1.0.10.29: MUTEX refactoring & optimization

[sbcl.git] / src / code / gc.lisp

;;;; garbage collection and allocation-related code

;;;; 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!KERNEL")
\f
;;;; DYNAMIC-USAGE and friends

(declaim (special sb!vm:*read-only-space-free-pointer*
                  sb!vm:*static-space-free-pointer*))

(eval-when (:compile-toplevel :execute)
  (sb!xc:defmacro def-c-var-fun (lisp-fun c-var-name)
    `(defun ,lisp-fun ()
       (sb!alien:extern-alien ,c-var-name (sb!alien:unsigned 32)))))

#!-sb-fluid
(declaim (inline current-dynamic-space-start))
#!+gencgc
(defun current-dynamic-space-start () sb!vm:dynamic-space-start)
#!-gencgc
(def-c-var-fun current-dynamic-space-start "current_dynamic_space")

#!-sb-fluid
(declaim (inline dynamic-usage))
#!+gencgc
(def-c-var-fun dynamic-usage "bytes_allocated")
#!-gencgc
(defun dynamic-usage ()
  (the (unsigned-byte 32)
       (- (sb!sys:sap-int (sb!c::dynamic-space-free-pointer))
          (current-dynamic-space-start))))

(defun static-space-usage ()
  (- (* sb!vm:*static-space-free-pointer* sb!vm:n-word-bytes)
     sb!vm:static-space-start))

(defun read-only-space-usage ()
  (- (* sb!vm::*read-only-space-free-pointer* sb!vm:n-word-bytes)
     sb!vm:read-only-space-start))

(defun control-stack-usage ()
  #!-stack-grows-downward-not-upward
  (- (sb!sys:sap-int (sb!c::control-stack-pointer-sap))
     (sb!sys:sap-int (sb!di::descriptor-sap sb!vm:*control-stack-start*)))
  #!+stack-grows-downward-not-upward
  (- (sb!sys:sap-int (sb!di::descriptor-sap sb!vm:*control-stack-end*))
     (sb!sys:sap-int (sb!c::control-stack-pointer-sap))))

(defun binding-stack-usage ()
  (- (sb!sys:sap-int (sb!c::binding-stack-pointer-sap))
     (sb!sys:sap-int (sb!di::descriptor-sap sb!vm:*binding-stack-start*))))
\f
;;;; ROOM

(defun room-minimal-info ()
  (format t "Dynamic space usage is:   ~10:D bytes.~%" (dynamic-usage))
  (format t "Read-only space usage is: ~10:D bytes.~%" (read-only-space-usage))
  (format t "Static space usage is:    ~10:D bytes.~%" (static-space-usage))
  (format t "Control stack usage is:   ~10:D bytes.~%" (control-stack-usage))
  (format t "Binding stack usage is:   ~10:D bytes.~%" (binding-stack-usage))
  #!+sb-thread
  (format t
          "Control and binding stack usage is for the current thread only.~%")
  (format t "Garbage collection is currently ~:[enabled~;DISABLED~].~%"
          *gc-inhibit*))

(defun room-intermediate-info ()
  (room-minimal-info)
  (sb!vm:memory-usage :count-spaces '(:dynamic)
                      :print-spaces t
                      :cutoff 0.05f0
                      :print-summary nil))

(defun room-maximal-info ()
  ;; FIXME: SB!VM:INSTANCE-USAGE calls suppressed until bug 344 is fixed
  (room-intermediate-info)
  ;; old way, could be restored when bug 344 fixed:
  ;;x (room-minimal-info)
  ;;x (sb!vm:memory-usage :count-spaces '(:static :dynamic))
  ;;x (sb!vm:instance-usage :dynamic :top-n 10)
  ;;x (sb!vm:instance-usage :static :top-n 10)
  )

(defun room (&optional (verbosity :default))
  #!+sb-doc
  "Print to *STANDARD-OUTPUT* information about the state of internal
  storage and its management. The optional argument controls the
  verbosity of output. If it is T, ROOM prints out a maximal amount of
  information. If it is NIL, ROOM prints out a minimal amount of
  information. If it is :DEFAULT or it is not supplied, ROOM prints out
  an intermediate amount of information."
  (fresh-line)
  (ecase verbosity
    ((t)
     (room-maximal-info))
    ((nil)
     (room-minimal-info))
    (:default
     (room-intermediate-info)))
  (values))
\f
;;;; GET-BYTES-CONSED

