(in-package "SB!IMPL")
-(defconstant sb!xc:internal-time-units-per-second 1000
- #!+sb-doc
- "The number of internal time units that fit into a second. See
- GET-INTERNAL-REAL-TIME and GET-INTERNAL-RUN-TIME.")
-
-(defconstant micro-seconds-per-internal-time-unit
- (/ 1000000 sb!xc:internal-time-units-per-second))
-\f
-;;; The base number of seconds for our internal "epoch". We initialize
-;;; this to the time of the first call to GET-INTERNAL-REAL-TIME, and
-;;; then subtract this out of the result.
-(defvar *internal-real-time-base-seconds* nil)
-(declaim (type (or (unsigned-byte 32) null) *internal-real-time-base-seconds*))
+(defun time-reinit ()
+ (reinit-internal-real-time))
-(defun get-internal-real-time ()
- #!+sb-doc
- "Return the real time in the internal time format. (See
- INTERNAL-TIME-UNITS-PER-SECOND.) This is useful for finding elapsed time."
- (multiple-value-bind (ignore seconds useconds) (sb!unix:unix-gettimeofday)
- (declare (ignore ignore) (type (unsigned-byte 32) seconds useconds))
- (let ((base *internal-real-time-base-seconds*)
- (uint (truncate useconds
- micro-seconds-per-internal-time-unit)))
- (declare (type (unsigned-byte 32) uint))
- (cond (base
- (truly-the (unsigned-byte 32)
- (+ (the (unsigned-byte 32)
- (* (the (unsigned-byte 32) (- seconds base))
- sb!xc:internal-time-units-per-second))
- uint)))
- (t
- (setq *internal-real-time-base-seconds* seconds)
- uint)))))
+;;; Implemented in unix.lisp and win32.lisp.
+#!+sb-doc
+(setf (fdocumentation 'get-internal-real-time 'function)
+ "Return the real time (\"wallclock time\") since startup in the internal
+time format. (See INTERNAL-TIME-UNITS-PER-SECOND.)")
(defun get-internal-run-time ()
#!+sb-doc
- "Return the run time in the internal time format. (See
- INTERNAL-TIME-UNITS-PER-SECOND.) This is useful for finding CPU usage."
- (declare (values (unsigned-byte 32)))
- (multiple-value-bind (ignore utime-sec utime-usec stime-sec stime-usec)
- (sb!unix:unix-fast-getrusage sb!unix:rusage_self)
- (declare (ignore ignore)
- (type (unsigned-byte 31) utime-sec stime-sec)
- ;; (Classic CMU CL had these (MOD 1000000) instead, but
- ;; at least in Linux 2.2.12, the type doesn't seem to be
- ;; documented anywhere and the observed behavior is to
- ;; sometimes return 1000000 exactly.)
- (type (integer 0 1000000) utime-usec stime-usec))
- (let ((result (+ (the (unsigned-byte 32)
- (* (the (unsigned-byte 32) (+ utime-sec stime-sec))
- sb!xc:internal-time-units-per-second))
- (floor (+ utime-usec
- stime-usec
- (floor micro-seconds-per-internal-time-unit 2))
- micro-seconds-per-internal-time-unit))))
- result)))
+ "Return the run time used by the process in the internal time format. (See
+INTERNAL-TIME-UNITS-PER-SECOND.) This is useful for finding CPU usage.
+Includes both \"system\" and \"user\" time."
+ (system-internal-run-time))
\f
;;;; Encode and decode universal times.
;;; number of seconds since 1970-01-01
;;; I'm obliged to Erik Naggum's "Long, Painful History of Time" paper
-;;; <http://heim.ifi.uio.no/~enag/lugm-time.html> for the choice of epoch
-;;; here. By starting the year in March, we avoid having to test the month
-;;; whenever deciding whether to account for a leap day. 2000 is especially
-;;; special, because it's disvisible by 400, hence the start of a 400 year
-;;; leap year cycle
+;;; <http://naggum.no/lugm-time.html> for the choice of epoch here.
