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 ;;; Repl commands
;; Copyright (C) 2001, 2009, 2010, 2011, 2013 Free Software Foundation, Inc.
;; This library is free software; you can redistribute it and/or
;; modify it under the terms of the GNU Lesser General Public
;; License as published by the Free Software Foundation; either
;; version 3 of the License, or (at your option) any later version.
;;
;; This library is distributed in the hope that it will be useful,
;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
;; Lesser General Public License for more details.
;;
;; You should have received a copy of the GNU Lesser General Public
;; License along with this library; if not, write to the Free Software
;; Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
;; 02110-1301 USA
;;; Code:
(define-module (system repl command)
#:use-module (system base syntax)
#:use-module (system base pmatch)
#:use-module (system base compile)
#:use-module (system repl common)
#:use-module (system repl debug)
#:use-module (system vm objcode)
#:use-module (system vm program)
#:use-module (system vm trap-state)
#:use-module (system vm vm)
#:use-module ((system vm frame) #:select (frame-return-values))
#:autoload (system base language) (lookup-language language-reader)
#:autoload (system vm trace) (call-with-trace)
#:use-module (ice-9 format)
#:use-module (ice-9 session)
#:use-module (ice-9 documentation)
#:use-module (ice-9 and-let-star)
#:use-module (ice-9 rdelim)
#:use-module (ice-9 control)
#:use-module ((ice-9 pretty-print) #:select ((pretty-print . pp)))
#:use-module ((system vm inspect) #:select ((inspect . %inspect)))
#:use-module (statprof)
#:export (meta-command define-meta-command))
;;;
;;; Meta command interface
;;;
(define *command-table*
'((help (help h) (show) (apropos a) (describe d))
(module (module m) (import use) (load l) (reload re) (binding b) (in))
(language (language L))
(compile (compile c) (compile-file cc)
(expand exp) (optimize opt)
(disassemble x) (disassemble-file xx))
(profile (time t) (profile pr) (trace tr))
(debug (backtrace bt) (up) (down) (frame fr)
(procedure proc) (locals) (error-message error)
(break br bp) (break-at-source break-at bs)
(step s) (step-instruction si)
(next n) (next-instruction ni)
(finish)
(tracepoint tp)
(traps) (delete del) (disable) (enable)
(registers regs))
(inspect (inspect i) (pretty-print pp))
(system (gc) (statistics stat) (option o)
(quit q continue cont))))
(define *show-table*
'((show (warranty w) (copying c) (version v))))
(define (group-name g) (car g))
(define (group-commands g) (cdr g))
(define *command-infos* (make-hash-table))
(define (command-name c) (car c))
(define (command-abbrevs c) (cdr c))
(define (command-info c) (hashq-ref *command-infos* (command-name c)))
(define (command-procedure c) (command-info-procedure (command-info c)))
(define (command-doc c) (procedure-documentation (command-procedure c)))
(define (make-command-info proc arguments-reader)
(cons proc arguments-reader))
(define (command-info-procedure info)
(car info))
(define (command-info-arguments-reader info)
(cdr info))
(define (command-usage c)
(let ((doc (command-doc c)))
(substring doc 0 (string-index doc #\newline))))
(define (command-summary c)
(let* ((doc (command-doc c))
(start (1+ (string-index doc #\newline))))
(cond ((string-index doc #\newline start)
=> (lambda (end) (substring doc start end)))
(else (substring doc start)))))
(define (lookup-group name)
(assq name *command-table*))
(define* (lookup-command key #:optional (table *command-table*))
(let loop ((groups table) (commands '()))
(cond ((and (null? groups) (null? commands)) #f)
((null? commands)
(loop (cdr groups) (cdar groups)))
((memq key (car commands)) (car commands))
(else (loop groups (cdr commands))))))
(define* (display-group group #:optional (abbrev? #t))
(format #t "~:(~A~) Commands~:[~; [abbrev]~]:~2%" (group-name group) abbrev?)
