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565 lines
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565 lines
23 KiB
Plaintext
Debugging GNU Emacs
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Copyright (c) 1985, 2000, 2001 Free Software Foundation, Inc.
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Permission is granted to anyone to make or distribute verbatim copies
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of this document as received, in any medium, provided that the
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copyright notice and permission notice are preserved,
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and that the distributor grants the recipient permission
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for further redistribution as permitted by this notice.
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Permission is granted to distribute modified versions
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of this document, or of portions of it,
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under the above conditions, provided also that they
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carry prominent notices stating who last changed them.
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[People who debug Emacs on Windows using native Windows debuggers
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should read the Windows-specific section near the end of this
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document.]
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It is a good idea to run Emacs under GDB (or some other suitable
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debugger) *all the time*. Then, when Emacs crashes, you will be able
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to debug the live process, not just a core dump. (This is especially
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important on systems which don't support core files, and instead print
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just the registers and some stack addresses.)
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If Emacs hangs, or seems to be stuck in some infinite loop, typing
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"kill -TSTP PID", where PID is the Emacs process ID, will cause GDB to
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kick in, provided that you run under GDB.
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** Getting control to the debugger
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`Fsignal' is a very useful place to put a breakpoint in.
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All Lisp errors go through there.
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It is useful, when debugging, to have a guaranteed way to return to
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the debugger at any time. When using X, this is easy: type C-c at the
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window where Emacs is running under GDB, and it will stop Emacs just
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as it would stop any ordinary program. When Emacs is running in a
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terminal, things are not so easy.
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The src/.gdbinit file in the Emacs distribution arranges for SIGINT
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(C-g in Emacs) to be passed to Emacs and not give control back to GDB.
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On modern POSIX systems, you can override that with this command:
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handle int stop nopass
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After this `handle' command, SIGINT will return control to GDB. If
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you want the C-g to cause a QUIT within Emacs as well, omit the
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`nopass'.
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A technique that can work when `handle SIGINT' does not is to store
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the code for some character into the variable stop_character. Thus,
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set stop_character = 29
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makes Control-] (decimal code 29) the stop character.
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Typing Control-] will cause immediate stop. You cannot
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use the set command until the inferior process has been started.
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Put a breakpoint early in `main', or suspend the Emacs,
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to get an opportunity to do the set command.
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** Examining Lisp object values.
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When you have a live process to debug, and it has not encountered a
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fatal error, you can use the GDB command `pr'. First print the value
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in the ordinary way, with the `p' command. Then type `pr' with no
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arguments. This calls a subroutine which uses the Lisp printer.
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Note: It is not a good idea to try `pr' if you know that Emacs is in
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deep trouble: its stack smashed (e.g., if it encountered SIGSEGV due
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to stack overflow), or crucial data structures, such as `obarray',
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corrupted, etc. In such cases, the Emacs subroutine called by `pr'
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might make more damage, like overwrite some data that is important for
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debugging the original problem.
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Also, on some systems it is impossible to use `pr' if you stopped
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Emacs while it was inside `select'. This is in fact what happens if
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you stop Emacs while it is waiting. In such a situation, don't try to
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use `pr'. Instead, use `s' to step out of the system call. Then
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Emacs will be between instructions and capable of handling `pr'.
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If you can't use `pr' command, for whatever reason, you can fall back
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on lower-level commands. Use the `xtype' command to print out the
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data type of the last data value. Once you know the data type, use
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the command that corresponds to that type. Here are these commands:
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xint xptr xwindow xmarker xoverlay xmiscfree xintfwd xboolfwd xobjfwd
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xbufobjfwd xkbobjfwd xbuflocal xbuffer xsymbol xstring xvector xframe
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xwinconfig xcompiled xcons xcar xcdr xsubr xprocess xfloat xscrollbar
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Each one of them applies to a certain type or class of types.
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(Some of these types are not visible in Lisp, because they exist only
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internally.)
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Each x... command prints some information about the value, and
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produces a GDB value (subsequently available in $) through which you
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can get at the rest of the contents.
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In general, most of the rest of the contents will be additional Lisp
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objects which you can examine in turn with the x... commands.
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Even with a live process, these x... commands are useful for
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examining the fields in a buffer, window, process, frame or marker.
