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1634 lines
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1634 lines
63 KiB
Plaintext
@comment -*-texinfo-*-
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@c This is part of the GNU Emacs Lisp Reference Manual.
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@c Copyright (C) 1992-1994, 1998-1999, 2001-2012 Free Software Foundation, Inc.
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@c See the file elisp.texi for copying conditions.
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@c This file can also be used by an independent Edebug User
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@c Manual in which case the Edebug node below should be used
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@c with the following links to the Bugs section and to the top level:
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@c , Bugs and Todo List, Top, Top
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@node Edebug, Syntax Errors, Debugger, Debugging
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@section Edebug
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@cindex Edebug debugging facility
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Edebug is a source-level debugger for Emacs Lisp programs, with which
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you can:
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@itemize @bullet
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@item
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Step through evaluation, stopping before and after each expression.
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@item
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Set conditional or unconditional breakpoints.
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@item
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Stop when a specified condition is true (the global break event).
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@item
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Trace slow or fast, stopping briefly at each stop point, or
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at each breakpoint.
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@item
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Display expression results and evaluate expressions as if outside of
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Edebug.
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@item
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Automatically re-evaluate a list of expressions and
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display their results each time Edebug updates the display.
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@item
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Output trace information on function calls and returns.
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@item
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Stop when an error occurs.
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@item
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Display a backtrace, omitting Edebug's own frames.
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@item
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Specify argument evaluation for macros and defining forms.
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@item
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Obtain rudimentary coverage testing and frequency counts.
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@end itemize
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The first three sections below should tell you enough about Edebug to
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start using it.
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@menu
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* Using Edebug:: Introduction to use of Edebug.
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* Instrumenting:: You must instrument your code
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in order to debug it with Edebug.
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* Modes: Edebug Execution Modes. Execution modes, stopping more or less often.
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* Jumping:: Commands to jump to a specified place.
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* Misc: Edebug Misc. Miscellaneous commands.
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* Breaks:: Setting breakpoints to make the program stop.
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* Trapping Errors:: Trapping errors with Edebug.
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* Views: Edebug Views. Views inside and outside of Edebug.
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* Eval: Edebug Eval. Evaluating expressions within Edebug.
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* Eval List:: Expressions whose values are displayed
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each time you enter Edebug.
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* Printing in Edebug:: Customization of printing.
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* Trace Buffer:: How to produce trace output in a buffer.
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* Coverage Testing:: How to test evaluation coverage.
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* The Outside Context:: Data that Edebug saves and restores.
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* Edebug and Macros:: Specifying how to handle macro calls.
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* Options: Edebug Options. Option variables for customizing Edebug.
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@end menu
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@node Using Edebug
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@subsection Using Edebug
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To debug a Lisp program with Edebug, you must first @dfn{instrument}
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the Lisp code that you want to debug. A simple way to do this is to
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first move point into the definition of a function or macro and then do
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@kbd{C-u C-M-x} (@code{eval-defun} with a prefix argument). See
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@ref{Instrumenting}, for alternative ways to instrument code.
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Once a function is instrumented, any call to the function activates
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Edebug. Depending on which Edebug execution mode you have selected,
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activating Edebug may stop execution and let you step through the
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function, or it may update the display and continue execution while
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checking for debugging commands. The default execution mode is step,
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which stops execution. @xref{Edebug Execution Modes}.
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Within Edebug, you normally view an Emacs buffer showing the source of
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the Lisp code you are debugging. This is referred to as the @dfn{source
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code buffer}, and it is temporarily read-only.
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An arrow in the left fringe indicates the line where the function is
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executing. Point initially shows where within the line the function is
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executing, but this ceases to be true if you move point yourself.
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If you instrument the definition of @code{fac} (shown below) and then
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execute @code{(fac 3)}, here is what you would normally see. Point is
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at the open-parenthesis before @code{if}.
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@example
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(defun fac (n)
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=>@point{}(if (< 0 n)
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(* n (fac (1- n)))
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1))
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@end example
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@cindex stop points
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The places within a function where Edebug can stop execution are called
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@dfn{stop points}. These occur both before and after each subexpression
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that is a list, and also after each variable reference.
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Here we use periods to show the stop points in the function
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@code{fac}:
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@example
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(defun fac (n)
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.(if .(< 0 n.).
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.(* n. .(fac .(1- n.).).).
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1).)
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@end example
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The special commands of Edebug are available in the source code buffer
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in addition to the commands of Emacs Lisp mode. For example, you can
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type the Edebug command @key{SPC} to execute until the next stop point.
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If you type @key{SPC} once after entry to @code{fac}, here is the
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display you will see:
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@example
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(defun fac (n)
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=>(if @point{}(< 0 n)
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(* n (fac (1- n)))
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1))
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@end example
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When Edebug stops execution after an expression, it displays the
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expression's value in the echo area.
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Other frequently used commands are @kbd{b} to set a breakpoint at a stop
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point, @kbd{g} to execute until a breakpoint is reached, and @kbd{q} to
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exit Edebug and return to the top-level command loop. Type @kbd{?} to
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display a list of all Edebug commands.
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@node Instrumenting
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@subsection Instrumenting for Edebug
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In order to use Edebug to debug Lisp code, you must first
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@dfn{instrument} the code. Instrumenting code inserts additional code
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into it, to invoke Edebug at the proper places.
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@kindex C-M-x
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@findex eval-defun (Edebug)
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When you invoke command @kbd{C-M-x} (@code{eval-defun}) with a
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prefix argument on a function definition, it instruments the
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definition before evaluating it. (This does not modify the source
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code itself.) If the variable @code{edebug-all-defs} is
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non-@code{nil}, that inverts the meaning of the prefix argument: in
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this case, @kbd{C-M-x} instruments the definition @emph{unless} it has
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a prefix argument. The default value of @code{edebug-all-defs} is
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@code{nil}. The command @kbd{M-x edebug-all-defs} toggles the value
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of the variable @code{edebug-all-defs}.
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@findex eval-region @r{(Edebug)}
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@findex eval-buffer @r{(Edebug)}
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@findex eval-current-buffer @r{(Edebug)}
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If @code{edebug-all-defs} is non-@code{nil}, then the commands
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@code{eval-region}, @code{eval-current-buffer}, and @code{eval-buffer}
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also instrument any definitions they evaluate. Similarly,
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@code{edebug-all-forms} controls whether @code{eval-region} should
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instrument @emph{any} form, even non-defining forms. This doesn't apply
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to loading or evaluations in the minibuffer. The command @kbd{M-x
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edebug-all-forms} toggles this option.
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@findex edebug-eval-top-level-form
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Another command, @kbd{M-x edebug-eval-top-level-form}, is available to
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instrument any top-level form regardless of the values of
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@code{edebug-all-defs} and @code{edebug-all-forms}.
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While Edebug is active, the command @kbd{I}
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(@code{edebug-instrument-callee}) instruments the definition of the
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function or macro called by the list form after point, if it is not already
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instrumented. This is possible only if Edebug knows where to find the
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source for that function; for this reason, after loading Edebug,
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@code{eval-region} records the position of every definition it
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evaluates, even if not instrumenting it. See also the @kbd{i} command
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(@pxref{Jumping}), which steps into the call after instrumenting the
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function.
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Edebug knows how to instrument all the standard special forms,
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@code{interactive} forms with an expression argument, anonymous lambda
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expressions, and other defining forms. However, Edebug cannot determine
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on its own what a user-defined macro will do with the arguments of a
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macro call, so you must provide that information using Edebug
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specifications; for details, @pxref{Edebug and Macros}.
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When Edebug is about to instrument code for the first time in a
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session, it runs the hook @code{edebug-setup-hook}, then sets it to
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@code{nil}. You can use this to load Edebug specifications
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associated with a package you are using, but only when you use Edebug.
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@findex eval-expression @r{(Edebug)}
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To remove instrumentation from a definition, simply re-evaluate its
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definition in a way that does not instrument. There are two ways of
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evaluating forms that never instrument them: from a file with
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@code{load}, and from the minibuffer with @code{eval-expression}
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(@kbd{M-:}).
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If Edebug detects a syntax error while instrumenting, it leaves point
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at the erroneous code and signals an @code{invalid-read-syntax} error.
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@c FIXME? I can't see that it "leaves point at the erroneous code".
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@xref{Edebug Eval}, for other evaluation functions available
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inside of Edebug.