;;; the total number of bytes freed so far (including any freeing
;;; which goes on in PURIFY)
;;;
;;; (We save this so that we can calculate the total number of bytes
;;; ever allocated by adding this to the number of bytes currently
;;; allocated and never freed.)
(declaim (type unsigned-byte *n-bytes-freed-or-purified*))
(defvar *n-bytes-freed-or-purified* 0)
(defun gc-reinit ()
  (gc-on)
  (gc)
  (setf *n-bytes-freed-or-purified* 0
        *gc-run-time* 0
        ;; See comment in interr.lisp
        *heap-exhausted-error-condition* (make-condition 'heap-exhausted-error)))

(declaim (ftype (function () unsigned-byte) get-bytes-consed))
(defun get-bytes-consed ()
  #!+sb-doc
  "Return the number of bytes consed since the program began. Typically
this result will be a consed bignum, so if you have an application (e.g.
profiling) which can't tolerate the overhead of consing bignums, you'll
probably want either to hack in at a lower level (as the code in the
SB-PROFILE package does), or to design a more microefficient interface
and submit it as a patch."
  (+ (dynamic-usage)
     *n-bytes-freed-or-purified*))
\f
;;;; GC hooks

(defvar *after-gc-hooks* nil
  "Called after each garbage collection, except for garbage collections
triggered during thread exits. In a multithreaded environment these hooks may
run in any thread.")

\f
;;;; internal GC

(sb!alien:define-alien-routine collect-garbage sb!alien:int
  (#!+gencgc last-gen #!-gencgc ignore sb!alien:int))

#!+sb-thread
(progn
  (sb!alien:define-alien-routine gc-stop-the-world sb!alien:void)
  (sb!alien:define-alien-routine gc-start-the-world sb!alien:void))
#!-sb-thread
(progn
  (defun gc-stop-the-world ())
  (defun gc-start-the-world ()))

\f
;;;; SUB-GC

;;; SUB-GC does a garbage collection.  This is called from three places:
;;; (1) The C runtime will call here when it detects that we've consed
;;;     enough to exceed the gc trigger threshold.  This is done in
;;;     alloc() for gencgc or interrupt_maybe_gc() for cheneygc
;;; (2) The user may request a collection using GC, below
;;; (3) At the end of a WITHOUT-GCING section, we are called if
;;;     *NEED-TO-COLLECT-GARBAGE* is true
;;;
;;; This is different from the behaviour in 0.7 and earlier: it no
;;; longer decides whether to GC based on thresholds.  If you call
;;; SUB-GC you will definitely get a GC either now or when the
;;; WITHOUT-GCING is over

;;; For GENCGC all generations < GEN will be GC'ed.

(defvar *already-in-gc*
  (sb!thread:make-mutex :name "GC lock") "ID of thread running SUB-GC")

;;; A unique GC id. This is supplied for code that needs to detect
;;; whether a GC has happened since some earlier point in time. For
;;; example:
;;;
;;;   (let ((epoch *gc-epoch*))
;;;      ...
;;;      (unless (eql epoch *gc-epoch)
;;;        ....))
;;;
;;; This isn't just a fixnum counter since then we'd have theoretical
;;; problems when exactly 2^29 GCs happen between epoch
;;; comparisons. Unlikely, but the cost of using a cons instead is too
;;; small to measure. -- JES, 2007-09-30
(declaim (type cons *gc-epoch*))
(defvar *gc-epoch* (cons nil nil))

(defun sub-gc (&key (gen 0))
  (unless (eq sb!thread:*current-thread*
              (sb!thread:mutex-value *already-in-gc*))
    ;; With gencgc, unless *GC-PENDING* every allocation in this
    ;; function triggers another gc, potentially exceeding maximum
    ;; interrupt nesting. If *GC-INHIBIT* is not true, however,
    ;; there is no guarantee that we would ever check for pending
    ;; GC -- so in that case we must first disable interrupts, which
    ;; needs to be done for GC anyways...
    (cond (*gc-inhibit*
           (setf *gc-pending* t))
          (t
           (without-interrupts
             (setf *gc-pending* t)
             (sb!thread:with-mutex (*already-in-gc*)
               (let ((old-usage (dynamic-usage))
                     (new-usage 0))
                 (unsafe-clear-roots)