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Here's an example using concepts explained in the node "Value History"
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of the GDB manual to print the variable frame from this line in
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xmenu.c:
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buf.frame_or_window = frame;
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First, use these commands:
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cd src
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gdb emacs
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b xmenu.c:1296
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r -q
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Then type C-x 5 2 to create a new frame, and it hits the breakpoint:
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(gdb) p frame
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$1 = 1077872640
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(gdb) xtype
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Lisp_Vectorlike
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PVEC_FRAME
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(gdb) xframe
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$2 = (struct frame *) 0x3f0800
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(gdb) p *$
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$3 = {
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size = 536871989,
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next = 0x366240,
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name = 809661752,
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[...]
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}
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(gdb) p $3->name
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$4 = 809661752
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Now we can use `pr' to print the name of the frame:
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(gdb) pr
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"emacs@steenrod.math.nwu.edu"
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The Emacs C code heavily uses macros defined in lisp.h. So suppose
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we want the address of the l-value expression near the bottom of
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`add_command_key' from keyboard.c:
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XVECTOR (this_command_keys)->contents[this_command_key_count++] = key;
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XVECTOR is a macro, and therefore GDB does not know about it.
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GDB cannot evaluate "p XVECTOR (this_command_keys)".
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However, you can use the xvector command in GDB to get the same
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result. Here is how:
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(gdb) p this_command_keys
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$1 = 1078005760
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(gdb) xvector
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$2 = (struct Lisp_Vector *) 0x411000
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0
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(gdb) p $->contents[this_command_key_count]
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$3 = 1077872640
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(gdb) p &$
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$4 = (int *) 0x411008
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Here's a related example of macros and the GDB `define' command.
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There are many Lisp vectors such as `recent_keys', which contains the
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last 100 keystrokes. We can print this Lisp vector
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p recent_keys
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pr
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But this may be inconvenient, since `recent_keys' is much more verbose
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than `C-h l'. We might want to print only the last 10 elements of
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this vector. `recent_keys' is updated in keyboard.c by the command
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XVECTOR (recent_keys)->contents[recent_keys_index] = c;
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So we define a GDB command `xvector-elts', so the last 10 keystrokes
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are printed by
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xvector-elts recent_keys recent_keys_index 10
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where you can define xvector-elts as follows:
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define xvector-elts
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set $i = 0
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p $arg0
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xvector
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set $foo = $
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while $i < $arg2
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p $foo->contents[$arg1-($i++)]
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pr
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end
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document xvector-elts
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Prints a range of elements of a Lisp vector.
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xvector-elts v n i
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prints `i' elements of the vector `v' ending at the index `n'.
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end
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** Getting Lisp-level backtrace information within GDB
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The most convenient way is to use the `xbacktrace' command. This
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shows the names of the Lisp functions that are currently active.
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If that doesn't work (e.g., because the `backtrace_list' structure is
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corrupted), type "bt" at the GDB prompt, to produce the C-level
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backtrace, and look for stack frames that call Ffuncall. Select them
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one by one in GDB, by typing "up N", where N is the appropriate number
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of frames to go up, and in each frame that calls Ffuncall type this:
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p *args
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pr
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This will print the name of the Lisp function called by that level
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of function calling.
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By printing the remaining elements of args, you can see the argument
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values. Here's how to print the first argument:
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p args[1]
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pr
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If you do not have a live process, you can use xtype and the other
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x... commands such as xsymbol to get such information, albeit less
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conveniently. For example:
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p *args
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xtype
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and, assuming that "xtype" says that args[0] is a symbol:
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xsymbol
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** Debugging what happens while preloading and dumping Emacs
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Type `gdb temacs' and start it with `r -batch -l loadup dump'.
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If temacs actually succeeds when running under GDB in this way, do not
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try to run the dumped Emacs, because it was dumped with the GDB
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breakpoints in it.
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** Debugging `temacs'
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Debugging `temacs' is useful when you want to establish whether a
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problem happens in an undumped Emacs. To run `temacs' under a
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debugger, type "gdb temacs", then start it with `r -batch -l loadup'.
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** If you encounter X protocol errors
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Try evaluating (x-synchronize t). That puts Emacs into synchronous
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mode, where each Xlib call checks for errors before it returns. This
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mode is much slower, but when you get an error, you will see exactly
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which call really caused the error.
