ikarus/benchmarks.larceny/src/gcbench.scm

;  This is adapted from a benchmark written by John Ellis and Pete Kovac
;  of Post Communications.
;  It was modified by Hans Boehm of Silicon Graphics.
;  It was translated into Scheme by William D Clinger of Northeastern Univ;
;    the Scheme version uses (RUN-BENCHMARK <string> <thunk>)
;  Last modified 30 May 1997.
; 
;       This is no substitute for real applications.  No actual application
;       is likely to behave in exactly this way.  However, this benchmark was
;       designed to be more representative of real applications than other
;       Java GC benchmarks of which we are aware.
;       It attempts to model those properties of allocation requests that
;       are important to current GC techniques.
;       It is designed to be used either to obtain a single overall performance
;       number, or to give a more detailed estimate of how collector
;       performance varies with object lifetimes.  It prints the time
;       required to allocate and collect balanced binary trees of various
;       sizes.  Smaller trees result in shorter object lifetimes.  Each cycle
;       allocates roughly the same amount of memory.
;       Two data structures are kept around during the entire process, so
;       that the measured performance is representative of applications
;       that maintain some live in-memory data.  One of these is a tree
;       containing many pointers.  The other is a large array containing
;       double precision floating point numbers.  Both should be of comparable
;       size.
; 
;       The results are only really meaningful together with a specification
;       of how much memory was used.  It is possible to trade memory for
;       better time performance.  This benchmark should be run in a 32 MB
;       heap, though we don't currently know how to enforce that uniformly.

; In the Java version, this routine prints the heap size and the amount
; of free memory.  There is no portable way to do this in Scheme; each
; implementation needs its own version.

(define (run-benchmark2 name thunk)
  (display name)
  (newline)
  (thunk))

(define (PrintDiagnostics)
  (display " Total memory available= ???????? bytes")
  (display "  Free memory= ???????? bytes")
  (newline))

(define (gcbench kStretchTreeDepth)
  
  ;  Nodes used by a tree of a given size
  (define (TreeSize i)
    (- (expt 2 (+ i 1)) 1))
  
  ;  Number of iterations to use for a given tree depth
  (define (NumIters i)
    (quotient (* 2 (TreeSize kStretchTreeDepth))
              (TreeSize i)))
  
  ;  Parameters are determined by kStretchTreeDepth.
  ;  In Boehm's version the parameters were fixed as follows:
  ;    public static final int kStretchTreeDepth    = 18;  // about 16Mb
  ;    public static final int kLongLivedTreeDepth  = 16;  // about 4Mb
  ;    public static final int kArraySize  = 500000;       // about 4Mb
  ;    public static final int kMinTreeDepth = 4;
  ;    public static final int kMaxTreeDepth = 16;
  ;  In Larceny the storage numbers above would be 12 Mby, 3 Mby, 6 Mby.
  
  (let* ((kLongLivedTreeDepth (- kStretchTreeDepth 2))
         (kArraySize          (* 4 (TreeSize kLongLivedTreeDepth)))
         (kMinTreeDepth       4)
         (kMaxTreeDepth       kLongLivedTreeDepth))
    
    ; Elements 3 and 4 of the allocated vectors are useless.
    
    (let* ((make-empty-node (lambda () (make-vector 4 0)))
           (make-node
            (lambda (l r)
              (let ((v (make-empty-node)))
                (vector-set! v 0 l)
                (vector-set! v 1 r)
                v)))
           (node.left (lambda (node) (vector-ref node 0)))
           (node.right (lambda (node) (vector-ref node 1)))
           (node.left-set! (lambda (node x) (vector-set! node 0 x)))
           (node.right-set! (lambda (node x) (vector-set! node 1 x))))
      
      ;  Build tree top down, assigning to older objects.
      (define (Populate iDepth thisNode)
        (if (<= iDepth 0)
            #f
            (let ((iDepth (- iDepth 1)))
              (node.left-set! thisNode (make-empty-node))
              (node.right-set! thisNode (make-empty-node))
              (Populate iDepth (node.left thisNode))
              (Populate iDepth (node.right thisNode)))))
      
      ;  Build tree bottom-up
      (define (MakeTree iDepth)
        (if (<= iDepth 0)
            (make-empty-node)
            (make-node (MakeTree (- iDepth 1))
                       (MakeTree (- iDepth 1)))))
      
      (define (TimeConstruction depth)
        (let ((iNumIters (NumIters depth)))
          (display (string-append "Creating "
                                  (number->string iNumIters)
                                  " trees of depth "
                                  (number->string depth)))
          (newline)
          (run-benchmark2
           "GCBench: Top down construction"
           (lambda ()
             (do ((i 0 (+ i 1)))
                 ((>= i iNumIters))
               (Populate depth (make-empty-node)))))
          (run-benchmark2
           "GCBench: Bottom up construction"
           (lambda ()
             (do ((i 0 (+ i 1)))
                 ((>= i iNumIters))
               (MakeTree depth))))))
      
      (define (main)
        (display "Garbage Collector Test")
        (newline)
        (display (string-append
                  " Stretching memory with a binary tree of depth "
                  (number->string kStretchTreeDepth)))
        (newline)
        (PrintDiagnostics)
        (run-benchmark2
         "GCBench: Main"
         (lambda ()
           ;  Stretch the memory space quickly
           (MakeTree kStretchTreeDepth)
                         
           ;  Create a long lived object
           (display (string-append
                     " Creating a long-lived binary tree of depth "
                     (number->string kLongLivedTreeDepth)))
           (newline)
           (let ((longLivedTree (make-empty-node)))
             (Populate kLongLivedTreeDepth longLivedTree)
                           
             ;  Create long-lived array, filling half of it
             (display (string-append
                       " Creating a long-lived array of "
                       (number->string kArraySize)
                       " inexact reals"))
             (newline)
             (let ((array (make-vector kArraySize 0.0)))
               (do ((i 0 (+ i 1)))
                   ((>= i (quotient kArraySize 2)))
                 (vector-set! array i (/ 1.0 (exact->inexact (+ i 1)))))
               (PrintDiagnostics)
                             
               (do ((d kMinTreeDepth (+ d 2)))
                   ((> d kMaxTreeDepth))
                 (TimeConstruction d))
                             
               (if (or (eq? longLivedTree '())
                       (let ((n (min 1000
                                     (- (quotient (vector-length array)
                                                  2)
                                        1))))
                         (not (FLOAT= (vector-ref array n)
                                      (/ 1.0 (exact->inexact (+ n 1)))))))
                   (begin (display "Failed") (newline)))
               ;  fake reference to LongLivedTree
               ;  and array
               ;  to keep them from being optimized away
               ))))
        (PrintDiagnostics))
      
      (main))))

(define (main . rest)
  (let ((k (if (null? rest) 18 (car rest))))
    (display "The garbage collector should touch about ")
    (display (expt 2 (- k 13)))
    (display " megabytes of heap storage.")
    (newline)
    (display "The use of more or less memory will skew the results.")
    (newline)
    (run-benchmark
      (string-append "GCBench" (number->string k))
      gcbench-iters
      (lambda (result) #t)
      (lambda (k) (lambda () (gcbench k)))
      k)))