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@node Edebug Execution Modes
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@subsection Edebug Execution Modes
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@cindex Edebug execution modes
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Edebug supports several execution modes for running the program you are
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debugging. We call these alternatives @dfn{Edebug execution modes}; do
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not confuse them with major or minor modes. The current Edebug execution mode
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determines how far Edebug continues execution before stopping---whether
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it stops at each stop point, or continues to the next breakpoint, for
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example---and how much Edebug displays the progress of the evaluation
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before it stops.
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Normally, you specify the Edebug execution mode by typing a command to
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continue the program in a certain mode. Here is a table of these
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commands; all except for @kbd{S} resume execution of the program, at
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least for a certain distance.
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@table @kbd
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@item S
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Stop: don't execute any more of the program, but wait for more
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Edebug commands (@code{edebug-stop}).
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@c FIXME Does not work. http://debbugs.gnu.org/9764
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@item @key{SPC}
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Step: stop at the next stop point encountered (@code{edebug-step-mode}).
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@item n
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Next: stop at the next stop point encountered after an expression
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(@code{edebug-next-mode}). Also see @code{edebug-forward-sexp} in
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@ref{Jumping}.
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@item t
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Trace: pause (normally one second) at each Edebug stop point
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(@code{edebug-trace-mode}).
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@item T
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Rapid trace: update the display at each stop point, but don't actually
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pause (@code{edebug-Trace-fast-mode}).
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@item g
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Go: run until the next breakpoint (@code{edebug-go-mode}). @xref{Breakpoints}.
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@item c
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Continue: pause one second at each breakpoint, and then continue
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(@code{edebug-continue-mode}).
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@item C
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Rapid continue: move point to each breakpoint, but don't pause
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(@code{edebug-Continue-fast-mode}).
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@item G
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Go non-stop: ignore breakpoints (@code{edebug-Go-nonstop-mode}). You
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can still stop the program by typing @kbd{S}, or any editing command.
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@end table
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In general, the execution modes earlier in the above list run the
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program more slowly or stop sooner than the modes later in the list.
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While executing or tracing, you can interrupt the execution by typing
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any Edebug command. Edebug stops the program at the next stop point and
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then executes the command you typed. For example, typing @kbd{t} during
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execution switches to trace mode at the next stop point. You can use
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@kbd{S} to stop execution without doing anything else.
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If your function happens to read input, a character you type intending
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to interrupt execution may be read by the function instead. You can
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avoid such unintended results by paying attention to when your program
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wants input.
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@cindex keyboard macros (Edebug)
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Keyboard macros containing the commands in this section do not
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completely work: exiting from Edebug, to resume the program, loses track
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of the keyboard macro. This is not easy to fix. Also, defining or
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executing a keyboard macro outside of Edebug does not affect commands
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inside Edebug. This is usually an advantage. See also the
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@code{edebug-continue-kbd-macro} option in @ref{Edebug Options}.
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When you enter a new Edebug level, the initial execution mode comes
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from the value of the variable @code{edebug-initial-mode}
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(@pxref{Edebug Options}). By default, this specifies step mode. Note
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that you may reenter the same Edebug level several times if, for
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example, an instrumented function is called several times from one
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command.
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@defopt edebug-sit-for-seconds
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This option specifies how many seconds to wait between execution steps
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in trace mode or continue mode. The default is 1 second.
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@end defopt
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@node Jumping
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@subsection Jumping
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The commands described in this section execute until they reach a
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specified location. All except @kbd{i} make a temporary breakpoint to
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establish the place to stop, then switch to go mode. Any other
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breakpoint reached before the intended stop point will also stop
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execution. @xref{Breakpoints}, for the details on breakpoints.
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These commands may fail to work as expected in case of nonlocal exit,
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as that can bypass the temporary breakpoint where you expected the
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program to stop.
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@table @kbd
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@item h
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Proceed to the stop point near where point is (@code{edebug-goto-here}).
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@item f
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Run the program for one expression
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(@code{edebug-forward-sexp}).
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@item o
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Run the program until the end of the containing sexp (@code{edebug-step-out}).
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@item i
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Step into the function or macro called by the form after point
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(@code{edebug-step-in}).
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@end table
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The @kbd{h} command proceeds to the stop point at or after the current
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location of point, using a temporary breakpoint.
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The @kbd{f} command runs the program forward over one expression. More
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precisely, it sets a temporary breakpoint at the position that
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@code{forward-sexp} would reach, then executes in go mode so that
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the program will stop at breakpoints.
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With a prefix argument @var{n}, the temporary breakpoint is placed
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@var{n} sexps beyond point. If the containing list ends before @var{n}
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more elements, then the place to stop is after the containing
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expression.
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You must check that the position @code{forward-sexp} finds is a place
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that the program will really get to. In @code{cond}, for example,
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this may not be true.
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For flexibility, the @kbd{f} command does @code{forward-sexp} starting
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at point, rather than at the stop point. If you want to execute one
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expression @emph{from the current stop point}, first type @kbd{w}
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(@code{edebug-where}) to move point there, and then type @kbd{f}.
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The @kbd{o} command continues ``out of'' an expression. It places a
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temporary breakpoint at the end of the sexp containing point. If the
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containing sexp is a function definition itself, @kbd{o} continues until
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just before the last sexp in the definition. If that is where you are
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now, it returns from the function and then stops. In other words, this
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command does not exit the currently executing function unless you are
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positioned after the last sexp.
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The @kbd{i} command steps into the function or macro called by the list
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form after point, and stops at its first stop point. Note that the form
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need not be the one about to be evaluated. But if the form is a
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function call about to be evaluated, remember to use this command before
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any of the arguments are evaluated, since otherwise it will be too late.
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The @kbd{i} command instruments the function or macro it's supposed to
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step into, if it isn't instrumented already. This is convenient, but keep
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in mind that the function or macro remains instrumented unless you explicitly
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arrange to deinstrument it.
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@node Edebug Misc
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@subsection Miscellaneous Edebug Commands
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Some miscellaneous Edebug commands are described here.
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@table @kbd
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@item ?
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Display the help message for Edebug (@code{edebug-help}).
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@item C-]
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Abort one level back to the previous command level
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(@code{abort-recursive-edit}).
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@item q
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Return to the top level editor command loop (@code{top-level}). This
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exits all recursive editing levels, including all levels of Edebug
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activity. However, instrumented code protected with
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@code{unwind-protect} or @code{condition-case} forms may resume
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debugging.
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@item Q
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Like @kbd{q}, but don't stop even for protected code
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(@code{edebug-top-level-nonstop}).
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@item r
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Redisplay the most recently known expression result in the echo area
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(@code{edebug-previous-result}).
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@item d
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Display a backtrace, excluding Edebug's own functions for clarity
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(@code{edebug-backtrace}).
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You cannot use debugger commands in the backtrace buffer in Edebug as
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you would in the standard debugger.
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The backtrace buffer is killed automatically when you continue
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execution.
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@end table
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You can invoke commands from Edebug that activate Edebug again
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recursively. Whenever Edebug is active, you can quit to the top level
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with @kbd{q} or abort one recursive edit level with @kbd{C-]}. You can
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display a backtrace of all the pending evaluations with @kbd{d}.
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@node Breaks
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@subsection Breaks
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Edebug's step mode stops execution when the next stop point is reached.
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There are three other ways to stop Edebug execution once it has started:
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breakpoints, the global break condition, and source breakpoints.
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@menu
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* Breakpoints:: Breakpoints at stop points.
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* Global Break Condition:: Breaking on an event.
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* Source Breakpoints:: Embedding breakpoints in source code.
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@end menu
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@node Breakpoints
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@subsubsection Edebug Breakpoints
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@cindex breakpoints (Edebug)
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While using Edebug, you can specify @dfn{breakpoints} in the program you
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are testing: these are places where execution should stop. You can set a
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breakpoint at any stop point, as defined in @ref{Using Edebug}. For
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setting and unsetting breakpoints, the stop point that is affected is
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the first one at or after point in the source code buffer. Here are the
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Edebug commands for breakpoints:
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@table @kbd
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@item b
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Set a breakpoint at the stop point at or after point
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(@code{edebug-set-breakpoint}). If you use a prefix argument, the
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breakpoint is temporary---it turns off the first time it stops the
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program.
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@item u
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Unset the breakpoint (if any) at the stop point at or after
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point (@code{edebug-unset-breakpoint}).
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@item x @var{condition} @key{RET}
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Set a conditional breakpoint which stops the program only if
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evaluating @var{condition} produces a non-@code{nil} value
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(@code{edebug-set-conditional-breakpoint}). With a prefix argument,
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the breakpoint is temporary.
