;;;; the debugger ;;;; This software is part of the SBCL system. See the README file for ;;;; more information. ;;;; ;;;; This software is derived from the CMU CL system, which was ;;;; written at Carnegie Mellon University and released into the ;;;; public domain. The software is in the public domain and is ;;;; provided with absolutely no warranty. See the COPYING and CREDITS ;;;; files for more information. (in-package "SB!DEBUG") ;;;; variables and constants ;;; things to consider when tweaking these values: ;;; * We're afraid to just default them to NIL and NIL, in case the ;;; user inadvertently causes a hairy data structure to be printed ;;; when he inadvertently enters the debugger. ;;; * We don't want to truncate output too much. These days anyone ;;; can easily run their Lisp in a windowing system or under Emacs, ;;; so it's not the end of the world even if the worst case is a ;;; few thousand lines of output. ;;; * As condition :REPORT methods are converted to use the pretty ;;; printer, they acquire *PRINT-LEVEL* constraints, so e.g. under ;;; sbcl-0.7.1.28's old value of *DEBUG-PRINT-LEVEL*=3, an ;;; ARG-COUNT-ERROR printed as ;;; error while parsing arguments to DESTRUCTURING-BIND: ;;; invalid number of elements in ;;; # ;;; to satisfy lambda list ;;; #: ;;; exactly 2 expected, but 5 found (defvar *debug-print-variable-alist* nil #!+sb-doc "an association list describing new bindings for special variables to be used within the debugger. Eg. ((*PRINT-LENGTH* . 10) (*PRINT-LEVEL* . 6) (*PRINT-PRETTY* . NIL)) The variables in the CAR positions are bound to the values in the CDR during the execution of some debug commands. When evaluating arbitrary expressions in the debugger, the normal values of the printer control variables are in effect. Initially empty, *DEBUG-PRINT-VARIABLE-ALIST* is typically used to provide bindings for printer control variables.") (defvar *debug-readtable* ;; KLUDGE: This can't be initialized in a cold toplevel form, ;; because the *STANDARD-READTABLE* isn't initialized until after ;; cold toplevel forms have run. So instead we initialize it ;; immediately after *STANDARD-READTABLE*. -- WHN 20000205 nil #!+sb-doc "*READTABLE* for the debugger") (defvar *in-the-debugger* nil #!+sb-doc "This is T while in the debugger.") ;;; nestedness inside debugger command loops (defvar *debug-command-level* 0) ;;; If this is bound before the debugger is invoked, it is used as the stack ;;; top by the debugger. It can either be the first interesting frame, or the ;;; name of the last uninteresting frame. (defvar *stack-top-hint* nil) (defvar *real-stack-top* nil) (defvar *stack-top* nil) (defvar *current-frame* nil) ;;; Beginner-oriented help messages are important because you end up ;;; in the debugger whenever something bad happens, or if you try to ;;; get out of the system with Ctrl-C or (EXIT) or EXIT or whatever. ;;; But after memorizing them the wasted screen space gets annoying.. (defvar *debug-beginner-help-p* t "Should the debugger display beginner-oriented help messages?") (defun debug-prompt (stream) (sb!thread::get-foreground) (format stream "~%~W~:[~;[~W~]] " (sb!di:frame-number *current-frame*) (> *debug-command-level* 1) *debug-command-level*)) (defparameter *debug-help-string* "The debug prompt is square brackets, with number(s) indicating the current control stack level and, if you've entered the debugger recursively, how deeply recursed you are. Any command -- including the name of a restart -- may be uniquely abbreviated. The debugger rebinds various special variables for controlling i/o, sometimes to defaults (much like WITH-STANDARD-IO-SYNTAX does) and sometimes to its own special values, based on SB-EXT:*DEBUG-PRINT-VARIABLE-ALIST*. Debug commands do not affect *, //, and similar variables, but evaluation in the debug loop does affect these variables. SB-DEBUG:*FLUSH-DEBUG-ERRORS* controls whether errors at the debug prompt drop you deeper into the debugger. The default NIL allows recursive entry to debugger. Getting in and out of the debugger: TOPLEVEL, TOP exits debugger and returns to top level REPL RESTART invokes restart numbered as shown (prompt if not given). ERROR prints the error condition and restart cases. The number of any restart, or its name, or a unique abbreviation for its name, is a valid command, and is the same as using RESTART to invoke that restart. Changing frames: UP up frame DOWN down frame BOTTOM bottom frame FRAME n frame n (n=0 for top frame) Inspecting frames: BACKTRACE [n] shows n frames going down the stack. LIST-LOCALS, L lists locals in current frame. PRINT, P displays function call for current frame. SOURCE [n] displays frame's source form with n levels of enclosing forms. Stepping: START Selects the CONTINUE restart if one exists and starts single-stepping. Single stepping affects only code compiled with under high DEBUG optimization quality. See User Manual for details. STEP Steps into the current form. NEXT Steps over the current form. OUT Stops stepping temporarily, but resumes it when the topmost frame that was stepped into returns. STOP Stops single-stepping. Function and macro commands: (SB-DEBUG:ARG n) Return the n'th argument in the current frame. (SB-DEBUG:VAR string-or-symbol [id]) Returns the value of the specified variable in the current frame. Other commands: RETURN expr Return the values resulting from evaluation of expr from the current frame, if this frame was compiled with a sufficiently high DEBUG optimization quality. RESTART-FRAME Restart execution of the current frame, if this frame is for a global function which was compiled with a sufficiently high DEBUG optimization quality. SLURP Discard all pending input on *STANDARD-INPUT*. (This can be useful when the debugger was invoked to handle an error in deeply nested input syntax, and now the reader is confused.)") (defmacro with-debug-io-syntax (() &body body) (let ((thunk (gensym "THUNK"))) `(dx-flet ((,thunk () ,@body)) (funcall-with-debug-io-syntax #',thunk)))) ;;; If LOC is an unknown location, then try to find the block start ;;; location. Used by source printing to some information instead of ;;; none for the user. (defun maybe-block-start-location (loc) (if (sb!di:code-location-unknown-p loc) (let* ((block (sb!di:code-location-debug-block loc)) (start (sb!di:do-debug-block-locations (loc block) (return loc)))) (cond ((and (not (sb!di:debug-block-elsewhere-p block)) start) (format *debug-io* "~%unknown location: using block start~%") start) (t loc))) loc)) ;;;; BACKTRACE (declaim (unsigned-byte *backtrace-frame-count*)) (defvar *backtrace-frame-count* 1000 "Default number of frames to backtrace. Defaults to 1000.") (declaim (type (member :minimal :normal :full) *method-frame-style*)) (defvar *method-frame-style* :normal "Determines how frames corresponding to method functions are represented in backtraces. Possible values are :MINIMAL, :NORMAL, and :FULL. :MINIMAL represents them as ( ...args...) if all arguments are available, and only a single method is applicable to the arguments -- otherwise behaves as :NORMAL. :NORMAL represents them as ((:method [*] (*)) ...args...) The frame is then followed by either [fast-method] or [slow-method], designating the kind of method function. (See below.) :FULL represents them using the actual funcallable method function name: ((sb-pcl:fast-method [*] (*)) ...args...) or ((sb-pcl:slow-method [*] (*)) ...args...) In the this case arguments may include values internal to SBCL's method dispatch machinery.") (define-deprecated-variable :early "1.1.4.9" *show-entry-point-details* :value nil) (defun backtrace (&optional (count *backtrace-frame-count*) (stream *debug-io*)) "Replaced by PRINT-BACKTRACE, will eventually be deprecated." (print-backtrace :count count :stream stream)) (defun backtrace-as-list (&optional (count *backtrace-frame-count*)) "Replaced by LIST-BACKTRACE, will eventually be deprecated." (list-backtrace :count count)) (defun backtrace-start-frame (frame-designator) (let ((here (sb!di:top-frame))) (labels ((current-frame () (let ((frame here)) ;; Our caller's caller. (loop repeat 2 do (setf frame (or (sb!di:frame-down frame) frame))) frame)) (interrupted-frame () (or (nth-value 1 (find-interrupted-name-and-frame)) (current-frame)))) (cond ((eq :current-frame frame-designator) (current-frame)) ((eq :interrupted-frame frame-designator) (interrupted-frame)) ((eq :debugger-frame frame-designator) (if (and *in-the-debugger* *current-frame*) *current-frame* (interrupted-frame))) ((sb!di:frame-p frame-designator) frame-designator) (t (error "Invalid designator for initial backtrace frame: ~S" frame-designator)))))) (defun map-backtrace (function &key (start 0) (from :debugger-frame) (count *backtrace-frame-count*)) #!