(for-each (lambda (c)
(display-summary (command-usage c)
(if abbrev? (command-abbrevs c) '())
(command-summary c)))
(group-commands group))
(newline))
(define (display-command command)
(display "Usage: ")
(display (command-doc command))
(newline))
(define (display-summary usage abbrevs summary)
(let* ((usage-len (string-length usage))
(abbrevs (if (pair? abbrevs)
(format #f "[,~A~{ ,~A~}]" (car abbrevs) (cdr abbrevs))
""))
(abbrevs-len (string-length abbrevs)))
(format #t " ,~A~A~A - ~A\n"
usage
(cond
((> abbrevs-len 32)
(error "abbrevs too long" abbrevs))
((> (+ usage-len abbrevs-len) 32)
(format #f "~%~v_" (+ 2 (- 32 abbrevs-len))))
(else
(format #f "~v_" (- 32 abbrevs-len usage-len))))
abbrevs
summary)))
(define (read-command repl)
(catch #t
(lambda () (read))
(lambda (key . args)
(pmatch args
((,subr ,msg ,args . ,rest)
(format #t "Throw to key `~a' while reading command:\n" key)
(display-error #f (current-output-port) subr msg args rest))
(else
(format #t "Throw to key `~a' with args `~s' while reading command.\n"
key args)))
(force-output)
*unspecified*)))
(define (read-command-arguments c repl)
((command-info-arguments-reader (command-info c)) repl))
(define (meta-command repl)
(let ((command (read-command repl)))
(cond
((eq? command *unspecified*)) ; read error, already signalled; pass.
((not (symbol? command))
(format #t "Meta-command not a symbol: ~s~%" command))
((lookup-command command)
=> (lambda (c)
(and=> (read-command-arguments c repl)
(lambda (args) (apply (command-procedure c) repl args)))))
(else
(format #t "Unknown meta command: ~A~%" command)))))
(define (add-meta-command! name category proc argument-reader)
(hashq-set! *command-infos* name (make-command-info proc argument-reader))
(if category
(let ((entry (assq category *command-table*)))
(if entry
(set-cdr! entry (append (cdr entry) (list (list name))))
(set! *command-table*
(append *command-table*
(list (list category (list name)))))))))
(define-syntax define-meta-command
(syntax-rules ()
((_ ((name category) repl (expression0 ...) . datums) docstring b0 b1 ...)
(add-meta-command!
'name
'category
(lambda* (repl expression0 ... . datums)
docstring
b0 b1 ...)
(lambda (repl)
(define (handle-read-error form-name key args)
(pmatch args
((,subr ,msg ,args . ,rest)
(format #t "Throw to key `~a' while reading ~@[argument `~A' of ~]command `~A':\n"
key form-name 'name)
(display-error #f (current-output-port) subr msg args rest))
(else
(format #t "Throw to key `~a' with args `~s' while reading ~@[ argument `~A' of ~]command `~A'.\n"
key args form-name 'name)))
(abort))
(% (let* ((expression0
(catch #t
(lambda ()
(repl-reader
""
(lambda* (#:optional (port (current-input-port)))
((language-reader (repl-language repl))
port (current-module)))))
(lambda (k . args)
(handle-read-error 'expression0 k args))))
...)
(append
(list expression0 ...)
(catch #t
(lambda ()
(let ((port (open-input-string (read-line))))
(let lp ((out '()))
(let ((x (read port)))
(if (eof-object? x)
(reverse out)
(lp (cons x out)))))))
(lambda (k . args)
(handle-read-error #f k args)))))
(lambda (k) #f))))) ; the abort handler
((_ ((name category) repl . datums) docstring b0 b1 ...)
(define-meta-command ((name category) repl () . datums)
docstring b0 b1 ...))
((_ (name repl (expression0 ...) . datums) docstring b0 b1 ...)
(define-meta-command ((name #f) repl (expression0 ...) . datums)
docstring b0 b1 ...))
((_ (name repl . datums) docstring b0 b1 ...)
(define-meta-command ((name #f) repl () . datums)
docstring b0 b1 ...))))
;;;
;;; Help commands
;;;
(define-meta-command (help repl . args)
"help [all | GROUP | [-c] COMMAND]
Show help.
With one argument, tries to look up the argument as a group name, giving
help on that group if successful. Otherwise tries to look up the
argument as a command, giving help on the command.
If there is a command whose name is also a group name, use the ,help
-c COMMAND form to give help on the command instead of the group.
Without any argument, a list of help commands and command groups
are displayed."