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@item B
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Move point to the next breakpoint in the current definition
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(@code{edebug-next-breakpoint}).
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@end table
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While in Edebug, you can set a breakpoint with @kbd{b} and unset one
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with @kbd{u}. First move point to the Edebug stop point of your choice,
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then type @kbd{b} or @kbd{u} to set or unset a breakpoint there.
|
|
Unsetting a breakpoint where none has been set has no effect.
|
|
|
|
Re-evaluating or reinstrumenting a definition removes all of its
|
|
previous breakpoints.
|
|
|
|
A @dfn{conditional breakpoint} tests a condition each time the program
|
|
gets there. Any errors that occur as a result of evaluating the
|
|
condition are ignored, as if the result were @code{nil}. To set a
|
|
conditional breakpoint, use @kbd{x}, and specify the condition
|
|
expression in the minibuffer. Setting a conditional breakpoint at a
|
|
stop point that has a previously established conditional breakpoint puts
|
|
the previous condition expression in the minibuffer so you can edit it.
|
|
|
|
You can make a conditional or unconditional breakpoint
|
|
@dfn{temporary} by using a prefix argument with the command to set the
|
|
breakpoint. When a temporary breakpoint stops the program, it is
|
|
automatically unset.
|
|
|
|
Edebug always stops or pauses at a breakpoint, except when the Edebug
|
|
mode is Go-nonstop. In that mode, it ignores breakpoints entirely.
|
|
|
|
To find out where your breakpoints are, use the @kbd{B} command, which
|
|
moves point to the next breakpoint following point, within the same
|
|
function, or to the first breakpoint if there are no following
|
|
breakpoints. This command does not continue execution---it just moves
|
|
point in the buffer.
|
|
|
|
@node Global Break Condition
|
|
@subsubsection Global Break Condition
|
|
|
|
@cindex stopping on events
|
|
@cindex global break condition
|
|
A @dfn{global break condition} stops execution when a specified
|
|
condition is satisfied, no matter where that may occur. Edebug
|
|
evaluates the global break condition at every stop point; if it
|
|
evaluates to a non-@code{nil} value, then execution stops or pauses
|
|
depending on the execution mode, as if a breakpoint had been hit. If
|
|
evaluating the condition gets an error, execution does not stop.
|
|
|
|
@findex edebug-set-global-break-condition
|
|
The condition expression is stored in
|
|
@code{edebug-global-break-condition}. You can specify a new expression
|
|
using the @kbd{X} command from the source code buffer while Edebug is
|
|
active, or using @kbd{C-x X X} from any buffer at any time, as long as
|
|
Edebug is loaded (@code{edebug-set-global-break-condition}).
|
|
|
|
The global break condition is the simplest way to find where in your
|
|
code some event occurs, but it makes code run much more slowly. So you
|
|
should reset the condition to @code{nil} when not using it.
|
|
|
|
@node Source Breakpoints
|
|
@subsubsection Source Breakpoints
|
|
|
|
@findex edebug
|
|
@cindex source breakpoints
|
|
All breakpoints in a definition are forgotten each time you
|
|
reinstrument it. If you wish to make a breakpoint that won't be
|
|
forgotten, you can write a @dfn{source breakpoint}, which is simply a
|
|
call to the function @code{edebug} in your source code. You can, of
|
|
course, make such a call conditional. For example, in the @code{fac}
|
|
function, you can insert the first line as shown below, to stop when the
|
|
argument reaches zero:
|
|
|
|
@example
|
|
(defun fac (n)
|
|
(if (= n 0) (edebug))
|
|
(if (< 0 n)
|
|
(* n (fac (1- n)))
|
|
1))
|
|
@end example
|
|
|
|
When the @code{fac} definition is instrumented and the function is
|
|
called, the call to @code{edebug} acts as a breakpoint. Depending on
|
|
the execution mode, Edebug stops or pauses there.
|
|
|
|
If no instrumented code is being executed when @code{edebug} is called,
|
|
that function calls @code{debug}.
|
|
@c This may not be a good idea anymore.
|
|
|
|
@node Trapping Errors
|
|
@subsection Trapping Errors
|
|
|
|
Emacs normally displays an error message when an error is signaled and
|
|
not handled with @code{condition-case}. While Edebug is active and
|
|
executing instrumented code, it normally responds to all unhandled
|
|
errors. You can customize this with the options @code{edebug-on-error}
|
|
and @code{edebug-on-quit}; see @ref{Edebug Options}.
|
|
|
|
When Edebug responds to an error, it shows the last stop point
|
|
encountered before the error. This may be the location of a call to a
|
|
function which was not instrumented, and within which the error actually
|
|
occurred. For an unbound variable error, the last known stop point
|
|
might be quite distant from the offending variable reference. In that
|
|
case, you might want to display a full backtrace (@pxref{Edebug Misc}).
|
|
|
|
@c Edebug should be changed for the following: -- dan
|
|
If you change @code{debug-on-error} or @code{debug-on-quit} while
|
|
Edebug is active, these changes will be forgotten when Edebug becomes
|
|
inactive. Furthermore, during Edebug's recursive edit, these variables
|
|
are bound to the values they had outside of Edebug.
|
|
|
|
@node Edebug Views
|
|
@subsection Edebug Views
|
|
|
|
These Edebug commands let you view aspects of the buffer and window
|
|
status as they were before entry to Edebug. The outside window
|
|
configuration is the collection of windows and contents that were in
|
|
effect outside of Edebug.
|
|
|
|
@table @kbd
|
|
@item v
|
|
Switch to viewing the outside window configuration
|
|
(@code{edebug-view-outside}). Type @kbd{C-x X w} to return to Edebug.
|
|
|
|
@item p
|
|
Temporarily display the outside current buffer with point at its
|
|
outside position (@code{edebug-bounce-point}), pausing for one second
|
|
before returning to Edebug. With a prefix argument @var{n}, pause for
|
|
@var{n} seconds instead.
|
|
|
|
@item w
|
|
Move point back to the current stop point in the source code buffer
|
|
(@code{edebug-where}).
|
|
|
|
If you use this command in a different window displaying the same
|
|
buffer, that window will be used instead to display the current
|
|
definition in the future.
|
|
|
|
@item W
|
|
@c Its function is not simply to forget the saved configuration -- dan
|
|
Toggle whether Edebug saves and restores the outside window
|
|
configuration (@code{edebug-toggle-save-windows}).
|
|
|
|
With a prefix argument, @code{W} only toggles saving and restoring of
|
|
the selected window. To specify a window that is not displaying the
|
|
source code buffer, you must use @kbd{C-x X W} from the global keymap.
|
|
@end table
|
|
|
|
You can view the outside window configuration with @kbd{v} or just
|
|
bounce to the point in the current buffer with @kbd{p}, even if
|
|
it is not normally displayed.
|
|
|
|
After moving point, you may wish to jump back to the stop point.
|
|
You can do that with @kbd{w} from a source code buffer. You can jump
|
|
back to the stop point in the source code buffer from any buffer using
|
|
@kbd{C-x X w}.
|
|
|
|
Each time you use @kbd{W} to turn saving @emph{off}, Edebug forgets the
|
|
saved outside window configuration---so that even if you turn saving
|
|
back @emph{on}, the current window configuration remains unchanged when
|
|
you next exit Edebug (by continuing the program). However, the
|
|
automatic redisplay of @file{*edebug*} and @file{*edebug-trace*} may
|
|
conflict with the buffers you wish to see unless you have enough windows
|
|
open.
|
|
|
|
@node Edebug Eval
|
|
@subsection Evaluation
|
|
|
|
While within Edebug, you can evaluate expressions as if Edebug
|
|
were not running. Edebug tries to be invisible to the expression's
|
|
evaluation and printing. Evaluation of expressions that cause side
|
|
effects will work as expected, except for changes to data that Edebug
|
|
explicitly saves and restores. @xref{The Outside Context}, for details
|
|
on this process.
|
|
|
|
@table @kbd
|
|
@item e @var{exp} @key{RET}
|
|
Evaluate expression @var{exp} in the context outside of Edebug
|
|
(@code{edebug-eval-expression}). That is, Edebug tries to minimize its
|
|
interference with the evaluation.
|
|
|
|
@item M-: @var{exp} @key{RET}
|
|
Evaluate expression @var{exp} in the context of Edebug itself
|
|
(@code{eval-expression}).
|
|
|
|
@item C-x C-e
|
|
Evaluate the expression before point, in the context outside of Edebug
|
|
(@code{edebug-eval-last-sexp}).
