pxref{Environment, ,Your program's environment}); if it fails to find an object file, it will display a message such as: @example prog.o: No such file or directory. @end example This will cause the @code{target} command to abort. When this happens, you should add the appropriate directory to the search path, with the @value{GDBN} command @code{path}, and execute the @code{target} command again. @node VxWorks Download @subsubsection VxWorks download @cindex download to VxWorks If you have connected to the VxWorks target and you want to debug an object that has not yet been loaded, you can use the @value{GDBN} @code{load} command to download a file from UNIX to VxWorks incrementally. The object file given as an argument to the @code{load} command is actually opened twice: first by the VxWorks target in order to download the code, then by @value{GDBN} in order to read the symbol table. This can lead to problems if the current working directories on the two systems differ. It is simplest to set the working directory on both systems to the directory in which the object file resides, and then to reference the file by its name, without any path. Thus, to load a program @file{prog.o}, residing in @file{wherever/vw/demo/rdb}, on VxWorks type: @example -> cd "wherever/vw/demo/rdb" @end example On @value{GDBN} type: @example (@value{GDBP}) cd wherever/vw/demo/rdb (@value{GDBP}) load prog.o @end example @value{GDBN} will display a response similar to the following: @smallexample Reading symbol data from wherever/vw/demo/rdb/prog.o... done. @end smallexample You can also use the @code{load} command to reload an object module after editing and recompiling the corresponding source file. Note that this will cause @value{GDBN} to delete all currently-defined breakpoints, auto-displays, and convenience variables, and to clear the value history. (This is necessary in order to preserve the integrity of debugger data structures that reference the target system's symbol table.) @node VxWorks Attach @subsubsection Running tasks @cindex running VxWorks tasks You can also attach to an existing task using the @code{attach} command as follows: @example (@value{GDBP}) attach @var{task} @end example @noindent where @var{task} is the VxWorks hexadecimal task ID. The task can be running or suspended when you attach to it. If running, it will be suspended at the time of attachment. @end ifset @ifset Hviii @node Hitachi H8/300 Remote @subsection @value{GDBN} and the Hitachi H8/300 @value{GDBN} needs to know these things to talk to your H8/300: @enumerate @item that you want to use @samp{target hms}, the remote debugging interface for the H8/300 (this is the default when GDB is configured specifically for the H8/300); @item what serial device connects your host to your H8/300 (the first serial device available on your host is the default); @ignore @c this is only for Unix hosts, not currently of interest. @item what speed to use over the serial device. @end ignore @end enumerate @kindex device @cindex serial device for H8/300 @ignore @c only for Unix hosts Use the special @code{gdb83} command @samp{device @var{port}} if you need to explicitly set the serial device. The default @var{port} is the first available port on your host. This is only necessary on Unix hosts, where it is typically something like @file{/dev/ttya}. @kindex speed @cindex serial line speed for H8/300 @code{gdb83} has another special command to set the communications speed for the H8/300: @samp{speed @var{bps}}. This command also is only used from Unix hosts; on DOS hosts, set the line speed as usual from outside GDB with the DOS @kbd{mode} command (for instance, @w{@samp{mode com2:9600,n,8,1,p}} for a 9600 bps connection). @end ignore @value{GDBN} depends on an auxiliary terminate-and-stay-resident program called @code{asynctsr} to communicate with the H8/300 development board through a PC serial port. You must also use the DOS @code{mode} command to set up the serial port on the DOS side. The following sample session illustrates the steps needed to start a program under @value{GDBN} control on your H8/300. The example uses a sample H8/300 program called @file{t.x}. First hook up your H8/300 development board. In this example, we use a board attached to serial port @code{COM2}; if you use a different serial port, substitute its name in the argument of the @code{mode} command. When you call @code{asynctsr}, the auxiliary comms program used by the degugger, you give it just the numeric part of the serial port's name; for example, @samp{asyncstr 2} below runs @code{asyncstr} on @code{COM2}. @example (eg-C:\H8300\TEST) mode com2:9600,n,8,1,p Resident portion of MODE loaded COM2: 9600, n, 8, 1, p (eg-C:\H8300\TEST) asynctsr 2 @end example @quotation @emph{Warning:} We have noticed a bug in PC-NFS that conflicts