(pmatch args
(()
(display-group (lookup-group 'help))
(display "Command Groups:\n\n")
(display-summary "help all" #f "List all commands")
(for-each (lambda (g)
(let* ((name (symbol->string (group-name g)))
(usage (string-append "help " name))
(header (string-append "List " name " commands")))
(display-summary usage #f header)))
(cdr *command-table*))
(newline)
(display
"Type `,help -c COMMAND' to show documentation of a particular command.")
(newline))
((all)
(for-each display-group *command-table*))
((,group) (guard (lookup-group group))
(display-group (lookup-group group)))
((,command) (guard (lookup-command command))
(display-command (lookup-command command)))
((-c ,command) (guard (lookup-command command))
(display-command (lookup-command command)))
((,command)
(format #t "Unknown command or group: ~A~%" command))
((-c ,command)
(format #t "Unknown command: ~A~%" command))
(else
(format #t "Bad arguments: ~A~%" args))))
(define-meta-command (show repl . args)
"show [TOPIC]
Gives information about Guile.
With one argument, tries to show a particular piece of information;
currently supported topics are `warranty' (or `w'), `copying' (or `c'),
and `version' (or `v').
Without any argument, a list of topics is displayed."
(pmatch args
(()
(display-group (car *show-table*) #f)
(newline))
((,topic) (guard (lookup-command topic *show-table*))
((command-procedure (lookup-command topic *show-table*)) repl))
((,command)
(format #t "Unknown topic: ~A~%" command))
(else
(format #t "Bad arguments: ~A~%" args))))
;;; `warranty', `copying' and `version' are "hidden" meta-commands, only
;;; accessible via `show'. They have an entry in *command-infos* but not
;;; in *command-table*.
(define-meta-command (warranty repl)
"show warranty
Details on the lack of warranty."
(display *warranty*)
(newline))
(define-meta-command (copying repl)
"show copying
Show the LGPLv3."
(display *copying*)
(newline))
(define-meta-command (version repl)
"show version
Version information."
(display *version*)
(newline))
(define-meta-command (apropos repl regexp)
"apropos REGEXP
Find bindings/modules/packages."
(apropos (->string regexp)))
(define-meta-command (describe repl (form))
"describe OBJ
Show description/documentation."
(display
(object-documentation
(let ((input (repl-parse repl form)))
(if (symbol? input)
(module-ref (current-module) input)
(repl-eval repl input)))))
(newline))
(define-meta-command (option repl . args)
"option [NAME] [EXP]
List/show/set options."
(pmatch args
(()
(for-each (lambda (spec)
(format #t " ~A~24t~A\n" (car spec) (cadr spec)))
(repl-options repl)))
((,name)
(display (repl-option-ref repl name))
(newline))
((,name ,exp)
;; Would be nice to evaluate in the current language, but the REPL
;; option parser doesn't permit that, currently.
(repl-option-set! repl name (eval exp (current-module))))))
(define-meta-command (quit repl)
"quit
Quit this session."
(throw 'quit))
;;;
;;; Module commands
;;;
(define-meta-command (module repl . args)
"module [MODULE]
Change modules / Show current module."
(pmatch args
(() (puts (module-name (current-module))))
((,mod-name) (guard (list? mod-name))
(set-current-module (resolve-module mod-name)))
(,mod-name (set-current-module (resolve-module mod-name)))))
(define-meta-command (import repl . args)
"import [MODULE ...]
Import modules / List those imported."
(let ()
(define (use name)
(let ((mod (resolve-interface name)))
(if mod
(module-use! (current-module) mod)
(format #t "No such module: ~A~%" name))))
(if (null? args)
(for-each puts (map module-name (module-uses (current-module))))
(for-each use args))))
(define-meta-command (load repl file)
"load FILE
Load a file in the current module."
(load (->string file)))
(define-meta-command (reload repl . args)
"reload [MODULE]
Reload the given module, or the current module if none was given."
(pmatch args
(() (reload-module (current-module)))
((,mod-name) (guard (list? mod-name))
(reload-module (resolve-module mod-name)))
(,mod-name (reload-module (resolve-module mod-name)))))
(define-meta-command (binding repl)
"binding
List current bindings."
(module-for-each (lambda (k v) (format #t "~23A ~A\n" k v))
(current-module)))
(define-meta-command (in repl module command-or-expression . args)
"in MODULE COMMAND-OR-EXPRESSION
Evaluate an expression or command in the context of module."