|
|
@end table
|
|
|
|
@cindex lexical binding (Edebug)
|
|
Edebug supports evaluation of expressions containing references to
|
|
lexically bound symbols created by the following constructs in
|
|
@file{cl.el}: @code{lexical-let}, @code{macrolet}, and
|
|
@code{symbol-macrolet}.
|
|
@c FIXME? What about lexical-binding = t?
|
|
|
|
@node Eval List
|
|
@subsection Evaluation List Buffer
|
|
|
|
You can use the @dfn{evaluation list buffer}, called @file{*edebug*}, to
|
|
evaluate expressions interactively. You can also set up the
|
|
@dfn{evaluation list} of expressions to be evaluated automatically each
|
|
time Edebug updates the display.
|
|
|
|
@table @kbd
|
|
@item E
|
|
Switch to the evaluation list buffer @file{*edebug*}
|
|
(@code{edebug-visit-eval-list}).
|
|
@end table
|
|
|
|
In the @file{*edebug*} buffer you can use the commands of Lisp
|
|
Interaction mode (@pxref{Lisp Interaction,,, emacs, The GNU Emacs
|
|
Manual}) as well as these special commands:
|
|
|
|
@table @kbd
|
|
@item C-j
|
|
Evaluate the expression before point, in the outside context, and insert
|
|
the value in the buffer (@code{edebug-eval-print-last-sexp}).
|
|
|
|
@item C-x C-e
|
|
Evaluate the expression before point, in the context outside of Edebug
|
|
(@code{edebug-eval-last-sexp}).
|
|
|
|
@item C-c C-u
|
|
Build a new evaluation list from the contents of the buffer
|
|
(@code{edebug-update-eval-list}).
|
|
|
|
@item C-c C-d
|
|
Delete the evaluation list group that point is in
|
|
(@code{edebug-delete-eval-item}).
|
|
|
|
@item C-c C-w
|
|
Switch back to the source code buffer at the current stop point
|
|
(@code{edebug-where}).
|
|
@end table
|
|
|
|
You can evaluate expressions in the evaluation list window with
|
|
@kbd{C-j} or @kbd{C-x C-e}, just as you would in @file{*scratch*};
|
|
but they are evaluated in the context outside of Edebug.
|
|
|
|
The expressions you enter interactively (and their results) are lost
|
|
when you continue execution; but you can set up an @dfn{evaluation list}
|
|
consisting of expressions to be evaluated each time execution stops.
|
|
|
|
@cindex evaluation list group
|
|
To do this, write one or more @dfn{evaluation list groups} in the
|
|
evaluation list buffer. An evaluation list group consists of one or
|
|
more Lisp expressions. Groups are separated by comment lines.
|
|
|
|
The command @kbd{C-c C-u} (@code{edebug-update-eval-list}) rebuilds the
|
|
evaluation list, scanning the buffer and using the first expression of
|
|
each group. (The idea is that the second expression of the group is the
|
|
value previously computed and displayed.)
|
|
|
|
Each entry to Edebug redisplays the evaluation list by inserting each
|
|
expression in the buffer, followed by its current value. It also
|
|
inserts comment lines so that each expression becomes its own group.
|
|
Thus, if you type @kbd{C-c C-u} again without changing the buffer text,
|
|
the evaluation list is effectively unchanged.
|
|
|
|
If an error occurs during an evaluation from the evaluation list,
|
|
the error message is displayed in a string as if it were the result.
|
|
Therefore, expressions using variables that are not currently valid do
|
|
not interrupt your debugging.
|
|
|
|
Here is an example of what the evaluation list window looks like after
|
|
several expressions have been added to it:
|
|
|
|
@smallexample
|
|
(current-buffer)
|
|
#<buffer *scratch*>
|
|
;---------------------------------------------------------------
|
|
(selected-window)
|
|
#<window 16 on *scratch*>
|
|
;---------------------------------------------------------------
|
|
(point)
|
|
196
|
|
;---------------------------------------------------------------
|
|
bad-var
|
|
"Symbol's value as variable is void: bad-var"
|
|
;---------------------------------------------------------------
|
|
(recursion-depth)
|
|
0
|
|
;---------------------------------------------------------------
|
|
this-command
|
|
eval-last-sexp
|
|
;---------------------------------------------------------------
|
|
@end smallexample
|
|
|
|
To delete a group, move point into it and type @kbd{C-c C-d}, or simply
|
|
delete the text for the group and update the evaluation list with
|
|
@kbd{C-c C-u}. To add a new expression to the evaluation list, insert
|
|
the expression at a suitable place, insert a new comment line, then type
|
|
@kbd{C-c C-u}. You need not insert dashes in the comment line---its
|
|
contents don't matter.
|
|
|
|
After selecting @file{*edebug*}, you can return to the source code
|
|
buffer with @kbd{C-c C-w}. The @file{*edebug*} buffer is killed when
|
|
you continue execution, and recreated next time it is needed.
|
|
|
|
@node Printing in Edebug
|
|
@subsection Printing in Edebug
|
|
|
|
@cindex printing (Edebug)
|
|
@cindex printing circular structures
|
|
@pindex cust-print
|
|
If an expression in your program produces a value containing circular
|
|
list structure, you may get an error when Edebug attempts to print it.
|
|
|
|
One way to cope with circular structure is to set @code{print-length}
|
|
or @code{print-level} to truncate the printing. Edebug does this for
|
|
you; it binds @code{print-length} and @code{print-level} to the values
|
|
of the variables @code{edebug-print-length} and
|
|
@code{edebug-print-level} (so long as they have non-@code{nil}
|
|
values). @xref{Output Variables}.
|
|
|
|
@defopt edebug-print-length
|
|
If non-@code{nil}, Edebug binds @code{print-length} to this value while
|
|
printing results. The default value is @code{50}.
|
|
@end defopt
|
|
|
|
@defopt edebug-print-level
|
|
If non-@code{nil}, Edebug binds @code{print-level} to this value while
|
|
printing results. The default value is @code{50}.
|
|
@end defopt
|
|
|
|
You can also print circular structures and structures that share
|
|
elements more informatively by binding @code{print-circle}
|
|
to a non-@code{nil} value.
|
|
|
|
Here is an example of code that creates a circular structure:
|
|
|
|
@example
|
|
(setq a '(x y))
|
|
(setcar a a)
|
|
@end example
|
|
|
|
@noindent
|
|
Custom printing prints this as @samp{Result: #1=(#1# y)}. The
|
|
@samp{#1=} notation labels the structure that follows it with the label
|
|
@samp{1}, and the @samp{#1#} notation references the previously labeled
|
|
structure. This notation is used for any shared elements of lists or
|
|
vectors.
|
|
|
|
@defopt edebug-print-circle
|
|
If non-@code{nil}, Edebug binds @code{print-circle} to this value while
|
|
printing results. The default value is @code{t}.
|
|
@end defopt
|
|
|
|
Other programs can also use custom printing; see @file{cust-print.el}
|
|
for details.
|
|
|
|
@node Trace Buffer
|
|
@subsection Trace Buffer
|
|
@cindex trace buffer
|
|
|
|
Edebug can record an execution trace, storing it in a buffer named
|
|
@file{*edebug-trace*}. This is a log of function calls and returns,
|
|
showing the function names and their arguments and values. To enable
|
|
trace recording, set @code{edebug-trace} to a non-@code{nil} value.
|
|
|
|
Making a trace buffer is not the same thing as using trace execution
|
|
mode (@pxref{Edebug Execution Modes}).
|
|
|
|
When trace recording is enabled, each function entry and exit adds
|
|
lines to the trace buffer. A function entry record consists of
|
|
@samp{::::@{}, followed by the function name and argument values. A
|
|
function exit record consists of @samp{::::@}}, followed by the function
|
|
name and result of the function.
|
|
|
|
The number of @samp{:}s in an entry shows its recursion depth. You
|
|
can use the braces in the trace buffer to find the matching beginning or
|
|
end of function calls.
|
|
|
|
@findex edebug-print-trace-before
|
|
@findex edebug-print-trace-after
|
|
You can customize trace recording for function entry and exit by
|
|
redefining the functions @code{edebug-print-trace-before} and
|
|
@code{edebug-print-trace-after}.
|
|
|
|
@defmac edebug-tracing string body@dots{}
|
|
This macro requests additional trace information around the execution
|
|
of the @var{body} forms. The argument @var{string} specifies text
|
|
to put in the trace buffer, after the @samp{@{} or @samp{@}}. All
|
|
the arguments are evaluated, and @code{edebug-tracing} returns the
|
|
value of the last form in @var{body}.