+sb-doc "Calls the designated FUNCTION with each frame on the call stack. Returns the last value returned by FUNCTION. COUNT is the number of frames to backtrace, defaulting to *BACKTRACE-FRAME-COUNT*. START is the number of the frame the backtrace should start from. FROM specifies the frame relative to which the frames are numbered. Possible values are an explicit SB-DI:FRAME object, and the keywords :CURRENT-FRAME, :INTERRUPTED-FRAME, and :DEBUGGER-FRAME. Default is :DEBUGGER-FRAME. :CURRENT-FRAME specifies the caller of MAP-BACKTRACE. :INTERRUPTED-FRAME specifies the first interrupted frame on the stack \(typically the frame where the error occurred, as opposed to error handling frames) if any, otherwise behaving as :CURRENT-FRAME. :DEBUGGER-FRAME specifies the currently debugged frame when inside the debugger, and behaves as :INTERRUPTED-FRAME outside the debugger. " (loop with result = nil for index upfrom 0 for frame = (backtrace-start-frame from) then (sb!di:frame-down frame) until (null frame) when (<= start index) do (if (minusp (decf count)) (return result) (setf result (funcall function frame))) finally (return result))) (defun print-backtrace (&key (stream *debug-io*) (start 0) (from :debugger-frame) (count *backtrace-frame-count*) (print-thread t) (print-frame-source nil) (method-frame-style *method-frame-style*)) #!+sb-doc "Print a listing of the call stack to STREAM, defaulting to *DEBUG-IO*. COUNT is the number of frames to backtrace, defaulting to *BACKTRACE-FRAME-COUNT*. START is the number of the frame the backtrace should start from. FROM specifies the frame relative to which the frames are numbered. Possible values are an explicit SB-DI:FRAME object, and the keywords :CURRENT-FRAME, :INTERRUPTED-FRAME, and :DEBUGGER-FRAME. Default is :DEBUGGER-FRAME. :CURRENT-FRAME specifies the caller of PRINT-BACKTRACE. :INTERRUPTED-FRAME specifies the first interrupted frame on the stack \(typically the frame where the error occured, as opposed to error handling frames) if any, otherwise behaving as :CURRENT-FRAME. :DEBUGGER-FRAME specifies the currently debugged frame when inside the debugger, and behaves as :INTERRUPTED-FRAME outside the debugger. If PRINT-THREAD is true (default), backtrace is preceded by printing the thread object the backtrace is from. If PRINT-FRAME-SOURCE is true (default is false), each frame is followed by printing the currently executing source form in the function responsible for that frame, when available. Requires the function to have been compiled at DEBUG 2 or higher. If PRINT-FRAME-SOURCE is :ALWAYS, it also reports \"no source available\" for frames for which were compiled at lower debug settings. METHOD-FRAME-STYLE (defaulting to *METHOD-FRAME-STYLE*), determines how frames corresponding to method functions are printed. Possible values are :MINIMAL, :NORMAL, and :FULL. See *METHOD-FRAME-STYLE* for more information." (with-debug-io-syntax () (fresh-line stream) (when print-thread (format stream "Backtrace for: ~S~%" sb!thread:*current-thread*)) (let ((*suppress-print-errors* (if (subtypep 'serious-condition *suppress-print-errors*) *suppress-print-errors* 'serious-condition)) (*print-circle* t) (n start)) (handler-bind ((print-not-readable #'print-unreadably)) (map-backtrace (lambda (frame) (print-frame-call frame stream :number n :method-frame-style method-frame-style :print-frame-source print-frame-source) (incf n)) :from (backtrace-start-frame from) :start start :count count))) (fresh-line stream) (values))) (defun list-backtrace (&key (count *backtrace-frame-count*) (start 0) (from :debugger-frame) (method-frame-style *method-frame-style*)) #!+sb-doc "Returns a list describing the call stack. Each frame is represented by a sublist: \( ...args...) where the name describes the function responsible for the frame. The name might not be bound to the actual function object. Unavailable arguments are represented by dummy objects that print as #. Objects with dynamic-extent allocation by the current thread are represented by substitutes to avoid references to them from leaking outside their legal extent. COUNT is the number of frames to backtrace, defaulting to *BACKTRACE-FRAME-COUNT*. START is the number of the frame the backtrace should start from. FROM specifies the frame relative to which the frames are numbered. Possible values are an explicit SB-DI:FRAME object, and the keywords :CURRENT-FRAME, :INTERRUPTED-FRAME, and :DEBUGGER-FRAME. Default is :DEBUGGER-FRAME. :CURRENT-FRAME specifies the caller of LIST-BACKTRACE. :INTERRUPTED-FRAME specifies the first interrupted frame on the stack \(typically the frame where the error occured, as opposed to error handling frames) if any, otherwise behaving as :CURRENT-FRAME. :DEBUGGER-FRAME specifies the currently debugged frame when inside the debugger, and behaves as :INTERRUPTED-FRAME outside the debugger. METHOD-FRAME-STYLE (defaulting to *METHOD-FRAME-STYLE*), determines how frames corresponding to method functions are printed. Possible values are :MINIMAL, :NORMAL, and :FULL. See *METHOD-FRAME-STYLE* for more information." (let (rbacktrace) (map-backtrace (lambda (frame) (push (frame-call-as-list frame :method-frame-style method-frame-style) rbacktrace)) :count count :start start :from (backtrace-start-frame from)) (nreverse rbacktrace))) (defun frame-call-as-list (frame &key (method-frame-style *method-frame-style*)) (multiple-value-bind (name args info) (frame-call frame :method-frame-style method-frame-style :replace-dynamic-extent-objects t) (values (cons name args) info))) (defun replace-dynamic-extent-object (obj) (if (stack-allocated-p obj) (make-unprintable-object (handler-case (format nil "dynamic-extent: ~S" obj) (error () "error printing dynamic-extent object"))) obj)) (defun stack-allocated-p (obj) "Returns T if OBJ is allocated on the stack of the current thread, NIL otherwise." (with-pinned-objects (obj) (let ((sap (int-sap (get-lisp-obj-address obj)))) (when (sb!vm:control-stack-pointer-valid-p sap nil) t)))) ;;;; frame printing (eval-when (:compile-toplevel :execute) ;;; This is a convenient way to express what to do for each type of ;;; lambda-list element. (sb!xc:defmacro lambda-list-element-dispatch (element &key required optional rest keyword more deleted) `(etypecase ,element (sb!di:debug-var ,@required) (cons (ecase (car ,element) (:optional ,@optional) (:rest ,@rest) (:keyword ,@keyword) (:more ,@more))) (symbol (aver (eq ,element :deleted)) ,@deleted))) (sb!xc:defmacro lambda-var-dispatch (variable location deleted valid other) (let ((var (gensym))) `(let ((,var ,variable)) (cond ((eq ,var :deleted) ,deleted) ((eq (sb!di:debug-var-validity ,var ,location) :valid) ,valid) (t ,other))))) ) ; EVAL-WHEN ;;; Extract the function argument values for a debug frame. (defun map-frame-args (thunk frame) (let ((debug-fun (sb!di:frame-debug-fun frame))) (dolist (element (sb!di:debug-fun-lambda-list debug-fun)) (funcall thunk element)))) (defun frame-args-as-list (frame) (handler-case (let ((location (sb!di:frame-code-location frame)) (reversed-result nil)) (block enumerating (map-frame-args (lambda (element) (lambda-list-element-dispatch element :required ((push (frame-call-arg element location frame) reversed-result)) :optional ((push (frame-call-arg (second element) location frame) reversed-result)) :keyword ((push (second element) reversed-result) (push (frame-call-arg (third element) location frame) reversed-result)) :deleted ((push (frame-call-arg element location frame) reversed-result)) :rest ((lambda-var-dispatch (second element) location nil (let ((rest (sb!di:debug-var-value (second element) frame))) (if (listp rest) (setf reversed-result (append (reverse rest) reversed-result)) (push (make-unprintable-object "unavailable &REST argument") reversed-result)) (return-from enumerating)) (push (make-unprintable-object "unavailable &REST argument") reversed-result))) :more ((lambda-var-dispatch (second element) location nil (let ((context (sb!di:debug-var-value (second element) frame)) (count (sb!di:debug-var-value (third element) frame))) (setf reversed-result (append (reverse (multiple-value-list (sb!c::%more-arg-values context 0 count))) reversed-result)) (return-from enumerating)) (push (make-unprintable-object "unavailable &MORE argument") reversed-result))))) frame)) (nreverse reversed-result)) (sb!di:lambda-list-unavailable () (make-unprintable-object "unavailable lambda list")))) (defun interrupted-frame-error (frame) (when (and (sb!di::compiled-frame-p frame) (sb!di::compiled-frame-escaped frame)) (let ((error-number (sb!vm:internal-error-args (sb!di::compiled-frame-escaped frame)))) (when (array-in-bounds-p sb!c:*backend-internal-errors* error-number) (car (svref sb!c:*backend-internal-errors* error-number)))))) (defun clean-xep (frame name args info) (values (second name) (if (consp args) (let* ((count (first args)) (real-args (rest args))) (if (and (integerp count) (eq (interrupted-frame-error frame) 'invalid-arg-count-error)) ;; So, this is a cheap trick -- but makes backtraces for ;; too-many-arguments-errors much, much easier to to ;; understand. FIXME: For :EXTERNAL frames at least we ;; should be able to get the actual arguments, really. (loop repeat count for arg = (if real-args (pop real-args) (make-unprintable-object "unknown")) collect arg) real-args)) args) (if (eq (car name) 'sb!c::tl-xep) (cons :tl info) info))) (defun clean-&more-processor (name args info) (values (second name) (if (consp args) (let* ((more (last args 2)) (context (first more)) (count (second more))) (append (butlast args 2) (if (fixnump count) (multiple-value-list (sb!c:%more-arg-values context 0 count)) (list (make-unprintable-object "more unavailable arguments"))))) args) (cons :more info))) (defun clean-fast-method (name args style info) (multiple-value-bind (cname cargs) (ecase style (:minimal (let ((gf-name (second name)) (real-args (cddr args))) (if (and (fboundp gf-name) (notany #'sb!impl::unprintable-object-p real-args) (let ((methods (compute-applicable-methods (fdefinition gf-name) real-args))) (and methods (not (cdr methods))))) (values gf-name real-args) (values (cons :method (cdr name)) real-args)))) (:normal (values (cons :method (cdr name)) (cddr args))) (:full (values name args))) (values cname cargs (cons :fast-method info)))) (defun clean-frame-call (frame name method-frame-style info) (let ((args (frame-args-as-list frame))) (if (consp name) (case (first name) ((sb!c::xep sb!c::tl-xep) (clean-xep frame name args info)) ((sb!c::&more-processor) (clean-&more-processor name args info)) ((sb!c::&optional-processor) (clean-frame-call frame (second name) method-frame-style info)) ((sb!pcl::fast-method) (clean-fast-method name args method-frame-style info)) (t (values name args info))) (values name args info)))) (defun frame-call (frame &key (method-frame-style *method-frame-style*) replace-dynamic-extent-objects) "Returns as multiple values a descriptive name for the function responsible for FRAME, arguments that that function, and a list providing additional information about the frame. Unavailable arguments are represented using dummy-objects printing as #. METHOD-FRAME-STYLE (defaulting to *METHOD-FRAME-STYLE*), determines how frames corresponding to method functions are printed. Possible values are :MINIMAL, :NORMAL, and :FULL. See *METHOD-FRAME-STYLE* for more information. If REPLACE-DYNAMIC-EXTENT-OBJECTS is true, objects allocated on the stack of the current thread are replaced with dummy objects which can safely escape." (let* ((debug-fun (sb!di:frame-debug-fun frame)) (kind (sb!di:debug-fun-kind debug-fun))) (multiple-value-bind (name args info) (clean-frame-call frame (sb!di:debug-fun-name debug-fun) method-frame-style (when kind (list kind))) (let ((args (if (and (consp args) replace-dynamic-extent-objects) (mapcar #'replace-dynamic-extent-object args) args))) (values name args info))))) (defun ensure-printable-object (object) (handler-case (with-open-stream (out (make-broadcast-stream)) (prin1 object out) object) (error (cond) (declare (ignore cond)) (make-unprintable-object "error printing object")))) (defun frame-call-arg (var location frame) (lambda-var-dispatch var location (make-unprintable-object "unused argument") (sb!di:debug-var-value var frame) (make-unprintable-object "unavailable argument"))) ;;; Prints a representation of the function call causing FRAME to ;;; exist. VERBOSITY indicates the level of information to output; ;;; zero indicates just printing the DEBUG-FUN's name, and one ;;; indicates displaying call-like, one-liner format with argument ;;; values. (defun print-frame-call (frame stream &key print-frame-source number (method-frame-style *method-frame-style*)) (when number (format stream "~&~S: " (if (integerp number) number (sb!di:frame-number frame)))) (multiple-value-bind (name args info) (frame-call frame :method-frame-style method-frame-style) (pprint-logical-block (stream nil :prefix "(" :suffix ")") ;; Since we go to some trouble to make nice informative function ;; names like (PRINT-OBJECT :AROUND (CLOWN T)), let's make sure ;; that they aren't truncated by *PRINT-LENGTH* and *PRINT-LEVEL*. ;; For the function arguments, we can just print normally. (let ((*print-length* nil) (*print-level* nil) (*print-pretty* nil) (*print-circle* t) (name (ensure-printable-object name))) (write name :stream stream :escape t :pretty (equal '(lambda ()) name)) ;; If we hit a &REST arg, then print as many of the values as ;; possible, punting the loop over lambda-list variables since any ;; other arguments will be in the &REST arg's list of values. (let ((args (ensure-printable-object args))) (if (listp args) (format stream "~{ ~_~S~}" args) (format stream " ~S" args))))) (when info (format stream " [~{~(~A~)~^,~}]" info))) (when print-frame-source (let ((loc (sb!di:frame-code-location frame))) (handler-case (let ((source (handler-case (code-location-source-form loc 0) (error (c) (format stream "~& error finding frame source: ~A" c))))) (format stream "~% source: ~S" source)) (sb!di:debug-condition () ;; This is mostly noise. (when (eq :always print-frame-source) (format stream "~& no source available for frame"))) (error (c) (format stream "~& error printing frame source: ~A" c)))))) ;;;; INVOKE-DEBUGGER (defvar *debugger-hook* nil #!+sb-doc "This is either NIL or a function of two arguments, a condition and the value of *DEBUGGER-HOOK*. This function can either handle the condition or return which causes the standard debugger to execute. The system passes the value of this variable to the function because it binds *DEBUGGER-HOOK* to NIL around the invocation.") (defvar *invoke-debugger-hook* nil #!