(let ((m (resolve-module module #:ensure #f)))
(if m
(pmatch command-or-expression
(('unquote ,command) (guard (lookup-command command))
(save-module-excursion
(lambda ()
(set-current-module m)
(apply (command-procedure (lookup-command command)) repl args))))
(,expression
(guard (null? args))
(repl-print repl (eval expression m)))
(else
(format #t "Invalid arguments to `in': expected a single expression or a command.\n")))
(format #t "No such module: ~s\n" module))))
;;;
;;; Language commands
;;;
(define-meta-command (language repl name)
"language LANGUAGE
Change languages."
(let ((lang (lookup-language name))
(cur (repl-language repl)))
(format #t "Happy hacking with ~a! To switch back, type `,L ~a'.\n"
(language-title lang) (language-name cur))
(current-language lang)
(set! (repl-language repl) lang)))
;;;
;;; Compile commands
;;;
(define-meta-command (compile repl (form))
"compile EXP
Generate compiled code."
(let ((x (repl-compile repl (repl-parse repl form))))
(cond ((objcode? x) (guile:disassemble x))
(else (repl-print repl x)))))
(define-meta-command (compile-file repl file . opts)
"compile-file FILE
Compile a file."
(compile-file (->string file) #:opts opts))
(define-meta-command (expand repl (form))
"expand EXP
Expand any macros in a form."
(let ((x (repl-expand repl (repl-parse repl form))))
(run-hook before-print-hook x)
(pp x)))
(define-meta-command (optimize repl (form))
"optimize EXP
Run the optimizer on a piece of code and print the result."
(let ((x (repl-optimize repl (repl-parse repl form))))
(run-hook before-print-hook x)
(pp x)))
(define (guile:disassemble x)
((@ (language assembly disassemble) disassemble) x))
(define-meta-command (disassemble repl (form))
"disassemble EXP
Disassemble a compiled procedure."
(let ((obj (repl-eval repl (repl-parse repl form))))
(if (or (program? obj) (objcode? obj))
(guile:disassemble obj)
(format #t "Argument to ,disassemble not a procedure or objcode: ~a~%"
obj))))
(define-meta-command (disassemble-file repl file)
"disassemble-file FILE
Disassemble a file."
(guile:disassemble (load-objcode (->string file))))
;;;
;;; Profile commands
;;;
(define-meta-command (time repl (form))
"time EXP
Time execution."
(let* ((gc-start (gc-run-time))
(real-start (get-internal-real-time))
(run-start (get-internal-run-time))
(result (repl-eval repl (repl-parse repl form)))
(run-end (get-internal-run-time))
(real-end (get-internal-real-time))
(gc-end (gc-run-time)))
(define (diff start end)
(/ (- end start) 1.0 internal-time-units-per-second))
(repl-print repl result)
(format #t ";; ~,6Fs real time, ~,6Fs run time. ~,6Fs spent in GC.\n"
(diff real-start real-end)
(diff run-start run-end)
(diff gc-start gc-end))
result))
(define-meta-command (profile repl (form) . opts)
"profile EXP
Profile execution."
;; FIXME opts
(apply statprof
(repl-prepare-eval-thunk repl (repl-parse repl form))
opts))
(define-meta-command (trace repl (form) . opts)
"trace EXP
Trace execution."
;; FIXME: doc options, or somehow deal with them better
(apply call-with-trace
(repl-prepare-eval-thunk repl (repl-parse repl form))
(cons* #:width (terminal-width) opts)))
;;;
;;; Debug commands
;;;
(define-syntax define-stack-command
(lambda (x)
(syntax-case x ()
((_ (name repl . args) docstring body body* ...)
#`(define-meta-command (name repl . args)
docstring
(let ((debug (repl-debug repl)))
(if debug
(letrec-syntax
((#,(datum->syntax #'repl 'frames)
(identifier-syntax (debug-frames debug)))
(#,(datum->syntax #'repl 'message)
(identifier-syntax (debug-error-message debug)))
(#,(datum->syntax #'repl 'for-trap?)