+;;; By starting the year in March, we avoid having to test the month
+;;; whenever deciding whether to account for a leap day. 2000 is
+;;; especially special, because it's divisible by 400, hence the start
+;;; of a 400 year leap year cycle
;;; If a universal-time is after time_t runs out, we find its offset
;;; from 1st March of whichever year it falls in, then add that to
;;; history (Perq time base?) could be cleaned up any on this basis.
;;; -- dan, 2003-08-08
+;;; In order to accomodate universal times between January 1st 1900
+;;; and sometime on December 13th 1901, I'm doing the same calculation
+;;; as described above in order to handle dates in that interval, by
+;;; normalizing them to March 1st 1903, which shares the same special
+;;; properties described above (except for the 400-year property, but
+;;; this isn't an issue for the limited range we need to handle).
+
+;;; One open issue is whether to pass UNIX a 64-bit time_t value on
+;;; 64-bit platforms. I don't know if time_t is always 64-bit on those
+;;; platforms, and looking at this file reveals a scary amount of
+;;; literal 31 and 32s.
+;;; -- bem, 2005-08-09
;;; Subtract from the returned Internal-Time to get the universal
;;; time. The offset between our time base and the Perq one is 2145
(defun get-universal-time ()
#!+sb-doc
- "Return a single integer for the current time of
- day in universal time format."
- (multiple-value-bind (res secs) (sb!unix:unix-gettimeofday)
- (declare (ignore res))
- (+ secs unix-to-universal-time)))
+ "Return a single integer for the current time of day in universal time
+format."
+ (+ (get-time-of-day) unix-to-universal-time))
(defun get-decoded-time ()
#!+sb-doc
(defconstant +mar-1-2000+ #.(encode-universal-time 0 0 0 1 3 2000 0))
(defconstant +mar-1-2035+ #.(encode-universal-time 0 0 0 1 3 2035 0))
+(defconstant +mar-1-1903+ #.(encode-universal-time 0 0 0 1 3 1903 0))
+
(defun years-since-mar-2000 (utime)
- "Returns number of complete years since March 1st 2000, and remainder in seconds"
+ "Returns number of complete years since March 1st 2000, and remainder in seconds"
(let* ((days-in-year (* 86400 365))
- (days-in-4year (+ (* 4 days-in-year) 86400))
- (days-in-100year (- (* 25 days-in-4year) 86400))
- (days-in-400year (+ (* 4 days-in-100year) 86400))
- (offset (- utime +mar-1-2000+))
- (year 0))
+ (days-in-4year (+ (* 4 days-in-year) 86400))
+ (days-in-100year (- (* 25 days-in-4year) 86400))
+ (days-in-400year (+ (* 4 days-in-100year) 86400))
+ (offset (- utime +mar-1-2000+))
+ (year 0))
(labels ((whole-num (x y inc max)
- (let ((w (truncate x y)))
- (when (and max (> w max)) (setf w max))
- (incf year (* w inc))
- (* w y))))
+ (let ((w (truncate x y)))
+ (when (and max (> w max)) (setf w max))
+ (incf year (* w inc))
+ (* w y))))
(decf offset (whole-num offset days-in-400year 400 nil))
(decf offset (whole-num offset days-in-100year 100 3))
(decf offset (whole-num offset days-in-4year 4 25))
(defun truncate-to-unix-range (utime)
(let ((unix-time (- utime unix-to-universal-time)))
- (if (< unix-time (ash 1 31))
- unix-time
- (multiple-value-bind (year offset) (years-since-mar-2000 utime)
- (declare (ignore year))
- (+ +mar-1-2035+ (- unix-to-universal-time) offset)))))
-
+ (cond
+ ((< unix-time (- (ash 1 31)))
+ (multiple-value-bind (year offset) (years-since-mar-2000 utime)
+ (declare (ignore year))
+ (+ +mar-1-1903+ (- unix-to-universal-time) offset)))
+ ((>= unix-time (ash 1 31))
+ (multiple-value-bind (year offset) (years-since-mar-2000 utime)
+ (declare (ignore year))
+ (+ +mar-1-2035+ (- unix-to-universal-time) offset)))
+ (t unix-time))))
+
(defun decode-universal-time (universal-time &optional time-zone)
#!+sb-doc
"Converts a universal-time to decoded time format returning the following
Completely ignores daylight-savings-time when time-zone is supplied."