+sb-doc "This is either NIL or a designator for a function of two arguments, to be run when the debugger is about to be entered. The function is run with *INVOKE-DEBUGGER-HOOK* bound to NIL to minimize recursive errors, and receives as arguments the condition that triggered debugger entry and the previous value of *INVOKE-DEBUGGER-HOOK* This mechanism is an SBCL extension similar to the standard *DEBUGGER-HOOK*. In contrast to *DEBUGGER-HOOK*, it is observed by INVOKE-DEBUGGER even when called by BREAK.") ;;; These are bound on each invocation of INVOKE-DEBUGGER. (defvar *debug-restarts*) (defvar *debug-condition*) (defvar *nested-debug-condition*) ;;; Oh, what a tangled web we weave when we preserve backwards ;;; compatibility with 1968-style use of global variables to control ;;; per-stream i/o properties; there's really no way to get this ;;; quite right, but we do what we can. (defun funcall-with-debug-io-syntax (fun &rest rest) (declare (type function fun)) ;; Try to force the other special variables into a useful state. (let (;; Protect from WITH-STANDARD-IO-SYNTAX some variables where ;; any default we might use is less useful than just reusing ;; the global values. (original-package *package*) (original-print-pretty *print-pretty*)) (with-standard-io-syntax (with-sane-io-syntax (let (;; We want the printer and reader to be in a useful ;; state, regardless of where the debugger was invoked ;; in the program. WITH-STANDARD-IO-SYNTAX and ;; WITH-SANE-IO-SYNTAX do much of what we want, but ;; * It doesn't affect our internal special variables ;; like *CURRENT-LEVEL-IN-PRINT*. ;; * It isn't customizable. ;; * It sets *PACKAGE* to COMMON-LISP-USER, which is not ;; helpful behavior for a debugger. ;; * There's no particularly good debugger default for ;; *PRINT-PRETTY*, since T is usually what you want ;; -- except absolutely not what you want when you're ;; debugging failures in PRINT-OBJECT logic. ;; We try to address all these issues with explicit ;; rebindings here. (sb!kernel:*current-level-in-print* 0) (*package* original-package) (*print-pretty* original-print-pretty) ;; Clear the circularity machinery to try to to reduce the ;; pain from sharing the circularity table across all ;; streams; if these are not rebound here, then setting ;; *PRINT-CIRCLE* within the debugger when debugging in a ;; state where something circular was being printed (e.g., ;; because the debugger was entered on an error in a ;; PRINT-OBJECT method) makes a hopeless mess. Binding them ;; here does seem somewhat ugly because it makes it more ;; difficult to debug the printing-of-circularities code ;; itself; however, as far as I (WHN, 2004-05-29) can see, ;; that's almost entirely academic as long as there's one ;; shared *C-H-T* for all streams (i.e., it's already ;; unreasonably difficult to debug print-circle machinery ;; given the buggy crosstalk between the debugger streams ;; and the stream you're trying to watch), and any fix for ;; that buggy arrangement will likely let this hack go away ;; naturally. (sb!impl::*circularity-hash-table* . nil) (sb!impl::*circularity-counter* . nil) (*readtable* *debug-readtable*)) (progv ;; (Why NREVERSE? PROGV makes the later entries have ;; precedence over the earlier entries. ;; *DEBUG-PRINT-VARIABLE-ALIST* is called an alist, so it's ;; expected that its earlier entries have precedence. And ;; the earlier-has-precedence behavior is mostly more ;; convenient, so that programmers can use PUSH or LIST* to ;; customize *DEBUG-PRINT-VARIABLE-ALIST*.) (nreverse (mapcar #'car *debug-print-variable-alist*)) (nreverse (mapcar #'cdr *debug-print-variable-alist*)) (apply fun rest))))))) ;;; This function is not inlined so it shows up in the backtrace; that ;;; can be rather handy when one has to debug the interplay between ;;; *INVOKE-DEBUGGER-HOOK* and *DEBUGGER-HOOK*. (declaim (notinline run-hook)) (defun run-hook (variable condition) (let ((old-hook (symbol-value variable))) (when old-hook (progv (list variable) (list nil) (funcall old-hook condition old-hook))))) ;;; We can bind *stack-top-hint* to a symbol, in which case this function will ;;; resolve that hint lazily before we enter the debugger. (defun resolve-stack-top-hint () (let ((hint *stack-top-hint*) (*stack-top-hint* nil)) (cond ;; No hint, just keep the debugger guts out. ((not hint) (find-caller-name-and-frame)) ;; Interrupted. Look for the interrupted frame -- if we don't find one ;; this falls back to the next case. ((and (eq hint 'invoke-interruption) (nth-value 1 (find-interrupted-name-and-frame)))) ;; Name of the first uninteresting frame. ((symbolp hint) (find-caller-of-named-frame hint)) ;; We already have a resolved hint. (t hint)))) (defun invoke-debugger (condition) #!+sb-doc "Enter the debugger." (let ((*stack-top-hint* (resolve-stack-top-hint))) ;; call *INVOKE-DEBUGGER-HOOK* first, so that *DEBUGGER-HOOK* is not ;; called when the debugger is disabled (run-hook '*invoke-debugger-hook* condition) (run-hook '*debugger-hook* condition) ;; We definitely want *PACKAGE* to be of valid type. ;; ;; Elsewhere in the system, we use the SANE-PACKAGE function for ;; this, but here causing an exception just as we're trying to handle ;; an exception would be confusing, so instead we use a special hack. (unless (and (packagep *package*) (package-name *package*)) (setf *package* (find-package :cl-user)) (format *error-output* "The value of ~S was not an undeleted PACKAGE. It has been ~ reset to ~S." '*package* *package*)) ;; Before we start our own output, finish any pending output. ;; Otherwise, if the user tried to track the progress of his program ;; using PRINT statements, he'd tend to lose the last line of output ;; or so, which'd be confusing. (flush-standard-output-streams) (funcall-with-debug-io-syntax #'%invoke-debugger condition))) (defun %print-debugger-invocation-reason (condition stream) (format stream "~2&") ;; Note: Ordinarily it's only a matter of taste whether to use ;; FORMAT "~<...~:>" or to use PPRINT-LOGICAL-BLOCK directly, but ;; until bug 403 is fixed, PPRINT-LOGICAL-BLOCK (STREAM NIL) is ;; definitely preferred, because the FORMAT alternative was acting odd. (pprint-logical-block (stream nil) (format stream "debugger invoked on a ~S~@[ in thread ~_~A~]: ~2I~_~A" (type-of condition) #!+sb-thread sb!thread:*current-thread* #!-sb-thread nil condition)) (terpri stream)) (defun %invoke-debugger (condition) (let ((*debug-condition* condition) (*debug-restarts* (compute-restarts condition)) (*nested-debug-condition* nil)) (handler-case ;; (The initial output here goes to *ERROR-OUTPUT*, because the ;; initial output is not interactive, just an error message, and ;; when people redirect *ERROR-OUTPUT*, they could reasonably ;; expect to see error messages logged there, regardless of what ;; the debugger does afterwards.) (unless (typep condition 'step-condition) (%print-debugger-invocation-reason condition *error-output*)) (error (condition) (setf *nested-debug-condition* condition) (let ((ndc-type (type-of *nested-debug-condition*))) (format *error-output* "~&~@<(A ~S was caught when trying to print ~S when ~ entering the debugger. Printing was aborted and the ~ ~S was stored in ~S.)