(identifier-syntax (debug-for-trap? debug)))
(#,(datum->syntax #'repl 'index)
(identifier-syntax
(id (debug-index debug))
((set! id exp) (set! (debug-index debug) exp))))
(#,(datum->syntax #'repl 'cur)
(identifier-syntax
(vector-ref #,(datum->syntax #'repl 'frames)
#,(datum->syntax #'repl 'index)))))
body body* ...)
(format #t "Nothing to debug.~%"))))))))
(define-stack-command (backtrace repl #:optional count
#:key (width (terminal-width)) full?)
"backtrace [COUNT] [#:width W] [#:full? F]
Print a backtrace.
Print a backtrace of all stack frames, or innermost COUNT frames.
If COUNT is negative, the last COUNT frames will be shown."
(print-frames frames
#:count count
#:width width
#:full? full?
#:for-trap? for-trap?))
(define-stack-command (up repl #:optional (count 1))
"up [COUNT]
Select a calling stack frame.
Select and print stack frames that called this one.
An argument says how many frames up to go."
(cond
((or (not (integer? count)) (<= count 0))
(format #t "Invalid argument to `up': expected a positive integer for COUNT.~%"))
((>= (+ count index) (vector-length frames))
(cond
((= index (1- (vector-length frames)))
(format #t "Already at outermost frame.\n"))
(else
(set! index (1- (vector-length frames)))
(print-frame cur #:index index
#:next-source? (and (zero? index) for-trap?)))))
(else
(set! index (+ count index))
(print-frame cur #:index index
#:next-source? (and (zero? index) for-trap?)))))
(define-stack-command (down repl #:optional (count 1))
"down [COUNT]
Select a called stack frame.
Select and print stack frames called by this one.
An argument says how many frames down to go."
(cond
((or (not (integer? count)) (<= count 0))
(format #t "Invalid argument to `down': expected a positive integer for COUNT.~%"))
((< (- index count) 0)
(cond
((zero? index)
(format #t "Already at innermost frame.\n"))
(else
(set! index 0)
(print-frame cur #:index index #:next-source? for-trap?))))
(else
(set! index (- index count))
(print-frame cur #:index index
#:next-source? (and (zero? index) for-trap?)))))
(define-stack-command (frame repl #:optional idx)
"frame [IDX]
Show a frame.
Show the selected frame.
With an argument, select a frame by index, then show it."
(cond
(idx
(cond
((or (not (integer? idx)) (< idx 0))
(format #t "Invalid argument to `frame': expected a non-negative integer for IDX.~%"))
((< idx (vector-length frames))
(set! index idx)
(print-frame cur #:index index
#:next-source? (and (zero? index) for-trap?)))
(else
(format #t "No such frame.~%"))))
(else (print-frame cur #:index index
#:next-source? (and (zero? index) for-trap?)))))
(define-stack-command (procedure repl)
"procedure
Print the procedure for the selected frame."
(repl-print repl (frame-procedure cur)))
(define-stack-command (locals repl #:key (width (terminal-width)))
"locals
Show local variables.
Show locally-bound variables in the selected frame."
(print-locals cur #:width width))
(define-stack-command (error-message repl)
"error-message
Show error message.
Display the message associated with the error that started the current
debugging REPL."
(format #t "~a~%" (if (string? message) message "No error message")))
(define-meta-command (break repl (form))
"break PROCEDURE
Break on calls to PROCEDURE.
Starts a recursive prompt when PROCEDURE is called."
(let ((proc (repl-eval repl (repl-parse repl form))))
(if (not (procedure? proc))
(error "Not a procedure: ~a" proc)
(let ((idx (add-trap-at-procedure-call! proc)))
(format #t "Trap ~a: ~a.~%" idx (trap-name idx))))))
(define-meta-command (break-at-source repl file line)
"break-at-source FILE LINE
Break when control reaches the given source location.
Starts a recursive prompt when control reaches line LINE of file FILE.
Note that the given source location must be inside a procedure."
(let ((file (if (symbol? file) (symbol->string file) file)))
(let ((idx (add-trap-at-source-location! file line)))
(format #t "Trap ~a: ~a.~%" idx (trap-name idx)))))
(define (repl-pop-continuation-resumer repl msg)
;; Capture the dynamic environment with this prompt thing. The
;; result is a procedure that takes a frame.
(% (call-with-values
(lambda ()
(abort
(lambda (k)
;; Call frame->stack-vector before reinstating the
;; continuation, so that we catch the %stacks fluid at
;; the time of capture.