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You can start Emacs in a synchronous mode by invoking it with the -xrm
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option, like this:
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emacs -xrm "emacs.synchronous: true"
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Setting a breakpoint in the function `x_error_quitter' and looking at
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the backtrace when Emacs stops inside that function will show what
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code causes the X protocol errors.
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** If the symptom of the bug is that Emacs fails to respond
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Don't assume Emacs is `hung'--it may instead be in an infinite loop.
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To find out which, make the problem happen under GDB and stop Emacs
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once it is not responding. (If Emacs is using X Windows directly, you
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can stop Emacs by typing C-z at the GDB job.) Then try stepping with
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`step'. If Emacs is hung, the `step' command won't return. If it is
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looping, `step' will return.
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If this shows Emacs is hung in a system call, stop it again and
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examine the arguments of the call. If you report the bug, it is very
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important to state exactly where in the source the system call is, and
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what the arguments are.
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If Emacs is in an infinite loop, try to determine where the loop
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starts and ends. The easiest way to do this is to use the GDB command
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`finish'. Each time you use it, Emacs resumes execution until it
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exits one stack frame. Keep typing `finish' until it doesn't
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return--that means the infinite loop is in the stack frame which you
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just tried to finish.
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Stop Emacs again, and use `finish' repeatedly again until you get back
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to that frame. Then use `next' to step through that frame. By
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stepping, you will see where the loop starts and ends. Also, examine
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the data being used in the loop and try to determine why the loop does
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not exit when it should.
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** If certain operations in Emacs are slower than they used to be, here
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is some advice for how to find out why.
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Stop Emacs repeatedly during the slow operation, and make a backtrace
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each time. Compare the backtraces looking for a pattern--a specific
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function that shows up more often than you'd expect.
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If you don't see a pattern in the C backtraces, get some Lisp
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backtrace information by typing "xbacktrace" or by looking at Ffuncall
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frames (see above), and again look for a pattern.
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When using X, you can stop Emacs at any time by typing C-z at GDB.
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When not using X, you can do this with C-g. On non-Unix platforms,
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such as MS-DOS, you might need to press C-BREAK instead.
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** If GDB does not run and your debuggers can't load Emacs.
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On some systems, no debugger can load Emacs with a symbol table,
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perhaps because they all have fixed limits on the number of symbols
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and Emacs exceeds the limits. Here is a method that can be used
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in such an extremity. Do
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nm -n temacs > nmout
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strip temacs
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adb temacs
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0xd:i
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0xe:i
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14:i
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17:i
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:r -l loadup (or whatever)
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It is necessary to refer to the file `nmout' to convert
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numeric addresses into symbols and vice versa.
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It is useful to be running under a window system.
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Then, if Emacs becomes hopelessly wedged, you can create
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another window to do kill -9 in. kill -ILL is often
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useful too, since that may make Emacs dump core or return
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to adb.
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** Debugging incorrect screen updating.
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To debug Emacs problems that update the screen wrong, it is useful
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to have a record of what input you typed and what Emacs sent to the
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screen. To make these records, do
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(open-dribble-file "~/.dribble")
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(open-termscript "~/.termscript")
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The dribble file contains all characters read by Emacs from the
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terminal, and the termscript file contains all characters it sent to
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the terminal. The use of the directory `~/' prevents interference
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with any other user.
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If you have irreproducible display problems, put those two expressions
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in your ~/.emacs file. When the problem happens, exit the Emacs that
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you were running, kill it, and rename the two files. Then you can start
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another Emacs without clobbering those files, and use it to examine them.
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An easy way to see if too much text is being redrawn on a terminal is to
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evaluate `(setq inverse-video t)' before you try the operation you think
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will cause too much redrawing. This doesn't refresh the screen, so only
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newly drawn text is in inverse video.
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The Emacs display code includes special debugging code, but it is
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normally disabled. You can enable it by building Emacs with the
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pre-processing symbol GLYPH_DEBUG defined. Here's one easy way,
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suitable for Unix and GNU systems, to build such a debugging version:
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MYCPPFLAGS='-DGLYPH_DEBUG=1' make
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Building Emacs like that activates many assertions which scrutinize
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display code operation more than Emacs does normally. (To see the
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code which tests these assertions, look for calls to the `xassert'
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macros.) Any assertion that is reported to fail should be
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investigated.