~@:>~%" ndc-type '*debug-condition* ndc-type '*nested-debug-condition*)) (when (typep *nested-debug-condition* 'cell-error) ;; what we really want to know when it's e.g. an UNBOUND-VARIABLE: (format *error-output* "~&(CELL-ERROR-NAME ~S) = ~S~%" '*nested-debug-condition* (cell-error-name *nested-debug-condition*))))) (let ((background-p (sb!thread::debugger-wait-until-foreground-thread *debug-io*))) ;; After the initial error/condition/whatever announcement to ;; *ERROR-OUTPUT*, we become interactive, and should talk on ;; *DEBUG-IO* from now on. (KLUDGE: This is a normative ;; statement, not a description of reality.:-| There's a lot of ;; older debugger code which was written to do i/o on whatever ;; stream was in fashion at the time, and not all of it has ;; been converted to behave this way. -- WHN 2000-11-16) (unwind-protect (let (;; We used to bind *STANDARD-OUTPUT* to *DEBUG-IO* ;; here as well, but that is probably bogus since it ;; removes the users ability to do output to a redirected ;; *S-O*. Now we just rebind it so that users can temporarily ;; frob it. FIXME: This and other "what gets bound when" ;; behaviour should be documented in the manual. (*standard-output* *standard-output*) ;; This seems reasonable: e.g. if the user has redirected ;; *ERROR-OUTPUT* to some log file, it's probably wrong ;; to send errors which occur in interactive debugging to ;; that file, and right to send them to *DEBUG-IO*. (*error-output* *debug-io*)) (unless (typep condition 'step-condition) (when *debug-beginner-help-p* (format *debug-io* "~%~@~2%")) (show-restarts *debug-restarts* *debug-io*)) (internal-debug)) (when background-p (sb!thread::release-foreground)))))) ;;; this function is for use in *INVOKE-DEBUGGER-HOOK* when ordinary ;;; ANSI behavior has been suppressed by the "--disable-debugger" ;;; command-line option (defun debugger-disabled-hook (condition previous-hook) (declare (ignore previous-hook)) ;; There is no one there to interact with, so report the ;; condition and terminate the program. (let ((*suppress-print-errors* t) (condition-error-message #.(format nil "A nested error within --disable-debugger error ~ handling prevents displaying the original error. Attempting ~ to print a backtrace.")) (backtrace-error-message #.(format nil "A nested error within --disable-debugger error ~ handling prevents printing the backtrace. Sorry, exiting."))) (labels ((failure-quit (&key abort) (/show0 "in FAILURE-QUIT (in --disable-debugger debugger hook)") (exit :code 1 :abort abort)) (display-condition () (handler-case (handler-case (print-condition) (condition () ;; printing failed, try to describe it (describe-condition))) (condition () ;; ok, give up trying to display the error and inform the user about it (finish-output *error-output*) (%primitive print condition-error-message)))) (print-condition () (format *error-output* "~&~@~2%" (type-of condition) #!+sb-thread sb!thread:*current-thread* #!-sb-thread nil condition) (finish-output *error-output*)) (describe-condition () (format *error-output* "~&Unhandled ~S~@[ in thread ~S~]:~%" (type-of condition) #!+sb-thread sb!thread:*current-thread* #!-sb-thread nil) (describe condition *error-output*) (finish-output *error-output*)) (display-backtrace () (handler-case (print-backtrace :stream *error-output* :from :interrupted-frame :print-thread t) (condition () (values))) (finish-output *error-output*))) ;; This HANDLER-CASE is here mostly to stop output immediately ;; (and fall through to QUIT) when there's an I/O error. Thus, ;; when we're run under a shell script or something, we can die ;; cleanly when the script dies (and our pipes are cut), instead ;; of falling into ldb or something messy like that. Similarly, we ;; can terminate cleanly even if BACKTRACE dies because of bugs in ;; user PRINT-OBJECT methods. Separate the error handling of the ;; two phases to maximize the chance of emitting some useful ;; information. (handler-case (progn (display-condition) (display-backtrace) (format *error-output* "~%unhandled condition in --disable-debugger mode, quitting~%") (finish-output *error-output*) (failure-quit)) (condition () ;; We IGNORE-ERRORS here because even %PRIMITIVE PRINT can ;; fail when our output streams are blown away, as e.g. when ;; we're running under a Unix shell script and it dies somehow ;; (e.g. because of a SIGINT). In that case, we might as well ;; just give it up for a bad job, and stop trying to notify ;; the user of anything. ;; ;; Actually, the only way I've run across to exercise the ;; problem is to have more than one layer of shell script. ;; I have a shell script which does ;; time nice -10 sh make.sh "$1" 2>&1 | tee make.tmp ;; and the problem occurs when I interrupt this with Ctrl-C ;; under Linux 2.2.14-5.0 and GNU bash, version 1.14.7(1). ;; I haven't figured out whether it's bash, time, tee, Linux, or ;; what that is responsible, but that it's possible at all ;; means that we should IGNORE-ERRORS here. -- WHN 2001-04-24 (ignore-errors (%primitive print backtrace-error-message)) (failure-quit :abort t)))))) (defvar *old-debugger-hook* nil) ;;; halt-on-failures and prompt-on-failures modes, suitable for ;;; noninteractive and interactive use respectively (defun disable-debugger () "When invoked, this function will turn off both the SBCL debugger and LDB (the low-level debugger). See also ENABLE-DEBUGGER." ;; *DEBUG-IO* used to be set here to *ERROR-OUTPUT* which is sort ;; of unexpected but mostly harmless, but then ENABLE-DEBUGGER had ;; to set it to a suitable value again and be very careful, ;; especially if the user has also set it. -- MG 2005-07-15 (unless (eq *invoke-debugger-hook* 'debugger-disabled-hook) (setf *old-debugger-hook* *invoke-debugger-hook* *invoke-debugger-hook* 'debugger-disabled-hook)) ;; This is not inside the UNLESS to ensure that LDB is disabled ;; regardless of what the old value of *INVOKE-DEBUGGER-HOOK* was. ;; This might matter for example when restoring a core. (sb!alien:alien-funcall (sb!alien:extern-alien "disable_lossage_handler" (function sb!alien:void)))) (defun enable-debugger () "Restore the debugger if it has been turned off by DISABLE-DEBUGGER." (when (eql *invoke-debugger-hook* 'debugger-disabled-hook) (setf *invoke-debugger-hook* *old-debugger-hook* *old-debugger-hook* nil)) (sb!alien:alien-funcall (sb!alien:extern-alien "enable_lossage_handler" (function sb!alien:void)))) (defun show-restarts (restarts s) (cond ((null restarts) (format s "~&(no restarts: If you didn't do this on purpose, ~ please report it as a bug.)~%")) (t (format s "~&restarts (invokable by number or by ~ possibly-abbreviated name):~%") (let ((count 0) (names-used '(nil)) (max-name-len 0)) (dolist (restart restarts) (let ((name (restart-name restart))) (when name (let ((len (length (princ-to-string name)))) (when (> len max-name-len) (setf max-name-len len)))))) (unless (zerop max-name-len) (incf max-name-len 3)) (dolist (restart restarts) (let ((name (restart-name restart))) ;; FIXME: maybe it would be better to display later names ;; in parens instead of brakets, not just omit them fully. ;; Call BREAK, call BREAK in the debugger, and tell me ;; it's not confusing looking. --NS 20050310 (cond ((member name names-used) (format s "~& ~2D: ~V@T~A~%" count max-name-len restart)) (t (format s "~& ~2D: [~VA] ~A~%" count (- max-name-len 3) name restart) (push name names-used)))) (incf count)))))) (defvar *debug-loop-fun* #'debug-loop-fun "a function taking no parameters that starts the low-level debug loop") ;;; When the debugger is invoked due to a stepper condition, we don't ;;; want to print the current frame before the first prompt for aesthetic ;;; reasons. (defvar *suppress-frame-print* nil) ;;; This calls DEBUG-LOOP, performing some simple initializations ;;; before doing so. INVOKE-DEBUGGER calls this to actually get into ;;; the debugger. SB!KERNEL::ERROR-ERROR calls this in emergencies ;;; to get into a debug prompt as quickly as possible with as little ;;; risk as possible for stepping on whatever is causing recursive ;;; errors. (defun internal-debug () (let ((*in-the-debugger* t) (*read-suppress* nil)) (unless (typep *debug-condition* 'step-condition) (clear-input *debug-io*)) (let ((*suppress-frame-print* (typep *debug-condition* 'step-condition))) (funcall *debug-loop-fun*)))) ;;;; DEBUG-LOOP ;;; Note: This defaulted to T in CMU CL. The changed default in SBCL ;;; was motivated by desire to play nicely with ILISP. (defvar *flush-debug-errors* nil #!