(lambda (frame)
(k frame
(frame->stack-vector
(frame-previous frame)))))))
(lambda (from stack)
(format #t "~a~%" msg)
(let ((vals (frame-return-values from)))
(if (null? vals)
(format #t "No return values.~%")
(begin
(format #t "Return values:~%")
(for-each (lambda (x) (repl-print repl x)) vals))))
((module-ref (resolve-interface '(system repl repl)) 'start-repl)
#:debug (make-debug stack 0 msg #t))))))
(define-stack-command (finish repl)
"finish
Run until the current frame finishes.
Resume execution, breaking when the current frame finishes."
(let ((handler (repl-pop-continuation-resumer
repl (format #f "Return from ~a" cur))))
(add-ephemeral-trap-at-frame-finish! cur handler)
(throw 'quit)))
(define (repl-next-resumer msg)
;; Capture the dynamic environment with this prompt thing. The
;; result is a procedure that takes a frame.
(% (let ((stack (abort
(lambda (k)
;; Call frame->stack-vector before reinstating the
;; continuation, so that we catch the %stacks fluid
;; at the time of capture.
(lambda (frame)
(k (frame->stack-vector frame)))))))
(format #t "~a~%" msg)
((module-ref (resolve-interface '(system repl repl)) 'start-repl)
#:debug (make-debug stack 0 msg #t)))))
(define-stack-command (step repl)
"step
Step until control reaches a different source location.
Step until control reaches a different source location."
(let ((msg (format #f "Step into ~a" cur)))
(add-ephemeral-stepping-trap! cur (repl-next-resumer msg)
#:into? #t #:instruction? #f)
(throw 'quit)))
(define-stack-command (step-instruction repl)
"step-instruction
Step until control reaches a different instruction.
Step until control reaches a different VM instruction."
(let ((msg (format #f "Step into ~a" cur)))
(add-ephemeral-stepping-trap! cur (repl-next-resumer msg)
#:into? #t #:instruction? #t)
(throw 'quit)))
(define-stack-command (next repl)
"next
Step until control reaches a different source location in the current frame.
Step until control reaches a different source location in the current frame."
(let ((msg (format #f "Step into ~a" cur)))
(add-ephemeral-stepping-trap! cur (repl-next-resumer msg)
#:into? #f #:instruction? #f)
(throw 'quit)))
(define-stack-command (next-instruction repl)
"next-instruction
Step until control reaches a different instruction in the current frame.
Step until control reaches a different VM instruction in the current frame."
(let ((msg (format #f "Step into ~a" cur)))
(add-ephemeral-stepping-trap! cur (repl-next-resumer msg)
#:into? #f #:instruction? #t)
(throw 'quit)))
(define-meta-command (tracepoint repl (form))
"tracepoint PROCEDURE
Add a tracepoint to PROCEDURE.
A tracepoint will print out the procedure and its arguments, when it is
called, and its return value(s) when it returns."
(let ((proc (repl-eval repl (repl-parse repl form))))
(if (not (procedure? proc))
(error "Not a procedure: ~a" proc)
(let ((idx (add-trace-at-procedure-call! proc)))
(format #t "Trap ~a: ~a.~%" idx (trap-name idx))))))
(define-meta-command (traps repl)
"traps
Show the set of currently attached traps.
Show the set of currently attached traps (breakpoints and tracepoints)."
(let ((traps (list-traps)))
(if (null? traps)
(format #t "No traps set.~%")
(for-each (lambda (idx)
(format #t " ~a: ~a~a~%"
idx (trap-name idx)
(if (trap-enabled? idx) "" " (disabled)")))
traps))))
(define-meta-command (delete repl idx)
"delete IDX
Delete a trap.
Delete a trap."
(if (not (integer? idx))
(error "expected a trap index (a non-negative integer)" idx)
(delete-trap! idx)))
(define-meta-command (disable repl idx)
"disable IDX
Disable a trap.
Disable a trap."
(if (not (integer? idx))
(error "expected a trap index (a non-negative integer)" idx)
(disable-trap! idx)))
(define-meta-command (enable repl idx)
"enable IDX
Enable a trap.
Enable a trap."