|
|
@end defmac
|
|
|
|
@defun edebug-trace format-string &rest format-args
|
|
This function inserts text in the trace buffer. It computes the text
|
|
with @code{(apply 'format @var{format-string} @var{format-args})}.
|
|
It also appends a newline to separate entries.
|
|
@end defun
|
|
|
|
@code{edebug-tracing} and @code{edebug-trace} insert lines in the
|
|
trace buffer whenever they are called, even if Edebug is not active.
|
|
Adding text to the trace buffer also scrolls its window to show the last
|
|
lines inserted.
|
|
|
|
@node Coverage Testing
|
|
@subsection Coverage Testing
|
|
|
|
@cindex coverage testing (Edebug)
|
|
@cindex frequency counts
|
|
@cindex performance analysis
|
|
Edebug provides rudimentary coverage testing and display of execution
|
|
frequency.
|
|
|
|
Coverage testing works by comparing the result of each expression with
|
|
the previous result; each form in the program is considered ``covered''
|
|
if it has returned two different values since you began testing coverage
|
|
in the current Emacs session. Thus, to do coverage testing on your
|
|
program, execute it under various conditions and note whether it behaves
|
|
correctly; Edebug will tell you when you have tried enough different
|
|
conditions that each form has returned two different values.
|
|
|
|
Coverage testing makes execution slower, so it is only done if
|
|
@code{edebug-test-coverage} is non-@code{nil}. Frequency counting is
|
|
performed for all executions of an instrumented function, even if the
|
|
execution mode is Go-nonstop, and regardless of whether coverage testing
|
|
is enabled.
|
|
|
|
@kindex C-x X =
|
|
@findex edebug-temp-display-freq-count
|
|
Use @kbd{C-x X =} (@code{edebug-display-freq-count}) to display both
|
|
the coverage information and the frequency counts for a definition.
|
|
Just @kbd{=} (@code{edebug-temp-display-freq-count}) displays the same
|
|
information temporarily, only until you type another key.
|
|
|
|
@deffn Command edebug-display-freq-count
|
|
This command displays the frequency count data for each line of the
|
|
current definition.
|
|
|
|
It inserts frequency counts as comment lines after each line of code.
|
|
You can undo all insertions with one @code{undo} command. The counts
|
|
appear under the @samp{(} before an expression or the @samp{)} after
|
|
an expression, or on the last character of a variable. To simplify
|
|
the display, a count is not shown if it is equal to the count of an
|
|
earlier expression on the same line.
|
|
|
|
The character @samp{=} following the count for an expression says that
|
|
the expression has returned the same value each time it was evaluated.
|
|
In other words, it is not yet ``covered'' for coverage testing purposes.
|
|
|
|
To clear the frequency count and coverage data for a definition,
|
|
simply reinstrument it with @code{eval-defun}.
|
|
@end deffn
|
|
|
|
For example, after evaluating @code{(fac 5)} with a source
|
|
breakpoint, and setting @code{edebug-test-coverage} to @code{t}, when
|
|
the breakpoint is reached, the frequency data looks like this:
|
|
|
|
@example
|
|
(defun fac (n)
|
|
(if (= n 0) (edebug))
|
|
;#6 1 = =5
|
|
(if (< 0 n)
|
|
;#5 =
|
|
(* n (fac (1- n)))
|
|
;# 5 0
|
|
1))
|
|
;# 0
|
|
@end example
|
|
|
|
The comment lines show that @code{fac} was called 6 times. The
|
|
first @code{if} statement returned 5 times with the same result each
|
|
time; the same is true of the condition on the second @code{if}.
|
|
The recursive call of @code{fac} did not return at all.
|
|
|
|
|
|
@node The Outside Context
|
|
@subsection The Outside Context
|
|
|
|
Edebug tries to be transparent to the program you are debugging, but it
|
|
does not succeed completely. Edebug also tries to be transparent when
|
|
you evaluate expressions with @kbd{e} or with the evaluation list
|
|
buffer, by temporarily restoring the outside context. This section
|
|
explains precisely what context Edebug restores, and how Edebug fails to
|
|
be completely transparent.
|
|
|
|
@menu
|
|
* Checking Whether to Stop:: When Edebug decides what to do.
|
|
* Edebug Display Update:: When Edebug updates the display.
|
|
* Edebug Recursive Edit:: When Edebug stops execution.
|
|
@end menu
|
|
|
|
@node Checking Whether to Stop
|
|
@subsubsection Checking Whether to Stop
|
|
|
|
Whenever Edebug is entered, it needs to save and restore certain data
|
|
before even deciding whether to make trace information or stop the
|
|
program.
|
|
|
|
@itemize @bullet
|
|
@item
|
|
@code{max-lisp-eval-depth} and @code{max-specpdl-size} are both
|
|
increased to reduce Edebug's impact on the stack. You could, however,
|
|
still run out of stack space when using Edebug.
|
|
|
|
@item
|
|
The state of keyboard macro execution is saved and restored. While
|
|
Edebug is active, @code{executing-kbd-macro} is bound to @code{nil}
|
|
unless @code{edebug-continue-kbd-macro} is non-@code{nil}.
|
|
@end itemize
|
|
|
|
|
|
@node Edebug Display Update
|
|
@subsubsection Edebug Display Update
|
|
|
|
@c This paragraph is not filled, because LaLiberte's conversion script
|
|
@c needs an xref to be on just one line.
|
|
When Edebug needs to display something (e.g., in trace mode), it saves
|
|
the current window configuration from ``outside'' Edebug
|
|
(@pxref{Window Configurations}). When you exit Edebug (by continuing
|
|
the program), it restores the previous window configuration.
|
|
|
|
Emacs redisplays only when it pauses. Usually, when you continue
|
|
execution, the program re-enters Edebug at a breakpoint or after
|
|
stepping, without pausing or reading input in between. In such cases,
|
|
Emacs never gets a chance to redisplay the ``outside'' configuration.
|
|
Consequently, what you see is the same window configuration as the last
|
|
time Edebug was active, with no interruption.
|
|
|
|
Entry to Edebug for displaying something also saves and restores the
|
|
following data (though some of them are deliberately not restored if an
|
|
error or quit signal occurs).
|
|
|
|
@itemize @bullet
|
|
@item
|
|
@cindex current buffer point and mark (Edebug)
|
|
Which buffer is current, and the positions of point and the mark in the
|
|
current buffer, are saved and restored.
|
|
|
|
@item
|
|
@cindex window configuration (Edebug)
|
|
The outside window configuration is saved and restored if
|
|
@code{edebug-save-windows} is non-@code{nil} (@pxref{Edebug Options}).
|
|
|
|
The window configuration is not restored on error or quit, but the
|
|
outside selected window @emph{is} reselected even on error or quit in
|
|
case a @code{save-excursion} is active. If the value of
|
|
@code{edebug-save-windows} is a list, only the listed windows are saved
|
|
and restored.
|
|
|
|
The window start and horizontal scrolling of the source code buffer are
|
|
not restored, however, so that the display remains coherent within Edebug.
|
|
|
|
@item
|
|
The value of point in each displayed buffer is saved and restored if
|
|
@code{edebug-save-displayed-buffer-points} is non-@code{nil}.
|
|
|
|
@item
|
|
The variables @code{overlay-arrow-position} and
|
|
@code{overlay-arrow-string} are saved and restored, so you can safely
|
|
invoke Edebug from the recursive edit elsewhere in the same buffer.
|
|
|
|
@item
|
|
@code{cursor-in-echo-area} is locally bound to @code{nil} so that
|
|
the cursor shows up in the window.
|
|
@end itemize
|
|
|
|
@node Edebug Recursive Edit
|
|
@subsubsection Edebug Recursive Edit
|
|
|
|
When Edebug is entered and actually reads commands from the user, it
|
|
saves (and later restores) these additional data:
|
|
|
|
@itemize @bullet
|
|
@item
|
|
The current match data. @xref{Match Data}.
|
|
|
|
@item
|
|
The variables @code{last-command}, @code{this-command},
|
|
@code{last-input-event}, @code{last-command-event},
|
|
@code{last-event-frame}, @code{last-nonmenu-event}, and
|
|
@code{track-mouse}. Commands used within Edebug do not affect these
|
|
variables outside of Edebug.
|
|
|
|
Executing commands within Edebug can change the key sequence that
|
|
would be returned by @code{this-command-keys}, and there is no way to
|
|
reset the key sequence from Lisp.
|
|
|
|
Edebug cannot save and restore the value of
|
|
@code{unread-command-events}. Entering Edebug while this variable has a
|
|
nontrivial value can interfere with execution of the program you are
|
|
debugging.