+sb-doc "When set, avoid calling INVOKE-DEBUGGER recursively when errors occur while executing in the debugger.") (defun debug-read (stream eof-restart) (declare (type stream stream)) (let* ((eof-marker (cons nil nil)) (form (read stream nil eof-marker))) (if (eq form eof-marker) (invoke-restart eof-restart) form))) (defun debug-loop-fun () (let* ((*debug-command-level* (1+ *debug-command-level*)) (*real-stack-top* (sb!di:top-frame)) (*stack-top* (or *stack-top-hint* *real-stack-top*)) (*stack-top-hint* nil) (*current-frame* *stack-top*)) (handler-bind ((sb!di:debug-condition (lambda (condition) (princ condition *debug-io*) (/show0 "handling d-c by THROWing DEBUG-LOOP-CATCHER") (throw 'debug-loop-catcher nil)))) (cond (*suppress-frame-print* (setf *suppress-frame-print* nil)) (t (terpri *debug-io*) (print-frame-call *current-frame* *debug-io* :print-frame-source t))) (loop (catch 'debug-loop-catcher (handler-bind ((error (lambda (condition) (when *flush-debug-errors* (clear-input *debug-io*) (princ condition *debug-io*) (format *debug-io* "~&error flushed (because ~ ~S is set)" '*flush-debug-errors*) (/show0 "throwing DEBUG-LOOP-CATCHER") (throw 'debug-loop-catcher nil))))) ;; We have to bind LEVEL for the restart function created ;; by WITH-SIMPLE-RESTART, and we need the explicit ABORT ;; restart that exists now so that EOF from read can drop ;; one debugger level. (let ((level *debug-command-level*) (restart-commands (make-restart-commands)) (abort-restart-for-eof (find-restart 'abort))) (flush-standard-output-streams) (debug-prompt *debug-io*) (force-output *debug-io*) (with-simple-restart (abort "~@" level) (let* ((exp (debug-read *debug-io* abort-restart-for-eof)) (cmd-fun (debug-command-p exp restart-commands))) (cond ((not cmd-fun) (debug-eval-print exp)) ((consp cmd-fun) (format *debug-io* "~&Your command, ~S, is ambiguous:~%" exp) (dolist (ele cmd-fun) (format *debug-io* " ~A~%" ele))) (t (funcall cmd-fun)))))))))))) (defvar *auto-eval-in-frame* t #!+sb-doc "When set (the default), evaluations in the debugger's command loop occur relative to the current frame's environment without the need of debugger forms that explicitly control this kind of evaluation.") (defun debug-eval (expr) (cond ((not (and (fboundp 'compile) *auto-eval-in-frame*)) (eval expr)) ((frame-has-debug-vars-p *current-frame*) (sb!di:eval-in-frame *current-frame* expr)) (t (format *debug-io* "; No debug variables for current frame: ~ using EVAL instead of EVAL-IN-FRAME.~%") (eval expr)))) (defun debug-eval-print (expr) (/noshow "entering DEBUG-EVAL-PRINT" expr) (let ((values (multiple-value-list (interactive-eval expr :eval #'debug-eval)))) (/noshow "done with EVAL in DEBUG-EVAL-PRINT") (dolist (value values) (fresh-line *debug-io*) (prin1 value *debug-io*))) (force-output *debug-io*)) ;;;; debug loop functions ;;; These commands are functions, not really commands, so that users ;;; can get their hands on the values returned. (eval-when (:execute :compile-toplevel) (sb!xc:defmacro define-var-operation (ref-or-set &optional value-var) `(let* ((temp (etypecase name (symbol (sb!di:debug-fun-symbol-vars (sb!di:frame-debug-fun *current-frame*) name)) (simple-string (sb!di:ambiguous-debug-vars (sb!di:frame-debug-fun *current-frame*) name)))) (location (sb!di:frame-code-location *current-frame*)) ;; Let's only deal with valid variables. (vars (remove-if-not (lambda (v) (eq (sb!di:debug-var-validity v location) :valid)) temp))) (declare (list vars)) (cond ((null vars) (error "No known valid variables match ~S." name)) ((= (length vars) 1) ,(ecase ref-or-set (:ref '(sb!di:debug-var-value (car vars) *current-frame*)) (:set `(setf (sb!di:debug-var-value (car vars) *current-frame*) ,value-var)))) (t ;; Since we have more than one, first see whether we have ;; any variables that exactly match the specification. (let* ((name (etypecase name (symbol (symbol-name name)) (simple-string name))) ;; FIXME: REMOVE-IF-NOT is deprecated, use STRING/= ;; instead. (exact (remove-if-not (lambda (v) (string= (sb!di:debug-var-symbol-name v) name)) vars)) (vars (or exact vars))) (declare (simple-string name) (list exact vars)) (cond ;; Check now for only having one variable. ((= (length vars) 1) ,(ecase ref-or-set (:ref '(sb!di:debug-var-value (car vars) *current-frame*)) (:set `(setf (sb!di:debug-var-value (car vars) *current-frame*) ,value-var)))) ;; If there weren't any exact matches, flame about ;; ambiguity unless all the variables have the same ;; name. ((and (not exact) (find-if-not (lambda (v) (string= (sb!di:debug-var-symbol-name v) (sb!di:debug-var-symbol-name (car vars)))) (cdr vars))) (error "specification ambiguous:~%~{ ~A~%~}" (mapcar #'sb!di:debug-var-symbol-name (delete-duplicates vars :test #'string= :key #'sb!di:debug-var-symbol-name)))) ;; All names are the same, so see whether the user ;; ID'ed one of them. (id-supplied (let ((v (find id vars :key #'sb!di:debug-var-id))) (unless v (error "invalid variable ID, ~W: should have been one of ~S" id (mapcar #'sb!di:debug-var-id vars))) ,(ecase ref-or-set (:ref '(sb!di:debug-var-value v *current-frame*)) (:set `(setf (sb!di:debug-var-value v *current-frame*) ,value-var))))) (t (error "Specify variable ID to disambiguate ~S. Use one of ~S." name (mapcar #'sb!di:debug-var-id vars))))))))) ) ; EVAL-WHEN ;;; FIXME: This doesn't work. It would be real nice we could make it ;;; work! Alas, it doesn't seem to work in CMU CL X86 either.. (defun var (name &optional (id 0 id-supplied)) #!+sb-doc "Return a variable's value if possible. NAME is a simple-string or symbol. If it is a simple-string, it is an initial substring of the variable's name. If name is a symbol, it has the same name and package as the variable whose value this function returns. If the symbol is uninterned, then the variable has the same name as the symbol, but it has no package. If name is the initial substring of variables with different names, then this return no values after displaying the ambiguous names. If name determines multiple variables with the same name, then you must use the optional id argument to specify which one you want. If you left id unspecified, then this returns no values after displaying the distinguishing id values. The result of this function is limited to the availability of variable information. This is SETF'able." (define-var-operation :ref)) (defun (setf var) (value name &optional (id 0 id-supplied)) (define-var-operation :set value)) ;;; This returns the COUNT'th arg as the user sees it from args, the ;;; result of SB!DI:DEBUG-FUN-LAMBDA-LIST. If this returns a ;;; potential DEBUG-VAR from the lambda-list, then the second value is ;;; T. If this returns a keyword symbol or a value from a rest arg, ;;; then the second value is NIL. ;;; ;;; FIXME: There's probably some way to merge the code here with ;;; FRAME-ARGS-AS-LIST. (A fair amount of logic is already shared ;;; through LAMBDA-LIST-ELEMENT-DISPATCH, but I suspect more could be.) (declaim (ftype (function (index list)) nth-arg)) (defun nth-arg (count args) (let ((n count)) (dolist (ele args (error "The argument specification ~S is out of range." n)) (lambda-list-element-dispatch ele :required ((if (zerop n) (return (values ele t)))) :optional ((if (zerop n) (return (values (second ele) t)))) :keyword ((cond ((zerop n) (return (values (second ele) nil))) ((zerop (decf n)) (return (values (third ele) t))))) :deleted ((if (zerop n) (return (values ele t)))) :rest ((let ((var (second ele))) (lambda-var-dispatch var (sb!di:frame-code-location *current-frame*) (error "unused &REST argument before n'th argument") (dolist (value (sb!di:debug-var-value var *current-frame*) (error "The argument specification ~S is out of range." n)) (if (zerop n) (return-from nth-arg (values value nil)) (decf n))) (error "invalid &REST argument before n'th argument"))))) (decf n)))) (defun arg (n) #!