(multiple-value-bind (daylight seconds-west)
(if time-zone
- (values nil (* time-zone 60 60))
- (multiple-value-bind (ignore seconds-west daylight)
- (sb!unix::get-timezone (truncate-to-unix-range universal-time))
- (declare (ignore ignore))
- (declare (fixnum seconds-west))
- (values daylight seconds-west)))
+ (values nil (* time-zone 60 60))
+ (multiple-value-bind (ignore seconds-west daylight)
+ (sb!unix::get-timezone (truncate-to-unix-range universal-time))
+ (declare (ignore ignore))
+ (declare (fixnum seconds-west))
+ (values daylight seconds-west)))
(declare (fixnum seconds-west))
(multiple-value-bind (weeks secs)
- (truncate (+ (- universal-time seconds-west) seconds-offset)
- seconds-in-week)
+ (truncate (+ (- universal-time seconds-west) seconds-offset)
+ seconds-in-week)
(let ((weeks (+ weeks weeks-offset)))
- (multiple-value-bind (t1 second)
- (truncate secs 60)
- (let ((tday (truncate t1 minutes-per-day)))
- (multiple-value-bind (hour minute)
- (truncate (- t1 (* tday minutes-per-day)) 60)
- (let* ((t2 (1- (* (+ (* weeks 7) tday november-17-1858) 4)))
- (tcent (truncate t2 quarter-days-per-century)))
- (setq t2 (mod t2 quarter-days-per-century))
- (setq t2 (+ (- t2 (mod t2 4)) 3))
- (let* ((year (+ (* tcent 100)
- (truncate t2 quarter-days-per-year)))
- (days-since-mar0
- (1+ (truncate (mod t2 quarter-days-per-year) 4)))
- (day (mod (+ tday weekday-november-17-1858) 7))
- (t3 (+ (* days-since-mar0 5) 456)))
- (cond ((>= t3 1989)
- (setq t3 (- t3 1836))
- (setq year (1+ year))))
- (multiple-value-bind (month t3)
- (truncate t3 153)
- (let ((date (1+ (truncate t3 5))))
- (values second minute hour date month year day
- daylight
- (if daylight
- (1+ (/ seconds-west 60 60))
- (/ seconds-west 60 60))))))))))))))
+ (multiple-value-bind (t1 second)
+ (truncate secs 60)
+ (let ((tday (truncate t1 minutes-per-day)))
+ (multiple-value-bind (hour minute)
+ (truncate (- t1 (* tday minutes-per-day)) 60)
+ (let* ((t2 (1- (* (+ (* weeks 7) tday november-17-1858) 4)))
+ (tcent (truncate t2 quarter-days-per-century)))
+ (setq t2 (mod t2 quarter-days-per-century))
+ (setq t2 (+ (- t2 (mod t2 4)) 3))
+ (let* ((year (+ (* tcent 100)
+ (truncate t2 quarter-days-per-year)))
+ (days-since-mar0
+ (1+ (truncate (mod t2 quarter-days-per-year) 4)))
+ (day (mod (+ tday weekday-november-17-1858) 7))
+ (t3 (+ (* days-since-mar0 5) 456)))
+ (cond ((>= t3 1989)
+ (setq t3 (- t3 1836))
+ (setq year (1+ year))))
+ (multiple-value-bind (month t3)
+ (truncate t3 153)
+ (let ((date (1+ (truncate t3 5))))
+ (values second minute hour date month year day
+ daylight
+ (if daylight
+ (1+ (/ seconds-west 60 60))
+ (/ seconds-west 60 60))))))))))))))
(defun pick-obvious-year (year)
(declare (type (mod 100) year))
(let* ((current-year (nth-value 5 (get-decoded-time)))
- (guess (+ year (* (truncate (- current-year 50) 100) 100))))
+ (guess (+ year (* (truncate (- current-year 50) 100) 100))))
(declare (type (integer 1900 9999) current-year guess))
(if (> (- current-year guess) 50)
- (+ guess 100)
- guess)))
+ (+ guess 100)
+ guess)))
(defun leap-years-before (year)
(let ((years (- year 1901)))
(+ (- (truncate years 4)
- (truncate years 100))
+ (truncate years 100))
(truncate (+ years 300) 400))))
(defvar *days-before-month*
#.(let ((reversed-result nil)
- (sum 0))
+ (sum 0))
(push nil reversed-result)
(dolist (days-in-month '(31 28 31 30 31 30 31 31 30 31 30 31))
- (push sum reversed-result)
- (incf sum days-in-month))
+ (push sum reversed-result)
+ (incf sum days-in-month))
(coerce (nreverse reversed-result) 'simple-vector)))
-
+
(defun encode-universal-time (second minute hour date month year
- &optional time-zone)
+ &optional time-zone)
#!+sb-doc
"The time values specified in decoded format are converted to
universal time, which is returned."