|
|
|
|
@item
|
|
Complex commands executed while in Edebug are added to the variable
|
|
@code{command-history}. In rare cases this can alter execution.
|
|
|
|
@item
|
|
Within Edebug, the recursion depth appears one deeper than the recursion
|
|
depth outside Edebug. This is not true of the automatically updated
|
|
evaluation list window.
|
|
|
|
@item
|
|
@code{standard-output} and @code{standard-input} are bound to @code{nil}
|
|
by the @code{recursive-edit}, but Edebug temporarily restores them during
|
|
evaluations.
|
|
|
|
@item
|
|
The state of keyboard macro definition is saved and restored. While
|
|
Edebug is active, @code{defining-kbd-macro} is bound to
|
|
@code{edebug-continue-kbd-macro}.
|
|
@end itemize
|
|
|
|
@node Edebug and Macros
|
|
@subsection Edebug and Macros
|
|
|
|
To make Edebug properly instrument expressions that call macros, some
|
|
extra care is needed. This subsection explains the details.
|
|
|
|
@menu
|
|
* Instrumenting Macro Calls:: The basic problem.
|
|
* Specification List:: How to specify complex patterns of evaluation.
|
|
* Backtracking:: What Edebug does when matching fails.
|
|
* Specification Examples:: To help understand specifications.
|
|
@end menu
|
|
|
|
@node Instrumenting Macro Calls
|
|
@subsubsection Instrumenting Macro Calls
|
|
|
|
When Edebug instruments an expression that calls a Lisp macro, it needs
|
|
additional information about the macro to do the job properly. This is
|
|
because there is no a-priori way to tell which subexpressions of the
|
|
macro call are forms to be evaluated. (Evaluation may occur explicitly
|
|
in the macro body, or when the resulting expansion is evaluated, or any
|
|
time later.)
|
|
|
|
Therefore, you must define an Edebug specification for each macro
|
|
that Edebug will encounter, to explain the format of calls to that
|
|
macro. To do this, add a @code{debug} declaration to the macro
|
|
definition. Here is a simple example that shows the specification for
|
|
the @code{for} example macro (@pxref{Argument Evaluation}).
|
|
|
|
@smallexample
|
|
(defmacro for (var from init to final do &rest body)
|
|
"Execute a simple \"for\" loop.
|
|
For example, (for i from 1 to 10 do (print i))."
|
|
(declare (debug (symbolp "from" form "to" form "do" &rest form)))
|
|
...)
|
|
@end smallexample
|
|
|
|
The Edebug specification says which parts of a call to the macro are
|
|
forms to be evaluated. For simple macros, the specification
|
|
often looks very similar to the formal argument list of the macro
|
|
definition, but specifications are much more general than macro
|
|
arguments. @xref{Defining Macros}, for more explanation of
|
|
the @code{declare} form.
|
|
|
|
@c See eg http://debbugs.gnu.org/10577
|
|
@c FIXME Maybe there should be an Edebug option to get it to
|
|
@c automatically load the entire source file containing the function
|
|
@c being instrumented. That would avoid this.
|
|
Take care to ensure that the specifications are known to Edebug when
|
|
you instrument code. If you are instrumenting a function from a file
|
|
that uses @code{eval-when-compile} to require another file containing
|
|
macro definitions, you may need to explicitly load that file.
|
|
|
|
You can also define an edebug specification for a macro separately
|
|
from the macro definition with @code{def-edebug-spec}. Adding
|
|
@code{debug} declarations is preferred, and more convenient, for macro
|
|
definitions in Lisp, but @code{def-edebug-spec} makes it possible to
|
|
define Edebug specifications for special forms implemented in C.
|
|
|
|
@deffn Macro def-edebug-spec macro specification
|
|
Specify which expressions of a call to macro @var{macro} are forms to be
|
|
evaluated. @var{specification} should be the edebug specification.
|
|
Neither argument is evaluated.
|
|
|
|
The @var{macro} argument can actually be any symbol, not just a macro
|
|
name.
|
|
@end deffn
|
|
|
|
Here is a table of the possibilities for @var{specification} and how each
|
|
directs processing of arguments.
|
|
|
|
@table @asis
|
|
@item @code{t}
|
|
All arguments are instrumented for evaluation.
|
|
|
|
@item @code{0}
|
|
None of the arguments is instrumented.
|
|
|
|
@item a symbol
|
|
The symbol must have an Edebug specification, which is used instead.
|
|
This indirection is repeated until another kind of specification is
|
|
found. This allows you to inherit the specification from another macro.
|
|
|
|
@item a list
|
|
The elements of the list describe the types of the arguments of a
|
|
calling form. The possible elements of a specification list are
|
|
described in the following sections.
|
|
@end table
|
|
|
|
If a macro has no Edebug specification, neither through a @code{debug}
|
|
declaration nor through a @code{def-edebug-spec} call, the variable
|
|
@code{edebug-eval-macro-args} comes into play.
|
|
|
|
@defopt edebug-eval-macro-args
|
|
This controls the way Edebug treats macro arguments with no explicit
|
|
Edebug specification. If it is @code{nil} (the default), none of the
|
|
arguments is instrumented for evaluation. Otherwise, all arguments
|
|
are instrumented.
|
|
@end defopt
|
|
|
|
@node Specification List
|
|
@subsubsection Specification List
|
|
|
|
@cindex Edebug specification list
|
|
A @dfn{specification list} is required for an Edebug specification if
|
|
some arguments of a macro call are evaluated while others are not. Some
|
|
elements in a specification list match one or more arguments, but others
|
|
modify the processing of all following elements. The latter, called
|
|
@dfn{specification keywords}, are symbols beginning with @samp{&} (such
|
|
as @code{&optional}).
|
|
|
|
A specification list may contain sublists, which match arguments that are
|
|
themselves lists, or it may contain vectors used for grouping. Sublists
|
|
and groups thus subdivide the specification list into a hierarchy of
|
|
levels. Specification keywords apply only to the remainder of the
|
|
sublist or group they are contained in.
|
|
|
|
When a specification list involves alternatives or repetition, matching
|
|
it against an actual macro call may require backtracking. For more
|
|
details, @pxref{Backtracking}.
|
|
|
|
Edebug specifications provide the power of regular expression matching,
|
|
plus some context-free grammar constructs: the matching of sublists with
|
|
balanced parentheses, recursive processing of forms, and recursion via
|
|
indirect specifications.
|
|
|
|
Here's a table of the possible elements of a specification list, with
|
|
their meanings (see @ref{Specification Examples}, for the referenced
|
|
examples):
|
|
|
|
@table @code
|
|
@item sexp
|
|
A single unevaluated Lisp object, which is not instrumented.
|
|
@c an "expression" is not necessarily intended for evaluation.
|
|
|
|
@item form
|
|
A single evaluated expression, which is instrumented.
|
|
|
|
@item place
|
|
@c I can't see that this index entry is useful without any explanation.
|
|
@c @findex edebug-unwrap
|
|
A place to store a value, as in the Common Lisp @code{setf} construct.
|
|
|
|
@item body
|
|
Short for @code{&rest form}. See @code{&rest} below.
|
|
|
|
@item function-form
|
|
A function form: either a quoted function symbol, a quoted lambda
|
|
expression, or a form (that should evaluate to a function symbol or
|
|
lambda expression). This is useful when an argument that's a lambda
|
|
expression might be quoted with @code{quote} rather than
|
|
@code{function}, since it instruments the body of the lambda expression
|
|
either way.
|
|
|
|
@item lambda-expr
|
|
A lambda expression with no quoting.
|
|
|
|
@item &optional
|
|
@c @kindex &optional @r{(Edebug)}
|
|
All following elements in the specification list are optional; as soon
|
|
as one does not match, Edebug stops matching at this level.
|
|
|
|
To make just a few elements optional, followed by non-optional elements,
|
|
use @code{[&optional @var{specs}@dots{}]}. To specify that several
|
|
elements must all match or none, use @code{&optional
|
|
[@var{specs}@dots{}]}. See the @code{defun} example.
|
|
|
|
@item &rest
|
|
@c @kindex &rest @r{(Edebug)}
|
|
All following elements in the specification list are repeated zero or
|
|
more times. In the last repetition, however, it is not a problem if the
|
|
expression runs out before matching all of the elements of the
|
|
specification list.
|
|
|
|
To repeat only a few elements, use @code{[&rest @var{specs}@dots{}]}.