with @code{asynctsr}. If you also run PC-NFS on your DOS host, you may need to disable it, or even boot without it, to use @code{asynctsr} to control your H8/300 board. @end quotation Now that serial communications are set up, and the H8/300 is connected, you can start up @value{GDBN}. Call @code{@value{GDBP}} with the name of your program as the argument. @code{@value{GDBP}} prompts you, as usual, with the prompt @samp{(@value{GDBP})}. Use two special commands to begin your debugging session: @samp{target hms} to specify cross-debugging to the Hitachi board, and the @code{load} command to download your program to the board. @code{load} displays the names of the program's sections, and a @samp{*} for each 2K of data downloaded. (If you want to refresh @value{GDBN} data on symbols or on the executable file without downloading, use the @value{GDBN} commands @code{file} or @code{symbol-file}. These commands, and @code{load} itself, are described in @ref{Files,,Commands to specify files}.) @smallexample (eg-C:\H8300\TEST) @value{GDBP} t.x GDB is free software and you are welcome to distribute copies of it under certain conditions; type "show copying" to see the conditions. There is absolutely no warranty for GDB; type "show warranty" for details. GDB @value{GDBVN}, Copyright 1992 Free Software Foundation, Inc... (gdb) target hms Connected to remote H8/300 HMS system. (gdb) load t.x .text : 0x8000 .. 0xabde *********** .data : 0xabde .. 0xad30 * .stack : 0xf000 .. 0xf014 * @end smallexample At this point, you're ready to run or debug your program. From here on, you can use all the usual @value{GDBN} commands. The @code{break} command sets breakpoints; the @code{run} command starts your program; @code{print} or @code{x} display data; the @code{continue} command resumes execution after stopping at a breakpoint. You can use the @code{help} command at any time to find out more about @value{GDBN} commands. Remember, however, that @emph{operating system} facilities aren't available on your H8/300; for example, if your program hangs, you can't send an interrupt---but you can press the @sc{reset} switch! Use the @sc{reset} button on the H8/300 board @itemize @bullet @item to interrupt your program (don't use @kbd{ctl-C} on the DOS host---it has no way to pass an interrupt signal to the H8/300); and @item to return to the @value{GDBN} command prompt after your program finishes normally. The communications protocol provides no other way for @value{GDBN} to detect program completion. @end itemize In either case, @value{GDBN} will see the effect of a @sc{reset} on the H8/300 board as a ``normal exit'' of your program. @end ifset @ifset SIMS @node Simulator @subsection Simulated CPU target @ifset GENERIC @cindex simulator @cindex simulator, Z8000 @cindex simulator, H8/300 @cindex Z8000 simulator @cindex H8/300 simulator @cindex CPU simulator For some configurations, @value{GDBN} includes a CPU simulator that you can use instead of a hardware CPU to debug your programs. Currently, a simulator is available when @value{GDBN} is configured to debug Zilog Z8000 or Hitachi H8/300 targets. @end ifset @ifclear GENERIC @ifset Hviii @cindex simulator, H8/300 @cindex Hitachi H8/300 simulator When configured for debugging Hitachi H8/300 targets, @value{GDBN} includes an H8/300 CPU simulator. @end ifset @ifset ZviiiK @cindex simulator, Z8000 @cindex Zilog Z8000 simulator When configured for debugging Zilog Z8000 targets, @value{GDBN} includes a Z8000 simulator. @end ifset @end ifclear @ifset ZviiiK For the Z8000 family, @samp{target sim} simulates either the Z8002 (the unsegmented variant of the Z8000 architecture) or the Z8001 (the segmented variant). The simulator recognizes which architecture is appropriate by inspecting the object code. @end ifset @table @code @item target sim @kindex sim @kindex target sim Debug programs on a simulated CPU @ifset GENERIC (which CPU depends on the @value{GDBN} configuration) @end ifset @end table @noindent After specifying this target, you can debug programs for the simulated CPU in the same style as programs for your host computer; use the @code{file} command to load a new program image, the @code{run} command to run your program, and so on. As well as making available all the usual machine registers (see @code{info reg}), this debugging target provides three additional items of information as specially named registers: @table @code @item cycles Counts clock-ticks in the simulator. @item insts Counts instructions run in the simulator. @item time Execution time in 60ths of a second. @end table You can refer to these values in @value{GDBN} expressions with the usual conventions; for example, @w{@samp{b fputc if $cycles>5000}} sets a conditional breakpoint that will suspend only after at least 5000 simulated clock ticks. @end ifset