(declare (type (mod 60) second)
- (type (mod 60) minute)
- (type (mod 24) hour)
- (type (integer 1 31) date)
- (type (integer 1 12) month)
- (type (or (integer 0 99) (integer 1900)) year)
- (type (or null rational) time-zone))
+ (type (mod 60) minute)
+ (type (mod 24) hour)
+ (type (integer 1 31) date)
+ (type (integer 1 12) month)
+ (type (or (integer 0 99) (integer 1899)) year)
+ ;; that type used to say (integer 1900), but that's
+ ;; incorrect when a time-zone is specified: we should be
+ ;; able to encode to produce 0 when a non-zero timezone is
+ ;; specified - bem, 2005-08-09
+ (type (or null rational) time-zone))
(let* ((year (if (< year 100)
- (pick-obvious-year year)
- year))
- (days (+ (1- date)
- (aref *days-before-month* month)
- (if (> month 2)
- (leap-years-before (1+ year))
- (leap-years-before year))
- (* (- year 1900) 365)))
- (hours (+ hour (* days 24))))
+ (pick-obvious-year year)
+ year))
+ (days (+ (1- date)
+ (aref *days-before-month* month)
+ (if (> month 2)
+ (leap-years-before (1+ year))
+ (leap-years-before year))
+ (* (- year 1900) 365)))
+ (hours (+ hour (* days 24)))
+ (encoded-time 0))
(if time-zone
- (+ second (* (+ minute (* (+ hours time-zone) 60)) 60))
- ;; can't ask unix for times after 2037: this is only a problem
- ;; if we need to query the system timezone
- (if (> year 2037)
- (labels ((leap-year-p (year)
- (cond ((zerop (mod year 400)) t)
- ((zerop (mod year 100)) nil)
- ((zerop (mod year 4)) t)
- (t nil))))
- (let* ((fake-year (if (leap-year-p year) 2036 2037))
- (fake-time (encode-universal-time second minute hour
- date month fake-year)))
- (+ fake-time
- (* 86400 (+ (* 365 (- year fake-year))
- (- (leap-years-before year)
- (leap-years-before fake-year)))))))
- (let* ((secwest-guess
- (sb!unix::unix-get-seconds-west
- (- (* hours 60 60) unix-to-universal-time)))
- (guess (+ second (* 60 (+ minute (* hours 60)))
- secwest-guess))
- (secwest
- (sb!unix::unix-get-seconds-west
- (- guess unix-to-universal-time))))
- (+ guess (- secwest secwest-guess)))))))
+ (setf encoded-time (+ second (* (+ minute (* (+ hours time-zone) 60)) 60)))
+ (let* ((secwest-guess
+ (sb!unix::unix-get-seconds-west
+ (truncate-to-unix-range (* hours 60 60))))
+ (guess (+ second (* 60 (+ minute (* hours 60)))
+ secwest-guess))
+ (secwest
+ (sb!unix::unix-get-seconds-west
+ (truncate-to-unix-range guess))))
+ (setf encoded-time (+ guess (- secwest secwest-guess)))))
+ (assert (typep encoded-time '(integer 0)))
+ encoded-time))
\f
;;;; TIME
(defvar *gc-run-time* 0
#!+sb-doc
- "the total CPU time spent doing garbage collection (as reported by
- GET-INTERNAL-RUN-TIME)")
+ "Total CPU time spent doing garbage collection (as reported by
+GET-INTERNAL-RUN-TIME.) Initialized to zero on startup. It is safe to bind
+this to zero in order to measure GC time inside a certain section of code, but
+doing so may interfere with results reported by eg. TIME.")