+sb-doc "Return the N'th argument's value if possible. Argument zero is the first argument in a frame's default printed representation. Count keyword/value pairs as separate arguments." (multiple-value-bind (var lambda-var-p) (nth-arg n (handler-case (sb!di:debug-fun-lambda-list (sb!di:frame-debug-fun *current-frame*)) (sb!di:lambda-list-unavailable () (error "No argument values are available.")))) (if lambda-var-p (lambda-var-dispatch var (sb!di:frame-code-location *current-frame*) (error "Unused arguments have no values.") (sb!di:debug-var-value var *current-frame*) (error "invalid argument value")) var))) ;;;; machinery for definition of debug loop commands (defvar *debug-commands* nil) ;;; Interface to *DEBUG-COMMANDS*. No required arguments in args are ;;; permitted. (defmacro !def-debug-command (name args &rest body) (let ((fun-name (symbolicate name "-DEBUG-COMMAND"))) `(progn (setf *debug-commands* (remove ,name *debug-commands* :key #'car :test #'string=)) (defun ,fun-name ,args (unless *in-the-debugger* (error "invoking debugger command while outside the debugger")) ,@body) (push (cons ,name #',fun-name) *debug-commands*) ',fun-name))) (defun !def-debug-command-alias (new-name existing-name) (let ((pair (assoc existing-name *debug-commands* :test #'string=))) (unless pair (error "unknown debug command name: ~S" existing-name)) (push (cons new-name (cdr pair)) *debug-commands*)) new-name) ;;; This takes a symbol and uses its name to find a debugger command, ;;; using initial substring matching. It returns the command function ;;; if form identifies only one command, but if form is ambiguous, ;;; this returns a list of the command names. If there are no matches, ;;; this returns nil. Whenever the loop that looks for a set of ;;; possibilities encounters an exact name match, we return that ;;; command function immediately. (defun debug-command-p (form &optional other-commands) (if (or (symbolp form) (integerp form)) (let* ((name (if (symbolp form) (symbol-name form) (format nil "~W" form))) (len (length name)) (res nil)) (declare (simple-string name) (fixnum len) (list res)) ;; Find matching commands, punting if exact match. (flet ((match-command (ele) (let* ((str (car ele)) (str-len (length str))) (declare (simple-string str) (fixnum str-len)) (cond ((< str-len len)) ((= str-len len) (when (string= name str :end1 len :end2 len) (return-from debug-command-p (cdr ele)))) ((string= name str :end1 len :end2 len) (push ele res)))))) (mapc #'match-command *debug-commands*) (mapc #'match-command other-commands)) ;; Return the right value. (cond ((not res) nil) ((= (length res) 1) (cdar res)) (t ; Just return the names. (do ((cmds res (cdr cmds))) ((not cmds) res) (setf (car cmds) (caar cmds)))))))) ;;; Return a list of debug commands (in the same format as ;;; *DEBUG-COMMANDS*) that invoke each active restart. ;;; ;;; Two commands are made for each restart: one for the number, and ;;; one for the restart name (unless it's been shadowed by an earlier ;;; restart of the same name, or it is NIL). (defun make-restart-commands (&optional (restarts *debug-restarts*)) (let ((commands) (num 0)) ; better be the same as show-restarts! (dolist (restart restarts) (let ((name (string (restart-name restart)))) (let ((restart-fun (lambda () (/show0 "in restart-command closure, about to i-r-i") (invoke-restart-interactively restart)))) (push (cons (prin1-to-string num) restart-fun) commands) (unless (or (null (restart-name restart)) (find name commands :key #'car :test #'string=)) (push (cons name restart-fun) commands)))) (incf num)) commands)) ;;;; frame-changing commands (!def-debug-command "UP" () (let ((next (sb!di:frame-up *current-frame*))) (cond (next (setf *current-frame* next) (print-frame-call next *debug-io*)) (t (format *debug-io* "~&Top of stack."))))) (!def-debug-command "DOWN" () (let ((next (sb!di:frame-down *current-frame*))) (cond (next (setf *current-frame* next) (print-frame-call next *debug-io*)) (t (format *debug-io* "~&Bottom of stack."))))) (!def-debug-command-alias "D" "DOWN") (!def-debug-command "BOTTOM" () (do ((prev *current-frame* lead) (lead (sb!di:frame-down *current-frame*) (sb!di:frame-down lead))) ((null lead) (setf *current-frame* prev) (print-frame-call prev *debug-io*)))) (!def-debug-command-alias "B" "BOTTOM") (!def-debug-command "FRAME" (&optional (n (read-prompting-maybe "frame number: "))) (setf *current-frame* (multiple-value-bind (next-frame-fun limit-string) (if (< n (sb!di:frame-number *current-frame*)) (values #'sb!di:frame-up "top") (values #'sb!di:frame-down "bottom")) (do ((frame *current-frame*)) ((= n (sb!di:frame-number frame)) frame) (let ((next-frame (funcall next-frame-fun frame))) (cond (next-frame (setf frame next-frame)) (t (format *debug-io* "The ~A of the stack was encountered.~%" limit-string) (return frame))))))) (print-frame-call *current-frame* *debug-io*)) (!def-debug-command-alias "F" "FRAME") ;;;; commands for entering and leaving the debugger (!def-debug-command "TOPLEVEL" () (throw 'toplevel-catcher nil)) ;;; make T safe (!def-debug-command-alias "TOP" "TOPLEVEL") (!def-debug-command "RESTART" () (/show0 "doing RESTART debug-command") (let ((num (read-if-available :prompt))) (when (eq num :prompt) (show-restarts *debug-restarts* *debug-io*) (write-string "restart: " *debug-io*) (force-output *debug-io*) (setf num (read *debug-io*))) (let ((restart (typecase num (unsigned-byte (nth num *debug-restarts*)) (symbol (find num *debug-restarts* :key #'restart-name :test (lambda (sym1 sym2) (string= (symbol-name sym1) (symbol-name sym2))))) (t (format *debug-io* "~S is invalid as a restart name.~%" num) (return-from restart-debug-command nil))))) (/show0 "got RESTART") (if restart (invoke-restart-interactively restart) (princ "There is no such restart." *debug-io*))))) ;;;; information commands (!def-debug-command "HELP" () ;; CMU CL had a little toy pager here, but "if you aren't running ;; ILISP (or a smart windowing system, or something) you deserve to ;; lose", so we've dropped it in SBCL. However, in case some ;; desperate holdout is running this on a dumb terminal somewhere, ;; we tell him where to find the message stored as a string. (format *debug-io* "~&~A~2%(The HELP string is stored in ~S.)~%" *debug-help-string* '*debug-help-string*)) (!def-debug-command-alias "?" "HELP") (!def-debug-command "ERROR" () (format *debug-io* "~A~%" *debug-condition*) (show-restarts *debug-restarts* *debug-io*)) (!def-debug-command "BACKTRACE" () (print-backtrace :count (read-if-available most-positive-fixnum))) (!def-debug-command "PRINT" () (print-frame-call *current-frame* *debug-io*)) (!def-debug-command-alias "P" "PRINT") (!def-debug-command "LIST-LOCALS" () (let ((d-fun (sb!di:frame-debug-fun *current-frame*))) (if (sb!di:debug-var-info-available d-fun) (let ((*standard-output* *debug-io*) (location (sb!di:frame-code-location *current-frame*)) (prefix (read-if-available nil)) (any-p nil) (any-valid-p nil) (more-context nil) (more-count nil)) (dolist (v (sb!di:ambiguous-debug-vars d-fun (if prefix (string prefix) ""))) (setf any-p t) (when (eq (sb!di:debug-var-validity v location) :valid) (setf any-valid-p t) (case (sb!di::debug-var-info v) (:more-context (setf more-context (sb!di:debug-var-value v *current-frame*))) (:more-count (setf more-count (sb!di:debug-var-value v *current-frame*)))) (format *debug-io* "~S~:[#~W~;~*~] = ~S~%" (sb!di:debug-var-symbol v) (zerop (sb!di:debug-var-id v)) (sb!di:debug-var-id v) (sb!di:debug-var-value v *current-frame*)))) (when (and more-context more-count) (format *debug-io* "~S = ~S~%" 'more (multiple-value-list (sb!c:%more-arg-values more-context 0 more-count)))) (cond ((not any-p) (format *debug-io* "There are no local variables ~@[starting with ~A ~]~ in the function." prefix)) ((not any-valid-p) (format *debug-io* "All variables ~@[starting with ~A ~]currently ~ have invalid values." prefix)))) (write-line "There is no variable information available." *debug-io*)))) (!def-debug-command-alias "L" "LIST-LOCALS") (!def-debug-command "SOURCE" () (print (code-location-source-form (sb!di:frame-code-location *current-frame*) (read-if-available 0)) *debug-io*)) ;;;; source location printing (defun code-location-source-form (location context &optional (errorp t)) (let* ((start-location (maybe-block-start-location location)) (form-num (sb!di:code-location-form-number start-location))) (multiple-value-bind (translations form) (sb!di:get-toplevel-form start-location) (cond ((< form-num (length translations)) (sb!di:source-path-context form (svref translations form-num) context)) (t (funcall (if errorp #'error #'warn) "~@")))))) ;;; start single-stepping (!def-debug-command "START" () (if (typep *debug-condition* 'step-condition) (format *debug-io* "~&Already single-stepping.