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Building with GLYPH_DEBUG defined also defines several helper
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functions which can help debugging display code. One such function is
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`dump_glyph_matrix'. If you run Emacs under GDB, you can print the
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contents of any glyph matrix by just calling that function with the
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matrix as its argument. For example, the following command will print
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the contents of the current matrix of the window whose pointer is in
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`w':
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(gdb) p dump_glyph_matrix (w->current_matrix, 2)
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(The second argument 2 tells dump_glyph_matrix to print the glyphs in
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a long form.) You can dump the selected window's current glyph matrix
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interactively with "M-x dump-glyph-matrix RET"; see the documentation
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of this function for more details.
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Several more functions for debugging display code are available in
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Emacs compiled with GLYPH_DEBUG defined; type "C-h f dump- TAB" and
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"C-h f trace- TAB" to see the full list.
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** Debugging LessTif
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If you encounter bugs whereby Emacs built with LessTif grabs all mouse
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and keyboard events, or LessTif menus behave weirdly, it might be
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helpful to set the `DEBUGSOURCES' and `DEBUG_FILE' environment
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variables, so that one can see what LessTif was doing at this point.
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For instance
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export DEBUGSOURCES="RowColumn.c:MenuShell.c:MenuUtil.c"
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export DEBUG_FILE=/usr/tmp/LESSTIF_TRACE
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emacs &
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causes LessTif to print traces from the three named source files to a
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file in `/usr/tmp' (that file can get pretty large). The above should
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be typed at the shell prompt before invoking Emacs, as shown by the
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last line above.
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Running GDB from another terminal could also help with such problems.
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You can arrange for GDB to run on one machine, with the Emacs display
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appearing on another. Then, when the bug happens, you can go back to
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the machine where you started GDB and use the debugger from there.
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** Debugging problems which happen in GC
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The array `last_marked' (defined on alloc.c) can be used to display up
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to 500 last objects marked by the garbage collection process.
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Whenever the garbage collector marks a Lisp object, it records the
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pointer to that object in the `last_marked' array. The variable
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`last_marked_index' holds the index into the `last_marked' array one
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place beyond where the pointer to the very last marked object is
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stored.
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The single most important goal in debugging GC problems is to find the
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Lisp data structure that got corrupted. This is not easy since GC
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changes the tag bits and relocates strings which make it hard to look
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at Lisp objects with commands such as `pr'. It is sometimes necessary
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to convert Lisp_Object variables into pointers to C struct's manually.
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Use the `last_marked' array and the source to reconstruct the sequence
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that objects were marked.
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Once you discover the corrupted Lisp object or data structure, it is
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useful to look at it in a fresh Emacs session and compare its contents
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with a session that you are debugging.
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** Debugging problems with non-ASCII characters
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If you experience problems which seem to be related to non-ASCII
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characters, such as \201 characters appearing in the buffer or in your
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files, set the variable byte-debug-flag to t. This causes Emacs to do
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some extra checks, such as look for broken relations between byte and
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character positions in buffers and strings; the resulting diagnostics
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might pinpoint the cause of the problem.
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** Running Emacs built with malloc debugging packages
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If Emacs exhibits bugs that seem to be related to use of memory
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allocated off the heap, it might be useful to link Emacs with a
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special debugging library, such as Electric Fence (a.k.a. efence) or
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GNU Checker, which helps find such problems.
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Emacs compiled with such packages might not run without some hacking,
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because Emacs replaces the system's memory allocation functions with
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its own versions, and because the dumping process might be
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incompatible with the way these packages use to track allocated
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memory. Here are some of the changes you might find necessary
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(SYSTEM-NAME and MACHINE-NAME are the names of your OS- and
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CPU-specific headers in the subdirectories of `src'):
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- In src/s/SYSTEM-NAME.h add "#define SYSTEM_MALLOC".
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- In src/m/MACHINE-NAME.h add "#define CANNOT_DUMP" and
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"#define CANNOT_UNEXEC".
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- Configure with a different --prefix= option. If you use GCC,
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version 2.7.2 is preferred, as some malloc debugging packages
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work a lot better with it than with 2.95 or later versions.
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- Type "make" then "make -k install".
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- If required, invoke the package-specific command to prepare
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src/temacs for execution.
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- cd ..; src/temacs
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(Note that this runs `temacs' instead of the usual `emacs' executable.
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This avoids problems with dumping Emacs mentioned above.)