|
|
To specify several elements that must all match on every repetition, use
|
|
@code{&rest [@var{specs}@dots{}]}.
|
|
|
|
@item &or
|
|
@c @kindex &or @r{(Edebug)}
|
|
Each of the following elements in the specification list is an
|
|
alternative. One of the alternatives must match, or the @code{&or}
|
|
specification fails.
|
|
|
|
Each list element following @code{&or} is a single alternative. To
|
|
group two or more list elements as a single alternative, enclose them in
|
|
@code{[@dots{}]}.
|
|
|
|
@item ¬
|
|
@c @kindex ¬ @r{(Edebug)}
|
|
Each of the following elements is matched as alternatives as if by using
|
|
@code{&or}, but if any of them match, the specification fails. If none
|
|
of them match, nothing is matched, but the @code{¬} specification
|
|
succeeds.
|
|
|
|
@c FIXME &key?
|
|
|
|
@item &define
|
|
@c @kindex &define @r{(Edebug)}
|
|
Indicates that the specification is for a defining form. The defining
|
|
form itself is not instrumented (that is, Edebug does not stop before and
|
|
after the defining form), but forms inside it typically will be
|
|
instrumented. The @code{&define} keyword should be the first element in
|
|
a list specification.
|
|
|
|
@item nil
|
|
This is successful when there are no more arguments to match at the
|
|
current argument list level; otherwise it fails. See sublist
|
|
specifications and the backquote example.
|
|
|
|
@item gate
|
|
@cindex preventing backtracking
|
|
No argument is matched but backtracking through the gate is disabled
|
|
while matching the remainder of the specifications at this level. This
|
|
is primarily used to generate more specific syntax error messages. See
|
|
@ref{Backtracking}, for more details. Also see the @code{let} example.
|
|
|
|
@item @var{other-symbol}
|
|
@cindex indirect specifications
|
|
Any other symbol in a specification list may be a predicate or an
|
|
indirect specification.
|
|
|
|
If the symbol has an Edebug specification, this @dfn{indirect
|
|
specification} should be either a list specification that is used in
|
|
place of the symbol, or a function that is called to process the
|
|
arguments. The specification may be defined with @code{def-edebug-spec}
|
|
just as for macros. See the @code{defun} example.
|
|
|
|
Otherwise, the symbol should be a predicate. The predicate is called
|
|
with the argument, and if the predicate returns @code{nil}, the
|
|
specification fails and the argument is not instrumented.
|
|
|
|
Some suitable predicates include @code{symbolp}, @code{integerp},
|
|
@code{stringp}, @code{vectorp}, and @code{atom}.
|
|
|
|
@item [@var{elements}@dots{}]
|
|
@cindex [@dots{}] (Edebug)
|
|
A vector of elements groups the elements into a single @dfn{group
|
|
specification}. Its meaning has nothing to do with vectors.
|
|
|
|
@item "@var{string}"
|
|
The argument should be a symbol named @var{string}. This specification
|
|
is equivalent to the quoted symbol, @code{'@var{symbol}}, where the name
|
|
of @var{symbol} is the @var{string}, but the string form is preferred.
|
|
|
|
@item (vector @var{elements}@dots{})
|
|
The argument should be a vector whose elements must match the
|
|
@var{elements} in the specification. See the backquote example.
|
|
|
|
@item (@var{elements}@dots{})
|
|
Any other list is a @dfn{sublist specification} and the argument must be
|
|
a list whose elements match the specification @var{elements}.
|
|
|
|
@cindex dotted lists (Edebug)
|
|
A sublist specification may be a dotted list and the corresponding list
|
|
argument may then be a dotted list. Alternatively, the last @sc{cdr} of a
|
|
dotted list specification may be another sublist specification (via a
|
|
grouping or an indirect specification, e.g., @code{(spec . [(more
|
|
specs@dots{})])}) whose elements match the non-dotted list arguments.
|
|
This is useful in recursive specifications such as in the backquote
|
|
example. Also see the description of a @code{nil} specification
|
|
above for terminating such recursion.
|
|
|
|
Note that a sublist specification written as @code{(specs . nil)}
|
|
is equivalent to @code{(specs)}, and @code{(specs .
|
|
(sublist-elements@dots{}))} is equivalent to @code{(specs
|
|
sublist-elements@dots{})}.
|
|
@end table
|
|
|
|
@c Need to document extensions with &symbol and :symbol
|
|
|
|
Here is a list of additional specifications that may appear only after
|
|
@code{&define}. See the @code{defun} example.
|
|
|
|
@table @code
|
|
@item name
|
|
The argument, a symbol, is the name of the defining form.
|
|
|
|
A defining form is not required to have a name field; and it may have
|
|
multiple name fields.
|
|
|
|
@item :name
|
|
This construct does not actually match an argument. The element
|
|
following @code{:name} should be a symbol; it is used as an additional
|
|
name component for the definition. You can use this to add a unique,
|
|
static component to the name of the definition. It may be used more
|
|
than once.
|
|
|
|
@item arg
|
|
The argument, a symbol, is the name of an argument of the defining form.
|
|
However, lambda-list keywords (symbols starting with @samp{&})
|
|
are not allowed.
|
|
|
|
@item lambda-list
|
|
@cindex lambda-list (Edebug)
|
|
This matches a lambda list---the argument list of a lambda expression.
|
|
|
|
@item def-body
|
|
The argument is the body of code in a definition. This is like
|
|
@code{body}, described above, but a definition body must be instrumented
|
|
with a different Edebug call that looks up information associated with
|
|
the definition. Use @code{def-body} for the highest level list of forms
|
|
within the definition.
|
|
|
|
@item def-form
|
|
The argument is a single, highest-level form in a definition. This is
|
|
like @code{def-body}, except it is used to match a single form rather than
|
|
a list of forms. As a special case, @code{def-form} also means that
|
|
tracing information is not output when the form is executed. See the
|
|
@code{interactive} example.
|
|
@end table
|
|
|
|
@node Backtracking
|
|
@subsubsection Backtracking in Specifications
|
|
|
|
@cindex backtracking
|
|
@cindex syntax error (Edebug)
|
|
If a specification fails to match at some point, this does not
|
|
necessarily mean a syntax error will be signaled; instead,
|
|
@dfn{backtracking} will take place until all alternatives have been
|
|
exhausted. Eventually every element of the argument list must be
|
|
matched by some element in the specification, and every required element
|
|
in the specification must match some argument.
|
|
|
|
When a syntax error is detected, it might not be reported until much
|
|
later, after higher-level alternatives have been exhausted, and with the
|
|
point positioned further from the real error. But if backtracking is
|
|
disabled when an error occurs, it can be reported immediately. Note
|
|
that backtracking is also reenabled automatically in several situations;
|
|
when a new alternative is established by @code{&optional},
|
|
@code{&rest}, or @code{&or}, or at the start of processing a sublist,
|
|
group, or indirect specification. The effect of enabling or disabling
|
|
backtracking is limited to the remainder of the level currently being
|
|
processed and lower levels.
|
|
|
|
Backtracking is disabled while matching any of the
|
|
form specifications (that is, @code{form}, @code{body}, @code{def-form}, and
|
|
@code{def-body}). These specifications will match any form so any error
|
|
must be in the form itself rather than at a higher level.
|
|
|
|
Backtracking is also disabled after successfully matching a quoted
|
|
symbol or string specification, since this usually indicates a
|
|
recognized construct. But if you have a set of alternative constructs that
|
|
all begin with the same symbol, you can usually work around this
|
|
constraint by factoring the symbol out of the alternatives, e.g.,
|
|
@code{["foo" &or [first case] [second case] ...]}.
|
|
|
|
Most needs are satisfied by these two ways that backtracking is
|
|
automatically disabled, but occasionally it is useful to explicitly
|
|
disable backtracking by using the @code{gate} specification. This is
|
|
useful when you know that no higher alternatives could apply. See the
|
|
example of the @code{let} specification.
|
|
|
|
@node Specification Examples
|
|
@subsubsection Specification Examples
|
|
|
|
It may be easier to understand Edebug specifications by studying
|
|
the examples provided here.
|
|
|
|
A @code{let} special form has a sequence of bindings and a body. Each
|
|
of the bindings is either a symbol or a sublist with a symbol and
|
|
optional expression. In the specification below, notice the @code{gate}
|
|
inside of the sublist to prevent backtracking once a sublist is found.
|
|
|
|
@ignore
|
|
@c FIXME? The actual definition in edebug.el looks like this (and always
|
|
@c has AFAICS). In fact, nothing in edebug.el uses gate. So maybe
|
|
@c this is just an example for illustration?