(declaim (type index *gc-run-time*))
+(defun print-time (&key real-time-ms user-run-time-us system-run-time-us
+ gc-run-time-ms processor-cycles eval-calls
+ lambdas-converted page-faults bytes-consed
+ aborted)
+ (let ((total-run-time-us (+ user-run-time-us system-run-time-us)))
+ (format *trace-output*
+ "~&Evaluation took:~%~
+ ~@< ~@;~/sb-impl::format-milliseconds/ of real time~%~
+ ~/sb-impl::format-microseconds/ of total run time ~
+ (~@/sb-impl::format-microseconds/ user, ~@/sb-impl::format-microseconds/ system)~%~
+ ~[[ Run times consist of ~/sb-impl::format-milliseconds/ GC time, ~
+ and ~/sb-impl::format-milliseconds/ non-GC time. ]~%~;~2*~]~
+ ~,2F% CPU~%~
+ ~@[~:D form~:P interpreted~%~]~
+ ~@[~:D lambda~:P converted~%~]~
+ ~@[~:D processor cycles~%~]~
+ ~@[~:D page fault~:P~%~]~
+ ~:D bytes consed~%~
+ ~@[~%before it was aborted by a non-local transfer of control.~%~]~:>~%"
+ real-time-ms
+ total-run-time-us
+ user-run-time-us
+ system-run-time-us
+ (if (zerop gc-run-time-ms) 1 0)
+ gc-run-time-ms
+ ;; Round up so we don't mislead by saying 0.0 seconds of non-GC time...
+ (- (ceiling total-run-time-us 1000) gc-run-time-ms)
+ (if (zerop real-time-ms)
+ 100.0
+ (float (* 100 (/ (round total-run-time-us 1000) real-time-ms))))
+ eval-calls
+ lambdas-converted
+ processor-cycles
+ page-faults
+ bytes-consed
+ aborted)))
+
(defmacro time (form)
#!+sb-doc
- "Execute FORM and print timing information on *TRACE-OUTPUT*."
- `(%time (lambda () ,form)))
+ "Execute FORM and print timing information on *TRACE-OUTPUT*.
+
+On some hardware platforms estimated processor cycle counts are
+included in this output; this number is slightly inflated, since it
+includes the pipeline involved in reading the cycle counter --
+executing \(TIME NIL) a few times will give you an idea of the
+overhead, and its variance. The cycle counters are also per processor,
+not per thread: if multiple threads are running on the same processor,
+the reported counts will include cycles taken up by all threads
+running on the processor where TIME was executed. Furthermore, if the
+operating system migrates the thread to another processor between
+reads of the cycle counter, the results will be completely bogus.
+Finally, the counter is cycle counter, incremented by the hardware
+even when the process is halted -- which is to say that cycles pass
+normally during operations like SLEEP."
+ `(call-with-timing #'print-time (lambda () ,form)))
;;; Return all the data that we want TIME to report.
(defun time-get-sys-info ()
(multiple-value-bind (user sys faults) (sb!sys:get-system-info)
(values user sys faults (get-bytes-consed))))
+(defun elapsed-cycles (h0 l0 h1 l1)
+ (declare (ignorable h0 l0 h1 l1))
+ #!+cycle-counter
+ (+ (ash (- h1 h0) 32)
+ (- l1 l0))
+ #!-cycle-counter
+ nil)
+(declaim (inline read-cycle-counter))
+(defun read-cycle-counter ()
+ #!+cycle-counter
+ (sb!vm::%read-cycle-counter)
+ #!-cycle-counter
+ (values 0 0))
+
+;;; This is so that we don't have to worry about the vagaries of
+;;; floating point printing, or about conversions to floats dropping
+;;; or introducing decimals, which are liable to imply wrong precision.