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Some malloc debugging libraries might print lots of false alarms for
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bitfields used by Emacs in some data structures. If you want to get
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rid of the false alarms, you will have to hack the definitions of
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these data structures on the respective headers to remove the `:N'
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bitfield definitions (which will cause each such field to use a full
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int).
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** Some suggestions for debugging on MS Windows:
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(written by Marc Fleischeuers, Geoff Voelker and Andrew Innes)
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To debug Emacs with Microsoft Visual C++, you either start emacs from
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the debugger or attach the debugger to a running emacs process.
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To start emacs from the debugger, you can use the file bin/debug.bat.
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The Microsoft Developer studio will start and under Project, Settings,
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Debug, General you can set the command-line arguments and Emacs's
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startup directory. Set breakpoints (Edit, Breakpoints) at Fsignal and
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other functions that you want to examine. Run the program (Build,
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Start debug). Emacs will start and the debugger will take control as
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soon as a breakpoint is hit.
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You can also attach the debugger to an already running Emacs process.
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To do this, start up the Microsoft Developer studio and select Build,
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Start debug, Attach to process. Choose the Emacs process from the
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list. Send a break to the running process (Debug, Break) and you will
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find that execution is halted somewhere in user32.dll. Open the stack
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trace window and go up the stack to w32_msg_pump. Now you can set
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breakpoints in Emacs (Edit, Breakpoints). Continue the running Emacs
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process (Debug, Step out) and control will return to Emacs, until a
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breakpoint is hit.
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To examine the contents of a Lisp variable, you can use the function
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'debug_print'. Right-click on a variable, select QuickWatch (it has
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an eyeglass symbol on its button in the toolbar), and in the text
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field at the top of the window, place 'debug_print(' and ')' around
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the expression. Press 'Recalculate' and the output is sent to stderr,
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and to the debugger via the OutputDebugString routine. The output
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sent to stderr should be displayed in the console window that was
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opened when the emacs.exe executable was started. The output sent to
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the debugger should be displayed in the 'Debug' pane in the Output
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window. If Emacs was started from the debugger, a console window was
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opened at Emacs' startup; this console window also shows the output of
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'debug_print'.
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For example, start and run Emacs in the debugger until it is waiting
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for user input. Then click on the `Break' button in the debugger to
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halt execution. Emacs should halt in `ZwUserGetMessage' waiting for
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an input event. Use the `Call Stack' window to select the procedure
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`w32_msp_pump' up the call stack (see below for why you have to do
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this). Open the QuickWatch window and enter
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"debug_print(Vexec_path)". Evaluating this expression will then print
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out the contents of the Lisp variable `exec-path'.
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If QuickWatch reports that the symbol is unknown, then check the call
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stack in the `Call Stack' window. If the selected frame in the call
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stack is not an Emacs procedure, then the debugger won't recognize
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Emacs symbols. Instead, select a frame that is inside an Emacs
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procedure and try using `debug_print' again.
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If QuickWatch invokes debug_print but nothing happens, then check the
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thread that is selected in the debugger. If the selected thread is
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not the last thread to run (the "current" thread), then it cannot be
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used to execute debug_print. Use the Debug menu to select the current
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thread and try using debug_print again. Note that the debugger halts
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execution (e.g., due to a breakpoint) in the context of the current
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thread, so this should only be a problem if you've explicitly switched
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threads.
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It is also possible to keep appropriately masked and typecast Lisp
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symbols in the Watch window, this is more convenient when steeping
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though the code. For instance, on entering apply_lambda, you can
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watch (struct Lisp_Symbol *) (0xfffffff & args[0]).
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Optimizations often confuse the MS debugger. For example, the
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debugger will sometimes report wrong line numbers, e.g., when it
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prints the backtrace for a crash. It is usually best to look at the
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disassembly to determine exactly what code is being run--the
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disassembly will probably show several source lines followed by a
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block of assembler for those lines. The actual point where Emacs
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crashes will be one of those source lines, but not neccesarily the one
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that the debugger reports.
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Another problematic area with the MS debugger is with variables that
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are stored in registers: it will sometimes display wrong values for
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those variables. Usually you will not be able to see any value for a
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register variable, but if it is only being stored in a register
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temporarily, you will see an old value for it. Again, you need to
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look at the disassembly to determine which registers are being used,
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and look at those registers directly, to see the actual current values
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of these variables.
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