(if (not (integer? idx))
(error "expected a trap index (a non-negative integer)" idx)
(enable-trap! idx)))
(define-stack-command (registers repl)
"registers
Print registers.
Print the registers of the current frame."
(print-registers cur))
(define-meta-command (width repl #:optional x)
"width [X]
Set debug output width.
Set the number of screen columns in the output from `backtrace' and
`locals'."
(terminal-width x)
(format #t "Set screen width to ~a columns.~%" (terminal-width)))
;;;
;;; Inspection commands
;;;
(define-meta-command (inspect repl (form))
"inspect EXP
Inspect the result(s) of evaluating EXP."
(call-with-values (repl-prepare-eval-thunk repl (repl-parse repl form))
(lambda args
(for-each %inspect args))))
(define-meta-command (pretty-print repl (form))
"pretty-print EXP
Pretty-print the result(s) of evaluating EXP."
(call-with-values (repl-prepare-eval-thunk repl (repl-parse repl form))
(lambda args
(for-each
(lambda (x)
(run-hook before-print-hook x)
(pp x))
args))))
;;;
;;; System commands
;;;
(define-meta-command (gc repl)
"gc
Garbage collection."
(gc))
(define-meta-command (statistics repl)
"statistics
Display statistics."
(let ((this-tms (times))
(this-gcs (gc-stats))
(last-tms (repl-tm-stats repl))
(last-gcs (repl-gc-stats repl)))
;; GC times
(let ((this-times (assq-ref this-gcs 'gc-times))
(last-times (assq-ref last-gcs 'gc-times)))
(display-diff-stat "GC times:" #t this-times last-times "times")
(newline))
;; Memory size
(let ((this-heap (assq-ref this-gcs 'heap-size))
(this-free (assq-ref this-gcs 'heap-free-size)))
(display-stat-title "Memory size:" "current" "limit")
(display-stat "heap" #f (- this-heap this-free) this-heap "bytes")
(newline))
;; Cells collected
(let ((this-alloc (assq-ref this-gcs 'heap-total-allocated))
(last-alloc (assq-ref last-gcs 'heap-total-allocated)))
(display-stat-title "Bytes allocated:" "diff" "total")
(display-diff-stat "allocated" #f this-alloc last-alloc "bytes")
(newline))
;; GC time taken
(let ((this-total (assq-ref this-gcs 'gc-time-taken))
(last-total (assq-ref last-gcs 'gc-time-taken)))
(display-stat-title "GC time taken:" "diff" "total")
(display-time-stat "total" this-total last-total)
(newline))
;; Process time spent
(let ((this-utime (tms:utime this-tms))
(last-utime (tms:utime last-tms))
(this-stime (tms:stime this-tms))
(last-stime (tms:stime last-tms))
(this-cutime (tms:cutime this-tms))
(last-cutime (tms:cutime last-tms))
(this-cstime (tms:cstime this-tms))
(last-cstime (tms:cstime last-tms)))
(display-stat-title "Process time spent:" "diff" "total")
(display-time-stat "user" this-utime last-utime)
(display-time-stat "system" this-stime last-stime)
(display-time-stat "child user" this-cutime last-cutime)
(display-time-stat "child system" this-cstime last-cstime)
(newline))
;; Save statistics
;; Save statistics
(set! (repl-tm-stats repl) this-tms)
(set! (repl-gc-stats repl) this-gcs)))
(define (display-stat title flag field1 field2 unit)
(let ((fmt (format #f "~~20~AA ~~10@A /~~10@A ~~A~~%" (if flag "" "@"))))
(format #t fmt title field1 field2 unit)))
(define (display-stat-title title field1 field2)
(display-stat title #t field1 field2 ""))
(define (display-diff-stat title flag this last unit)
(display-stat title flag (- this last) this unit))
(define (display-time-stat title this last)
(define (conv num)
(format #f "~10,2F" (exact->inexact (/ num internal-time-units-per-second))))
(display-stat title #f (conv (- this last)) (conv this) "s"))
(define (display-mips-stat title this-time this-clock last-time last-clock)
(define (mips time clock)
(if (= time 0) "----" (format #f "~10,2F" (/ clock time 1000000.0))))
(display-stat title #f
(mips (- this-time last-time) (- this-clock last-clock))
(mips this-time this-clock) "mips"))