|
|
(def-edebug-spec let
|
|
((&rest
|
|
&or (symbolp &optional form) symbolp)
|
|
body))
|
|
@end ignore
|
|
@example
|
|
(def-edebug-spec let
|
|
((&rest
|
|
&or symbolp (gate symbolp &optional form))
|
|
body))
|
|
@end example
|
|
|
|
Edebug uses the following specifications for @code{defun} and the
|
|
associated argument list and @code{interactive} specifications. It is
|
|
necessary to handle interactive forms specially since an expression
|
|
argument is actually evaluated outside of the function body. (The
|
|
specification for @code{defmacro} is very similar to that for
|
|
@code{defun}, but allows for the @code{declare} statement.)
|
|
|
|
@smallexample
|
|
(def-edebug-spec defun
|
|
(&define name lambda-list
|
|
[&optional stringp] ; @r{Match the doc string, if present.}
|
|
[&optional ("interactive" interactive)]
|
|
def-body))
|
|
|
|
(def-edebug-spec lambda-list
|
|
(([&rest arg]
|
|
[&optional ["&optional" arg &rest arg]]
|
|
&optional ["&rest" arg]
|
|
)))
|
|
|
|
(def-edebug-spec interactive
|
|
(&optional &or stringp def-form)) ; @r{Notice: @code{def-form}}
|
|
@end smallexample
|
|
|
|
The specification for backquote below illustrates how to match
|
|
dotted lists and use @code{nil} to terminate recursion. It also
|
|
illustrates how components of a vector may be matched. (The actual
|
|
specification defined by Edebug is a little different, and does not
|
|
support dotted lists because doing so causes very deep recursion that
|
|
could fail.)
|
|
|
|
@smallexample
|
|
(def-edebug-spec \` (backquote-form)) ; @r{Alias just for clarity.}
|
|
|
|
(def-edebug-spec backquote-form
|
|
(&or ([&or "," ",@@"] &or ("quote" backquote-form) form)
|
|
(backquote-form . [&or nil backquote-form])
|
|
(vector &rest backquote-form)
|
|
sexp))
|
|
@end smallexample
|
|
|
|
|
|
@node Edebug Options
|
|
@subsection Edebug Options
|
|
|
|
These options affect the behavior of Edebug:
|
|
@c Previously defopt'd:
|
|
@c edebug-sit-for-seconds, edebug-print-length, edebug-print-level
|
|
@c edebug-print-circle, edebug-eval-macro-args
|
|
|
|
@defopt edebug-setup-hook
|
|
Functions to call before Edebug is used. Each time it is set to a new
|
|
value, Edebug will call those functions once and then
|
|
reset @code{edebug-setup-hook} to @code{nil}. You could use this to
|
|
load up Edebug specifications associated with a package you are using,
|
|
but only when you also use Edebug.
|
|
@xref{Instrumenting}.
|
|
@end defopt
|
|
|
|
@defopt edebug-all-defs
|
|
If this is non-@code{nil}, normal evaluation of defining forms such as
|
|
@code{defun} and @code{defmacro} instruments them for Edebug. This
|
|
applies to @code{eval-defun}, @code{eval-region}, @code{eval-buffer},
|
|
and @code{eval-current-buffer}.
|
|
|
|
Use the command @kbd{M-x edebug-all-defs} to toggle the value of this
|
|
option. @xref{Instrumenting}.
|
|
@end defopt
|
|
|
|
@defopt edebug-all-forms
|
|
If this is non-@code{nil}, the commands @code{eval-defun},
|
|
@code{eval-region}, @code{eval-buffer}, and @code{eval-current-buffer}
|
|
instrument all forms, even those that don't define anything.
|
|
This doesn't apply to loading or evaluations in the minibuffer.
|
|
|
|
Use the command @kbd{M-x edebug-all-forms} to toggle the value of this
|
|
option. @xref{Instrumenting}.
|
|
@end defopt
|
|
|
|
@defopt edebug-save-windows
|
|
If this is non-@code{nil}, Edebug saves and restores the window
|
|
configuration. That takes some time, so if your program does not care
|
|
what happens to the window configurations, it is better to set this
|
|
variable to @code{nil}.
|
|
|
|
If the value is a list, only the listed windows are saved and
|
|
restored.
|
|
|
|
You can use the @kbd{W} command in Edebug to change this variable
|
|
interactively. @xref{Edebug Display Update}.
|
|
@end defopt
|
|
|
|
@defopt edebug-save-displayed-buffer-points
|
|
If this is non-@code{nil}, Edebug saves and restores point in all
|
|
displayed buffers.
|
|
|
|
Saving and restoring point in other buffers is necessary if you are
|
|
debugging code that changes the point of a buffer that is displayed in
|
|
a non-selected window. If Edebug or the user then selects the window,
|
|
point in that buffer will move to the window's value of point.
|
|
|
|
Saving and restoring point in all buffers is expensive, since it
|
|
requires selecting each window twice, so enable this only if you need
|
|
it. @xref{Edebug Display Update}.
|
|
@end defopt
|
|
|
|
@defopt edebug-initial-mode
|
|
If this variable is non-@code{nil}, it specifies the initial execution
|
|
mode for Edebug when it is first activated. Possible values are
|
|
@code{step}, @code{next}, @code{go}, @code{Go-nonstop}, @code{trace},
|
|
@code{Trace-fast}, @code{continue}, and @code{Continue-fast}.
|
|
|
|
The default value is @code{step}.
|
|
@xref{Edebug Execution Modes}.
|
|
@end defopt
|
|
|
|
@defopt edebug-trace
|
|
If this is non-@code{nil}, trace each function entry and exit.
|
|
Tracing output is displayed in a buffer named @file{*edebug-trace*}, one
|
|
function entry or exit per line, indented by the recursion level.
|
|
|
|
Also see @code{edebug-tracing}, in @ref{Trace Buffer}.
|
|
@end defopt
|
|
|
|
@defopt edebug-test-coverage
|
|
If non-@code{nil}, Edebug tests coverage of all expressions debugged.
|
|
@xref{Coverage Testing}.
|
|
@end defopt
|
|
|
|
@defopt edebug-continue-kbd-macro
|
|
If non-@code{nil}, continue defining or executing any keyboard macro
|
|
that is executing outside of Edebug. Use this with caution since it is not
|
|
debugged.
|
|
@xref{Edebug Execution Modes}.
|
|
@end defopt
|
|
|
|
@defopt edebug-unwrap-results
|
|
If non-@code{nil}, Edebug tries to remove any of its own
|
|
instrumentation when showing the results of expressions. This is
|
|
relevant when debugging macros where the results of expressions are
|
|
themselves instrumented expressions. As a very artificial example,
|
|
suppose that the example function @code{fac} has been instrumented,
|
|
and consider a macro of the form:
|
|
|
|
@c FIXME find a less silly example.
|
|
@smallexample
|
|
(defmacro test () "Edebug example."
|
|
(if (symbol-function 'fac)
|
|
@dots{}))
|
|
@end smallexample
|
|
|
|
If you instrument the @code{test} macro and step through it, then by
|
|
default the result of the @code{symbol-function} call has numerous
|
|
@code{edebug-after} and @code{edebug-before} forms, which can make it
|
|
difficult to see the ``actual'' result. If
|
|
@code{edebug-unwrap-results} is non-@code{nil}, Edebug tries to remove
|
|
these forms from the result.
|
|
@end defopt
|
|
|
|
@defopt edebug-on-error
|
|
Edebug binds @code{debug-on-error} to this value, if
|
|
@code{debug-on-error} was previously @code{nil}. @xref{Trapping
|
|
Errors}.
|
|
@end defopt
|
|
|
|
@defopt edebug-on-quit
|
|
Edebug binds @code{debug-on-quit} to this value, if
|
|
@code{debug-on-quit} was previously @code{nil}. @xref{Trapping
|
|
Errors}.
|
|
@end defopt
|
|
|
|
If you change the values of @code{edebug-on-error} or
|
|
@code{edebug-on-quit} while Edebug is active, their values won't be used
|
|
until the @emph{next} time Edebug is invoked via a new command.
|
|
@c Not necessarily a deeper command level.
|
|
@c A new command is not precisely true, but that is close enough -- dan
|
|
|
|
@defopt edebug-global-break-condition
|
|
If non-@code{nil}, an expression to test for at every stop point. If
|
|
the result is non-@code{nil}, then break. Errors are ignored.
|
|
@xref{Global Break Condition}.
|
|
@end defopt
|