~%") (let ((restart (find-restart 'continue *debug-condition*))) (cond (restart (sb!impl::enable-stepping) (invoke-restart restart)) (t (format *debug-io* "~&Non-continuable error, cannot start stepping.~%")))))) (defmacro def-step-command (command-name restart-name) `(!def-debug-command ,command-name () (if (typep *debug-condition* 'step-condition) (let ((restart (find-restart ',restart-name *debug-condition*))) (aver restart) (invoke-restart restart)) (format *debug-io* "~&Not currently single-stepping. (Use START to activate the single-stepper)~%")))) (def-step-command "STEP" step-into) (def-step-command "NEXT" step-next) (def-step-command "STOP" step-continue) (!def-debug-command-alias "S" "STEP") (!def-debug-command-alias "N" "NEXT") (!def-debug-command "OUT" () (if (typep *debug-condition* 'step-condition) (if sb!impl::*step-out* (let ((restart (find-restart 'step-out *debug-condition*))) (aver restart) (invoke-restart restart)) (format *debug-io* "~&OUT can only be used step out of frames that were originally stepped into with STEP.~%")) (format *debug-io* "~&Not currently single-stepping. (Use START to activate the single-stepper)~%"))) ;;; miscellaneous commands (!def-debug-command "DESCRIBE" () (let* ((curloc (sb!di:frame-code-location *current-frame*)) (debug-fun (sb!di:code-location-debug-fun curloc)) (function (sb!di:debug-fun-fun debug-fun))) (if function (describe function) (format *debug-io* "can't figure out the function for this frame")))) (!def-debug-command "SLURP" () (loop while (read-char-no-hang *standard-input*))) ;;; RETURN-FROM-FRAME and RESTART-FRAME (defun unwind-to-frame-and-call (frame thunk) #!+unwind-to-frame-and-call-vop (flet ((sap-int/fixnum (sap) ;; On unithreaded X86 *BINDING-STACK-POINTER* and ;; *CURRENT-CATCH-BLOCK* are negative, so we need to jump through ;; some hoops to make these calculated values negative too. (ash (truly-the (signed-byte #.sb!vm:n-word-bits) (sap-int sap)) (- sb!vm::n-fixnum-tag-bits)))) ;; To properly unwind the stack, we need three pieces of information: ;; * The unwind block that should be active after the unwind ;; * The catch block that should be active after the unwind ;; * The values that the binding stack pointer should have after the ;; unwind. (let* ((block (sap-int/fixnum (find-enclosing-catch-block frame))) (unbind-to (sap-int/fixnum (find-binding-stack-pointer frame)))) ;; This VOP will run the neccessary cleanup forms, reset the fp, and ;; then call the supplied function. (sb!vm::%primitive sb!vm::unwind-to-frame-and-call (sb!di::frame-pointer frame) (find-enclosing-uwp frame) (lambda () ;; Before calling the user-specified ;; function, we need to restore the binding ;; stack and the catch block. The unwind block ;; is taken care of by the VOP. (sb!vm::%primitive sb!vm::unbind-to-here unbind-to) (setf sb!vm::*current-catch-block* block) (funcall thunk))))) #!-unwind-to-frame-and-call-vop (let ((tag (gensym))) (sb!di:replace-frame-catch-tag frame 'sb!c:debug-catch-tag tag) (throw tag thunk))) (defun find-binding-stack-pointer (frame) #!-stack-grows-downward-not-upward (declare (ignore frame)) #!-stack-grows-downward-not-upward (error "Not implemented on this architecture") #!+stack-grows-downward-not-upward (let ((bsp (sb!vm::binding-stack-pointer-sap)) (unbind-to nil) (fp (sb!di::frame-pointer frame)) (start (int-sap (ldb (byte #.sb!vm:n-word-bits 0) (ash sb!vm:*binding-stack-start* sb!vm:n-fixnum-tag-bits))))) ;; Walk the binding stack looking for an entry where the symbol is ;; an unbound-symbol marker and the value is equal to the frame ;; pointer. These entries are inserted into the stack by the ;; BIND-SENTINEL VOP and removed by UNBIND-SENTINEL (inserted into ;; the function during IR2). If an entry wasn't found, the ;; function that the frame corresponds to wasn't compiled with a ;; high enough debug setting, and can't be restarted / returned ;; from. (loop until (sap= bsp start) do (progn (setf bsp (sap+ bsp (- (* sb!vm:binding-size sb!vm:n-word-bytes)))) (let ((symbol (sap-ref-word bsp (* sb!vm:binding-symbol-slot sb!vm:n-word-bytes))) (value (sap-ref-sap bsp (* sb!vm:binding-value-slot sb!vm:n-word-bytes)))) (when (eql symbol sb!vm:unbound-marker-widetag) (when (sap= value fp) (setf unbind-to bsp)))))) unbind-to)) (defun find-enclosing-catch-block (frame) ;; Walk the catch block chain looking for the first entry with an address ;; higher than the pointer for FRAME or a null pointer. (let* ((frame-pointer (sb!di::frame-pointer frame)) (current-block (int-sap (ldb (byte #.sb!vm:n-word-bits 0) (ash sb!vm::*current-catch-block* sb!vm:n-fixnum-tag-bits)))) (enclosing-block (loop for block = current-block then (sap-ref-sap block (* sb!vm:catch-block-previous-catch-slot sb!vm::n-word-bytes)) when (or (zerop (sap-int block)) (sap> block frame-pointer)) return block))) enclosing-block)) (defun find-enclosing-uwp (frame) ;; Walk the UWP chain looking for the first entry with an address ;; higher than the pointer for FRAME or a null pointer. (let* ((frame-pointer (sb!di::frame-pointer frame)) (current-uwp (int-sap (ldb (byte #.sb!vm:n-word-bits 0) (ash sb!vm::*current-unwind-protect-block* sb!vm:n-fixnum-tag-bits)))) (enclosing-uwp (loop for uwp-block = current-uwp then (sap-ref-sap uwp-block sb!vm:unwind-block-current-uwp-slot) when (or (zerop (sap-int uwp-block)) (sap> uwp-block frame-pointer)) return uwp-block))) enclosing-uwp)) (!def-debug-command "RETURN" (&optional (return (read-prompting-maybe "return: "))) (if (frame-has-debug-tag-p *current-frame*) (let* ((code-location (sb!di:frame-code-location *current-frame*)) (values (multiple-value-list (funcall (sb!di:preprocess-for-eval return code-location) *current-frame*)))) (unwind-to-frame-and-call *current-frame* (lambda () (values-list values)))) (format *debug-io* "~@"))) (!def-debug-command "RESTART-FRAME" () (if (frame-has-debug-tag-p *current-frame*) (multiple-value-bind (fname args) (frame-call *current-frame*) (multiple-value-bind (fun arglist ok) (if (and (legal-fun-name-p fname) (fboundp fname)) (values (fdefinition fname) args t) (values (sb!di:debug-fun-fun (sb!di:frame-debug-fun *current-frame*)) (frame-args-as-list *current-frame*) nil)) (when (and fun (or ok (y-or-n-p "~@"))) (unwind-to-frame-and-call *current-frame* (lambda () ;; Ensure TCO. (declare (optimize (debug 0))) (apply fun arglist)))) (format *debug-io* "Can't restart ~S: no function for frame." *current-frame*))) (format *debug-io* "~@" *current-frame*))) (defun frame-has-debug-tag-p (frame) #!+unwind-to-frame-and-call-vop (not (null (find-binding-stack-pointer frame))) #!-unwind-to-frame-and-call-vop (find 'sb!c:debug-catch-tag (sb!di::frame-catches frame) :key #'car)) (defun frame-has-debug-vars-p (frame) (sb!di:debug-var-info-available (sb!di:code-location-debug-fun (sb!di:frame-code-location frame)))) ;;;; debug loop command utilities (defun read-prompting-maybe (prompt) (unless (sb!int:listen-skip-whitespace *debug-io*) (princ prompt *debug-io*) (force-output *debug-io*)) (read *debug-io*)) (defun read-if-available (default) (if (sb!int:listen-skip-whitespace *debug-io*) (read *debug-io*) default))