                 (gc-stop-the-world)
                 (let ((start-time (get-internal-run-time)))
                   (collect-garbage gen)
                   (setf *gc-epoch* (cons nil nil))
                   (incf *gc-run-time*
                         (- (get-internal-run-time) start-time)))
                 (setf *gc-pending* nil
                       new-usage (dynamic-usage))
                 (gc-start-the-world)

                 ;; In a multithreaded environment the other threads will
                 ;; see *n-b-f-o-p* change a little late, but that's OK.
                 (let ((freed (- old-usage new-usage)))
                   ;; GENCGC occasionally reports negative here, but the
                   ;; current belief is that it is part of the normal order
                   ;; of things and not a bug.
                   (when (plusp freed)
                     (incf *n-bytes-freed-or-purified* freed))))))

           ;; Outside the mutex, interrupts enabled: these may cause
           ;; another GC. FIXME: it can potentially exceed maximum
           ;; interrupt nesting by triggering GCs.
           ;;
           ;; Can that be avoided by having the finalizers and hooks
           ;; run only from the outermost SUB-GC?
           ;;
           ;; KLUDGE: Don't run the hooks in GC's triggered by dying
           ;; threads, so that user-code never runs with
           ;;   (thread-alive-p *current-thread*) => nil
           ;; The long-term solution will be to keep a separate thread
           ;; for finalizers and after-gc hooks.
           (when (sb!thread:thread-alive-p sb!thread:*current-thread*)
             (run-pending-finalizers)
             (dolist (hook *after-gc-hooks*)
               (handler-case
                   (funcall hook)
                 (serious-condition (c)
                   (warn "Error calling after-GC hook ~S:~% ~A" hook c)))))))))

;;; This is the user-advertised garbage collection function.
(defun gc (&key (gen 0) (full nil) &allow-other-keys)
  #!+(and sb-doc gencgc)
  "Initiate a garbage collection. GEN controls the number of generations
  to garbage collect."
  #!+(and sb-doc (not gencgc))
  "Initiate a garbage collection. GEN may be provided for compatibility with
  generational garbage collectors, but is ignored in this implementation."
  (sub-gc :gen (if full 6 gen)))

(defun unsafe-clear-roots ()
  ;; KLUDGE: Do things in an attempt to get rid of extra roots. Unsafe
  ;; as having these cons more then we have space left leads to huge
  ;; badness.
  (scrub-control-stack)
  ;; Power cache of the bignum printer: drops overly large bignums and
  ;; removes duplicate entries.
  (scrub-power-cache)
  ;; FIXME: CTYPE-OF-CACHE-CLEAR isn't thread-safe.
  #!-sb-thread
  (ctype-of-cache-clear))

\f
;;;; auxiliary functions

(defun bytes-consed-between-gcs ()
  #!+sb-doc
  "Return the amount of memory that will be allocated before the next garbage
   collection is initiated. This can be set with SETF."
  (sb!alien:extern-alien "bytes_consed_between_gcs"
                         (sb!alien:unsigned 32)))

(defun (setf bytes-consed-between-gcs) (val)
  (declare (type index val))
  (setf (sb!alien:extern-alien "bytes_consed_between_gcs"
                               (sb!alien:unsigned 32))
        val))

(declaim (inline maybe-handle-pending-gc))
(defun maybe-handle-pending-gc ()
  (when (and (not *gc-inhibit*)
             (or #!+sb-thread *stop-for-gc-pending*
                 *gc-pending*))
    (sb!unix::receive-pending-interrupt)))

;;; These work both regardless of whether we're inside WITHOUT-GCING
;;; or not.
(defun gc-on ()
  #!+sb-doc
  "Enable the garbage collector."
  (setq *gc-inhibit* nil)
  (maybe-handle-pending-gc)
  nil)

(defun gc-off ()
  #!+sb-doc
  "Disable the garbage collector."
  (setq *gc-inhibit* t)
  nil)