ikarus/benchmarks.larceny/src/gcbench.sml

192 lines
6.9 KiB
Standard ML

(*
; 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,
; and modified for compatibility with the Gambit benchmark suite.
; It was translated into Standard ML by William D Clinger.
; Last modified 6 July 1999.
;
; 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.
*)
datatype Tree = Dummy
| Node of { left: Tree ref, right: Tree ref, i: int, j: int }
fun make_empty_node () =
Node { left= ref Dummy, right= ref Dummy, i= 0, j= 0 }
fun make_node (l, r) =
Node { left= ref l, right= ref r, i= 0, j= 0 }
fun PrintDiagnostics () = ()
fun gcbench kStretchTreeDepth =
let open Int
fun expt (m:int, n:int) =
if n = 0 then 1 else m * expt (m, n - 1)
(* Nodes used by a tree of a given size *)
fun TreeSize i =
expt (2, i + 1) - 1
(* Number of iterations to use for a given tree depth *)
fun NumIters i =
(2 * (TreeSize kStretchTreeDepth)) div (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.
*)
val kLongLivedTreeDepth = kStretchTreeDepth - 2
val kArraySize = 4 * (TreeSize kLongLivedTreeDepth)
val kMinTreeDepth = 4
val kMaxTreeDepth = kLongLivedTreeDepth
(* Build tree top down, assigning to older objects. *)
fun Populate (iDepth, Node { left=lr, right=rr, i, j }) =
if iDepth <= 0
then false
else let val iDepth = iDepth - 1
in
(
lr := make_empty_node();
rr := make_empty_node();
Populate (iDepth, !lr);
Populate (iDepth, !rr)
)
end
(* Build tree bottom-up *)
fun MakeTree iDepth =
if iDepth <= 0
then make_empty_node()
else make_node (MakeTree (iDepth - 1),
MakeTree (iDepth - 1))
fun TimeConstruction depth =
let val iNumIters = NumIters depth
in
(
print (concat ["Creating ",
toString iNumIters,
" trees of depth ",
toString depth,
"\n"]);
let fun loop i =
if i < iNumIters
then (Populate (depth, make_empty_node());
loop (i + 1))
else ()
in loop 0
end;
let fun loop i =
if i < iNumIters
then (MakeTree depth;
loop (i + 1))
else ()
in loop 0
end
)
end
fun main () =
(
print "Garbage Collector Test\n";
print (concat [" Stretching memory with a binary tree of depth ",
toString kStretchTreeDepth,
"\n"]);
PrintDiagnostics();
(* Stretch the memory space quickly *)
MakeTree kStretchTreeDepth;
(* Create a long lived object *)
print (concat[" Creating a long-lived binary tree of depth ",
toString kLongLivedTreeDepth,
"\n"]);
let val longLivedTree = make_empty_node()
in
(
Populate (kLongLivedTreeDepth, longLivedTree);
(* Create long-lived array, filling half of it *)
print (concat [" Creating a long-lived array of ",
toString kArraySize,
" inexact reals\n"]);
let open Array
val arr = array (kArraySize, 0.0)
fun loop1 i =
if i < (kArraySize div 2)
then (update (arr, i, 1.0/(Real.fromInt(i)));
loop1 (i + 1))
else ()
fun loop2 d =
if d <= kMaxTreeDepth
then (TimeConstruction d;
loop2 (d + 2))
else ()
in
(
loop1 0;
PrintDiagnostics();
loop2 kMinTreeDepth;
if (longLivedTree = Dummy)
orelse
let val n = min (1000, (length(arr) div 2) - 1)
in Real.!= (sub (arr, n), (1.0 / Real.fromInt(n)))
end
then print "Failed\n"
else ()
(* fake reference to LongLivedTree
and array to keep them from being optimized away
*)
)
end)
end;
PrintDiagnostics())
in main()
end
fun main () =
run_benchmark ("gcbench",
1,
fn () => gcbench 18,
fn (result) => true)