+(defun format-microseconds (stream usec &optional colonp atp)
+ (declare (ignore colonp))
+ (%format-decimal stream usec 6)
+ (unless atp
+ (write-string " seconds" stream)))
+
+(defun format-milliseconds (stream usec &optional colonp atp)
+ (declare (ignore colonp))
+ (%format-decimal stream usec 3)
+ (unless atp
+ (write-string " seconds" stream)))
+
+(defun %format-decimal (stream number power)
+ (declare (stream stream)
+ (integer number power))
+ (when (minusp number)
+ (write-char #\- stream)
+ (setf number (- number)))
+ (let ((scale (expt 10 power)))
+ (labels ((%fraction (fraction)
+ (if (zerop fraction)
+ (%zeroes)
+ (let ((scaled (* 10 fraction)))
+ (loop while (< scaled scale)
+ do (write-char #\0 stream)
+ (setf scaled (* scaled 10)))))
+ (format stream "~D" fraction))
+ (%zeroes ()
+ (let ((scaled (/ scale 10)))
+ (write-char #\0 stream)
+ (loop while (> scaled 1)
+ do (write-char #\0 stream)
+ (setf scaled (/ scaled 10))))))
+ (cond ((zerop number)
+ (write-string "0." stream)
+ (%zeroes))
+ ((< number scale)
+ (write-string "0." stream)
+ (%fraction number))
+ ((= number scale)
+ (write-string "1." stream)
+ (%zeroes))
+ ((> number scale)
+ (multiple-value-bind (whole fraction) (floor number scale)
+ (format stream "~D." whole)
+ (%fraction fraction))))))
+ nil)
+
;;; The guts of the TIME macro. Compute overheads, run the (compiled)
;;; function, report the times.
-(defun %time (fun)
- (declare (type function fun))
+(defun call-with-timing (timer function &rest arguments)
+ #!+sb-doc
+ "Calls FUNCTION with ARGUMENTS, and gathers timing information about it.
+Then calls TIMER with keyword arguments describing the information collected.
+Calls TIMER even if FUNCTION performs a non-local transfer of control. Finally
+returns values returned by FUNCTION.
+
+ :USER-RUN-TIME-US
+ User run time in microseconds.
+
+ :SYSTEM-RUN-TIME-US
+ System run time in microseconds.
+
+ :REAL-TIME-MS
+ Real time in milliseconds.
+
+ :GC-RUN-TIME-MS
+ GC run time in milliseconds (included in user and system run time.)
+
+ :PROCESSOR-CYCLES
+ Approximate number of processor cycles used. (Omitted if not supported on
+ the platform -- currently available on x86 and x86-64 only.)
+
+ :EVAL-CALLS
+ Number of calls to EVAL. (Omitted if zero.)
+
+ :LAMBDAS-CONVERTED
+ Number of lambdas converted. (Omitted if zero.)
+
+ :PAGE-FAULTS
+ Number of page faults. (Omitted if zero.)
+
+ :BYTES-CONSED
+ Approximate number of bytes consed.
+
+ :ABORTED
+ True if FUNCTION caused a non-local transfer of control. (Omitted if
+ NIL.)
+
+EXPERIMENTAL: Interface subject to change."
(let (old-run-utime
- new-run-utime
- old-run-stime
- new-run-stime
- old-real-time
- new-real-time
- old-page-faults
- new-page-faults
- real-time-overhead
- run-utime-overhead
- run-stime-overhead
- page-faults-overhead
- old-bytes-consed
- new-bytes-consed
- cons-overhead)
+ new-run-utime
+ old-run-stime
+ new-run-stime
+ old-real-time
+ new-real-time
+ old-page-faults
+ new-page-faults
+ real-time-overhead
+ run-utime-overhead
+ run-stime-overhead
+ page-faults-overhead
+ old-bytes-consed
+ new-bytes-consed
+ cons-overhead
+ (fun (if (functionp function) function (fdefinition function))))
+ (declare (function fun))
;; Calculate the overhead...
(multiple-value-setq
- (old-run-utime old-run-stime old-page-faults old-bytes-consed)
+ (old-run-utime old-run-stime old-page-faults old-bytes-consed)
(time-get-sys-info))
;; Do it a second time to make sure everything is faulted in.
(multiple-value-setq
- (old-run-utime old-run-stime old-page-faults old-bytes-consed)
+ (old-run-utime old-run-stime old-page-faults old-bytes-consed)
(time-get-sys-info))
(multiple-value-setq
- (new-run-utime new-run-stime new-page-faults new-bytes-consed)
+ (new-run-utime new-run-stime new-page-faults new-bytes-consed)
(time-get-sys-info))
(setq run-utime-overhead (- new-run-utime old-run-utime))
(setq run-stime-overhead (- new-run-stime old-run-stime))
(setq cons-overhead (- new-bytes-consed old-bytes-consed))
;; Now get the initial times.
(multiple-value-setq
- (old-run-utime old-run-stime old-page-faults old-bytes-consed)
+ (old-run-utime old-run-stime old-page-faults old-bytes-consed)
(time-get-sys-info))
(setq old-real-time (get-internal-real-time))
- (let ((start-gc-run-time *gc-run-time*))
- (multiple-value-prog1
- ;; Execute the form and return its values.
- (funcall fun)
- (multiple-value-setq
- (new-run-utime new-run-stime new-page-faults new-bytes-consed)
- (time-get-sys-info))
- (setq new-real-time (- (get-internal-real-time) real-time-overhead))
- (let ((gc-run-time (max (- *gc-run-time* start-gc-run-time) 0)))
- (format *trace-output*
- "~&Evaluation took:~% ~
- ~S second~:P of real time~% ~
- ~S second~:P of user run time~% ~
- ~S second~:P of system run time~% ~
-~@[ [Run times include ~S second~:P GC run time.]~% ~]~
- ~S page fault~:P and~% ~
- ~:D bytes consed.~%"
- (max (/ (- new-real-time old-real-time)
- (float sb!xc:internal-time-units-per-second))
- 0.0)
- (max (/ (- new-run-utime old-run-utime) 1000000.0) 0.0)
- (max (/ (- new-run-stime old-run-stime) 1000000.0) 0.0)
- (unless (zerop gc-run-time)
- (/ (float gc-run-time)
- (float sb!xc:internal-time-units-per-second)))
- (max (- new-page-faults old-page-faults) 0)
- (max (- new-bytes-consed old-bytes-consed) 0)))))))
+ (let ((start-gc-internal-run-time *gc-run-time*)
+ (*eval-calls* 0)
+ (sb!c::*lambda-conversions* 0)
+ (aborted t))
+ (declare (special *eval-calls* sb!c::*lambda-conversions*))
+ (multiple-value-bind (h0 l0) (read-cycle-counter)
+ (unwind-protect
+ (multiple-value-prog1 (apply fun arguments)
+ (setf aborted nil))
+ (multiple-value-bind (h1 l1) (read-cycle-counter)
+ (let ((stop-gc-internal-run-time *gc-run-time*))
+ (multiple-value-setq
+ (new-run-utime new-run-stime new-page-faults new-bytes-consed)
+ (time-get-sys-info))
+ (setq new-real-time (- (get-internal-real-time) real-time-overhead))
+ (let* ((gc-internal-run-time (max (- stop-gc-internal-run-time start-gc-internal-run-time) 0))
+ (real-time (max (- new-real-time old-real-time) 0))
+ (user-run-time (max (- new-run-utime old-run-utime) 0))
+ (system-run-time (max (- new-run-stime old-run-stime) 0))
+ (cycles (elapsed-cycles h0 l0 h1 l1))
+ (page-faults (max (- new-page-faults old-page-faults) 0)))
+ (let (plist)
+ (flet ((note (name value &optional test)
+ (unless (and test (funcall test value))
+ (setf plist (list* name value plist)))))
+ (note :aborted aborted #'not)
+ (note :bytes-consed (max (- new-bytes-consed old-bytes-consed) 0))
+ (note :page-faults page-faults #'zerop)
+ ;; cycle counting isn't supported everywhere.
+ (when cycles
+ (note :processor-cycles cycles #'zerop)
+ (note :lambdas-converted sb!c::*lambda-conversions* #'zerop))
+ (note :eval-calls *eval-calls* #'zerop)
+ (note :gc-run-time-ms gc-internal-run-time)
+ (note :system-run-time-us system-run-time)
+ (note :user-run-time-us user-run-time)
+ (note :real-time-ms real-time))
+ (apply timer plist))))))))))